KR20190114607A - Future Energy Generation System Implementation Method and Its Generation System - Google Patents

Abstract

The present invention relates to a method for implementing a future energy generation system and a power generation system therefor and, more specifically, to a method for implementing a future energy generation system that generates electricity in a clean, economical, and safe manner and generates future energy by using a photovoltaic generation method. According to an embodiment of the present invention, a method for implementing a future energy generation system comprises the steps of: configuring a charging station that performs at least one of the functions of generating electricity economically in a clean and safe manner and storing the electricity in an electricity storage device, or receiving the electricity generated by a future energy generation method and transferring the electricity to an electricity consumer; configuring the electricity storage device for transferring the electricity of the charging station by a wireless transfer method; configuring a wireless transfer means of the electricity storage device such that the electricity storage device can perform the wireless transfer method; configuring an electricity consumer using the electricity supplied from the charging station; and transferring the electricity generated at or supplied from the charging station to the electricity consumer by the wireless transfer method by the wireless transfer means of the electricity storage device that stores or maintains a charged state.

Description

Future Energy Generation System Implementation Method and Its Generation System

The present invention relates to a method for implementing a future energy power generation system and a power generation system, and more particularly, a future energy power generation system for producing (powering) and producing future power (power generation) of clean and economical electricity in a photovoltaic manner. It relates to an implementation method and a power generation system thereof.

Coal, oil, and natural gas, fossil fuels that make up about 80% of the energy used by humans, are being depleted.

Currently, petroleum, which is used most as an energy source, is mainly used as a fuel for transportation, and natural gas generated from the upper part of crude oil is made into a liquid state and used as a raw material for chemical products or heating gas.

However, the consumption of fossil fuels has doubled every 20 years since 1900, and environmental scientists expect fossil fuels to disappear in the next 50 to 200 years.

In addition, fossil fuels are a major contributor to environmental pollution, and in particular, petroleum emits carbon, which is one of the greenhouse gases.

The environmental pollution of fossil fuels has aggravated global warming and fine dust pollution, threatening the spread of abnormal climate change and human health.

Meanwhile, nuclear power plants developed by humans to replace fossil fuels also operate nuclear power plants due to the risks and management problems of nuclear power plants in the wake of the US Dracmile power plant, the Roca accident, the former Soviet Union Chernobyl accident, and the Fukushima nuclear accident during the recent Great East Japan Earthquake. The reduction or complete closure only realized that mankind could live a safer life.

Therefore, in order to solve the problem of energy depletion such as fossil fuel depletion and the serious side effects such as environmental pollution caused by fossil fuel consumption, and also to reduce or completely shut down nuclear power plants, the future humanity must always use the new future energy. A major change is needed.

Therefore, human beings are now choosing green energy or renewable energy as future energy that can replace the energy (including electricity) produced by the existing fossil fuels, nuclear power plants, and nuclear power plants. In particular, the only energy production method with optimal conditions is the future energy production method of mankind that can produce a large amount of electricity (power) indefinitely in a clean way (without pollution fine dust carbon emission) and can produce almost permanently. That's solar power.

Therefore, human beings prefer solar power generation as the future energy production technology, and are investing heavily in the development of solar power technology and facilities.

However, at present, the production (power generation) technology and the delivery (transmission) technology (method) of photovoltaic electricity developed by human beings are underdeveloped and face technical limitations. The proliferation of power generation is stagnating or slowing down,

The deterioration (technical limitations) of the production (power generation) technology and the delivery (transmission) technology (method) is based on solar power generation, which is the energy of the future (including electricity) produced by existing fossil fuels, nuclear power plants, and nuclear power plants. It is the biggest reason for not realizing the hope of mankind to replace it with electric energy.

At present, humanity is still This is because the underdevelopment (limitation) of the production (power generation) technology (method) and the delivery (transmission) technology (method) is not overcome, and the following problems are not solved (overcome).

First, electricity (energy) produced by photovoltaic power generation does not overcome economic problems.

As described above, among the renewable energy or green energy, as a future energy of the future of humankind, it is possible to produce a large amount of electricity (electric power) indefinitely in a clean manner (without pollution fine dust carbon emission) and to produce almost permanently. The only optimal energy production method is solar power generation.

The photovoltaic power generation method has a very small amount of electricity (power) produced as compared to the area (place, space, etc.) occupied by photovoltaic power generation facilities, and thus the electricity (energy) produced in this way is not economical.

In particular, such urban areas, factory areas, industrial complexes, etc., if the land (expensive land) is expensive and occupies this expensive land and produces and operates a small amount of electric energy, it is produced here. The production cost of electricity is inevitably high, and thus the economy and its competitiveness are lost compared to electricity produced by consuming existing fossil fuels or electricity produced by nuclear power plants.

In addition, in large urban apartments, buildings, factories, and industrial complexes that require large amounts of electric energy, there are few or small spaces for installing renewable energy or green energy production facilities. There are too many problems, such that the installation of photovoltaic power generation facilities in such a narrow place can not easily meet the demand for large amounts of electricity (power) by the amount of electricity (power) produced here.

Therefore, the installation of green energy or renewable energy production facilities in places where the actual demand for electricity (electric power) such as cities, industrial complexes, factory areas, etc. is required in large quantities has no merit. The most detrimental factor for humans' dreams to replace many energy problems such as fossil fuels and nuclear power plants with the proliferation of new renewable energy and green energy production facilities and future energy through mass production. It becomes (problem).

However, human beings today do not have the technology to overcome these problems.

Second, due to the technical limitations of the existing electric transfer method (power transmission method by power line), it is not overcoming the problem of not fully utilizing the optimal places for more economical and mass production of photovoltaic electricity (energy).

As described above in the first problem, the photovoltaic power generation facility needs a large area, and in order to produce such a photovoltaic electricity more economically and in large quantities,

The land (land value) is not expensive at all, and it is wide and spacious, so that it is more economical and easy to produce a large amount of electric energy only if it has a condition to install large-scale photovoltaic facilities.

One example of this is the installation of photovoltaic facilities and the production of photovoltaic electricity.

 Distant seas, distant seas of wide lakes, distant rivers of wide rivers, distant seas of wide dams, and vast open waters with no other land price,

Any one or more of Selecting and installing the photovoltaic power generation facility at the selected place thus selects a place having an optimal condition.

However, the above water (distant) places such as the far sea can cool the heat of the photovoltaic module constituting the photovoltaic facility sufficiently with water, which makes the photovoltaic module more efficient in producing electricity. The sunlight is stronger, and there is no blockage, so the time to shine is longer, and the overall advantage is to greatly increase the electricity (power) production,

In addition, the large area (ground value) occupied by photovoltaic power generation facilities is free of charge, and the vast open area is uniform, so that the optimal conditions for producing a large amount of electricity (electric power) by installing a large amount of photovoltaic facilities are provided. On the other hand, there are so many advantages,

Disadvantages, most of these sites (on the water) require the installation of submarine cables with existing technology (transmission through power lines) in order to transfer large quantities of electricity produced here to land. By increasing even more, it is a big factor to greatly increase the cost of photovoltaic electricity generation, and also the distance to the power line (transmission line) connected to the city center or factory area that actually consumes the generated electricity. It is farther away from each other, so if the transmission line using the existing power line is installed, the cost is also enormously larger, and as the transmission distance increases, the power loss rate increases even more.

Therefore, as a result, in selecting the method of transporting the electricity produced (generated) in the large-scale photovoltaic facilities installed on the distant waters such as the far sea to a place (a city, a factory area, etc.) that consumes a large amount. In this case, it becomes difficult to meet the economics of the existing wired transfer method (power transmission method through power lines), and the present humanity cannot use it as a place for producing photovoltaic electricity on distant waters such as the sea. I'm facing

Human beings of today cannot overcome the problem of not using solar power as a place for producing photovoltaic electricity on distant waters, such as the sea, which is the best place to produce such a large amount of photovoltaic electricity very cheaply and economically. I don't have a technique.

Third, the existing photovoltaic facility technology developed by mankind has not overcome the problem that the base load can not handle.

In order to be able to solve the energy problem of humanity in the future,

In order for solar power to replace electricity from coal or nuclear power plants, and solar power plants to replace nuclear power plants or thermal power plants, the photovoltaic electricity produced by humans in the future, It must be able to handle the base load.

However, the technology of photovoltaic facilities developed by mankind now produces electricity (power generation) only during a short time (3 to 5 hours) during the day when the sun rises 24 hours a day. It is impossible to cover all base loads for 24 hours by replacing coal fires, and the problems of existing fossil fuels and nuclear power plants cannot realize human dreams to replace many energies. Another big problem is that.

However, human beings are currently using photovoltaic electricity generated by conventional solar power facilities. They do not have the technology to handle the base load.

Fourthly, humanity is now able to produce the photovoltaic electricity in a clean way (without pollution fine dust carbon emissions), almost indefinitely, almost permanently, and with no safety risks such as nuclear power plants. Method).

In the future, the energy used by mankind is too much, and the amount of energy used is continuously rising.

This future energy must be able to be continuously produced in an enduring (eternal) way without depletion of energy, and must be produced in such a way that the amount of energy can be produced almost indefinitely so that no humans can use it in the future. It will be able to be qualified as a new future energy of mankind, and this future energy must be produced in a clean and pollution-free way so that it does not cause environmental pollution problems such as fossil fuels, and it is produced without any safety risks such as nuclear power plants. Should be.

However, human beings do not have the production technology for the future energy or the method of realizing it.

Publication No. 10-2017-0124379 (Published 10 November 2017)

The present invention has been made to solve the above-described problems, and an object thereof is to provide a method for implementing a future energy generation system and a power generation system which can produce electricity (energy) economically by a photovoltaic generation method.

In addition, another object of the present invention is to provide a future energy generation system implementation method and a power generation system that can fully utilize the optimal places to produce more photovoltaic electricity (energy) more economically and mass production.

In addition, another object of the present invention is to provide a method for implementing a future energy generation system having a photovoltaic facility technology that can handle the base load and its power generation system.

And another object of the present invention is to be able to produce photovoltaic electricity in a clean way (without pollution fine dust carbon emissions), almost indefinitely, almost permanently, and with no safety risks such as nuclear power plants. The present invention provides a method of implementing a future energy power generation system having a technology and a power generation system thereof.

The future energy generation system implementation method according to an embodiment of the present invention for achieving the above object (a) to produce (generate) economical electricity in a clean and safe manner (stored) or stored in the electrical storage device (charge), future energy Comprising a charging station that performs any one or more of the role of receiving the electricity (produced) produced by the production method and delivering to the electrical consumer;

(b) constructing an electrical storage device for transferring electricity of the charging station by a wireless transfer method;

(c) configuring an electrical storage device wireless transfer means to enable the electrical storage device to perform a wireless transfer method;

(d) constructing an electrical consumer using (consuming) electricity supplied from the charging station; And

(e) An electric storage device which stores (charges) or maintains a charge (stored) state of electricity produced (generated) or transmitted from the charging station, is transferred to the electric consumer by a wireless transfer method by the electric storage device wireless transfer means. Making a step;

It is configured to include.

In addition, the wireless transfer method,

It is characterized in that it is a method of supplying the electricity produced (generated) or delivered in the charging station to the electric consumer by realizing the charging, transfer, consumption, recovery, recharge cycle of electricity.

In addition, the charge, transfer, consumption, recovery, recharge cycle of the electricity,

One or two or more of the plurality of the electric storage devices are stored (charged) or stored (charged) in any one or more of electricity generated (generated) or transmitted from the charging station, Including the entire process of transferring to the electrical consumer, and consumed (discharged) stored (charged) electricity at the electrical consumer, and then recovered to the charging station to re-save (recharge), 1 It is characterized in that the cycle is a continuous or repeatedly performed a plurality of times or two or more times.

In addition, the electrical storage device wireless transfer means,

Between the charging station and the electrical consumer, characterized in that the various means, including any one or more of the role of the electrical storage device is transferred or recovered.

In addition, the method for configuring the various means of the electrical storage device wireless transfer means,

The producer and the consumer of the electric storage device are configured, and the charged electric storage device produced by the producer is configured to be exchanged and distributed at various stages, and the sale is made by buying and selling the charged electric storage devices. The method is made so that the consumer (consumer) is reached, and after the consumer (consumer) consumes (discharges) the electricity of the charged electric storage device thus reached, the discharged electric storage device is again returned to the consumer (consumer). A distribution structure including sales, including all such processes, in which a method of exchanging and distributing at various stages from a plurality of stages is carried out, and a method of selling and selling the charged electric storage devices is included, and collected to a producer. Through the formation of

The one or more electricity, which is produced (generated) or delivered at the charging station, is stored (charged) or stored (charged) while being transferred to a distribution method including sales to the electric consumer, It includes one or more steps including consuming (discharging) the stored (charged) electricity at the electricity consumer, and then recovering and restoring (recharging) the distribution method including sales to the charging station. To ensure that all processes of continuous and repeated multiple or more times are achieved,

A first method comprising a distribution method including sales;

When the producer and the consumer of the electric storage device are configured and the consumer orders the charged electric storage device, the producer delivers the charged electric storage device to the consumer, and the discharged electric storage device consumed by the consumer is the producer. By retrieving an order and delivery structure that includes all of these processes,

At least one of the electricity produced or generated at the charging station is stored (charged) or stored (charged) while being transferred to the electric consumer in an order and delivery method. Once or twice including the process of consuming (discharging) the stored (charged) electricity at the consumer, and then recovering and restoring (recharging) to the charging station again by the order and delivery method. So that all the processes can be carried out over and over again,

A second method consisting of an order and a delivery method,

The producer and the consumer of the electrical storage device are configured, and the consumer to be transferred from the producer to the consumer through any one or more of the methods to enable the transfer of the charged electrical storage device that the consumer needs, The discharged electrical storage device that has been consumed (discharged) causes other transportable structures to be formed, including any such process, to be returned to the producer by one or more of the other methods that enable transport. through,

At least one of the electricity produced or generated at the charging station is transferred to the electric consumer through other transferable methods while being stored (charged) or stored (charged), and the It includes one or more steps including consuming (discharging) electricity stored in the electricity consumption station, and then recovering and restoring (recharging) the battery through other transferable methods. To ensure that all processes of continuous and repeated multiple or more times are achieved,

The third method constituted by other transferable methods,

Among the fourth method using a mixture of the first method to the third method,

It is characterized by one or more methods.

In addition, the method of configuring the electrical storage device wireless transfer means by the other transferable method of the third method,

The electrical storage device is transferred from the charging station to the electrical consumer, the method of recovering from the electrical consumer to the charging station,

A first method of loading, transporting, transferring, transferring and transporting the electric storage device in a general vehicle;

After reconstructing the general transport means to a dedicated transport means for the electric storage device so that it can be used only for the purpose of handling only the electric storage device, the electric storage device is loaded on the transport means for transporting only the electric storage device, and transported and transported. The second way to transfer, transfer,

As an electric only transportation means for storing (charging) electricity and outputting (discharging) electricity, it is a method of equipping or mounting an electric storage device therein, superconducting power storage device car, superconducting power storage device. Ships, superconducting power storage aircraft, superconducting power storage devices trains, large capacity power storage systems (large capacity power storage systems) cars, large capacity power storage systems (large capacity power storage systems) ships, large capacity power storage devices (large capacity power storage systems) aircraft, Massive power storage system (large-capacity power storage system) Train, battery (electrical storage or ESS) train, battery (electrical storage or ESS) car, battery (electrical storage or ESS) ship, battery (electrical storage or ESS) Develop (or make) by aircraft,

The vehicle is transformed (made) into a vehicle for exclusive use of electricity so as to be used exclusively for storing (charging) electricity and outputting (discharging) electricity.

By directly operating the electric dedicated transport means itself,

After the electricity is stored (charged) in the electric dedicated transportation means, the charging station goes to the electric consumer, and the electricity stored in the electric dedicated transportation means itself (charged) outputs (discharges) the electricity, and then goes to the charging station. A third method of using the electricity-only transport means only for the purpose of continuously repeating a cycle of re-storing (charging) the electricity-only transport means once or twice or more a plurality of times;

Among the fourth method using a mixture of the first method to the third method,

It is characterized by one or more methods.

In addition, the distribution method including the sale of the first method,

The electrical storage device is characterized in that it has a structure that can be bought and sold to each other between the producer and the consumer and the third party through the distribution process.

In addition, the method of making the electrical storage device has a structure that can be bought and sold to each other between the producer, the consumer and the third party through the distribution process,

The structure makes it easy to identify the value (price) of the electric storage device between the seller and the buyer, so that the value (price) of the electric storage device can be formed differently according to the degree of use and the amount of electric storage according to various specifications. It is characterized by the method.

In addition, the value of the electric storage device (price) of the electric storage device can be easily identified between the seller and the buyer, so that the value (price) of the electric storage device can be formed differently according to the degree of use and the amount of electricity storage according to various specifications. How to make it possible,

The method of displaying the number of times of charging and discharging the electricity to the electric storage device, or to display the number of times of charging and discharging the electricity and at the same time to display the remaining capacity of electricity. It features.

In addition, the electrical storage device,

At least one of the electricity produced or generated at the charging station is transferred (charged) or stored (charged) while being stored (charged) or transferred from the charging station to the electrical consumer through an electrical storage device wireless transfer means. The consumption of electricity at the electric consumer (discharge) is characterized in that the function of recovering back to the charging station through the electric storage wireless transfer means, so that all can be performed smoothly.

In addition, the electrical storage device,

It is characterized in that it is standardized and standardized with a function and structure capable of continuously and repeatedly performing the charging, transferring, consuming, recovering and recharging cycles of electricity one or two or more times.

In addition, the method for standardizing and shaping the electrical storage device,

The size and weight are to be standardized to a certain standard, but in accordance with the site use conditions to make a number of types by the standard, the same type of each of the types of the above-described multiple types of electrical storage devices to make the same electrical specifications are formed It is characterized by.

In addition, the method for standardizing and shaping the electrical storage device,

A first method of using a product, an article, a facility, or a device that performs any one or more functions of storing (charging) or outputting (discharging) existing electricity,

One or two cycles of charging, transferring, consuming, retrieving, and recharging electricity to a product, article, facility, or device that performs one or more of the functions of storing (charging) or discharging (discharging) electricity. A second method used by reinforcing, changing (modifying) to further provide a structure (apparatus) capable of continuously and repeatedly performing a plurality of times;

Make new products, articles, equipment and devices capable of performing any one or more of the functions of storing (charging) or discharging (discharging) electricity, but do not charge, transfer, consume, recover, recharge cycles of electricity. To be equipped with the function and structure to continuously and repeatedly perform many or more times,

In the process of continuously or repeatedly performing the charge, transfer, consumption, recovery, and recharge cycles of the plurality of times a plurality of times, the size of the transfer and recovery can be made smoothly by using the electric storage wireless transfer means And the third to be standardized to a certain standard, but to make a number of types to meet the site use conditions, the same type of each of the standardized electrical storage devices to be made (developed) to use the same electrical specifications for the same type Way,

Among the fourth method using a mixture of the first method to the third method,

It is characterized by one or more methods.

In addition, the second method,

Existing, currently developed, produced and sold distribution

Large capacity energy storage device, large storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Transfer of any one or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or various products, articles, equipment, devices that store (charge) electricity and output (discharge) electricity. It is characterized in that it is used to reinforce and avoid trouble and convenient in the recovery process.

In addition, the third method,

Existing, currently developed, produced and sold distribution

Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Same as any one or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or a variety of products, articles, facilities, and devices that store (charge) electricity and output (discharge) electricity. Or create a new dedicated electrical storage device with similar functionality and structure,

It is made of reinforcement to make it convenient and trouble-free during transportation and recovery.

The specifications are made of a number of types to suit the reality of charging stations or electrical consumers, but to be standardized to a certain size and weight, the standardized electrical storage device is used to make a standardized electrical specifications, or

Equipped with the new dedicated electric storage device in various means of transportation, superconducting power storage car, superconducting power storage ship, superconducting power storage aircraft, superconducting power storage train, large capacity power storage system (large capacity power storage system) car, Massive power storage system (large-capacity power storage system) Vessels, large-capacity power storage system (large-capacity power storage system) aircraft, large-capacity power storage system (large-capacity power storage system) trains, batteries (electrical storage or ESS) trains, batteries (electrical storage Device or ESS) car, battery (electrical storage device or ESS) ship, battery (electrical storage device or ESS) aircraft, transportation equipment with the function of storing (charging) and outputting (discharging) electricity. Characterized in that.

In addition, the electric consumer,

The first consumer who has no place (space) to install a charging station or a place where space is inexpensive, or an electric mass consumer that is good at consuming (discharging) electricity in large quantities, and where there is no place (space) to install the charging station, or is inexpensive In the case of one or more of the second consumer where there is only a place (space),

The method of receiving economical electricity produced (generated) in a clean and safe manner at the first or second consumer,

Is installed at a location spaced apart from the first or second consumer and at any one or more of the charging station or intermediate storage station that produces (generated) economical electricity in a clean and safe manner, the method of receiving electricity through a wireless transfer method It is characterized by.

In addition, the electric consumer,

It is a first consumer where there is no place (space) to install a charging station or a place where space is inexpensive, or an electric mass consumer that is good at consuming (discharging) electricity in large quantities, and there is no place (space) or economical to install the charging station. In the case of one or more of the second consumer where there is only a place (space) to fall off,

The method of receiving electricity produced (generated) by the future energy production method in the first or second consumer,

Installed at a location apart from the first or second consumer, and at any one or more of the charging station or intermediate storage station that receives the electricity (generated) to be produced (generated) by the future energy production method and delivers to the electrical consumer, through a wireless transfer method Characterized in that it is a method of receiving electricity.

In addition, any one or more of the filling station or intermediate station,

The method of receiving electricity (energy) brought by the electric energy transport device from the sky or the space and delivering it back to the electric consumer,

By installing a large-capacity secondary electric storage device in the charging station or intermediate storage, and storing (charge) the electricity (energy) brought by the electric energy transport device from the sky or the space again in the large-capacity secondary electric storage device (charge) Thereafter, the first method of storing (charging) the electricity thus stored in the electrical storage device made to perform the wireless transfer method and supplying the stored electricity to the electric consumer using the wireless transfer method,

After receiving the electric storage device, which is stored (charged) by the electric energy transport device from the sky or the space, is delivered from the charging station or the intermediate storage station, and then wirelessly transfers the charged electric storage device itself. A second method of supplying to the electric consumer using a method,

Among the third method of supplying a mixture of the first method and the second method,

It is characterized by any one or more methods.

In addition, the future energy production method,

It is characterized in that it is a method of receiving the electricity (energy) brought by the electric energy transport device from the earth or space and the electricity produced (generated) from the earth and space.

In addition, the electric energy transport device,

It is equipped with a photovoltaic power generation unit composed of photovoltaic power generation facilities that generate (generate) electrical energy by receiving light energy of the sun over the earth or in space.

It is provided with an electrical storage device including a function of storing (charging) electricity produced by the photovoltaic unit in the sky or space and delivering electricity that has been stored (charged) at a designated charging station.

The electricity produced in the photovoltaic unit (generated) is stored in the electrical storage device, and configured to be connected to each other, the electrical and control circuits to enable the output (discharged) of the stored (charged),

In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station, the earth and space,

It is characterized in that the flying device to store (charge) the photovoltaic electricity produced (generated) in the photovoltaic unit from the sky or the space to the electrical storage device, bringing it to the designated charging station and deliver.

In addition, the electric energy transportation device,

Rather than the total amount of energy consumed (consumed) in a single cycle of electricity production and transportation, electricity is generated (generated) from the sky and space through a single cycle of electricity production and transportation, and brought to a designated charging station. It is characterized by making the total amount of energy (transported) more.

In addition, the energy required for the operation (driving) of the electric energy transportation device,

It is characterized in that it is obtained by a method of dealing with the natural force (energy) obtained naturally by utilizing the principle of nature (or the order of the universe) without incurring extra energy.

In addition, the method for handling the energy required for the operation (driving) of the electric energy transportation device with the force of nature,

When the electric energy transport device floats over the earth or in space, stays in the earth or in space, returns to the designated electric energy transmission site from the earth or in space, or travels in which a large amount of energy is consumed (driving When running (driving) sections, a large amount of energy consumed in any one or more running sections,

It is characterized in that it is obtained by a method of dealing with the natural force (energy) obtained naturally by utilizing the principle of nature (or the order of the universe) without incurring extra energy.

In addition, the method of applying the buoyancy in the air as a method of bearing the energy required for the operation (driving) of the electric energy transportation device with the natural force,

Create a space having a certain volume inside the electric energy transport device to form a natural buoyancy by filling a buoyancy material in the space, or to form artificial buoyancy by applying a negative pressure (-pressure) or vacuum to the space, or electric A first method of providing a buoyancy device made to have a buoyancy of at least one of natural buoyancy or artificial buoyancy in the energy transport device by any one or more of the methods,

A second method of providing a buoyancy device made to have one or more buoyancy of the natural buoyancy or artificial buoyancy as an additional configuration in an electric energy transport device;

Among the third method of adjusting the magnitude of one or more buoyancy among the natural buoyancy, artificial buoyancy, or buoyancy of the buoyancy device in the first and second methods,

It is characterized by one or more methods.

In addition, the method of adjusting the magnitude of the buoyancy in the third method,

The buoyancy of any one or more of the natural buoyancy, artificial buoyancy formed in the electric energy transport device, or buoyancy of the buoyancy device provided separately to the electric energy transport device,

In the pressure of a buoyant material, negative pressure (-pressure), vacuum or in the volume of space in which the buoyancy is to be formed,

It is characterized in that it is a method of applying or adjusting any one or more of them.

In addition, the buoyancy device,

An object having a closed volume of a constant volume, the mass per volume of the object has a lower mass than the air per the same volume of the surrounding air, it characterized in that the effect of buoyancy can be generated over the earth (air).

In addition, the method of making the mass per volume of the object has a lower mass than the air per equal volume of the surrounding air,

It is characterized in that any one or more of the method of inserting (injecting), applying negative pressure (-pressure), or applying vacuum to an object having a constant volume of closed space.

In addition, the power of nature,

It is a buoyancy force in the air that tries to push it up in the opposite direction of the earth's gravity.

In addition, the future energy production method,

It is equipped with a photovoltaic power generation unit composed of photovoltaic power generation facilities that generate (generate) electrical energy by receiving light energy of the sun over the earth or in space.

It is provided with an electrical storage device including a function of storing (charging) electricity produced by the photovoltaic unit in the sky or space and delivering electricity that has been stored (charged) at a designated charging station.

The electricity produced in the photovoltaic unit (generated) is stored in the electrical storage device, and configured to be connected to each other, the electrical and control circuits to enable the output (discharged) of the stored (charged),

In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station, the earth and space,

The electric energy transport device is a flying device that stores (charges) solar power generated in the photovoltaic unit from the sky or space and stores it in the electrical storage device, and delivers it to the designated charging station. after,

The electric energy transport apparatus is made into one or two or more plural, and the designated charging station is also made into one or two or more plural places,

Countless electric energy transport devices of one or more than two of them fly up the earth or into space (space),

While staying in the sky or space (space), it produces (generated) photovoltaic electricity through the photovoltaic unit provided in the main body, charges (stores) it in the electrical storage device provided in the main body, and returns to the designated charging station and delivers it.

Fly back up to the earth or space (space), stay in the earth or space (space), produce (generate) and recharge (store) photovoltaic electricity, then return to the designated charging station and deliver the electricity By repeating the cycle, the process of continuously repeating a plurality of times one or two times a number of times, it is characterized in that it is a way to bring the photovoltaic electricity brought to mankind.

In addition, the flying device is characterized in that it is used as an electric energy transportation device by making a drone.

In addition, the method of configuring the electrical consumer of step (d),

At least one of the areas, facilities, buildings, facilities, equipment, devices, customers, or existing electricity sources that use existing electricity or require new use of electricity, or all electricity consumption sources that use existing electricity or require new use. In the electricity consumer,

The electrical storage device that stores (charges) or maintains the charging (stored) state of electricity produced (generated) or transmitted from the charging station is transferred to the electrical consumer using a wireless transfer method based on the electrical storage device wireless transfer means. Through it, the electricity supplied from the charging station to the electrical consumer, characterized in that the method of using to replace the electricity of the existing power system network.

In addition, a method of replacing the electricity of the existing power system network with electricity supplied from the charging station to the electrical consumer,

A method of converting direct current (DC) electricity output (discharged) from a charged electric storage device transferred from the charging station into direct alternating current (AC) electricity at the electrical consumer, and using alternating current (AC) electricity at the electrical consumer. It is characterized by.

In addition, a method of replacing the electricity of the existing power system network with electricity supplied from the charging station to the electrical consumer,

It is a method of directly using the direct current (DC) electricity itself without converting the direct current (DC) electricity output (discharged) in the charged electrical storage device transferred from the charging station to the alternating current (AC) electricity at the electrical consumer. It is characterized by.

In addition, a method of directly using the direct current (DC) electricity itself,

The electric load (s) used in the electrical consumer, characterized in that the method is used as an electrical load directly operated by direct current (DC) electricity itself output (discharged) in the charged electrical storage device transferred from the charging station. .

In addition, an electric load which is directly operated by the direct current (DC) electricity itself,

It is characterized in that any one or more of the heating electric load of the use of all or part of the prefabricated heating wire (battery electric operation prefabricated heating wire) that operates by battery electricity as the electric load for heat generation.

In addition, the method of manufacturing the battery electric operation prefabricated heating wire,

Making an ultrafine wire from a single metal or an alloy metal having different number of strands, thickness, material, and function;

By combining and bundling the ultra-fine wires prefabricated to have at least one of low resistance value or multi function required to obtain desired heat by using battery electricity or safe low voltage direct current (DC) electricity of 24V or less. Bundling of; And

Making the one bundle soon to be a strand of hot wire;

Characterized in that it comprises a.

In addition, the prefabricated heating wire,

Microfiber wires can be made of many, many, single or alloy metals,

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,

Any one or more selected from all the ultrafine wires prepared above are synthesized into two or more multiple strands to make one combination, and the combination is prepared by making one strand of the hot wire.

In addition, the one combination,

Combine all the microfibers inside to be in contact with each other and make a composite assembly in a bundle,

The microfibers in the bundle are brought into intimate contact with each other, and the entire surfaces of all the microfibers in the bundle are in contact with each other in the longitudinal direction from the beginning to the end of the bundle, so that the current flows to all the microfibers throughout the contact surface. Synthetic combination is made in such a way that the energized contact is possible, and it is characterized in that it is made into one bundle through bundling operation again.

In addition, the prefabricated heating wire,

First, a heating wire having a low resistance value necessary to obtain a desired heat using battery electricity or a safe low voltage direct current (DC) electricity below 24V,

Secondly, a battery wire or a heating wire that exhibits one or more additional functions with the low resistance required to obtain the desired heat using safe low voltage direct current (DC) electricity below 24V,

Third, any heating wire of at least one of the first and second heating wires and excellent flexibility of heating wires,

Fourth, customized heating wires, each of which is precisely matched to each other in various cases so as to have any one or more functions of the first to third heating wires,

Fifth of the heating wires that can be economically and easily mass-produced at any time with the same product with the same performance as the customized heating wires made by the fourth above,

It is characterized in that it is produced by any one or more hot wire.

In addition, the customized heating wire,

It is characterized by changing the combination of the micro wires into a bundle in which the combination change of the micro wires is made through the bundling operation.

In addition, the combination change of the micro fine lines,

Microfiber wires can be made of many, many, single or alloy metals,

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,

By selecting any one or more of all the prepared ultrafine wires, changing the selection of the selected ultrafine wires differently may be a combination change of the ultrafine wires, but synthesizing the microfine wires into at least two strands in one combination It is characterized by making.

In addition, changing the selection box,

If you select any one micro fine line, select one fine line as different fine line and change the selection of fine line, change the number of strands to 2 or more strands

If you select any two or more micro wires, select one or more micro wires from two or more micro wires as different micro wires, and change the selection of the micro wires,

If any two or more fine wires are selected, any one or more fine wires of two or more fine wires are selected as different fine wires, and the selection of the fine wires is changed, but the number of strands of the selected fine wires is changed or selected. How to change,

To be made in any one or more ways, it is characterized in that the number of extra fine strands in the combination is two or more.

In addition, changing the selection box,

Among all the prepared ultrafine wires, a classification type group may be selected from only one kind group classified as resistance value, thickness, material, and function, but in the selected single classification type group, the same ultrafine wires are combined into two or more strands. To form a combination, and the combination of the first and second combinations allows the total number of ultrafine wires to be at least two strands, the first method of changing the number of strands,

Among all the prepared ultrafine wires, a classification type group is selected from any one of a kind group classified into resistance value, thickness, material, and function. Select the additional fine line by changing the number of strands again after changing the fine line to any one of the classification types except for the type corresponding to the selected classification type group among the material and function types. In this way, the final selection (modification) is a combination of at least two strands by combining at least two strands to form a single combination, the combination is made in the second method for the total number of ultrafine lines to be at least two strands ,

Among the prepared ultrafine wires, any two or more classification type groups are selected from among the group of types classified by resistance value, thickness, material, and function, and each of the selected classification types is selected by one or more strands in different classification types. A third method in which the selected ultrafine wires are combined into at least two types to form a single combination, and the combination of the three fine wires includes at least two strands of total fine wires;

Among the prepared ultrafine wires, each of the ultrafine wires is selected from any two or more types of classification groups classified into resistance values, thicknesses, materials, and functions, and at least one strand is selected for each of the selected classification types. In this case, the selected fine wire is changed back into any one of the classification types except for the one corresponding to the selected classification type group among the resistance value, thickness, material, and function type. In addition, it is possible to make an additional selection (change) in such a way as to make an ultrafine line, thereby forming one combination by combining at least two kinds of ultrafine lines selected from different classification types. Combination of the fourth method to ensure that the total amount of the fine wire is at least two strands,

Among the prepared ultrafine wires, each of the ultrafine wires is selected from at least two classification type groups among the types of groups classified into resistance values, thicknesses, materials, and functions, and at least one strand is selected for each of the selected classification types. In this case, the selected fine wire is changed back into any one of the classification types except for the one corresponding to the selected classification type group among the resistance value, thickness, material, and function type. After the fine line becomes the fine line, the selected fine line is further selected (changed) by changing the number of strands again, so that the final fine line selected at least two kinds of fine lines selected from different classification types are selected. Combination to form a combination, one combination is composed of at least two strands of total ultra fine wire Fifth way to lose,

Among all the prepared ultrafine wires, a classification type group is selected from any one of the kind groups classified by resistance value, thickness, material, and function, but within the selected classification type group, two different ultrafine wires have two or more strands. The sixth method of the present invention is to make a combination through the combination, wherein the one combination is such that the total amount of micro fine lines is at least two strands.

Among all the prepared ultrafine wires, a classification type group is selected from any one of the kind groups classified by resistance value, thickness, material, and function, but within the selected classification type group, two different ultrafine wires have two or more strands. And the selected micro fine lines are combined again by changing the number of strands to form a single combination, and the combination of the two fine lines enables the total micro fine line number to be at least two strands. Of the methods,

It is characterized by using any one or more methods.

In addition, the ultra-fine wire in the one classification type group selected in the second method may be any one of the classification types except for the type corresponding to the selected classification type group among resistance values, thicknesses, materials, and function types. After making the fine line changed again, the method of changing the number of strands again in this selected fine line,

If only one classification type group selected as one is selected as the material type, change the micro fine lines within the classification type group selected with this material to one or more of thickness, function and resistance value except for material change. In the final selected fine line, again change the number of strands to the same fine line,

If only one kind of classification type group is selected as the resistance value type, in changing the ultrafine lines again within the classification type group selected by this resistance value, change to one or more of thickness, function and material except for the change of resistance value. In this way, the final selected fine line again changes the number of strands to the same fine line,

If only one classification type group is selected as the function type, change the micro fine lines within the classification type group selected by this function to one or more of the material, thickness and resistance value except for the function change. In the final selected fine line, again change the number of strands to the same fine line,

If only one kind of classification type group is selected as the thickness type, within the classification type group selected by this thickness, change to one or more of materials, functions, and resistance values except for the thickness change in changing the fine lines again. In the final selected fine line, you can change the number of strands to the same fine line again.

It is characterized by any one or more methods.

In addition, the ultra-fine wire selected in the fourth method is any one of the classification types except for the type corresponding to the selected classification type group among the resistance value, thickness, material, and function type in the same classification type group. The way to become the micro fine line which I changed to a kind again,

When any one of the selected classification type groups is selected as the material type, within the classification type group selected by this material, the method of changing to one or more of thickness, function, and resistance value except for material change only in changing the ultrafine lines again,

When any one of the selected classification type groups is selected as the resistance value type, within the classification type group selected by this resistance value, a method of changing to one or more of thickness, function, and material except for changing the resistance value again in changing the ultrafine wires again. ,

If any one of the selected classification type groups is selected as the function type, within the classification type group selected by this function, the method of changing to one or more of materials, thicknesses, and resistance values except for the function change in changing the fine lines again,

If any one of the selected classification type groups is selected as the thickness type, within the classification type group selected with this thickness, one of the methods of changing to one or more of materials, functions, and resistance values except for the thickness change in changing the fine lines again,

It is characterized by any one or more methods.

In addition, the ultra-fine wire selected in the fifth method is any one of the classification types except for the type corresponding to the selected classification type group among the resistance value, thickness, material, and function type in the same classification type group. How to change the number of strands again in the fine line selected in this way,

When the same classification type group is selected as the resistance value type, a method of additionally changing the number of strands for these by changing one or more of thickness, function, and material except for changing the resistance value in changing the ultrafine wires,

If the same classification type group is selected as the material type, the method of additionally changing the number of strands for these by changing one or more of the thickness, function, and resistance value except for changing the material in changing the ultrafine wires,

When the same classification type group is selected as the thickness type, the method of additionally changing the number of strands of these materials by changing any one or more of materials, functions, and resistance values except the thickness change in changing the fine lines,

If the same classification type group is selected as the functional type, the method of additionally changing the number of strands of these materials by changing one or more of the material, thickness, and resistance value except for the functional change in changing the micro fine lines,

It is characterized by any one or more methods.

In addition, the prefabricated heating wire,

By using battery electricity or safe low voltage direct current (DC) electricity of 24V or less, it becomes heating wire having low resistance value necessary to obtain desired heat,

Using battery electricity or safe low voltage direct current (DC) electricity below 24V,

Is a hot wire that emits far infrared rays,

It is a heating wire that generates instantaneous high temperature heating and high efficiency heating,

Among the heated wires that increased flexibility,

In a way that makes it a hot wire

Microfiber groups can be made of many, many, single or alloy metals,

Prepare by making a variety of ultra-fine wire groups having a specific resistance value but different resistance values,

Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,

Prepare a variety of ultra-fine wire groups having a specific material but different materials,

Prepare a variety of ultra-fine wire groups with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,

Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed fine wire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. After collecting the values to create big data,

Any one or more selected from all of the prepared ultrafine wire groups may be synthesized into two or more groups to form a single combination, and the combination may be a single strand of hot wire.

In addition, the combination of the ultrafine wire groups by changing the combination of the ultrafine wire groups through a bundle change is characterized in that to create a customized hot wire in one bundle.

In addition, the combination change of the ultra fine groups,

By selecting any one or more of the prepared ultrafine wire groups, changing the selected ultrafine wire group to be different from each other is a combination change of the ultrafine wire groups, and synthesizes the ultrafine wire group into at least two groups. It is characterized by making one combination.

In addition, changing the selection box,

In case of selecting one ultrafine wire group, select one ultrafine wire group as a different ultrafine wire group, and change the selection of the ultrafine wire group, but select the same number of ultrafine wire groups in two or more groups. Change it,

If you have selected any two or more fine wire groups, select one or more fine wire groups among two or more fine wire groups as different fine wire groups, and change the selection of the fine wire groups,

If you select any two or more fine wire groups, select one or more fine wire groups among two or more fine wire groups as different fine wire groups, and change the selection of the fine wire groups, but select Change or select How to change the number of groups of the micro fine line group,

The method may be performed in any one or more ways, and the number of groups of the ultrafine wire groups in the one combination may be two or more groups.

In addition, changing the selection box,

Among the prepared ultrafine wire groups, a classification type group may be selected from only one kind group classified as resistance value, thickness, material, and function, and the same ultrafine wire group is classified into two groups within only one selected classification type group. Through the above combination to form a single combination, the combination of the above is to make the total number of ultra-fine wire group of at least two groups, the first method of changing the number of groups,

Among the prepared ultrafine wire groups, a classification type group may be selected from any one of the types of groups classified into resistance values, thicknesses, materials, and functions, and the ultrafine wire groups within the selected single classification group group may again have resistance values. Change the number of groups in the selected fine line group again after changing it to one of the classification types except for the one corresponding to the selected classification type group among the thickness, material, and function type. In this way, the final selected (modified) microfiber group is finally combined into at least two groups to form one combination. Second method to make it,

Among the prepared ultrafine wire groups, any two or more classification type groups are selected from the group of categories classified by resistance value, thickness, material, and function. A third method in which a combination of at least two types of ultra fine wire groups selected by type forms one or more combinations;

Among the prepared ultrafine wire groups, each ultrafine wire group is selected from at least two classification type groups among the types of groups classified by resistance value, thickness, material, and function. The ultra-fine wire group selected in this way is selected from the group of any one of the classification types except for the type corresponding to the selected classification group among the resistance value, thickness, material, and function type. In order to make the selected ultrafine wire group changed again, it is possible to combine the final selected ultrafine wire group by combining at least two kinds of ultrafine wire groups selected from different classification types. In one combination of the above, the fourth method for the total number of ultra fine wire groups to be at least two groups,

Among the prepared ultrafine wire groups, each ultrafine wire group may be selected from at least two classification type groups among the types of groups classified by resistance value, thickness, material, and function. The ultra-fine wire group selected in this way is selected from the group of any one of the classification types except for the type corresponding to the selected classification group among the resistance value, thickness, material, and function type. After the result is changed to the ultra fine wire group, the selected ultra fine wire group is further selected (changed) by changing the number of groups again, and thus the fine selected fine wire group is finally selected from different classification types. The sun group combines at least two types to form one combination. A fifth method of this quantity be made of at least two groups,

Among the prepared ultrafine wire groups, a classification type group may be selected from any one of the types of groups classified by resistance value, thickness, material, and function, and within the selected classification type group, two different ultrafine wire groups may be selected. The sixth method of the present invention is to combine one or more groups to form one combination, and the one combination thus constitutes at least two groups in total.

Among the prepared ultrafine wire groups, a classification type group may be selected from any one of the types of groups classified by resistance value, thickness, material, and function, and within the selected classification type group, two different ultrafine wire groups may be selected. Selected to be more than a group, and the selected ultra-fine wire groups are combined again by changing the number of groups to form a combination, and the combination of the two combinations of the above-described ultra fine wire groups is at least two groups. Among the seventh methods to make it happen,

It is characterized by using any one or more methods.

In addition, the ultra-fine wire group,

Combined two or more strands of microfibers with the same taxonomy and the same properties, which are thinner than the corresponding microfibers used in single strands, so that the entire face of these two or more microstrands in the longitudinal direction While contacting each other from the beginning to the end, the current can flow through all the ultra-fine wires as a whole, it is characterized in that the combination of the combination of the electric contact is made by the electrical synthesis is made of one bundle.

In addition, the prefabricated heating wire,

Battery Electricity or Safety Low Voltage Direct Current (DC) below 24V

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,

It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,

Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,

Prepare a variety of ultra-fine wire groups having a specific material but different materials,

Prepare a variety of ultra-fine wire groups with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,

Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed fine wire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. After collecting the values to create big data,

The micro fine wires used by one strand of the prepared micro fine wires and any one of the prepared ultra fine wire groups may be used in combination,

It is characterized by using any one of the prepared ultrafine wire group to the ultrafine wires used by one strand of the prepared ultrafine wires.

In addition, the prefabricated heating wire,

Battery Electricity or Safety Low Voltage Direct Current (DC) below 24V

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,

One or more of the prepared micro fine wires are used in combination with the micro fine wire group more effective in performing a multi-function, or

In addition to using a micro wire group more effective in performing a multi-function to the micro wires used by one strand of the prepared micro wires,

It is characterized by using any one or more of the methods using only the ultra fine wire group which is more effective in performing the multi-function.

In addition, a micro wire group more effective in performing the multi-function,

One strand of NASLON, which is a steel fiber, has a thickness of 20 µm or less, and 100 or more strands of the same thickness, while the entire surfaces of these multiple strands of microfibers are in contact with each other from the beginning to the end in the longitudinal direction, so that all the microscopic wires are in contact with the current as a whole. It can be flowed to each other, it characterized in that a bundle by combining the combination of the electrical contact is made to the electrical synthesis to each other.

In addition, the hot wire is emitted from the far infrared,

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,

It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,

Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,

Prepare a variety of ultra-fine wire groups having a specific material but different materials,

Prepare a variety of ultra-fine wire groups with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,

Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. Collect the values to create and prepare the big data,

In addition, a fine fiber group made of one bundle may be prepared by making one strand of NASLON, which is a steel fiber, having a thickness of 20 μm or less with 100 or more strands having the same thickness.

NASLON 1 strand of steel fiber has a thickness of 12㎛ (corresponding ultrafine wire diameter), and prepare the ultrafine wire group consisting of 550 strands with the same thickness,

Prepare a microfiber group consisting of 1 strand of NASLON, which is steel fiber, having a thickness of 8 μm (correspondingly fine wire diameter), and having 1,000 strands of the same thickness.

One strand of NASLON, a steel fiber, has a diameter of 6,5 µm (correspondingly fine wire diameter), and a microfine wire group consisting of 2,000 strands with the same thickness is prepared.

Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups, which are more effective in performing a multi-function,

Battery electricity or safe low-voltage direct-current (DC) power of 24V or less, many of which are multi-stranded microwires, multiple-group ultrafine wire groups, or a mixture of ultrafine wires and ultrafine wire groups that emit far infrared rays while generating heat due to resistance And select one or more of them, and then combine the selected one or more of the multiple strands of the multiple strands, the multiple group of the fine strands, or a mixture of the micro and the ultrafine group to contact each other to form a composite combination. A composite combination of any one or more of these multiple strands of microfibers, multiple groups of microfibres, or a mixture of micro and microfibers, into one bundle, such a bundle being one strand Electric dipole radiation, which emits far-infrared rays. ation) is characterized in that it is manufactured with a geometric structure that can be radiated larger and better.

In addition, a more effective method of making the electric dipole radiation have a geometric structure that can be radiated larger and better,

Synthetic combinations inside the bundle,

When the resistance value, material or thickness of one or more of a plurality of micro wires, a plurality of micro wire groups, or a mixture of a micro wire and a micro wire group are one or more, the same condition may be used. Make the number of strands (or the number of groups, or the number of mixtures) of one or more of the same, or the same as that of the same,

One or more of two or more groups having different resistance values and having a same resistance value for each group having a different resistance value, or a mixture of micro wires and micro wire groups having a same resistance value 1 It is a method of making into strands (or 1 group, 1 mixed thing) or two strands (or 2 groups, two mixed things) or more.

In addition, at least two groups having different resistance values,

Divide into two or more groups with different heating functions, divide into two or more groups with different materials, or divide into two or more groups with different thicknesses, using any one or more of these methods, For each different group, one or more strands (or one group, one mixed substance) or two strands (or one or more of the fine wire, the fine wire group, or a mixture of the fine wire and the fine wire group having the same resistance value) are used. Two groups, two mixed ones)

It is characterized by having a different resistance value.

In addition, the method of controlling the far infrared emission of the prefabricated heating wire,

The number of strands of the microfibers of the bundle synthesized by any one or more of a plurality of microfibers, a plurality of microfibers group, or a mixture of microfibers and microfibers group, the number of groups of the microfibers group, Or a first method of changing (adjusting) any one or more of the number of mixtures of the ultrafine wires and the ultrafine wire groups,

A second method of changing (adjusting) the self-heating temperature of the bundle synthesized by any one or more of a plurality of micro strands, a plurality of micro strand groups, or a mixture of a micro strand and a micro strand group,

The bundle of the bundle synthesized by any one or more of a plurality of micro fine wires, a plurality of fine wire groups, or a combination of a fine wire and a fine wire group by a combination of the first method and the second method. It modifies one or more of the number of strands of the micro wire, the number of groups of the micro wire group, or the number of mixtures of the micro wire and the micro wire group, and simultaneously controls the heating temperature of one bundle (heat wire) itself. Among the third method,

It is characterized by any one or more methods.

In addition, a method of changing (adjusting) one or more of the number of strands of the ultrafine wire of the bundle, the number of groups of the ultrafine wire group, or the number of mixtures of the ultrafine wire and the ultrafine wire group,

The ultrafine wire, the ultrafine wire of the bundle in a state in which at least one of the resistance value, material or thickness of any one or more of the ultrafine wire, the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group has the same condition It is a method of changing (adjusting) the number of strands (or the number of groups, or the number of mixed things) of any one or more of a group, or a mixture of an ultrafine wire and an ultrafine wire group.

Further, in the state in which at least one of the resistance value, the material, or the thickness of any one or more of the ultrafine wire, the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group has the same condition, the ultrafine wire of the bundle, The method of changing (adjusting) the number of strands (or the number of groups or the number of mixtures) of any one or more of the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group,

The combined resistance value per unit length of one bundle (heat wire) is the same, but the number of strands (or number of groups, or groups) of any one or more of the fine wire, the ultra fine wire group, or a mixture of the ultra fine wire and the ultra fine wire group, or And a method of changing (adjusting) the number of mixed materials).

In addition, a method of changing (adjusting) one or more of the number of strands of the ultrafine wire of the bundle, the number of groups of the ultrafine wire group, or the number of mixtures of the ultrafine wire and the ultrafine wire group,

Two or more of a plurality of micro fine wires, a plurality of micro wire groups, or a mixture of micro wires and micro wire groups having at least one of the same material, the same resistance value, or the same thickness, two or more In a heating wire made of multiple groups and made of one bundle, the combined resistance value per unit length of the whole bundle (heating wire) should be the same, but within the respective group, the fine wire, the fine wire group, or the fine inside thereof. It is characterized by a method of individually adjusting (number of groups or number of mixed or mixed) of the one or more of the mixed line and the fine line group (the same or different for each group).

In addition, the method of adjusting the self-heating temperature of the bundle (heating wire) of the second method and the third method, the amount of current flowing into the bundle (heating wire) by adjusting the resistance value per unit length of the bundle (heating wire) itself. It is characterized in that the method to be adjusted.

In addition, the method for adjusting the resistance value per unit length of the bundle (heat wire) itself,

The bundle (heating wire) itself is made of a customized heating element having various low resistance values required to obtain desired heat by using battery electricity or safety low voltage direct current (DC) electricity of 24V or less, and the bundle (heating wire) is changed through a combination change. It is characterized in that it is a method of adjusting the desired low resistance value per unit length, so that it can be customized to have a desired resistance as one resistance value.

In addition, it is characterized in that the self-heating temperature of the bundle (heating wire) of the second method and the third method is changed (adjusted) within a range of 80 ° C to 600 ° C.

In addition, the heating wire having the instantaneous high temperature heating, high efficiency heating function,

By splitting the prepared micro fine lines into more thin strands, or by making the thickness of the micro fine lines thinner, the number of strands is made by increasing the number of strands, and synthesizing these micro fine lines into a prefabricated process and bundling Made of one bundle, characterized in that the bundle is manufactured to be a strand of hot wire.

Also, in making the one bundle,

One strand is made of ultrafine wire having a thickness of 20 µm or less (based on the diameter of the ultrafine wire), and then the same ultrafine wire is bundled into a plurality of strands of 100 or more strands of the same thickness, and synthesized in energized contact with one bundle.

Used in combination with the ultra-fine wires used by one strand,

In addition to the extra fine wire to be used by one strand or used,

Use only one bundle itself instead of the fine wire,

In the method of using two or more bundles instead of the fine wire,

It is characterized by increasing the instantaneous high temperature heating, high efficiency heating function by any one or more methods.

In addition, the prefabricated heating wire in a way to be a heating wire having a constant temperature maintaining function,

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,

It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,

Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,

Prepare a variety of ultra-fine wire groups having a specific material but different materials,

Prepare a variety of ultra-fine wire groups with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,

Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. Collect the values to create and prepare the big data,

In addition, a fine fiber group made of one bundle may be prepared by making one strand of NASLON, which is a steel fiber, having a thickness of 20 μm or less with 100 or more strands having the same thickness.

NASLON 1 strand of steel fiber has a thickness of 12㎛ (corresponding ultrafine wire diameter), and prepare the ultrafine wire group consisting of 550 strands with the same thickness,

Prepare a microfiber group consisting of 1 strand of NASLON, which is steel fiber, having a thickness of 8 μm (correspondingly fine wire diameter), and having 1,000 strands of the same thickness.

One strand of NASLON, a steel fiber, has a diameter of 6,5 µm (correspondingly fine wire diameter), and a microfine wire group consisting of 2,000 strands with the same thickness is prepared.

       Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups, which are more effective in performing a multi-function,

       Multiple strands (or multiple groups, or multiple strands) of two or more fine strands (or two or more mixed groups) of a micro wire (or a group of micro wires and a micro wire group) having a predetermined resistance value Choose a combination), and make a group with two functions with different heating function,

The first type group continues to generate heat when current flows, and the second type group generates less heat after reaching a predetermined temperature and conducts current just like a conductor rather than conducting heat as it is conductored. It makes these two micro-wires (or groups of micro-wires, or a mixture of micro-wires and micro-wire groups) combined into one bundle, making these bundles perform as a bundle. It is characterized in that the manufacturing to be a hot wire.

In addition, the prefabricated heating wire is a method to be a hot wire having a function of excellent tensile strength and durability, and easily disconnected or little change in resistance value,

First, the material is steel fiber (NASLON) and the thickness of one strand is 20㎛ or less, the method of using one or more groups of ultrafine wire groups made of 100 or more of the same thickness,

The second material is steel fiber (NASLON) and the thickness of one strand is 12㎛ (corresponding microwire diameter), the microwire group consisting of 550 strands with the same thickness, or more than one group,

One or more microfiber groups consisting of 1,000 strands having the same thickness as one strand of steel fiber (NASLON) having a thickness of 8 μm (corresponding ultrafine wire diameter), or

Any one or more of the method of using one or more groups of ultra-fine wire groups consisting of 2,000 strands having the same thickness as one strand of steel fiber (NASLON) having a thickness of 6,5 μm (the corresponding fine wire diameter),

Third, one or more microfine wire groups having a thickness of 1 strand of NASLON, which is a steel fiber, which is the first group, are 12 μm or less in diameter, and the number of strands is equal to or greater than 550.

The second group, a single fine wire made of a single metal or an alloy metal, is a fine wire or an ultra fine wire group having a thickness of 140 μm or less and corresponding strands having the same thickness or more;

The thickness of one fine-wire strand made of nickel-copper alloy metal (alloy made of 20-25 wt% of nickel and 75-80 wt% of copper) is 180 μm or less, and the number of strands is 1 A micro wire or micro wire group consisting of more than one strand,

140 micro-wires made of iron chromium alumina molybdenum alloy metal (alloy 68 ~ 73% by weight, chromium 18 ~ 22%, alumina 5-6% by weight, molybdenum 3-4% by weight) Among the ultrafine wires or ultrafine wire groups each having a thickness of equal to or less than μm (corresponding fine wire diameter) and having the same thickness, the number of strands is 1 or more strands.

Of the method of using a combination of any one or more of the ultra-fine wire group of the first group, and one or more of the ultra-fine wire or ultra-fine wire group of the second group,

The ultrafine wire, or the ultrafine wire group formed by any one or more methods, is combined to make a single bundle for conducting synthetic combination, and the bundle is characterized in that it is manufactured to be a single strand of hot wire.

In addition, it is characterized in that the hot wire having a function of suppressing the oxidation reaction by coating the prefabricated heating wire.

In addition, the heat wire with excellent flexibility,

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,

In the prepared ultrafine wires, the fine wires are made thinner and the number of strands is further increased, while having the same resistance value as when the heating wire is made into 1 strand.

It is characterized by manufacturing in this ultrafine wire.

In addition, using the battery electricity or safe low voltage direct current (DC) electricity of 24V or less to have a low resistance value required to obtain the desired heat,

Prepare by making a variety of micro wires having a specific resistance value but different resistance values,

Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,

Prepare a variety of microfiber wires having a specific material but different materials,

Prepare a variety of ultra-fine wire with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, and function desired, separate the fine wires to meet the desired specifications from the single metal or alloy metal, and prepare them in various ways,

For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,

It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,

Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,

Prepare a variety of ultra-fine wire groups having a specific material but different materials,

Prepare a variety of ultra-fine wire groups with a specific function but different functions,

By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,

Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. Collect the values to create and prepare the big data,

In addition, a fine fiber group made of one bundle may be prepared by making one strand of NASLON, which is a steel fiber, having a thickness of 20 μm or less with 100 or more strands having the same thickness.

NASLON 1 strand of steel fiber has a thickness of 12㎛ (corresponding ultrafine wire diameter), and prepare the ultrafine wire group consisting of 550 strands with the same thickness,

Prepare a microfiber group consisting of 1 strand of NASLON, which is steel fiber, having a thickness of 8 μm (correspondingly fine wire diameter), and having 1,000 strands of the same thickness.

One strand of NASLON, a steel fiber, has a diameter of 6,5 µm (correspondingly fine wire diameter), and a microfine wire group consisting of 2,000 strands with the same thickness is prepared.

Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups, which are more effective in performing a multi-function,

After selecting a micro wire (or a group of micro wires or a mixture of micro wires and micro wire groups) having a resistance value per unit length higher than that of a conductor, the micro wire (or a micro wire group having a higher resistance value than such a conductor), or A bundle of composites produced by increasing the number of strands (or the number of groups or the number) of a mixture of ultra fine wires and ultra fine wires, and synthesizing them in energized contact with each other in the longitudinal direction to lower the composite resistance value. The first method to make these bundles a single strand of heat,

Dividing the method into two or more groups, the first group is a micro wire (or a combination of a micro wire group or a combination of a micro wire group and a micro wire group) having a resistance value equal to or similar to a conductor per unit length. Select it,

After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than the conductor,

The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The second method of making a strand of hot wire,

Dividing the selection into two or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group) to be carried out,

After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than the conductor,

The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The third method of making a strand of hot wire,

Dividing the selection into three or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor, rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group) to be carried out,

The second group selects a micro wire (or a micro wire group or a mixture of micro wire and micro wire groups) having a resistance value equal or similar to that of a conductor per unit length,

After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,

The first group, the second group, and the third or more groups of microfibers (or microfibers, or a mixture of microfibers and microfibers) are combined into a single bundle by energizing and contacting each other in the longitudinal direction. , The fourth method of making these bundles a single strand of heat,

Among the fifth method using a mixture of the first method to the fourth method,

It is characterized by any one or more methods.

In addition, the bundling operation,

The combination of the ultrafine wires is characterized in that it is carried out by a method of covering the coating to be split, or the coating to be split to be electrically synthesized.

And the bundle operation

All micro-wires in the bundle are brought into close contact with each other, and the entire surface of all the micro-wires in the bundle from the start to the end in the longitudinal direction is in contact with each other in the longitudinal direction, so that the current can flow to all the micro-wires throughout the contact surface. Composite combination of ultra fine wires,

A first method of wrapping a plurality of micro fine wires with high temperature fibers by wrapping the high temperature fibers overlapping with the high temperature fibers in a longitudinal direction,

The second method of bundling itself into a body by twisting itself through a combine machine,

A third method of extracting and bundling while coating the coating machine,

A fourth method of bundling the third method two or more times,

A fifth method using a different coating material for each coating number as the fourth method,

A sixth method of extracting and bundling one or two or more coatings made of the first method or the second method into a coater;

The first or second method is made by coating the coating machine once or twice or more, the coating material is the same by the number of times, or the number of parts by the same part is different, the number of times pulled while coating all differently The seventh method of bundling out,

Eighth method of inserting the adhesive between the upper and lower plates of the plate-shaped material, and then melted and bundled with the adhesive,

Among the ninth method of inserting any one or more of the bundles made by the first method to the eighth method between the upper and lower plates of the plate-shaped material, injecting the adhesive and then melting and bundling the adhesive,

It is characterized by performing in any one or more ways.

Future energy power generation system according to an embodiment of the present invention, to produce (generated) economical electricity in a clean and safe way to store (charge) in the electrical storage device, or to deliver electricity (generated) produced by the future energy production method Receiving station that performs any one or more of receiving and delivering to the electrical consumer;

An electrical storage device for storing (charging) electricity of the charging station;

An electrical consumer that uses (consumes) electricity supplied from the charging station; And

Electrical storage means for transferring the electrical storage device stored (charged) or maintained in the charged (stored) state of the electricity produced or generated in the charging station to the electrical consumer by a wireless transfer method:

It is configured to include.

In addition, the wireless transfer method,

It is characterized in that it is a method of supplying the electricity produced (generated) or delivered in the charging station to the electric consumer by realizing the charging, transfer, consumption, recovery, recharge cycle of electricity.

In addition, the charge, transfer, consumption, recovery, recharge cycle of the electricity,

One or more than one electrical storage device transfers any one or more of the electricity produced or generated at the charging station to the electrical consumer while remaining stored (charged) or stored (charged). At least once or twice, including the process of consuming (discharging) the stored (charged) electricity at the electrical consumer, and then recovering and restoring (recharging) the charging station again. It is characterized by a cycle of continuously performing a plurality of times repeatedly.

In addition, the electrical storage device wireless transfer means,

Between the charging station and the electrical consumer, the electrical storage device is characterized in that it is a variety of means for performing any one or more roles of being transported or recovered.

In addition, the various means,

The producer and the consumer of the electrical storage device is configured, the charged electrical storage device produced by the producer is exchanged and distributed at various stages of the activity, the method is made by selling and selling the charged electrical storage device to each other After the consumer (consumer) consumes (discharges) the electricity of the charged electric storage device, the discharged electric storage device is again subjected to several steps from the consumer (consumer). A distribution structure is formed that includes a sale including all of these processes, in which a method of exchanging and distributing at a location is performed, and a method of selling and selling the charged electric storage devices is included, and is returned to the producer. Through letting

 The one or more electricity, which is produced (generated) or delivered at the charging station, is stored (charged) or stored (charged) while being transferred to a distribution method including sales to the electric consumer, It includes one or more steps including consuming (discharging) the stored (charged) electricity at the electricity consumer, and then recovering and restoring (recharging) the distribution method including sales to the charging station. A first means of a distribution method including a sale in which all processes of continuously performing a plurality of times more than two times are performed;

When the producer and the consumer of the electric storage device are configured and the consumer orders the charged electric storage device, the producer delivers the charged electric storage device to the consumer, and the discharged electric storage device consumed by the consumer is the producer. By retrieving an order and delivery structure that includes all of these processes,

At least one of the electricity produced or generated at the charging station is stored (charged) or stored (charged) while being transferred to the electric consumer in an order and delivery method. Once or twice including the process of consuming (discharging) the stored (charged) electricity at the consumer, and then recovering and restoring (recharging) to the charging station again by the order and delivery method. The second means of the order and delivery method, in which all the processes of repeatedly performing the above-described multiple times are performed;

The producer and the consumer of the electrical storage device are configured, and the consumer to be transferred from the producer to the consumer through any one or more of the methods to enable the transfer of the charged electrical storage device that the consumer needs, The discharged electrical storage device that has been consumed (discharged) causes other transportable structures to be formed, including any such process, to be returned to the producer by one or more of the other methods that enable transport. through,

At least one of the electricity produced or generated at the charging station is transferred to the electric consumer through other transferable methods while being stored (charged) or stored (charged), and the It includes one or more steps including consuming (discharging) electricity stored in the electricity consumption station, and then recovering and restoring (recharging) the battery through other transferable methods. The third means of other transferable methods, in which all the processes of continuously and repeatedly performing two or more times a plurality of times are performed;

Among the fourth means using a mixture of the first to third means,

It is characterized by one or more means.

In addition, the third means,

Third a means for loading, transporting, transferring, transferring, and transporting the electrical storage device in a general means of transportation so that the electrical storage device is transferred from the charging station to the electrical consumer, and recovered from the electrical consumption station to the charging station;

After reconstructing a general vehicle into a vehicle for exclusive use of the electric storage device so that it can be used only for the purpose of handling only the electric storage device, the electric storage device is transferred from the charging station to the electric consumer, and is recovered from the electric consumer to the charging station. 3b means for carrying, transporting, transferring, transferring and moving the electric storage device in the electric storage device-only vehicle;

As an electric only transportation means for storing (charging) electricity and outputting (discharging) electricity, it is a method of fixedly equipped or fixedly equipped with an electric storage device therein,

Superconducting power storage car, superconducting power storage ship, superconducting power storage aircraft aircraft, superconducting power storage device train, large capacity power storage system (large capacity power storage system) car, large capacity power storage system (large capacity power storage system) ship, large capacity power Storage (large-capacity power storage system) Aircraft, large-capacity power storage (large-capacity power storage system) trains, batteries (electrical storage or ESS) trains, batteries (electrical storage or ESS) cars, batteries (electrical storage or ESS) Developed (made) by ships, batteries (electrical storage or ESS) aircraft,

Any one or more of the other means of transportation is developed (made) by transforming it into an electric only means of transportation so that it can be used exclusively for storing (charging) electricity and outputting (discharging) electricity.

By directly operating the electric dedicated transport means itself,

The electricity is stored (charged) in the dedicated electric transport means and goes to the electric consumer at the charging station, and after outputting (discharged) electricity that has been stored (charged) in the dedicated electric transport means itself at the electric consumer, the power is returned to the charging station. Third c means for continuously repeating a plurality of times one or two or more cycles of restoring (charging) the dedicated transport means itself;

Among the 3d means which uses the said 3a means-3c means,

It is characterized by one or more means.

In addition, the first means,

The electric storage device is characterized in that it has a structure that can be bought and sold to each other between the producer and the consumer and the third party through the distribution process.

In addition, in order to identify the value (price) of the electrical storage device between the seller and the buyer in the distribution process, the value (price) of the electrical storage device is formed differently according to the degree of use and the amount of electrical storage for each specification. .

In addition, the value (price) identification of the electrical storage device,

The number of times of charging and discharging the electricity is displayed on the electrical storage device, or the number of times of charging and discharging the electricity is displayed, and the remaining capacity of electricity is also displayed.

In addition, the electrical storage device,

Large capacity energy storage device, large storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Storage (ESS), power storage (device), DC power supply (equipment), battery (electric storage or ESS) car, battery (electric storage or ESS) ship, battery (electric storage or ESS) aircraft, One or more of various transportation means having a function of storing (charging) and outputting (discharging) electricity, or various products, articles, facilities, and apparatuses that store (charge) and output (discharge) electricity. It is done.

In addition, the electrical storage device,

It is standardized and standardized with a function and structure capable of continuously and repeatedly performing a plurality of times of charging, transferring, consuming, recovering, and recharging cycles of electricity one or more times.

In addition, the standardized and standardized electrical storage device,

Standardize the electrical storage device to a standard with a constant size and weight, but make a plurality of types according to the specifications to meet the site use conditions, and the same type of the various types of electrical storage devices that have been standardized to form the same electrical specifications It features.

In addition, the standardized and standardized electrical storage device,

The first device as it is, a variety of general products, articles, equipment, devices that perform any one or more functions of storing (charging) or outputting (discharging) existing electricity,

One or more cycles of charging, transferring, consuming, recovering and recharging electricity to general products, articles, equipment, and devices that perform any one or more functions of storing (charging) or discharging (discharging) electricity. A second device that is reinforced or modified (modified) so that the structure (device) is additionally equipped to continuously and repeatedly perform a plurality of times more than two times,

Make new, dedicated products, articles, equipment, and devices capable of performing any one or more of the functions of storing (charging) or outputting (discharging) electricity, and charging, transporting, consuming, recovering, recharging cycles of the electricity. In the process of repeatedly performing a number of times more than one or two times, standardize the size and weight to a certain standard so that the transfer and recovery can be made smoothly by using the electric storage device wireless transfer means. A third device made of a plurality of types according to the standard, and the same type of each of the standardized types of electrical storage devices is standardized to have the same electrical specifications;

Among the fourth devices using the first to third devices,

It is characterized by any one or more devices.

In addition, the first device,

Existing, currently developed, produced and sold

Large capacity energy storage device, large storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy It is characterized in that the storage device (ESS), power storage equipment (device), DC power supply (equipment), or any one or more of a variety of products, articles, equipment, devices that store (charge) and output (discharge) electricity. .

In addition, the second device,

Existing, currently developed, produced and sold

Large capacity energy storage device, large storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy One or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or a variety of products, articles, facilities, and devices that store (charge) and output (discharge) electricity. It is characterized in that it is reinforced in the recovery process so as to be convenient and trouble-free.

In addition, the third device,

Existing, currently developed, produced and sold

Large capacity energy storage device, large storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy The same as any one or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or various products, articles, facilities, devices that store (charge) and output (discharge) electricity; It has a similar function and structure, but reinforces the existing ones to make a new dedicated electric storage device so that it is convenient and trouble-free in the transportation and recovery process.

Superconducting power storage device car, superconducting power storage device ship, superconducting power storage device aircraft, superconducting power storage device train, large capacity power storage system (large capacity power storage system) car, large capacity Power storage device (large capacity power storage system) Ship, large capacity power storage device (large capacity power storage system) Aircraft, large capacity power storage device (large capacity power storage system) Train, battery (electric storage device or ESS) train, battery (electric storage device) Or ESS) a vehicle, a battery (electric storage device or ESS) ship, a battery (electric storage device or ESS) aircraft, and a device made to be a means of transportation having a function of storing (charging) and outputting (discharging) electricity. It is characterized by.

In addition, the electric consumer,

The first consumer has no place (space) to install the charging station or only has a low economy (space), and an electric mass consumer that is good at consuming (discharging) electricity in large quantities and has no place (space) or economical efficiency to install the charging station. In the case of one or more of the second consumer where there is only a place (space),

Installed at a location away from the first or second consumer and at least one of the charging station or intermediate storage station that produces (generated) economical electricity in the clean and safe manner, the electricity is supplied via a wireless transfer method It is done.

In addition, the charging station,

It is a charging station that produces (generates) electricity that is stored (charging) stored in the electricity storage device by installing an electricity generation power facility having a lower cost of producing electricity, which is generated from green energy or renewable energy power facilities. It is characterized by.

In addition, the charging station,

A photovoltaic power generation facility is installed, characterized in that the charging station for producing (power generation) photovoltaic electricity stored in the electrical storage device.

In addition, the charging station,

It is economical place to install photovoltaic facilities, or the installation cost of photovoltaic electricity that is produced (generated) by installing photovoltaic power generation facilities at any one or more places where it is cheaper than the generation unit price of the existing power system electricity. ,

One or two or more solar power generation facilities are installed, characterized in that the charging station for producing (generating) the photovoltaic electricity stored in the electrical storage device.

In addition, the location conditions of the economical place to install the photovoltaic power generation equipment,

Locational first condition that the land price of the place where the photovoltaic facilities are installed is economically inexpensive or does not enter,

Locational second condition, which is a place where solar light is strong or has a long time, so that the amount of photovoltaic electricity is generated.

Locational third condition, which is a spacious place to install the photovoltaic power generation equipment in a large size,

The electricity (generated) produced in the photovoltaic facility is stored (charged) in an electrical storage device and transferred to an electrical consumer, and the consumed (discharged) electrical storage device is a location that is a good place to economically perform a recovery process. Of the fourth condition,

It is characterized by any one or more locational conditions.

In addition, the place with the location conditions of the economical place to install the photovoltaic power generation equipment,

The land where the photovoltaic facility is installed is economically inexpensive land, reservoirs, rivers, lakes, dams, uninhabited islands, uninhabited beaches, small uninhabited islands, uninhabited land, other uninhabited areas, Among other places that don't cost land,

It is characterized by any one or more places.

In addition, the location of the power generation price of the photovoltaic electricity that is produced (generated) here by installing the photovoltaic power generation facilities is cheaper than the power generation price of the existing power system electricity,

The amount of photovoltaic electricity (power) produced (generated) at the photovoltaic power generation facilities is higher than the amount of electricity (power) generated at various power plants generated by consuming fossil fuels such as existing nuclear power plants or thermal power plants. It is characterized in that it is a good place to install large-scale photovoltaic power generation equipment.

In addition, the place with the above location conditions,

Sea, desert, plateau, poles, distant sea, wide desert, wide plateau, distant sea of broad lake, distant sea of wide river, distant sea of wide dam, uninhabited tundra, wide desert island, uninhabited Other large areas, among other large and spacious places that don't cost land,

It is characterized by any one or more places.

In addition, the charging station,

Transfer the charged electrical storage device from the charging station to the electrical consumer, one or more places equipped with various infrastructures that can be made quickly and smoothly, the intermediate storage house where the electrical storage device (charged or discharged) is collected 1 Many places are installed more than two places or two places,

It is characterized in that the charging station for transferring and recovering the electrical storage device (charged or discharged) between the intermediate station and the charging station by a wireless transfer method.

In addition, the intermediate collection station,

Various roads, air routes, shipping routes, and other transportation facilities that connect between the intermediate storage station and the electrical consumer, which can be made quickly and smoothly to transfer the electrical storage device (charged) from the intermediate storage station to the electrical consumer. Related infrastructure is built,

The cost of the process of supplying electricity from the charging station to the electric consumer using the wireless transfer method is characterized in that the intermediate collection station is cheaper than the cost of using the conventional wire transfer method.

In addition, the electric consumer,

The first consumer has no place (space) to install the charging station or only has a low economy (space), and an electric mass consumer that is good at consuming (discharging) electricity in large quantities and has no place (space) or economical efficiency to install the charging station. In the case of one or more of the second consumer where there is only a place (space),

It is installed at a location away from the first or second consumer and at least one of the charging station or intermediate storage station for producing (generated) electricity in the future energy production method, characterized in that the electricity is supplied via a wireless transfer method. .

Also,

The electricity produced (generated) by the future energy production method,

It is characterized in that the electricity is produced without endless exhaustion of energy and produced without the problem of environmental pollution and safety risks.

In addition, the electricity is produced without endless depletion of energy while being produced in an infinite amount of environmental pollution problems and safety risks,

It is characterized in that the electricity brought by the electric energy transportation device from the space and the earth.

In addition, the place where the charging station to receive the electricity (generated) produced by the future energy production method to be delivered to the electrical consumer, should be installed,

Inside charging stations that produce (generate) economical electricity in a clean and safe way,

Involvement of various roads, air routes, shipping routes, and other transportation facilities connecting the intermediate storage station with the electrical consumption station, which can be carried out quickly and smoothly to transfer the electrical storage device (charged) from the intermediate storage station to the electrical consumer. The infrastructure is established so that the cost of supplying electricity from the charging station to the electric consumer using the wireless transfer method is lower than the cost of using the conventional wire transfer method.

Or a place where you can receive and transfer electricity at low cost,

It is characterized by any one or more places.

In addition, a place where the electricity can be cheaply received and delivered,

In the process of receiving the electricity (energy) brought by the electric energy transport device from the sky or the space and delivering it to the electric consumer,

In the charging station, the cost in the process of supplying electricity to the electric consumer using the wireless transfer method, characterized in that the place to go cheaper than the cost in the process using the conventional wire transfer method.

In addition, the place where the cost of the process of supplying electricity to the electric consumer by using the wireless transfer method in the charging station is cheaper than the cost of the process using the existing wire transfer method,

Relevant infrastructure of roads, air routes, shipping routes, and other transportation facilities connecting the charging station with the electrical consumption station, which makes it possible to quickly and smoothly transfer the electrical storage device (charged) from the charging station to the electrical consumption station. It is characterized by being a place.

In addition, the electric energy transport device,

It is equipped with a photovoltaic power generation unit composed of photovoltaic power generation facilities that generate (generate) electric energy by receiving light energy from the sun or the sky,

It is provided with an electrical storage device including a function of storing (charging) the electricity produced (generated) in the solar power generation unit in the sky or space, and delivering the electricity stored (charged) at a designated charging station,

The electricity produced in the photovoltaic unit (generated) is stored in an electrical storage device, and configured to be connected to each other, the electric, control circuits to output (discharge) the stored (charged) electricity,

In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station, the earth and space,

It is characterized in that the flying device to store (charge) the photovoltaic electricity produced (generated) in the photovoltaic power generation unit from the sky or the space to the electrical storage device, bringing it to the designated charging station and deliver.

In addition, the electricity production, transportation cycle,

The electric energy transport device flies up into the earth or space (space), stays in the earth or space (space), produces (generates) and charges (stores) solar electricity, then returns to the designated charging station Characterized in that it is an integral process up to delivering electrical energy.

In addition, the designated charging station,

Collecting (collecting), storing (charging), or the removable electric storage device which has been charged and transported is recovered from the earth or space and stored in the electric storage device provided in the electric energy transport device. Among those designated stations that use a location, location, or name, with facilities, facilities or personnel to replace the removable electrical storage device to be recharged,

It is characterized in that any one or more charging station.

In addition, the electric energy transport device,

Rather than the total amount of energy consumed (consumed) in a single cycle of electricity production and transportation, electricity is generated (generated) from the sky and space through a single cycle of electricity production and transportation, and brought to a designated charging station. It is characterized by a higher total amount of energy (which has been transported).

In addition, the energy required for the operation (driving) of the electric energy transportation device,

It is characterized by the fact that natural forces (energy) obtained naturally by utilizing the principles of nature without incurring extra energy.

In addition, the natural force (energy),

When the electric energy transport device floats over the earth or in space, stays in the earth or in space, returns to the designated electric energy delivery site from the earth or in space, or drives a large amount of energy. During the operation (driving) of the section, it is characterized in that it takes energy in any one or more of the running section.

In addition, the power of nature,

It is a buoyancy force in the air that tries to push it up in the opposite direction of the earth's gravity.

In addition, the buoyancy in the air,

Natural buoyancy made using a buoyancy material, artificial buoyancy made by applying a negative pressure (-) or vacuum to artificially generate buoyancy is characterized in that at least one.

In addition, the natural buoyancy,

It is characterized in that the buoyancy is formed naturally by filling the buoyancy material in the space having a certain volume (object having a certain volume of space).

In addition, the buoyancy material,

It is characterized in that the material having a density lower than the density of air.

In addition, the material having a density lower than the density of the air,

Helium gas, hydrogen gas, methane gas, characterized in that any one or more of nitrogen.

In addition, the artificial buoyancy is characterized in that the buoyancy is formed by applying a negative pressure (-) or a vacuum to artificially generate buoyancy in a space having a certain volume (object having a certain volume of space).

In addition, by forming a space having a certain volume inside the electric energy transport device to fill the buoyancy material in the space to form a natural buoyancy, or to form artificial buoyancy by applying a negative pressure (-pressure) or vacuum in the space The first method comprising any one or more of the method of installing a buoyancy device made to have one or more buoyancy of natural buoyancy or artificial buoyancy, or inside the electric energy transport device,

A second method of providing a buoyancy device having one or more buoyancy of the natural buoyancy or artificial buoyancy as an additional configuration separately to the electric energy transport device;

Among the third method of adjusting the magnitude of the buoyancy of any one or more of the natural buoyancy, artificial buoyancy, or buoyancy device in the first method and the second method,

It is characterized in that to cover the energy required for the operation (drive) of the electric energy transport device in any one or more ways.

In addition, the adjustment of the magnitude of the buoyancy in the third method,

Buoyancy of any one or more of the natural buoyancy, artificial buoyancy, or buoyancy of the buoyancy device provided separately to the electrical energy transport device to be formed in the electrical energy transport device,

In the pressure of a buoyant material, negative pressure (-pressure), vacuum, or the volume of space in which the buoyancy is to be formed,

It is characterized by applying or adjusting any one or more of them.

In addition, the buoyancy device,

An object having a closed volume of a constant volume, the mass per volume of the object has a lower mass than the air per the same volume of the surrounding air, it characterized in that the effect of buoyancy in the air (air) over the earth.

In addition, by inserting (injecting) a buoyant material, applying a negative pressure (-pressure), or applying a vacuum to an object having a constant volume of closed space,

The mass per volume of the object is characterized by having a lower mass than the air per equal volume of the surrounding air.

In addition, the flying device is characterized in that it is used as an electric energy transportation device by making a drone.

In addition, the electric consumer is an electric load that generates heat among the electric loads directly operated by direct current (DC) electricity itself, which is output (discharged) from the electric storage device, characterized in that all or part of the battery-operated prefabricated heating wire is used.

In addition, the battery electric operation prefabricated heating wire,

Low-resistance value or multi-function required to obtain the desired heat using ultra-fine wires made of single metal or alloy metal with different strands, thicknesses, materials, and functions. Among them, to have any one or more, prefabricated synthetically made into one bundle through the bundling operation, characterized in that one such bundle is a strand of hot wire.

In addition, the desired column,

It is characterized in that the heat to obtain a desired amount of heat only if you consume a lot of energy in the place where heat is needed.

In addition, the heat is required to consume a lot of energy where the heat is needed to obtain the desired amount of heat,

Heat required for building floor heating, heat required for space heating, water or other liquids, heat required for melting, boiling or warming solids, heat required for thawing or melting snow, heat required for drying Energy required for space heating applications, farming (crop cultivation) facility heat for house heating, heat tracing, heating jackets, or other fields that require heat. Among the heat of various uses that consume a lot and get heat,

It is characterized in that any one or more columns.

In addition, the prefabricated heating wire,

First, a heating wire having a low resistance value necessary to obtain a desired heat using battery electricity or a safe low voltage direct current (DC) electricity below 24V,

Secondly, a battery wire or a heating wire that exhibits one or more additional functions with the low resistance required to obtain the desired heat using safe low voltage direct current (DC) electricity below 24V,

Third, any heating wire of at least one of the first and second heating wires and excellent flexibility of heating wires,

Fourth, customized heating wires, each of which is precisely matched to each other in various cases so as to have any one or more functions of the first to third heating wires,

Fifth of the heating wires that can be economically and easily mass-produced at any time with the same product with the same performance as the customized heating wires made by the fourth above,

It is characterized in that any one or more hot wire.

In addition, the customized heating wire,

The combination of the ultrafine wires is changed, and the bundle of the ultrafine wires is changed through a bundle.

In addition, the ultra-fine wire group of the heating wire to perform the multi-function,

One strand of NASLON, which is a steel fiber, has a thickness of 20 µm or less, and 100 or more strands of the same thickness, while the entire surfaces of these multiple strands of microfibers are in contact with each other from the beginning to the end in the longitudinal direction, so that all the microscopic wires are in contact with the current as a whole. It can be flowed to each other, it is characterized in that the bundle is made by combining the combination so that the electrical contact is made to each other.

In addition, the ultra-fine wire group of the heating wire to perform the multi-function,

One strand of NASLON, a steel fiber, has a thickness of 12 μm (correspondingly fine wire diameter), and the number of strands having the same thickness is 550.

One strand of NASLON, a steel fiber, has a thickness of 8 µm (correspondingly fine wire diameter), and the number of strands having the same thickness is 1,000, or

The thickness of 1 strand of NASLON, which is a steel fiber, is 6,5 µm (correspondingly fine wire diameter), and the number of strands having the same thickness is 2,000 strands,

It is characterized in that it is made of any one or more groups.

In addition, the multi-function heating wire,

With prefabricated heating wires, all of these features are flexible, with the low resistance required to achieve the desired heat using battery electricity or safe low-voltage direct current (DC) electricity below 24V, and at the same time performing any one or more functions simultaneously. It is characterized in that the hot wire is expressed in complex.

In addition, the heating wire having any one or more specific functions,

Heat rays that emit far infrared rays,

Instant high temperature heating, heating wire with high efficiency heating function,

Heating wire with constant temperature function,

Hot wire with excellent tensile strength and durability, easy disconnection or low resistance value change,

Among the hot wires having a function of suppressing oxidation reactions,

It is characterized in that any one or more hot wire.

In addition, the heating wire is emitted from the far infrared,

Battery electricity or safe low-voltage direct-current (DC) electricity of 24V or less, many of the micro strands of multiple strands, the multiple groups of micro strands, or the combination of the micro strands and micro strand groups that generate far infrared rays while generating heat due to resistance And select one or more of these, and then combine one or more of the selected micro strands of the multiple strands, the multiple groups of the micro strands, or a mixture of the micro strands and the micro strands group so as to be in contact with each other. A composite combination of any one or more of these multiple strands of microfibers, multiple groups of microfibers, or a mixture of microfibers and microfibers, into one bundle, In a way that makes the strands hot wires, which can be more easily radiated by the electric dipole radiation from which far infrared radiation is emitted. It is characterized by having a geometry.

In addition, the geometry in which the electric dipole radiation can be radiated larger and better,

Synthetic combinations inside the bundle,

When the resistance value, material or thickness of one or more of a plurality of micro wires, a plurality of micro wire groups, or a mixture of a micro wire and a micro wire group are one or more, the same condition may be used. Make the number of strands (or the number of groups, or the number of mixtures) of one or more of the same, or the same as that of the same,

One or more of two or more groups having different resistance values and having the same resistance value for each group having different resistance values, or at least one of a mixture of the micro wires and the micro wire groups. It is characterized by making it into more than one strand (or one group, one mixed thing) or two strands (or two groups, two mixed things).

In addition, the micro fine wire, the micro fine wire group, or a mixture of the ultra fine wire and the ultra fine wire group,

When the electricity flows, the dipole moment is made and is characterized in that the material (material) to emit a large amount of far infrared rays.

In addition, when the electricity flows, a dipole moment is formed, and a material (material) that emits a large amount of far infrared rays,

When the material itself is heated to a temperature of 50 ℃, far infrared rays have a wavelength length in the range of 3 to 200 microns (μm), mono- or alloy metals emitting more than 60% of emissivity,

Pure iron or alloy metal containing pure iron,

Alloy metal containing carbon,

SUS 316, SUS 304, stainless steel alloy metal,

Steel fiber (metal fiber) (NASLON),

Nickel and copper alloy metals made from 20-25 wt% nickel and 75-80 wt% copper,

Among alloy metals made from 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum,

It is characterized by any one or more.

In addition, the heating wire having the constant temperature maintaining function,

Multiple strands (or multiple groups, or multiple strands) of two or more fine strands (or two or more mixed groups) of a micro wire (or a group of micro wires and a micro wire group) having a predetermined resistance value Choose a combination), and make a group with two functions with different heating function,

The first type group continues to generate heat when current flows, and the second type group generates less heat after reaching a predetermined temperature and conducts current just like a conductor rather than conducting heat as it is conductored. It is a bundle made by synthesizing these two ultrafine wires (or a combination of ultrafine wire groups, or a combination of ultrafine wire groups and ultrafine wire groups) into one.

In addition, the heating wire having the constant temperature maintaining function,

After the heating operation is started and the electricity is continuously supplied, the temperature-keeping function is expressed in the material itself, and once it has risen to a certain temperature unless there is a temperature change in the surrounding environment in the heating wire (bundle) material itself without a separate temperature control device The temperature of the rising stop is characterized in that the heating wire is kept constant.

In addition, the first type group is a steel fiber (NASLON), the second type group is characterized in that the silicon copper alloy.

In addition, the heating wire having a function of suppressing the oxidation reaction,

SUS 316, SUS 304, stainless steel alloy metal,

Steel fiber (metal fiber) (NASLON),

Alloy metal made by adding a small amount of molybdenum to a nickel copper alloy made of 20-25 wt% nickel and 75-80 wt% copper,

Mixing ratio 68% to 73% by weight of iron, 18% to 22% by weight of chromium, 5% to 6% by weight of alumina, and 3% to 4% by weight of molybdenum iron chromium alumina molybdenum alloy, by adding at least one of manganese and carbon Among the alloy metals made,

It is characterized in that it is made of a fine wire made of any one or more materials.

In addition, the low resistance value required to obtain a desired heat by using a pre-battery electricity or a safe low voltage direct current (DC) electricity of 24 V or less,

After selecting a micro wire (or a group of micro wires or a mixture of micro wires and micro wire groups) having a higher resistance value per unit length than a conductor, the micro wire (or a micro wire group having a higher resistance value than the conductor), or A bundle of composites produced by increasing the number of strands (or the number of groups or the number) of a mixture of ultra fine wires and ultra fine wires, and synthesizing them in energized contact with each other in the longitudinal direction to lower the composite resistance value. The first method to make these bundles a single strand of heat,

Dividing the method into two or more groups, the first group is a micro wire (or a combination of a micro wire group or a combination of a micro wire group and a micro wire group) having a resistance value equal to or similar to a conductor per unit length. Select it,

After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than the conductor,

The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The second method of making a strand of hot wire,

Dividing the selection into two or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group) to be carried out,

After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than the conductor,

The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The third method of making a strand of hot wire,

Dividing the selection into three or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor, rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group) to be carried out,

The second group selects a micro wire (or a micro wire group or a mixture of micro wire and micro wire groups) having a resistance value equal or similar to that of a conductor per unit length,

After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,

The first group, the second group, and the third or more groups of microfibers (or microfibers, or a mixture of microfibers and microfibers) are combined into a single bundle by energizing and contacting each other in the longitudinal direction. , The fourth method of making these bundles a single strand of heat,

Among the fifth method using a mixture of the first method to the fourth method,

It is characterized by obtaining in any one or more ways.

In addition, in the first to fifth methods, the resistance value per unit length is the same as or similar to that of a conductor, or the ultrafine wire (or the ultrafine wire group or the ultrafine wire having a resistance value higher than that of the conductor). Metal is a material of a mixture of micro fine wire groups,

Gold, platinum, silver, copper, aluminum, pure iron, tungsten, or nickel, characterized in that any one or more.

In addition, in the first to fifth methods, the resistance value per unit length is the same as or similar to that of a conductor, or the ultrafine wire (or the ultrafine wire group or the ultrafine wire having a resistance value higher than that of the conductor). Alloy metal is a material of a mixture of ultra fine wire groups,

Nickel copper alloy alloy metal, nickel chromium alloy alloy metal, iron chromium alloy alloy metal, iron carbon alloy alloy metal, hard copper or hard alloy alloy metal, steel fiber (metal fiber) (NASLON), graphene or graphene Alloy metals, stainless steels (SUS 316 and SUS 304) alloy metals mixed with, alloy metals containing pure iron or pure iron, alloy metals containing carbon,

Nickel and copper alloy metals made from 20-25 wt% nickel and 75-80 wt% copper,

Among alloy metals made from 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum,

It is characterized by any one or more.

In addition, in the third method to the fifth method, a fine wire that performs a function of generating less heat after reaching a predetermined temperature and allowing a current to simply flow like a conductor rather than generating heat while being conductive. (Or a mixture of an ultrafine wire group or a mixture of an ultrafine wire group and an ultrafine wire group)

It is characterized in that any one or more of silicon copper alloy series alloy metal, silicon bronze alloy series alloy metal, silicon iron alloy series alloy metal.

In addition, the bundling operation,

All micro-wires in the bundle are brought into close contact with each other, and the entire surface of all the micro-wires in the bundle from the start to the end in the longitudinal direction is in contact with each other in the longitudinal direction, so that the current can flow to all the micro-wires throughout the contact surface. Composite combination of ultra fine wires,

A first method of wrapping a plurality of micro fine wires with high temperature fibers by wrapping the high temperature fibers overlapping with the high temperature fibers in a longitudinal direction,

The second method of bundling itself into a body by twisting itself through a combine machine,

A third method of extracting and bundling while coating the coating machine,

A fourth method of bundling the third method two or more times,

A fifth method using a different coating material for each coating number as the fourth method,

A sixth method of extracting and bundling one or two or more coatings made of the first method or the second method into a coater;

The first or second method is made by coating the coating machine once or twice or more, the coating material is the same by the number of times, or the number of parts by the same part is different, the number of times pulled while coating all differently The seventh method of bundling out,

Eighth method of inserting the adhesive between the upper and lower plates of the plate-shaped material, and then melted and bundled with the adhesive,

Among the ninth method of inserting any one or more of the bundles made by the first method to the eighth method between the upper and lower plates of the plate-shaped material, injecting the adhesive and then melting and bundling the adhesive,

It is characterized by any one or more methods.

In addition, the high temperature fiber coating material of the said 1st, 6th, 7th method,

Aramid, polyarylate (POLYARYLATE), gyrone, a fiber made of graphene (carbon fiber), characterized in that any one or more.

In addition, the coating material of the third, fourth, fifth, sixth, seventh, nineth methods,

Teflon, PVC, silicon, graphene, ceramics, ceramics, carbon black, ceramic coating material REFRACTOCOAT (reflector coat), tetraethylortho [silicate (TEOS) + silica zirconium silicate powder dispersed in liquid binder Putty], Cerakwool (Cerakwool), or Aerogel (Aerogel), characterized in that any one.

In addition, the battery electricity,

Characterized in that the electricity is output (discharged) in various electrical storage devices capable of charging or discharging electricity.

In addition, the various electrical storage device,

At least one of the electric storage device, characterized in that.

In addition, the various electrical storage device,

An electric storage device that outputs (discharges) direct current (DC) electricity and outputs (discharges) any one or more of electricity at a specific range of voltages of 24 V or less or a voltage of 24 V or less. do.

In addition, the battery electricity,

Characterized in that any one or more of the direct current (DC) of the various voltage bands output (discharged) in the electrical storage device.

In addition, the battery electricity,

The use of direct current (DC) electricity, characterized in that any one or more of any voltage of a voltage of 24V or less or a voltage of a specific range of voltage of 24V or less.

In addition, the safety low voltage direct current (DC) electricity of the 24V or less,

The use of direct current (DC) electricity, characterized in that any one or more of any voltage of a voltage of 24V or less or a voltage of a specific range of voltage of 24V or less.

In addition, the safety low voltage direct current (DC) electricity of the 24V or less,

Among the electricity output from the electrical storage device, it is characterized in that any one or more of any of the voltage of the voltage of 24V or less or the voltage of a specific range of voltage of 24V or less.

In addition, the low resistance value,

The battery is characterized in that the resistance value that can flow the amount of current that can cause the desired heat operation.

In addition, the low resistance value,

The electricity output from the electrical storage device, characterized in that the resistance value that can flow the amount of current that can cause the desired heating operation.

In addition, the low resistance value,

Electricity is output (discharged) from the various electrical storage devices capable of charging or discharging electricity, characterized in that the resistance value that can flow the amount of current that can cause the desired heat operation.

In addition, the low resistance value,

It is a direct current (DC) electricity, but any one or more of a voltage of 24V or less, or electricity of a specific range of voltages of 24V or less, which is a resistance value capable of flowing an amount of current that can cause a desired heating operation. It features.

In addition, the low resistance value,

Any of the voltage of 24V or less output from the electrical storage device or any one or more of the electricity of a specific range of voltage of 24V or less voltage, the resistance value that can flow the amount of current that can cause a desired heating operation It is characterized by.

In addition, the desired column,

In order to obtain a desired heating value or temperature within the desired time in the prefabricated heating wire, the amount of power in proportion to the heating value is consumed within the corresponding time in the prefabricated heating wire, and for this purpose, the power value (power amount) is calculated by dividing by the corresponding voltage to be used. The current value (amount of current) is heat generated when a heating operation is caused to flow to the prefabricated heating wire at a corresponding time with a corresponding voltage.

In addition, the material (material) of the prefabricated heating wire of the low resistance value,

Any one of silver, tungsten, platinum, aluminum, copper, nickel, pure iron,

SUS 316, SUS 304, stainless steel alloy metal,

Steel fiber (metal fiber) (NASLON),

Nickel copper alloy metal made from 20-25 wt% nickel and 75-80 wt% copper,

Iron chromium alumina molybdenum alloy metal made from 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum,

Among the silicon copper alloy metals made of 20% by weight of silicon and 80% by weight of copper,

It is characterized by any one or more.

In addition, the micro fine wire,

Among the ultrafine wires made of the above-mentioned silver and having a resistance value of 0.1058 kPa (fine wire thickness 0.1531 mm 2), 0.241 kPa (fine wire thickness 0.06721 mm 2), or 1.1150 kPa (fine wire thickness 0.014527 mm 2),

It is characterized by any one or more.

In addition, the micro fine wire,

An ultrafine wire made of tungsten and having a resistance value of 1 m 3 (length of ultra fine wire 0.0532 mm 2), 5.768 mm (fine wire thickness 0.0095 mm 2) or 8.179 mm (fine wire thickness 0.0067 mm 2),

It is made of platinum and the resistance value per 1m length is 0.2058Ω (fine wire thickness 0.51mm2), 0.913Ω (fine wire thickness 0.115mm2), 2.058Ω (fine wire thickness 0.051mm2), 4.565Ω (fine wire thickness 0.023mm2) Or 14.999 Ω (fine wire thickness 0.007mm2),

It is characterized by any one or more.

In addition, the micro fine wire,

The steel fiber (metal fiber) (NASLON) and the resistance value per 1m length is 50.5Ω (microwire thickness 0.017229mm2), 90.3Ω (microwire thickness 0.009635mm2), 170.5Ω (microwire thickness 0.005103mm2) or 281Ω ( In the ultra fine wire having a fine wire thickness of 0.003096 mm2),

 It is characterized by any one or more.

In addition, the micro fine wire,

An ultrafine wire made of copper and having a resistance value of 0.1098 kPa (microwire thickness 0.1538 mm 2), 0.235 kPa (microwire thickness 0.0718 mm 2) or 1.1123 kPa (microwire thickness 0.015386 mm 2),

Among the ultrafine wires made of the above-mentioned aluminum and having a resistance value of 0.0201 mW (fine wire thickness 1.3 mm 2), 0.0315 mW (fine wire thickness 0.83 mm 2) or 0.356 mW (fine wire thickness 0.0735 mm 2),

It is characterized by any one or more.

In addition, the micro fine wire,

An ultrafine wire made of nickel and having a resistance value of 1,018 mW (fine wire thickness 0.053 mm 2), 6.2727 mW (fine wire thickness 0.011 mm 2) or 8.625 mW (fine wire thickness 0.008 mm 2),

It is made of pure iron and the resistance value per 1m length is 0.1886Ω (fine wire thickness 0.53mm2), 0.909Ω (fine wire thickness 0.11mm2), 2Ω (fine wire thickness 0.05mm2), 4.347Ω (fine wire thickness 0.023mm2) or Of the fine wire which is 12.5Ω (fine wire thickness 0.008mm2),

It is characterized by any one or more.

In addition, the micro fine wire,

The fine wire made of SUS 316 and having a resistance value of 1 m in length of 50 mW (fine wire thickness 0.015386 mm 2), 90 mW (fine wire thickness 0.00785 mm 2), 170 mW (fine wire thickness 0.004525 mm 2) or 280 m (fine wire thickness 0.002523 mm 2) medium,

 It is characterized by any one or more.

In addition, the micro fine wire,

An ultrafine wire made of the above-mentioned iron chromium alumina molybdenum alloy and having a resistance value of 48 mW (fine wire thickness 0.015386 mm 2) or 82 mW (fine wire thickness 0.00785 mm 2),

An ultrafine wire made of the nickel-copper alloy and having a resistance value of 11 mW (fine wire thickness 0.025434 mm 2) or 36 mW (fine wire thickness 0.00785 mm 2),

The ultra fine wire made of SUS 316 and having a resistance value of 1,650 m (fine wire thickness 0.0001005 mm 2), 17,330 mW (fine wire thickness 0.00004436 mm 2) or 26,375 m (fine wire thickness 0.00002914 mm 2),

The ultra-fine wire made of the steel fiber (NASLON) and having a resistance value of 1,700 m (fine wire thickness 0.000113 mm 2), 17,319 m (fine wire thickness 0.00005024 mm 2) or 26,239 m (fine wire thickness 0.00003316 mm 2) medium,

It is characterized by any one or more.

In addition, the micro fine wire,

A fine wire made by adding a small amount of molybdenum to the nickel copper alloy and having a resistance value of 11.2 kW (micro wire thickness 0.02512 mm 2) or 36.5 kW (micro wire thickness 0.00770 mm 2) per 1 m length,

Among the ultrafine wires made by adding at least one of manganese and carbon to the iron chromium alumina molybdenum alloy and having a resistance value of 48.7 Ω (fine wire thickness 0.0151 mm 2) or 83.7 Ω (fine wire thickness 0.008785 mm 2) per 1 m length,

It is characterized by any one or more.

And the micro fine line,

Among the ultrafine wires made of the above-mentioned silicon copper alloy and having a resistance value of 50 m (fine wire thickness 1 mm 2) or 104.8 m (fine wire thickness 0.477 mm 2) per 1 m length,

It is characterized by any one or more.

According to the above-mentioned means for solving the problems, it is possible to economically produce electricity (energy) by the photovoltaic power generation method.

In addition, it is possible to make full use of the best places to produce solar power (energy) more economically and mass.

In addition, it may have a photovoltaic facility technology that can handle the base load.

And technology that can produce photovoltaic electricity in a clean way (without pollution, fine dust, carbon emissions), almost indefinitely, almost permanently, and with no safety risks such as nuclear power plants. Can have

1 is a flowchart illustrating a method of implementing a future energy generation system according to an embodiment of the present invention.
2 is a block diagram of a future energy generation system according to an embodiment of the present invention.
3 is a flow chart illustrating a method of manufacturing a battery-operated prefabricated heating wire used for heating in the electrical consumer shown in FIG. 2.
4 is an exemplary view of a prefabricated heating wire manufactured by FIG. 3.

Hereinafter, the configuration and operation of the embodiments of the present invention will be described with reference to the accompanying drawings.

It should be noted that the same elements among the drawings are denoted by the same reference numerals and symbols as much as possible even though they are shown in different drawings.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

<Example 1>

1 is a flow chart showing a method of implementing a future energy generation system according to an embodiment of the present invention, Figure 2 is a block diagram of a future energy generation system according to an embodiment of the present invention.

As shown in Figures 1 and 2 the implementation method of the future energy generation system according to an embodiment of the present invention,

(a) Production (power generation) of economical electricity in a clean and safe way (stored or charged) in the electrical storage device 20, or received by the electricity produced (generated) by the future energy production method to the electrical consumer 30. In the step of delivering, configuring the charging station 10 to perform any one or more roles (S10);

(b) constructing an electrical storage device 20 for transferring electricity of the charging station 10 by a wireless transfer method (S12);

(c) configuring the electrical storage device wireless transfer means 40 so that the electrical storage device 20 can perform the wireless transfer method (S14);

(d) constructing an electric consumer (30) using (consuming) electricity supplied from the charging station (10) (S16); And

(e) An electric storage device 20 that stores (charges) or maintains a charge (stored) state of electricity produced (generated) or transmitted from the charging station 10 to the electric storage device wireless transfer means 40. Transferring to the electric consumer 30 by a wireless transfer method (S18);

It is configured to include.

<Example 2>

The future energy generation system implementation method and the power generation system according to the present invention is a technology (method) that solves and overcomes all the problems of the first to fourth in the technology that is the background of the invention,

As the most important prerequisite for the implementation of the present invention, by presenting a common optimal solution that can completely overcome all four problems at the same time,

In <Example 1>,

By supplying the electricity produced (generated) or delivered in the charging station 10 to the electric consumer (area, facility, building, equipment, equipment, consumer, etc.) 30,

Instead of using a conventional wire transfer method (transmission and power distribution through a power line and a power line), a method of supplying through a wireless transfer method according to the present invention should be used.

The wireless transfer method,

Electricity produced (generated) or transmitted from the charging station 10 is supplied to the electric consumer 30 by realizing the charge, transfer, consumption, recovery, and recharge cycles of electricity.

And the charge, transfer, consumption, recovery, recharge cycle of the electricity,

One or two or more of the plurality of the electrical storage devices, while maintaining (charged) or stored (charged) the electricity of any one or more of those produced (generated) or delivered at the charging station, A one-time process involving transferring to an electrical consumer, consuming (discharging) electricity stored (charged) at the electrical consumer, and then recovering and restoring (recharging) the charging station again. Or a cycle of continuously and repeatedly performing two or more times a plurality of times.

In more detail,

As the future energy of humanity in the future, among the new renewable energy or green energy, especially as the future energy of humanity in the future, it can produce a large amount of electricity (electric power) indefinitely in a clean way (without pollution, fine dust, carbon emission) and produce almost permanently. The only way to produce energy with optimal conditions would be to use solar power generation (because the earth's surface receives 14,000 watts of energy from the sun for an hour). Billion kWh), equivalent to nine times the world's annual electricity production in 2008 (the amount of sunlight shining into the earth for about seven minutes is greater than the global energy use for one year). The objective of the present invention can be easily changed only by converting the photovoltaic power generation method to the future energy production (power generation) method of humanity in the future. Can be achieved-Source of Ministry of Trade, Industry and Energy),

The reason why such a good photovoltaic power generation method is not widely spread as future energy of human beings until now and is not activated or popularized is that the first problem and the fourth problem as described above are not overcome in the technology that is the background of the present invention. Because.

Therefore, as a way to overcome all four of these problems,

① The first problem, how to completely overcome (solve) the problem that the electricity (energy) produced by photovoltaic power generation is not economical,

In detail,

As mentioned above, the area (place or space) occupied by photovoltaic facilities is much wider (many) than that of conventional thermal or nuclear power plants, while the amount of energy (electricity) produced here is greater than that of conventional thermal or nuclear power plants. Much less,

Compared to the large area (place, space, etc.) occupied by photovoltaic facilities, the amount of electricity (power) produced (generated) is so small that the energy (energy) produced is not economically due to high land (ground) costs. It's going to be

In particular, the mass electricity consumption centers (new cities, urban areas, various buildings, various apartments, factory areas, various industrial facilities, various buildings, various large electric facilities or electric devices, various large electric consumers, etc.) that are suitable for consuming (discharging) electricity in large quantities. In (), if the land is expensive and the solar power equipment is installed and operated, which takes up a lot of this expensive land and produces a small amount of electric energy, the production cost of electricity produced here is very expensive. Inevitably, it loses its economic feasibility and competitiveness compared to electricity produced by consuming existing fossil fuels or electricity produced by nuclear power plants.

In addition, in the electrical mass consumption area, which is good for consuming (discharging) electricity in a large amount, there are few or small places (spaces) in which photovoltaic power generation facilities can be installed in large sizes, while the demand for electricity is too large. The installation of photovoltaic power generation facilities at a large place also causes a problem that the amount of electricity (power) produced here can not easily meet the demand of large amounts of electricity (power).

However, in contrast to the above phenomenon, a place where solar power generation facilities are installed to produce photovoltaic electricity, and a good place to generate electricity (power generation) (ground, water, sea, or space) mostly uses electricity. It is far from consumers (new cities, urban areas, various buildings, various apartments, factory areas, various industrial facilities, various buildings, various large electric facilities or electric devices, and various large electric customers) which are good to consume (discharge) in large quantities. While the locational conditions for producing (generating) electricity are greatly advantageous as described above, they have a characteristic of being located at a distance (distantly) from a consumer who is good at consuming (discharging) such electricity. .

Therefore, the existing wired transfer method (transmission and distribution method through a transformer and a power line) of the electricity produced (generated) at a place where the electricity is produced (generated) is good for the mass consumption of electricity (discharged) which is good for consuming a large amount of electricity. ), The greater the transmission distance, the greater the transmission cost, and the greater the power loss rate, which in turn increases the power generation cost of photovoltaic electricity and significantly reduces its competitiveness. do.

As a result, the problem of using the existing wired transfer method without improving the technology of transmitting electricity produced in the photovoltaic power generation facilities, prevents the good photovoltaic power generation method from spreading to the present time. It is the main cause of this problem, and it is a major problem that makes it difficult to achieve activation and popularization.

If you verify this problem using Example 1,

In electricity mass consumption that is good to consume electricity (discharge) in large quantities,

When you want to use the large amount of electricity, photovoltaic electricity that is the future energy to produce in a safe and clean way,

In order to produce (generate) the photovoltaic electricity directly at the mass electricity consumer, a large area (land) to install the photovoltaic power generation facilities is required, and such mass electricity consumer usually develops the urban area or the industrial area. Expensive, and the installation or installation location of photovoltaic power generation facilities is small,

In fact, when the photovoltaic electricity is produced (generated) locally, power generation costs due to the rise of the zone are greatly increased, or the photovoltaic electricity cannot be sufficiently produced (generated) or hardly produced (generated).

Therefore, even in such a case, by using the photovoltaic electricity that is the future energy to produce a large amount of electricity necessary in a safe and clean manner in the mass electricity consumer,

The location of the photovoltaic electricity production and the actual consumption of photovoltaic electricity is configured differently,

The solar power generator is a good place to produce electricity (power generation) (ground, water, sea, or space), or it is good to produce electricity (power generation) and continuously produces a large amount of electricity (power generation). ) A good place to go (ground, water, sea, or space),

A large-scale photovoltaic facility (facility) is installed here, and a large amount of photovoltaic electricity is produced (generated) in such a place, and a large amount of photovoltaic electricity produced in this way is generated. The method to send it to the consumer who is easy to consume (discharge) and to be able to use (electricity consumption),

When assuming that the photovoltaic electricity that is produced (generated) in a safe and clean manner is an optimal method of making electricity more economical,

As a method of supplying the photovoltaic electricity produced in large quantities in the photovoltaic electricity producing area (electric power generation) to the place where the photovoltaic electricity is actually consumed, that is, the electricity supply method,

Method to supply by using the existing wired transfer method that is currently used by humanity,

Comparing the method of supplying using the wireless transfer method according to the present invention,

First, if applied by applying the method of supplying using the wire transfer method of the existing electricity supply method,

In Example 1, the positions of the photovoltaic electricity producing place and the photovoltaic electricity consumption place are different from each other, and the electricity produced (generated) in the photovoltaic electricity producing place is As a method of sending photovoltaic electricity to a place where it is actually consumed, the transmission (or distribution) method through an existing power line (power system network) should be used.

In order to transmit (or distribute) the electricity through a power line (power system network), a substation facility is required because the voltage must be increased to a high voltage, and a power transmission facility for transferring the electricity, and each customer who actually consumes the electricity. There is a tremendous amount of power costs for power transmission and distribution, such as sending distribution equipment and a transformer for receiving and converting the distributed electricity into a voltage that is easy to use. The longer and longer these sections, the more exponentially the cost. Will grow,

The bigger problem is that the longer the power transmission interval, the greater the electrical losses.

In addition, the electricity produced (generated) in the photovoltaic facility is very low voltage direct current electricity (the electricity produced in one photovoltaic cell constituting the photovoltaic module as a photovoltaic facility is DC 1V or less) and the direct current electricity is Therefore, in order to transmit such electricity, it is necessary to switch to AC (AC) electricity as well as boosting power, and thus, an inverter facility is required in addition to the power transmission and distribution substation facility, and an additional cost increases, and there is an additional electric loss.

Therefore, a method (technology) of transferring (supplying) the photovoltaic electricity by a transmission (or distribution) method (wired transmission method) through a power line (power system network), which is an existing technology,

As a result, the photovoltaic electricity generation cost is raised significantly (electricity supply fee becomes expensive), and existing problems such as thermal power plants that generate electricity through the consumption of existing fossil fuels or nuclear power plants that threaten human safety. It is a major factor that raises the cost of generating electricity of photovoltaic electricity more than the cost of electricity produced using this many methods.

Problems such as fossil fuels make it impossible to realize the large-scale transition to photovoltaic electricity, a clean, infinite and permanent future energy, away from many existing energy uses.

On the other hand, by applying the method to supply using the wireless transfer method according to the present invention,

In Example 1, the positions of the photovoltaic electricity producing site and the photovoltaic electricity consumption place are configured differently, and the electricity produced (generated) at the photovoltaic electricity producing site is As a way of sending photovoltaic electricity to the actual consumer, we use the wireless transfer method.

The wireless transfer method is a method of realizing charging, transferring, consuming, recovering and recharging cycles of electricity, so that electricity generated (generated) or delivered at the charging station is supplied to the electric consumer.

The charging, transporting, consuming, recovering and recharging cycles of the electricity may include one or two or more of the plurality of electric storage devices, which generate or generate electricity at the charging station or deliver the electricity. While being stored (charged) or stored (charged), the electricity is transferred to the electricity consumer (area, facility, building, equipment, device, customer, etc.) and consumed (charged) electricity stored at the electricity consumer ( It is a cycle in which one or two or more times a plurality of times is continuously and repeatedly carried out, which includes the entire process from discharge to the charging station and recovery and restoring (recharging).

Therefore, by supplying the electricity produced (generated) in the place of producing the photovoltaic electricity using the wireless transfer method according to the present invention as described above, to the actual consumption of the photovoltaic electricity,

As a method of sending the photovoltaic electricity to an actual place of consumption, a method of charging, transferring, consuming, recovering and recharging the electricity is used.

The electricity is not transmitted (or distributed) through the power line (power system network), and the electricity stored in the electric storage device is charged (delivered) by delivery through delivery, thereby eliminating the need for the power line itself. There is no need for a substation for boosting the voltage to a high voltage, the power transmission facility for transferring the electricity, the distribution facility for transmitting the electricity to each consumer actually consumed, and a transformer for receiving the converted electricity and converting it into an easy-to-use voltage. It is possible to completely zero the cost of various power equipment for the existing power transmission and distribution, such as no need, and also to eliminate the big problem that the cost is exponentially increased as the length and distance of these sections are long. Will be

The longer the transmission section, which was the biggest problem, the more the problem that the electric loss is larger is completely solved, so the power loss rate can be completely zeroed.

In addition, another problem of the existing wire transfer method, the electricity produced (generated) in the photovoltaic facility is very low voltage direct current electricity and direct current electricity is not transmitted, so for the transmission of such electricity, boosting as well as AC (AC) ) In addition to the power transmission and distribution substation equipment is required to be converted to electricity, additional equipment costs are increased, and additionally the loss of electricity from this problem,

When the wireless transfer method according to the present invention is used, since the very low voltage direct current electricity, which is electricity produced (generated) in a solar power generation facility, is directly stored in an electrical storage device and transferred to a delivery method, such an inverter installation itself is unnecessary. .

Therefore, the method (technology) for transferring (supplying) the photovoltaic electricity to the electric consumer by the wireless transfer method according to the present invention,

As a result, the photovoltaic power generation cost is significantly lowered and produced (generated) using many existing problems such as a thermal power plant that generates electricity through consumption of existing fossil fuels, or a nuclear power plant that threatens human safety. By making the electricity more economically cheaper than the cost of generating electricity (the electricity supply fee becomes cheaper than nuclear or thermal power generation electricity),

The wireless transfer method according to the present invention makes the electricity produced in the photovoltaic facility become economical electricity that greatly reduces the production (power generation) cost,

In addition, the problems such as fossil fuel is a key technology and driving force to realize the large-scale transition to photovoltaic electricity, which is a clean, infinite and permanent future energy to escape from the existing energy use.

In addition, as described above, even a technician body that supplies photovoltaic electricity by wireless transfer method can reduce a lot of costs compared to the existing wired transfer method, thereby greatly reducing the cost of producing photovoltaic electricity (power generation) to make electricity economically. Can,

In addition, a place (space) for producing (generating) the photovoltaic electricity is selected in this way by selecting a place (ground, water, sea, or space) suitable for producing (generating) electricity as described below. If the photovoltaic facility is installed at a place and the electricity produced (generated) is continuously supplied for use at an electric consumer where the electrical energy consumption (discharge) is required,

As the sun only rises, electricity is produced at the lowest cost and can be transported (delivered) at a very low cost, so the electricity generated (generated) at these locations and in these facilities will minimize costs and consequently significantly reduce the cost of power generation. By doing so, it becomes more economical electricity.

As an example in this way, the charging station in <Example 1> is a place to install the photovoltaic power generation equipment and produce photovoltaic electricity,

One or two charging stations in <Example 1> are selected by selecting a good place (ground, water, sea, space, etc.) for producing electricity and installing the photovoltaic power generation facilities in the selected place. We make many places more than point.

Let's take an example of the locational condition as a good place to produce electricity for the installation of these charging stations.

The place where you install the photovoltaic facilities is a place where the value of the place (land value, rent, etc.) is cheaper or the place value (land value, rent, etc.) is hardly entered,

Where the sunlight shines more intensely or the time it shines is longer, so that the amount of photovoltaic electricity is generated.

It is a spacious place where you can install photovoltaic power generation equipment in a larger size,

The electricity generated by the photovoltaic facilities is stored (charged) in an electrical storage device and transferred to an electrical consumer. The consumed (discharged) electricity storage device is a better place to perform the recovery process more economically. Among the places that should be,

It must be at least one locational condition.

And for example, the places with the best location to install these charging stations,

Economically inexpensive land areas (including deep mountains, barren land, low or undeveloped areas, badlands, etc.), reservoirs, rivers, lakes, dams, little islands, little beaches, small uninhabited islands , Little or no national territory (such as those rarely found in rural areas such as Russia, Alaska, Mongolia, etc.), or other areas where little or no humanity (other land costs) are rarely used (ground, water, on the sea, or in space). Etc.)

Any one or more places (ground, water, sea, or space, etc.) are the best place to install the filling station.

However, the above places (spaces) are mostly far from the city center or factory area that requires a large amount of electricity, and thus the land (ground price) has the advantage of being inexpensive, while the distance from the city center or factory area is far from the existing power lines. When the transmission line is installed, the cost increases enormously, and as the transmission distance increases, the power loss rate increases greatly. Therefore, the production of power generation (power generation) in these places and the transmission through the power line by the conventional wired transfer method are necessary. As I was not able to do it,

In the future, if the wireless transfer method according to the present invention is used to supply electricity with a technology that eliminates both the power line and the transmission equipment, the photovoltaic can be produced even at a place where the electricity is far away from the electrical consumer. By generating electricity at will, we can speed up the world a little cheaper and more economically than electricity from existing nuclear power plants or coal-fired plants.

In the past, one or two or more charging stations of two or more places are installed with large photovoltaic power generation facilities, and the electricity generated (generated) is stored (charged) in one or two or more electric storage devices. Thereafter, the plurality of electrical storage devices thus stored (charged) are transferred to an electrical mass consumer that is easy to consume (discharge) a large amount of electricity, and then transferred through the wireless transfer method, and thus the plurality of electrical storages thus transferred. The electricity output from the devices can be used as the actual consumption of electricity in a mass consumer, which is good at consuming (discharging) a large amount of electricity (which needs to be consumed).

And continuously bring the various electrical storage devices standardized to be reused and distributed to the charging station to charge (store) the electricity and transfer the electricity to a large mass consumer that is easy to consume (discharge) the mass. In the mass consumer of electricity which is good to consume (discharge) a large amount of electricity, the electricity stored in the electric storage devices thus transferred is used where the mass electricity is needed, and the electric storage devices that use up the stored electricity are returned to the charging station again. To re-supply and resupply, and if this method is repeated continuously,

In addition to reducing the enormous cost and enormous loss of electricity (power) consumed in the transmission (distribution) method through the power line used in the existing technology, it is also possible to drastically reduce the installation cost of the charging station (photovoltaic power generation). Since a large area is required to install the equipment, the ratio of land (land value) to the generation cost of photovoltaic electricity is very high, which greatly reduces or rarely reduces the land (land value). If you install photovoltaic equipment),

In addition, in the same place, a large amount of solar power can be produced (generated), more solar light is produced, and more solar power is produced (generated) due to the longer light shining time. The cost of electricity generation can be significantly lower than that of electricity generated from existing nuclear power plants or thermal power plants, that is, it can produce (generate) electricity at the most economical level.

As a result, it is possible to meet all of the large-scale electricity demands used in large apartment buildings, factory areas, industrial zones, etc., which are needed in large quantities by electric energy alone, with only the solar energy of the future energy. It is possible to supply the electricity very economically and inexpensively and ultimately to replace all existing thermal power plants or nuclear power plants with the future energy generation system according to the present invention, it is possible to achieve the object of the present invention.

② Due to the technical limitations of the existing electricity transfer method (power line transmission method), which is the second problem, it was not possible to fully utilize the optimal places to produce solar power (energy) more economically and in large quantities. How to overcome it,

In detail,

As described above in the first problem of ①, the photovoltaic power generation equipment needs a large area,

In the future, the most obvious way for mankind not to use electricity produced by many nuclear power plants or fossil fuels such as coal-fired power plants is not used.

 The installation cost of photovoltaic electricity produced by the installation of photovoltaic power generation facilities is based on the electricity generation cost of electricity generated from various power plants that consume fossil fuels such as nuclear power plants or thermal power plants. Electricity must be produced (generated) at a lower cost than the cost of generating power, and the electricity must be used at the electric consumer.

However, in order to do this, the amount of photovoltaic electricity (power) produced (generated) in the photovoltaic facility is larger than the amount of electricity (power) generated in various power plants generated by consuming fossil fuel such as an existing nuclear power plant or a thermal power plant. In order to enable production (power generation), large-scale photovoltaic facilities should be installed where a large amount of photovoltaic electricity is produced (generated).

Therefore, in order to produce a large amount of electricity by installing a large photovoltaic power generation facility as described above, a place for installing such a large photovoltaic power generation facility is needed,

Such a place would be more economical and easily produce (generate) a large amount of electricity only when the land (land value) is large, spacious and spacious, and has a location condition to install large-scale photovoltaic facilities.

As an example of a place that meets these location conditions,

Oceans, deserts, plateaus, polar regions (North Pole, Antarctica), distant oceans, wide deserts (Sahara Desert, etc.), vast plateaus (such as the large, uninhabited Mongolian plateaus), distant seas of vast lakes, wide The distant core of the river, the distant core of the wide dam, the vast and uninhabited tundra (such as the vast areas of no-human in the tundra regions of Siberian fields, Russia, Alaska, Mongolia, etc.), the vast deserted islands In other areas, in large, spacious places (land, water, on the sea, or in space) that don't cost anything at all,

Any one or more places (ground, water, sea, or space, etc.) become places with optimal location conditions.

Then, at least one of the above places is selected, and the photovoltaic power generation facilities are installed at one or two or more places selected in this way, so that the charging station in Example 1 is large or We make many places more than two places.

However, in places such as distant seas, such as above, it is possible to cool the heat of the photovoltaic module constituting the photovoltaic facility sufficiently with water, so that the photovoltaic module is more efficient in producing electricity, and such places are sunlight It is also stronger and there is no blockage, so the time to shine the sun is longer, and overall, it can greatly increase the electricity (power) production.

In addition, the large area (ground value) occupied by photovoltaic power generation facilities is free of charge, and the vast open area is uniform, so that the optimal conditions for producing a large amount of electricity (electric power) by installing a large amount of photovoltaic facilities are provided. On the other hand, there are so many advantages,

Disadvantages of most of these sites (on the water) require the installation of submarine cables with existing technology (power transmission over power lines) in order to transfer large quantities of electricity produced here to land over water. As it increases more significantly, it is a big factor to greatly increase the cost of generating electricity for photovoltaic power generation, and also the distance to the power line (transmission line) connected to the electricity mass consumption station that actually consumes the generated electricity. Farther away, if the transmission line using the existing power line is installed, the cost is also enormously larger, and the greater the transmission distance, the greater the power loss rate.

As a result, in the selection of a method of transferring the electricity produced (generated) to the mass electricity consumer in the large photovoltaic facilities installed in the charging stations installed in distant waters such as distant seas as described above. It is difficult to meet economic feasibility by the wired transport method, and now it is difficult for human beings to use it as a place for producing photovoltaic electricity on distant waters such as the sea.

However, in selecting the method of transferring the electricity (generated) produced in the large photovoltaic power generation facilities installed in the large charging stations installed on the distant waters such as the sea to the mass consumer of electricity, the wireless transfer according to the present invention If you switch the method of electricity supply (feed),

Due to the technical limitations of the existing electricity transfer method, human beings can overcome the problem of not fully utilizing the optimal places to produce solar power (energy) more economically and in large quantities.

In other words, the best places to produce more economically and mass-produced photovoltaic electricity (energy), which could not be utilized due to technical limitations,

Large charging stations (one or two) located in distant seas, large lakes, large rivers, large dams, and other areas of land that are large and open above the water. In the above-mentioned charging stations installed in a large number of places, the solar power generation, which is the future energy of mankind in the future, is mass produced (generated),

This massive amount of photovoltaic electricity produced in large quantities is stored (charged) in electrical storage devices (one or more than two), loaded into ships, then landed, and then transported back to land by land transport ( Transportation), such as charging, transferring, consuming, retrieving, and recharging cycles, which are the wireless transfer methods described above in ①, have little power loss rate, submarine cable installation cost, and transmission line. By eliminating the installation cost of various necessary power facilities according to the transmission and transmission method through various power lines such as furnaces, it becomes much cheaper and more economical electricity, and all of the enormous amount of energy used by human beings It is possible to produce (generate) a large amount of electricity even after replacing

The best places to produce more economically and mass-produced photovoltaic electricity (energy) that could not be utilized due to technical limitations,

Solar power generation, the future energy of humankind, in the ocean, the distant sea of the wide lake, the distant river of the wide river, the distant sea of the wide dam, and the place on the vast and vast water where no other land (land value) is occupied. It is possible to produce a large amount of (power generation), this can be further accelerated to completely replace the electricity produced (generated) in the existing thermal power plant or nuclear power plant can achieve the object of the present invention more effectively.

③ The third problem, how to completely overcome (solve) the problem that the existing photovoltaic power generation technology developed by mankind cannot afford the base load.

In detail,

The most common energy used by mankind after the Second Industrial Revolution is electricity, and nuclear power or thermal power plants that produce such electricity 24 hours a day are under load. As it is a way of producing electricity a lot, in order to make a great transition to future energy without any problem, humanity must replace existing nuclear power plants or fire plants that can handle such base loads with photovoltaic power plants that produce future energy.

Therefore, the charging stations in which the above-mentioned photovoltaic facilities are installed should be virtually photovoltaic power plants that produce photovoltaic electricity, and these photovoltaic plants should replace the existing nuclear power plants or plants. Only in the future can human energy problems be reliably solved.

However, in order to replace the electricity of a coal-fired power plant or a nuclear power plant, and to replace a nuclear power plant or a thermal power plant, such photovoltaic electricity is produced (generated) in a photovoltaic power plant that is a future energy production (power generation) method. As a result, it must be able to fully handle the base load currently used by mankind.

If the photovoltaic power plant producing the future energy does not produce electricity that can handle the base load, the object of the present invention cannot be achieved.

The base load is the continuous demand for the lowest of the generation loads that fluctuate temporally or seasonally when human beings currently produce electricity (power generation) to supply electricity according to the condition that human beings use electricity at the same time 24 hours a day. In terms of power generation capacity,

Since electricity used by mankind is used 24 hours a day at any time, electricity must be continuously supplied for 24 hours. Simultaneous demand for electricity for 24 hours is always present and this demand is the base load. During peak periods, there is always peak demand and peak time zones, which are the peak loads.

However, the most optimal photovoltaic power generation method of future energy production method based on the existing technology developed by mankind is electricity generation (power generation) only during a short time (3-5 hours) during the day when the sun rises.

Therefore, it is impossible to replace the nuclear power plant or the thermal power plant to cover all base loads for 24 hours by using the conventional photovoltaic method, which only generates electricity (power generation) during the 24 hours a day.

This is because most of the electricity produced by the existing solar photovoltaic facilities is integrated into a single network by integrating all the power lines (power transmission and distribution lines) that allow electricity from existing nuclear power plants or fire plants to flow. This system has a structure (system) that flows into the existing power system network connected in parallel (hereinafter referred to as the existing power system network), and the existing power system network is a structure that continuously supplies electricity in accordance with the required electric power for 24 hours a day. The structure that stores electricity is very inadequate (system),

The photovoltaic electricity produced by the existing solar photovoltaic facilities flows through the power lines of the existing power grid as soon as they are produced and naturally disappears (or disappears) over time, regardless of whether they are actually consumed or not.

Therefore, it generates electricity (power generation) only for a few hours during the day when the sun rises during the day, and flows it into the power system network. The system does not operate other power plants (nuclear power or nuclear plants) during that time because electricity produced during the hours of the day when the sun rises cannot be stored but covers the electricity demand of that time. In other time zones, however, electricity must be supplied according to the electricity demand, so that electricity demand can be generated from existing nuclear power plants and sinter plants that can produce electricity even when the sun is not rising. The power plant is a base load plant.

Therefore, the structure (system) used by linking (connecting) the existing photovoltaic power generation facilities of the existing technology and the existing power system network is a technology using the above-described wire transfer method, and a conventional photovoltaic power plant using such a wire transfer method. Can never bear the base load.

In addition, in addition to the above problems, the structure (system) used in connection (connected) to the existing photovoltaic power generation equipment and the existing power system network,

If you generate more than a certain amount of solar power during the day, the more electricity becomes useless electricity. Therefore, if you increase the above-mentioned photovoltaic facilities above a certain capacity, virtually all of them All of them become useless, and in the future, humans will not be able to achieve the purpose of the present invention to replace the existing nuclear power plants or thermal power plants with solar power plants.

Because electricity used by human beings is used 24 hours a day at any time, electricity must be supplied continuously for 24 hours. The conventional solar photovoltaic facilities supply electricity only when the sun rises. The base load-bearing power plants (electric power plant, power plant) that produce electricity even during the time period are structures that produce electricity once they generate electricity, so that they continue to generate electricity while maintaining almost constant electricity production for 24 hours a day. The photovoltaic power generation facilities of the existing technology, which supply electricity only during the time when the sun rises, cannot supply electricity in the absence of the sun, and the existing base load power plants produce electricity at this time, and as a result, the existing load power plants We do not handle the production and supply of constant base load electricity (power) for 24 hours. Can not be a, the solar power plant will be able to handle the peak load can not only handle their base load power plants.

However, these peak loads usually peak during 2-3 months in summer (normally between 14:00 and 17:00 in summer), and in winter during 2-3 months (in winter between 17:00 and 19:00 in winter). This peak value increases, and the difference between the peak load and the base load is not much in the rest of the season,

If the photovoltaic power generation facilities are installed at a capacity equal to or more than the difference between the peak load and the base load, the surplus facilities are all reduced to a facility that is of no help except during the peak load time period.

On the other hand, the photovoltaic power plants constructed above the maximum difference between the base load and the peak load have electricity remaining even during the peak load period, thereby virtually eliminating the need for use (producing electricity). The construction of a photovoltaic power plant with a certain capacity or more, which becomes useless, is now very unnecessary in the existing power system network (system) of humanity, and there is no need for a photovoltaic power plant with a certain capacity or more. As such, the existing outdated technology structure (system) is a further problem that hinders the spread of the photovoltaic power plant (solar power generation facilities), which is an optimal technology of future energy production.

Therefore, in order to solve all the problems of the conventional photovoltaic power plants (photovoltaic power generation facilities), the transfer method of electricity produced (generated) by the conventional photovoltaic power plants (photovoltaic power generation facilities),

In the conventional wired transfer method (power transmission method via power line), the transfer method should be switched to the wireless transfer method according to the present invention.

When transferring the electricity produced in the photovoltaic power plants (photovoltaic power generation facilities) by a wireless transfer method according to the present invention,

As described above in the above ① and ②, the electricity generated by the photovoltaic power plants (photovoltaic facilities) is stored in a large number of electric storage devices, so no matter how much electricity is produced. Even if the power generation is not possible to produce electricity in a time when there is no sun after storing all of them, it generates the effect of using the electricity stored in the electrical storage devices in this time period, thereby being able to bear all of the problems of the base load No matter how many solar power plants (photovoltaic power plants) constructed by the present invention are constructed, the electricity produced here does not naturally disappear at all, so in any case, it does not fall into unnecessary power plants. Substantial future energy production development that can surely replace many nuclear power plants or fire plants It becomes a cow and a practical solution to completely overcome the above problems.

④ The fourth problem, humanity at present, is to clean up the photovoltaic electricity in a clean way (without pollution, fine dust, carbon emissions), almost indefinitely, almost permanently, and with no risk of safety concerns like nuclear power plants, How to completely overcome (solve) the problem of not having the technology to produce,

It will be described in detail as follows.

In the future, the energy used by mankind is too much, and the amount of energy used is continuously rising.

This future energy must be able to be continuously produced in an enduring (eternal) way without depletion of energy, and must be produced in such a way that the amount of energy can be produced almost indefinitely so that no humans can use it in the future. It will be able to be qualified as a new future energy of mankind, and this future energy must be produced in a clean and pollution-free way so that it does not cause environmental pollution problems such as fossil fuels, and it is produced without any safety risks such as nuclear power plants. Should be.

Therefore, the best way to do this is to replace the existing nuclear power plants or thermal power plants with photovoltaic power plants (photovoltaic power plants) as described above. Solar cells (photovoltaic modules) must be installed to generate electricity (power generation) by receiving light, and these solar cells all produce electricity as the area of sunlight gets larger and the quantity of solar cells installed increases. The amount increases.

However, the solar cells developed by humans so far have very little electricity (power generation) compared to the installed area, so it is enormously broad to install (generate) as much electricity (power) as human beings need by installing solar power facilities. Installation area is required.

In addition, as the installation area of the photovoltaic facility increases, the installation area cost (ground value, etc.) increases, and as the installation area cost increases, the electrical energy production (power generation) unit costs more and there is no economic feasibility.

Therefore, in order to install (photovoltaic) an infinite amount of almost infinite energy in the future, the installation of photovoltaic facilities necessary for this requires an almost infinitely large footprint, and this almost infinite footprint The production of this product on the ground causes the cost of electricity production (power generation) to increase due to the increase in the installation area cost, resulting in less or no economic feasibility, and the fact that the ground area (installation space) is finite. It is virtually impossible to create an infinite footprint on the ground to install a bay.

However, since there is infinite space in the sky and space, and the installation area cost is zero, the place for electricity production (power generation) by solar power generation facilities can be realized only in the sky or in space to realize the infinite installation area. In addition, the installation area cost can also be provided at zero cost, so that it is possible to have a substantial economic condition for producing an almost infinite amount of energy desired by the present invention with photovoltaic electricity.

In addition, photovoltaic power generation is characterized in that the stronger the sunlight, the direct sunlight, the greater the amount of power generation in the same photovoltaic facilities (solar cell, photovoltaic module, etc.). It is much stronger compared to the earth (the higher the air density, the less air obscuring the sun, and the stronger the sun's light), and the better location for direct sunlight. Has the advantage of losing

In addition, the sun shines on the ground only during the day, and the solar light that makes the actual solar power generate electricity is only about 4 hours during the day, whereas the time that shines on the earth is much longer than the ground. It's long, and the sun shines 24 hours a day in space (space), so if you go up the earth or in space (space) to unfold your solar power plant and run it in a way that turns you away from the sun and direct sunlight, Three to twelve times more solar power generation (generation) can be obtained.

However, to go up above the earth or space (space) to produce (power generation) photovoltaic electricity,

When applying the existing photovoltaic technology developed by mankind, the existing method is a wired transfer method (power transmission method through power lines) as described above, and the existing power system network exists in the space or space (space space). In addition, since power lines for power transmission cannot be installed separately, the reality is impossible.

However, to illustrate this in the wireless transfer method according to the present invention, Example 2,

First, assuming that the charging station of step <a> (a) is a Seoul charging station located on the ground in Seoul, South Korea, transportation of the electrical storage device of step <c> of step <c> of Seoul and the Seoul charging station After making the drone a means, install a solar cell, a photovoltaic facility on the drone, so that it can get up to the sky and receive sunlight (for example, install a foldable solar module to climb from above the earth to the earth). When it is folded up, and climbs over the earth, looking at the sun and spreading it out, it installs the sun's light in a wider area so that it can receive more direct sunlight),

On the other hand, the function of storing (charging) electricity produced by the solar cells installed in the drone and bringing it to the Seoul charging station on the ground and delivering the electricity stored (charged) at the Seoul charging station (charging to another electric storage device or earth (B) additionally installing the electrical storage device of step <b> (b) made to perform the function of delivering the electrical storage device itself stored in the air to the drone,

When the drone rises above the earth and expands the folding solar cell, electricity begins to be produced (generated), and the generated (generated) electricity is stored in an electric storage device installed in the drone, and then the storage capacity of the electric storage device. When enough electricity has been stored (charged), the drone descends to the Seoul charging station on the ground and is placed on the secondary air storage device (ESS) with huge capacity for the delivery of electricity installed at this station. Discharge (charge the secondary electrical storage device) stored in the (charge), or the electrical storage device stored above the earth is lowered to the charging station to replace the discharged electrical storage device that needs to be stored after loading , Go up above the earth again to recharge, go down to the ground station again and discharge,

In this way, the electricity stored in the secondary electric storage device installed in the ground charging station may be transferred to the customers who need energy (electricity) of each ground by the wireless transfer method according to the present invention as described above.

And I don't want to be big and heavier in weight because I can mount these drones with solar photovoltaic equipment that can produce more electricity, and electricity storage that can store more electricity. By making drones with increased performance that can easily ascend into the air (such as drones with buoyancy described below), these drones can be made into one or more hundreds of thousands, hundreds of millions, or more. Alternatively, if there are numerous installations in the air and continuously reciprocating between the charging stations of step (a) in the same manner as described above, the electricity is produced, stored, and brought to the designated charging station. Human beings are the most safe, cleanest and most permanently and permanently Can be produced in one way,

In the future, human beings will be able to completely replace fossil fuels with future energy produced (generated) by the present invention, which is infinite, permanent, safe and clean pollution-free energy produced in the above-described manner, as well as nuclear power. We will be able to reduce or completely shut down the power plant, and solve global environmental and energy depletion problems.

In conclusion from the above,

As the most important prerequisite for the achievement of the invention, a common optimal way to completely overcome all four problems simultaneously is

In <Example 1>,

By supplying the electricity produced (generated) or delivered at the charging station to the electric consumer (region, facility, building, equipment, equipment, consumer, etc.),

Instead of using a conventional wired transfer method, a method of supplying a wireless transfer method according to the present invention should be used.

The wireless transfer method,

It is a method of supplying the electricity produced (generated) or delivered at the charging station to the electric consumer by realizing the charging, transferring, consuming, recovering and recharging cycles of electricity.

And the charge, transfer, consumption, recovery, recharge cycle of the electricity,

One or two or more of the plurality of the electrical storage devices are stored (charged) or stored (charged) while maintaining (charged) or stored (charged) electricity of any one or more of the electricity produced or generated at the charging station. A one-time process comprising the steps of transferring to the consumer, consuming (discharging) the electricity stored in the electric consumer, and then recovering and restoring (recharging) the electricity again. It is a cycle that continuously performs a plurality of times more than two times.

<Example 3>

As described in <Example 1> and <Example 2>,

In a method for transferring and recovering the electrical storage device (s),

The first embodiment will be described in detail with reference to the method of performing the transfer and recovery using the wireless storage means of the electrical storage device of step (c).

As described above in Example 2, in the current method of producing electricity (power generation), the existing photovoltaic power generation method has yet to catch up or replace the thermal power generation or nuclear power generation method. For a big reason (problem), it is the biggest problem for the customers to use the existing wire transfer method, the electricity supply method must be switched to the wireless transfer method to overcome this problem.

For example, there is apartment A in the city center, and apartment A is a large apartment complex. In order to heat such an apartment, a large amount of energy is required for heating. The energy to heat the apartment A is safe and clean. Assuming that electricity is used, apartment A has little free space to install photovoltaic facilities (solar panels, etc.), so that A has a large space for installing photovoltaic facilities in order to obtain the heating electricity required for these large apartments. Suppose a large-scale photovoltaic facility (solar panel, etc.) is installed in a mountain located far from the apartment, and the electricity needed for apartment A is permanently produced and used indefinitely without pollution.

In order to send the electricity produced (generated) in Yasan far away from the spacious A apartment to the A apartment, the only method used and developed by mankind until now is the existing wire transfer method (technology).

Therefore, in order to transmit the electricity by the conventional wired transfer method, a substation facility is required as the voltage must be increased to a high voltage, and a power transmission facility that transfers it, a voltage that is easily received by receiving it at the place where the electricity is needed (a consumer) The transfer cost is enormous, and the electrical loss is large, such as the need for a transformer to convert the power supply.

In addition, since the electricity produced in the photovoltaic facility is very low voltage direct current (DC 1V or less electricity) and direct current electricity cannot be transmitted, it is necessary to switch to AC power as well as boosting power for transmission of such electricity. In addition to the equipment, additional inverter equipment is required, which increases the additional cost, and additionally, the loss of electricity is generated, and as a result, the electricity produced in this way increases the unit price (electricity usage fee is expensive).

As a result, rather than using the electricity generated by generating photovoltaic facilities in such a distant place as above, the electricity required for heating in apartment A is used instead of electricity generated from the electricity grid (nuclear or thermal power plants). Since the use of KEPCO electricity operated by electricity generated in Korea has resulted in much cheaper results, the power transmission method by conventional wire transfer method that transmits electricity used by humanity until now is solar power generation. There is no choice but to be popularized.

Therefore, if there is little free space to install photovoltaic facilities (solar panels, etc.) at each customer or site that requires a large amount of electric energy (consumes a large amount of electricity), such as electricity required for heating in apartment A. In order to use photovoltaic electricity in these customers or on-site, the electricity is transferred to a brand new concept, completely deviating from the conventional wire transfer method, which has been used as a way of sending electricity used by humanity to where it is needed. Should be.

In other words, the large-scale solar power plant (solar panel, etc.) is installed in Yasan, which has a large space far from the apartment A, which is good for installing photovoltaic power generation facilities. By using a wireless transfer method, a large amount of electricity is transferred to apartment A, and the photovoltaic electricity thus transferred is used as electricity in large quantities in apartment A.

The wireless transfer method is as described above in Embodiment 2.

Wherein the electrical storage device to achieve the process of the wireless transfer method is achieved by realizing the above charge, transfer, consumption, recovery, recharge cycle of the electricity,

<Embodiment 1> The electrical storage device wireless transfer means for enabling the electrical storage device of step (c) to perform the wireless transfer method should be configured.

Because, in order to transfer the electrical storage device (s) from the charging station to the electrical consumption station and to recover it back from the electrical storage station to the charging station, a vehicle carrying the electrical storage device (s) is required, and such transportation As a means, a configuration of a transport means for transporting the actual electrical storage device, such as a kind of more effective means of transportation, or an operation method for operating such a vehicle more effectively, is necessary.

The role of this transport means,

It is because it is possible to achieve a wireless transfer method that puts the electricity of the charging station in the electric storage device, loaded on the transfer device, and transferred to the electric consumer to directly use the electricity transferred and contained in the electric consumer.

Therefore, the electric storage device transfer means is a means for achieving a method of transferring the electricity to the consumer as a result as a result of the wireless, the electrical storage device transfer means is referred to herein as 'electric storage device wireless transfer means,'

As an example of operating such an electrical storage device wireless transfer means,

To the photovoltaic electricity producer who operates a large amount of photovoltaic power generation facilities (such as solar panels) in a large mountain in the mountains far away from the apartment A. When ordering (delivery request) for a charged electrical storage device, the producer delivers the charged electrical storage device to the consumer in a vehicle such as a truck, and delivers it to the consumer, which has already been delivered to the consumer. By exchanging with the used (discharged) electric storage device, this discharged electric storage device is operated by such electric storage device wireless transportation means such as being loaded into a returning van and recovered. It is produced (developed) in a distant night mountain where a large photovoltaic facility (solar panel, etc.) is installed. Sunshine may be the electric power the electric sobicheo be supplied to the radio transferring method systemically (in A apartment electricity is required a large amount of electric consumer).

To recap it,

In order to implement a future energy generation system according to the present invention, electricity must be supplied to the charging station by a wireless transfer method, and the wireless transfer method is used to realize a charge, transfer, consumption, recovery and recharge cycle of electricity. It is done by

The realization of such charge, transfer, consumption, recovery and recharge cycles of electricity can be enabled by operating the electrical storage wireless transfer means,

In conclusion, in realizing the charging, transfer, consumption, recovery and charging cycles of the electricity,

The method of transporting and recovering the electrical storage device (s) is a method of transporting and recovering using the wireless storage means of the electrical storage device.

Next, a description will be given of configuring the electrical storage device wireless transfer means in a more effective manner.

The object of the present invention is to produce by the future energy generation system of the present invention, without using the energy (thermal power generation, etc.) obtained from the consumption of fossil fuels, which are many problems and exhaustion of existing problems, or the dangerous nuclear power plant of which safety is not guaranteed. The future energy that is developed) is to be used by human beings to replace many existing energy problems in the future, and to do this, economic, usability (convenience, etc.) and future are necessary.

First, look at the economic side,

The unit cost of producing and supplying photovoltaic electricity, which is the future energy produced (generated) by the present invention, does not guarantee the energy (thermal power generation electricity, etc.) obtained from the consumption of existing fossil fuels or the safety of the nuclear power plant. It must be cheaper than the cost of power generation and economical (must be economical), and the future energy of the present invention can be more competitive,

In order to make the power generation cost economical, the electric storage device wireless transportation means has to be constructed in a more effective way in a cheaper and more economical manner, resulting in low power generation costs.

That is, when a method for operating the electric storage device wireless transfer means more cheaply and economically is configured,

Electricity produced (generated) at the charging station (where a large distance from the A apartment is installed in a large mountain and a large photovoltaic facility (solar panel, etc.) is installed), In this method, the wireless transfer method applied in the present invention can be made at a lower cost than the wired transfer method, which is a conventional power transmission method, and is produced (generated) by the future energy generation system of the present invention. The cost of producing and supplying photovoltaic electricity, which is the future energy, is economical because it is cheaper than the energy generated by the consumption of existing fossil fuels (heat generation electricity, etc.) or the safety of dangerous nuclear power plants. (Economical).

Next, look at the usability (convenience, etc.) and the future.

Such various effective means are those detailed below.

The purchase of electricity must be made by various more effective means detailed in the following, and the electricity purchase price is removed from the frame of having to pay the electricity company (KEPCO) to the electricity company. Anyone who can buy (buy a charged electrical storage device) can open a very free age of electricity distribution where they can buy and sell electricity anytime and anywhere as if they were buying or selling general goods, power transmission lines, distribution lines and substations. The facility will disappear, and will be able to live in a world free from hateful facilities, electric shock hazards and electromagnetic wave hazards, and the handling of the electrical storage device becomes so convenient that it becomes very convenient to use immediately at any time where electricity is needed. By further obtaining various advantages, the future energy of the present invention This is because the existing problems may be more competitive than many energies.

When explaining the optimal configuration of the electric storage device wireless transfer means as follows.

In the <Example 1> (c) in the configuration of the electrical storage device wireless transfer means for enabling the electrical storage device to perform the wireless transfer method,

Of the various means constituted by the electrical storage device wireless transfer means, a more effective means of the configuration,

The producer and the consumer of the electric storage device are configured, and the electric storage device produced and charged by the producer is exchanged and distributed at various stages, and the sales are made by buying and selling the charged electric storage device. The method is included to reach the consumer (consumer), and after the consumer (consumer) consumes (discharges) the electricity of the charged electric storage device thus reached, the discharged electric storage device is returned from the consumer (consumer) again. The distribution structure includes sales including all such processes, in which a method of exchange and distribution is carried out at various stages, and a method of selling and selling the charged electrical storage devices is included, and is returned to the producer. Through the formation,

The one or more electricity, which is produced (generated) or delivered at the charging station, is stored (charged) or stored (charged) while being transferred to a distribution method including sales to the electric consumer, It includes one or more steps including consuming (discharging) the stored (charged) electricity at the electricity consumer, and then recovering and restoring (recharging) the distribution method including sales to the charging station. To ensure that all processes of continuous and repeated multiple or more times are achieved,

A first method of constructing the electrical storage device wireless transfer means by a distribution method including sales;

When the producer and the consumer of the electric storage device are configured and the consumer orders the charged electric storage device, the producer delivers the charged electric storage device to the consumer, and the discharged electric storage device consumed by the consumer is the producer. By retrieving an order and delivery structure that includes all of these processes,

At least one of the electricity produced or generated at the charging station is stored (charged) or stored (charged) while being transferred to the electric consumer in an order and delivery method. Once or twice including the process of consuming (discharging) the stored (charged) electricity at the consumer, and then recovering and restoring (recharging) to the charging station again by the order and delivery method. So that all the processes can be carried out over and over again,

A second method of configuring an electric storage device wireless transfer means by an order and a delivery method;

The producer and the consumer of the electrical storage device are configured, and the consumer to be transferred from the producer to the consumer through any one or more of all the methods to enable the transfer of the charged electrical storage device that the consumer needs, the consumer Discharged electrical storage devices consumed (discharged) allow other transportable structures to be formed, including any such process, to be returned to the producer by any one or more of all other methods that enable transport. Through,

At least one of the electricity produced or generated at the charging station is transferred to the electric consumer through other transferable methods while being stored (charged) or stored (charged), and the It includes one or more steps including consuming (discharging) electricity stored in the electricity consumption station, and then recovering and restoring (recharging) the battery through other transferable methods. To ensure that all processes of continuous and repeated multiple or more times are achieved,

A third method of constructing an electric storage device wireless transfer means through another transferable method,

Among the fourth method using a mixture of the first method to the third method,

The use of any one or more methods is to configure the electric storage device wireless transfer means in the most effective and optimal way in terms of economics, usability (convenience, etc.), future.

And in the third and fourth methods,

As a more effective method of configuring the electric storage device wireless transfer means through other transferable methods,

The electrical storage device (s) is transferred from the charging station to the electrical consumer, and recovering from the electrical consumer to the charging station,

The electric storage device is loaded on a general means of transportation (vehicle, train, ship, aircraft, etc.), and is transported, transported, transmitted, or moved, etc.

A first method of transferring the charged electric storage device from the charging station to the electric consumer, and recovering the electric storage device consumed (discharged) at the electric consumer back to the charging station;

After reconstructing a general vehicle (vehicle, train, ship, aircraft, etc.) into a vehicle for exclusive use of the electrical storage device so that it can be used only for the purpose of handling only the electrical storage device, By loading the electrical storage device, transportation, transfer, transfer, movement, etc.,

A second method of transferring the charged electric storage device from the charging station to the electric consumer, and recovering the electric storage device consumed (discharged) at the electric consumer back to the charging station;

As an electric only transportation means for storing (charging) electricity and outputting (discharging) electricity, a method of fixedly equipping or fixedly mounting an electric storage device therein,

Superconducting power storage car, superconducting power storage ship, superconducting power storage aircraft aircraft, superconducting power storage device train, large capacity power storage system (large capacity power storage system) car, large capacity power storage system (large capacity power storage system) ship, large capacity power Storage (large-capacity power storage system) Aircraft, large-capacity power storage (large-capacity power storage system) trains, batteries (electrical storage or ESS) trains, batteries (electrical storage or ESS) cars, batteries (electrical storage or ESS) Developed (made) by ships, batteries (electrical storage or ESS) aircraft, or

Any one or more of the various means of transportation is developed (made) to be a dedicated electric vehicle to be used only for the purpose of storing (charging) electricity and outputting (discharging) electricity.

By directly operating such electric transport means itself,

After the electricity is stored (charged) in the electric dedicated transportation means, the charging station goes to the electric consumer, and the electricity stored in the electric dedicated transportation means itself (charged) outputs (discharges) the electricity, and then goes to the charging station. A third method of allowing the electric dedicated transportation means to be used only for the purpose of continuously repeating a cycle of re-storing (charging) one or two or more times a number of times to return to the electric dedicated transportation means itself;

Among the fourth method using a mixture of the first method to the third method,

In any one or more ways, the method of configuring the electrical storage device wireless transfer means is a more effective method of configuring the electrical storage device wireless transfer means through the other transferable method.

Further, in the first method and the fourth method,

As a way to more effectively carry out distribution methods that include sales,

Only when the electric storage device is made to have a structure in which a buyer can buy and sell to each other between a producer and a consumer and a third party through a distribution process can perform a distribution method including more sales more effectively. .

And the method of making the electrical storage device has a structure that can be bought and sold to each other between producers, consumers and third parties through the distribution process,

In order to be able to easily identify the value (price) of the electrical storage device between the seller and the buyer, so that the value (price) of the electrical storage device can be formed differently according to the degree of use and the amount of electrical storage according to various specifications. You can make it

In one such embodiment,

In order to be able to easily identify the value (price) of the electrical storage device between the seller and the buyer, so that the value (price) of the electrical storage device can be formed differently according to the degree of use and the amount of electrical storage according to various specifications. How to make it, in a more effective way,

The method of displaying the number of times of charging and discharging the electricity in the electrical storage device, or the number of times of charging and discharging the electricity and the remaining capacity of the electricity is also displayed. It is to make and distribute an electric storage device.

<Example 4>

The electrical storage device in the <Example 1> to <Example 3>,

Various electrical storage devices that perform one or more functions of storing (charging) electrical energy or outputting (discharging) electrical energy should be provided.

Because, as described above in Embodiments 1 to 4, an optimal method for overcoming the four problems is to generate electricity or to handle electricity at one or more of the charging stations. Since the transfer method does not use the existing wired transfer method but transfers using the wireless transfer method,

The electrical storage device, as described above in the <Example 3> in order to achieve such a wireless transfer method,

By using the electrical storage device wireless transfer means (distribution or order delivery, while maintaining (charged) or stored (charged) at least one of the electricity produced or generated at the charging station Other transfer methods, etc.), the transfer from the charging station to the electric consumer (area, facility, building, equipment, equipment, consumer, etc.), the electricity consumed (discharged) at the electric consumer is again transferred to the electrical storage device By means of means (distribution or order delivery, other transfer methods, etc.), all the functions of recovery to the charging station should be made smoothly. It can be an electrical storage device that accomplishes the above-mentioned wireless transfer method, which is the most core technology that can completely overcome the problem,

After this transfer, it is necessary to output electricity (discharge) transferred from the electrical consumer, so that electricity can be supplied to various electricity facilities, machines, devices, etc. that require electricity consumption.

The electrical storage device should be an electrical storage device that performs one or more functions of storing (charging) and outputting (discharging) electrical energy.

In addition, such an electric storage device may be innumerable in many ways (eg, voltage, current capacity, etc.) to produce, handle, and store (charge) electricity at the charging station that produces, stores, or handles electricity. Can and

In the electrical consumer, various kinds of electrical equipment, machines, devices, etc. that require electricity consumption in actual use (consumption) may also be numerous and numerous, having many specifications.

If the electrical storage device is made in accordance with all the local requirements of the electrical storage device is to be made into a number of different types of electrical storage device,

As an example of so many different kinds of electrical storage devices,

Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, electricity Storage device, energy storage device (ESS), power storage facility (device), DC power supply device (equipment), battery (electric storage device or ESS) car, battery (electric storage device or ESS) ship, battery (electric storage device or ESS) Aircraft, other transportation means having the function of storing (charging) electricity and outputting (discharging) electricity, or various products, articles, facilities for storing (charging) electricity and outputting (discharging) electricity For example, any one or more of the devices may all be used.

Therefore, in conclusion, the electrical storage device,

Various electrical storage devices which perform one or more functions of storing (charging) or outputting (discharging) electrical energy,

Various electrical storage devices that perform one or more functions of storing (charging) or outputting (discharging) the electrical energy,

Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, electricity Storage device, energy storage device (ESS), power storage facility (device), DC power supply device (equipment), battery (electric storage device or ESS) car, battery (electric storage device or ESS) ship, battery (electric storage device or ESS) Aircraft, other transportation means having the function of storing (charging) electricity and outputting (discharging) electricity, or various products, articles, facilities for storing (charging) electricity and outputting (discharging) electricity , Any one or more of the devices.

In addition, the electrical storage device,

At least one of the electricity produced or generated at the charging station is stored (charged) or stored (charged) while being stored (charged) or stored at the charging station via the electric storage device. The electrical storage device, which is transferred to and consumed (discharged) at the electric consumer, should be an electrical storage device made to perform all functions of recovering to the charging station through the electrical storage device wireless transfer means again.

Example 5

Referring to the other important functions to be provided in the above-described electrical storage device in Example 4,

The electrical storage device,

Electric storage device made by the method of standardization and standardization with the function and structure that can continuously and repeatedly perform the charge, transfer, consumption, recovery, and recharge cycles of electricity one or more times. Should be

As described above in the <Example 2> and the <Example 3>, the wireless transfer method is a method of supplying the electricity of the charging station to the electric consumer, and stores the electricity of the charging station in the electrical storage device (charging) It is possible to realize a cycle of charging, transferring, consuming, recovering and recharging electricity between the charging station and the electric consumer, and this cycle uses the electrical storage device wireless transfer means described above in the fourth embodiment. It is only possible to achieve the transfer and recovery of the electrical storage device.

Therefore, the electrical storage device,

The charging, transport, consumption, recovery, and recharge cycles of electricity must be made complete. In order to do this, the electrical storage device,

Electric storage device made by the method of standardization and standardization with the function and structure that can continuously and repeatedly perform the charge, transfer, consumption, recovery, and recharge cycles of electricity one or more times. Should be

That is, the electrical storage devices,

The function of storing (charging) electricity should be made smoothly, and it should be structured without any problem in transportation by using the electric storage device wireless transfer means while storing (charging) electricity, and outputting the stored (charged) electricity. (Discharge) should be made smoothly, and after exhausting the stored (charged) electricity, it should have a structure that is not a problem even after recovering using the electric storage device wireless transfer means. The function of restoring (recharging) the storage device should be made smoothly, and it should be made to perform the process including all functions and actions up to this.

In addition, a function and structure capable of continuously and repeatedly performing a plurality of times of charging, transferring, consuming, recovering, and recharging cycles of electricity as described above should be made.

And, as described above, in order to facilitate the transfer and recovery using the electrical storage device wireless transfer means generally should be made to be standardized to a certain standard, a certain electrical specification to be sold and sold and tradeable.

To explain this method in more detail,

The electrical storage devices must be standardized regularly, and the number of times can be reused (continuously charging and discharging and reused for many times), and these standards must be freely distributed and easily recovered on the market.

For example, in the form of LPG currently on the market, after the standardization of the gas cylinder, the gas cylinder is continuously reused, and the gas stored there is stored at a designated gas filling station and delivered to the required customer. The gas cylinders delivered by the customer and used up at the customer are standardized in such a way that the electrical storage devices can be reused and reused many times in a manner that the delivery unit collects and takes them to the gas filling station and charges and reuses the gas. After charging (storage) the electricity in the market, it is distributed to the market, and once it is used, it is collected again and sent to a constant charging station.

Therefore, the electrical storage device according to the present invention should be transported by the distribution, order delivery, and other transport methods as described above,

The electric storage device is standardized and standardized with a function and structure capable of continuously and repeatedly performing a plurality of times of charging, transferring, consuming, recovering and recharging electricity. By the way,

The size and weight of the electrical storage device is to be standardized to a certain standard, but to make a number of types according to the specifications to meet the site use conditions, the same type of each type of the standardized multiple types of electrical storage devices are the same electrical specifications It should be a way to make formalization happen.

In addition, the electrical storage device,

With the function and structure that can continuously perform the charge, transfer, consumption, recovery, and recharge cycles of electricity one or two or more times a number of times repeatedly, the method of standardization and standardization,

A first method of using a variety of general products, articles, equipment, and devices that perform any one or more functions of storing (charging) or outputting (discharging) existing electricity,

The charging, transporting, consuming, retrieving, and recharging cycles of electricity are carried out on a variety of general products, articles, equipment, and devices which perform one or more functions of storing (charging) or outputting (discharging) electricity. A second method used by reinforcing, changing (modifying) to further provide a structure (device) capable of continuously and repeatedly performing a plurality of times one or two times,

In the development (development) of a variety of products, articles, equipment, and devices capable of performing any one or more functions of storing (charging) or outputting (discharging) electricity,

It is equipped with the function and structure to continuously and repeatedly perform the charge, transfer, consumption, recovery and recharge cycles of electricity one or two times,

In the process of repeatedly performing the charging, transferring, consuming, recovering, recharging cycles of the electricity one or more times a plurality of times, so that the transfer and recovery can be made smoothly by using the electric storage wireless transfer means, The size and weight should be standardized to a certain standard, but make a number of kinds to meet the site use conditions, and separately the new electrical storage devices so that the same type of each type of standardized electrical storage devices can be standardized. The third method of making and using it exclusively,

Among the fourth method using a mixture of the first method to the third method,

Is created and used in more than one way,

And a more effective way to first realize the first method,

Existing, currently developed, produced and sold by human technology,

Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, Batteries, industrial batteries, electrical storage devices, energy storage devices (ESS), power storage equipment (devices), DC power supply (equipment), or other products that store (charge) and output (discharge) electricity, It is to use any one or more of the article, equipment, apparatus.

For an embodiment of this first method.

The electric storage device can be stored (charged) for 50KWH (KVAH) electricity in one industrial battery (electric storage device) produced and sold by a company called Tinkle Power Plant (www.twinklecar.com) in Korea. Although these products are being used as the electric storage device as it is, the electricity generated at the charging station is stored (charged) here, loaded on various transportation means (vehicles, ships, aircraft, etc.), and far from the charging station. Transported to the electric consumer, the electricity stored in the industrial battery to use (discharge), the industrial battery used in this way is loaded on various transportation means (vehicles, ships, aircraft, etc.), and transported to the charging station, The process of recharging with electricity generated in the charging station is to use a plurality of times one or two or more times.

And a more effective way to first realize the second method,

Existing, currently developed, produced and sold by human technology,

Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, Batteries, industrial batteries, electrical storage devices, energy storage devices (ESS), power storage equipment (devices), DC power supply (equipment), or other products that store (charge) and output (discharge) electricity, Any one or more of the goods, equipment or devices may be further reinforced (e.g. by reinforcing the frame-once again in a case made of metal) so that it is convenient and free of problems during transport and retrieval. It can be shocked, tripped, or just handled as much as possible.

Taking this embodiment of the second method,

An industrial battery (electric storage device) produced and sold by a company called the Republic of Korea's Tinkle Power Plant of the first method is made by putting a case made of metal separately into the case, and loading and unloading the case into a vehicle. After attaching a device that performs a convenient function (e.g. attaching a hook to make it easier to lift and lower a weight, such as a person or crane),

The industrial battery case is transported by containing the industrial battery, and when used, it is taken out of the case and used. The overall transport, recovery and usage are to be used in the same manner as in the first embodiment.

And a more effective way to first realize the third method,

Existing, currently developed, produced and sold by human technology,

Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, electricity Storage devices, energy storage devices (ESS), power storage equipment (devices), DC power supplies (equipment), or other products, articles, equipment, devices that store (charge) electricity and output (discharge) electricity To have the same or similar functionality and structure as any one or more of

These newly created electrical storage devices are made more reinforcement than existing ones (e.g. by reinforcing the frame-once again in a metal case) so that they are convenient and trouble-free during transport and retrieval. To some degree of shock, to fall, or to deal with it for some time),

The specifications of the various electrical storage devices made in this way are made into a standardized product by making a plurality of types to be suitable for the charging station or the reality of the electric consumer (more efficient to be applied to the site conditions), and standardized to a certain size and a constant weight, These standardized electrical storage devices make the electrical specifications such as storage (charge), output (discharge) capacity, voltage, and current amount of electricity uniform. It is to be used as a device.

In addition, by adding a new dedicated electric storage device made in the above, such as by mounting in various means of transportation, superconducting power storage device car, superconducting power storage ship, superconducting power storage device aircraft, superconducting power storage Device Train, Massive Power Storage System Car, Massive Power Storage System Ship, Massive Power Storage System (Large Power Storage System) Aircraft, Massive Power Storage System (Large Power Storage System) Train Battery (electric storage or ESS) trains, batteries (electric storage or ESS) cars, batteries (electric storage or ESS) ships, batteries (electric storage or ESS) aircraft, other electricity to store (charge) and electricity It is intended to be used for various purposes of the vehicle having a function to output (discharge).

Taking an embodiment of this third method,

The internal battery and the external case are fixed by equipping a case made of metal with an industrial battery having the same specification as an industrial battery (electric storage device) produced and sold by a company called the Republic of Korea Tinkle Power Plant of the first method. Made and attached to the case with a device that performs a convenient function of loading and unloading the vehicle (e.g. attaching a hook to facilitate lifting and unloading of a device that lifts and lowers weight, such as a person or a crane),

The industrial battery fixedly provided in the casing thus made is used in the same manner as in the embodiment of the first method.

In addition, industrial batteries (electric storage or ESS) cars, industrial batteries (electric storage or ESS) ships, industrial batteries (electric storage or ESS) aircraft, industrial batteries (electric storage or ESS) trains, other electric After carrying out the various means of transportation equipped with (mounted) the industrial battery having the function of storing (charging) and outputting (discharging) electricity, and directly transporting such an electric storage device,

After storing (charging) the electricity generated in the charging station in the electric storage device and a vehicle, the electric storage device and the vehicle are directly driven and transported to an electric consumer, which is far from the charging station, thereby transporting the electricity stored in the industrial battery. The electric storage device and the vehicle used in this way are directly operated by the electric storage device and the vehicle, and transported to the charging station to recharge the electricity generated by the charging station. Or you can use it many times over and over again.

<Example 6>

<Example 1> In the clean and safe method of step (a), more economical electricity is produced (generated) and stored (charged) in an electrical storage device, or delivered (generated) produced by a future energy production method. In the step of configuring a charging station that serves any one or more of receiving and delivering to the electrical consumer,

As described above in ① and ② of <Example 2>,

In the electrical consumer where there is no place (space) to install the charging station (only narrow space) or the place (space) where economic efficiency is low, or an electric mass consumption place (new city, urban area, various buildings, Various apartments, factory areas, various industrial facilities, various buildings, various large electric facilities or electric devices, various large electric consumers, etc., but there are no places (spaces) for installing the charging station (narrowing spaces) or low economic efficiency (spaces). In the electricity mass consumer which there is only),

In step (a) of <Example 1>, a more economical electricity is produced (generated) in a clean and safe manner and stored (charged) in an electrical storage device, or electricity produced (generated) by a future energy production method. This section describes how to receive electricity from the charging station, which serves as one or more of receiving and transmitting to the electricity consumer, more economically.

As described above in Example 2, as the future energy to replace the electrical energy produced (generated) by the existing fossil fuel or nuclear power plants, the most optimal energy is produced by photovoltaic power generation. Power generation) photovoltaic electricity.

However, the use of photovoltaic electricity, the optimal future energy, is not universalized and popularized to humanity at present, and has no merit to replace the electricity generated by fossil fuels or nuclear power plants.

The biggest reason (problem) among them is as described above in (1) and (2) of <Example 2>,

The discrepancy between a good place to produce (generate) electricity (ground, water, sea, or space) and a good place to consume electricity (region, facility, building, equipment, equipment, consumer, etc.) This is because they do not overcome (solved) various problems that occur.

That is, large apartments, buildings, and factories in urban areas, which are electricity mass consumption destinations (regions, facilities, buildings, facilities, devices, customers, etc.), which are suitable for consuming large amounts of photovoltaic electricity, as described in ① of <Example 2>. In areas and industrial complexes, there are few or small places where solar power generation facilities can be installed, while the demand for electricity is too high. Therefore, the problem that the electricity (power) produced here is not able to easily meet the demand of a large amount of electricity (power) is a problem that cannot be overcome (resolved) by current human technology.

In addition, as described in ① of <Example 2>, large apartments in urban areas, buildings, factories, industrial complexes, etc., which are convenient for mass consumption of photovoltaic electricity, are expensive. If you install and operate such photovoltaic facilities, which take up such a large amount of land and produce a small amount of electric energy, the production cost of electricity produced here will be very expensive. The problem of losing economic feasibility and competitiveness compared to electricity produced by consumption or electricity produced in nuclear power plants is also a problem that cannot be overcome (resolved) by human technology.

On the other hand, as described above in (1) of <Example 2>,

Very low land (including deep mountains, barren land, small or undeveloped areas, badlands, freezing lands), reservoirs, rivers, lakes, dams, seas, deserts, etc.

It is said that the land is inexpensive or low at all, the sun is strong and has a large area, i.e., the optimum conditions for producing the photovoltaic electricity at a very low cost by installing the photovoltaic facilities. Places that are good for producing electricity (ground, water, sea, or space) are often far from electricity consumers (regions, facilities, buildings, equipment, devices, customers, etc.) that are likely to consume large amounts of electricity. As it has the characteristics, when the transmission line using the existing power line is installed, the cost is enormously large, and as the transmission distance increases, the power loss rate also increases greatly, which is not solved by current human technology. .

In addition, as described above in ② of <Example 2>,

Due to the technical limitations of the existing method of electric transfer (power transmission by power line), it is not fully utilizing the optimal places to produce solar power (energy) more economically and in large quantities,

Due to these existing technical limitations, the best places to produce solar power (energy) more economically and in large quantities,

Solar power generation, the future energy of humankind, in the ocean, the distant sea of the wide lake, the distant river of the wide river, the distant sea of the wide dam, and the place on the vast and vast water where no other land (land value) is occupied. It is very difficult for human beings to produce (generate) large quantities of electricity at present. The human race is in a situation where it is difficult to completely replace the electricity produced by the existing coal-fired power plants or nuclear power plants with the photovoltaic electricity that is optimal for future energy. Problems are also problems that cannot be overcome (resolved) by human technology at present.

Thus, photovoltaic electricity is produced in a clean way that can eliminate the global environmental problems of fossil fuels, and is produced in a very safe way that completely escapes dangerous methods such as nuclear power plants. Even if it is the optimal future energy, it is possible to produce permanently and to produce the infinite amount of energy that humans can use and replace the energy that is almost infinitely used in the future.

 The above-mentioned problems have been comprehensively generated due to a mismatch between a good place for producing (power generation) such a photovoltaic electricity and an electric consumer for consuming photovoltaic electricity. Until now, it does not have the merit of using good photovoltaic electricity as above.

Without this merit, the use of photovoltaic electricity, which is the optimal future energy, is not universalized and popularized in the electricity consumers or mass electricity consumers that consume a large amount of electricity. I have not been able to replace electricity from nuclear power plants with photovoltaic electricity, the future energy.

Therefore, in order to solve this problem, as described above in the above ① and ② of <Example 2>,

What is necessary is to solve the problem by applying the future energy generation system technology of the present invention presented in <Example 1> to the above-described sites that do not feel the merit of photovoltaic electricity.

If you rearrange these methods,

In <Example 1>, the electric consumer,

A first consumer where there is no place (space) for installing the charging station or a place (space) having low economic feasibility,

Electric mass consumer who can consume (discharge) large quantities of electricity (new cities, urban areas, various buildings, apartments, factory areas, various industrial facilities, various buildings, large electric facilities or electric devices, and large electric customers) In addition, in the case of any one or more consumer destinations among the second consumer where there is no place (space) to install the charging station (narrow space) or only a place (space) of low economic feasibility,

In the electrical consumer (s), a method of receiving more economical electricity that is produced (generated) in a clean and safe manner,

Installed at a location spaced apart from the charging station (s),

In any one or more of a charging station or an intermediate collection station that produces (generates) electricity more economically in the clean and safe manner, the electricity is transferred through the wireless transfer method described in the <Example 2> and <Example 3>. Use the supply method.

In addition, the electric consumer,

A first consumer where there is no place (space) for installing the charging station or a place (space) having low economic feasibility,

In the case of one or more of the second consumer, which is a good mass consumer of electricity (discharged), which has a place (space) where the charging station is installed (narrow) or has only a low economic place (space). ,

 In the electrical consumer (s), a method of receiving electricity produced (generated) by the future energy production method,

Installed at a location spaced apart from the charging station (s),

In any one or more of a charging station or an intermediate collection station which receives electricity produced (generated) by the future energy production method and delivers the electricity to the electric consumer, a method of receiving electricity through a wireless transfer method is used.

For a detailed description of the methods described above, refer to the above description with examples in (1) and (2) of <Embodiment 2>.

<Example 7>

In step (a) of <Example 1> and <Example 6>,

A method of configuring a charging station for producing (generating) electricity more economically in the above clean and safe manner will be described.

In order to implement the present invention, as described above in (1) and (2) of the <Example 2>, <Example 3>, and <Example 6>, the production (power generation) by the technology of the future energy generation system according to the present invention The electricity to be produced should be more economical electricity and be produced (generated) in a safer and cleaner way than electricity from fossil fuel-fired or nuclear power plants.

In order to do this, it is necessary to produce (generate) electricity from the way of producing electricity (power generation) (power equipment) itself.

The method of producing electricity (electric power) in a safer and cleaner way than the electricity of thermal power plants or nuclear power plants generated by the consumption of conventional fossil fuels is currently developed by humankind. The method of producing electricity (power generation) with power generation power equipment by energy is becoming the best way.

By the way, such power generation facilities based on green energy or power generation facilities based on new and renewable energy, almost do not produce (generate) electricity with economical efficiency.

In particular, it is produced (generated) significantly more expensive than the power generation cost of thermal power plants or nuclear power plants, which are generated by the consumption of conventional fossil fuels. Thus, as described above in Examples 2 and 6, there is no economic feasibility. Due to the cost of power generation, the expansion of the market is delayed, and human beings are currently moving away from the existing energy that has many problems.

Thus, for the implementation of the present invention,

Example 1 (a) A charging station for producing (generating) electricity more economically in a clean and safe manner in step (a),

In order to receive more economical electricity that is produced (generated) in any one or more of the first and second consumers in <Example 6> in a clean and safe manner, separated from the electrical consumer (s). A charging station that produces electricity more economically in a clean and safe way,

It should be the following charging station.

The charging station,

A charging station for generating (generating) electricity that is stored (charging) stored in the electrical storage devices by installing a power generation facility having a lower cost of producing electricity, which is generated from green energy or renewable energy. Should be

In addition, the charging station,

It should be a charging station for installing (generating) photovoltaic electricity that installs photovoltaic facilities and stores (charges) the electricity storage devices.

In addition, the charging station,

Is a more economical place to install photovoltaic (ground, water, sea, or space),

The installation cost of photovoltaic electricity produced by the installation of photovoltaic power generation facilities is based on the electricity generation cost of electricity generated from various power plants that consume fossil fuels such as nuclear power plants or thermal power plants. Among places that can be economically cheaper than the unit cost (ground, water, sea, or space),

By selecting one or two or more places in any one or more places, and installing one or two or more units of photovoltaic power generation facilities in such one or more places or more places,

It should be a charging station for producing (generating) photovoltaic electricity stored in the electrical storage devices (charging).

And the location conditions that must be a more economical place to install the photovoltaic power generation facilities,

Place to install photovoltaic power generation equipment,

Locational first condition that the place's value (land value, rent, etc.) should be economically inexpensive or the place where the value of the place (land value, rent, etc.) is hardly entered,

Locational second condition that should be a place where the sunlight shines more intensely or the time for shining is longer, so that the amount of photovoltaic electricity is generated.

Locational third condition that should be a more spacious place to install photovoltaic power generation facilities in a larger size,

The electricity generated by the photovoltaic facilities is stored (charged) in an electrical storage device and transferred to an electrical consumer. The consumed (discharged) electricity storage device is a better place to perform the recovery process more economically. Among the fourth condition to be located,

You must have at least one locational condition.

And where a more economical place to install the photovoltaic power generation equipment has the location conditions that must be provided,

Economically inexpensive land areas (including deep mountains, barren land, low or undeveloped areas, badlands, etc.), reservoirs, rivers, lakes, dams, little islands, little beaches, small uninhabited islands , Little or no landland (such as in Russia, Alaska, Mongolia, etc.), and other areas with little or no other land (land price) Space, etc.)

Any one or more places (ground, water, sea or space, etc.) should be a more economical place to install the photovoltaic facility.

In addition, the unit cost of the photovoltaic electricity produced (generated) by installing the photovoltaic power generation equipment is an existing power system (operated by electricity generated from various power plants that consume fossil fuel such as nuclear power plants or thermal power plants). Locational conditions that must be in place that can be economically cheaper than electricity generation cost,

The amount of photovoltaic electricity (power) produced by the photovoltaic facilities installed in these places is more than the amount of electricity (power) generated by various power plants that consume and generate fossil fuels such as nuclear power plants or thermal power plants. It is a location that should be a good place to install photovoltaic facilities on a large scale to enable mass production (power generation).

And where the above conditions are met,

Oceans, deserts, plateaus, polar regions (North Pole, Antarctica), distant oceans, wide deserts (Sahara Desert, etc.), vast plateaus (such as the large, uninhabited Mongolian plateaus), distant seas of vast lakes, wide Distant cores of rivers, distant cores of wide dams, wide open areas without humans (such as large areas with no humans in the remote regions of Siberian fields, Russia, Alaska, Mongolia, etc.), wide deserted islands In other large areas, and in large, spacious places (such as land, water, sea, or spaces) that don't cost any land (land value) at all,

Any one or more places (ground, water, sea, or space, etc.) become places having the above location conditions.

In addition, the charging station,

In the charging station, one or two places (ground, water, sea, or space) where various infrastructures are installed to transfer the charged electric storage device to the electric consumer, can be made quickly and smoothly. Selecting one or more places, one or two intermediate storage places where the electrical storage devices (charged or discharged electrical storage devices) are gathered at one or more places of the selected one or two or more places. By installing at least a plurality of places, the electrical storage devices (charged electric storage devices or discharged electric storage devices) are mutually connected between the intermediate storage station (s) and the charging station (s). It should be a charging station which is transported and recovered by the wireless transfer method described in 2>.

And the intermediate house is

The electric storage device charged from the charging station is transferred to the charging station by the wireless transfer method described in <Example 2>, and the discharged electric storage device is transferred to the charging station by the wireless transfer method described in <Example 2>. Where,

In the intermediate storage center, various roads, air routes, shipping roads connecting the intermediate storage center and the electrical consumer, which transfer the charged electrical storage device to the electrical consumer, can be made quickly and smoothly. Various infrastructures (social overhead capital) or other infrastructure such as transportation facilities are established,

By utilizing such intermediate storage, the cost of the process of supplying electricity from the charging station to the electric consumer using the wireless transfer method described in the above-described <Example 2> is achieved by using the conventional wire transfer method. It is an intermediate collection station that serves to enter the economy more cheaply than the cost in the process of supplying electricity from the charging station to the electric consumer.

For a detailed description of the methods described above, reference is made to the foregoing descriptions of examples in (1) and (2) of the <Example 2>, and <Example 3> and <Example 6>.

<Example 8>

In step (a) of <Example 1> and <Example 6>,

It describes a method of configuring a charging station that receives the electricity (generated) produced by the future energy production method and delivers it to the electrical consumer.

In the future, the energy used by mankind is too much, and the amount of energy used is continuously rising.

This future energy must be able to be continuously produced in an enduring (eternal) way without depletion of energy, and must be produced in such a way that the amount of energy can be produced almost indefinitely so that no humans can use it in the future. It will be able to be qualified as a new future energy of mankind, and this future energy must be produced in a clean and pollution-free way so that it does not cause environmental pollution problems such as fossil fuels, and it is produced without any safety risks such as nuclear power plants. Should be.

Therefore, for the implementation of the present invention, as described above in (4) of <Example 2>, the electricity produced (generated) by the technology of the future energy generation system according to the present invention is produced (generated) by the future energy production method Should be electricity,

In order to do this, the method of producing electricity (power generation) itself must be produced (generated) from the earth and space or the future energy production method, which is completely different from the existing methods. A charging station that collects electricity that has been produced (generated) and receives it and delivers it to the electricity consumer is absolutely necessary.

for this

<Example 1> Charging station for receiving the electricity produced (generated) by the future energy production method of step (a) to deliver to the electrical consumer,

At least one of the first and second consumers in <Example 6> is spaced apart from the electrical consumer (s) in order to receive electricity generated (generated) by a future energy production method. The charging station that receives electricity generated (generated) by the future energy production method to be installed and delivers it to the electric consumer,

It should be the following charging station.

The charging station that receives electricity produced (generated) by the future energy production method and delivers the electricity to the consumer,

It should be a charging station that receives electricity produced (generated) by future energy production methods.

And the <Example 1> the electricity produced (generated) by the future energy production method of step (a),

It is produced continuously in a permanent (everlasting) way without energy depletion, and in such a way that it produces almost infinite amounts of energy so that there is no shortage no matter how much human beings use in the future, and environmental pollution problems such as fossil fuel It must be electricity that is produced in a clean, pollution-free way (without pollution, fine dust and carbon emissions), and without any safety risks such as nuclear power plants.

And in the cleanest way (without pollution, fine dust, carbon emissions), almost indefinitely, almost permanently, and among the methods of producing electricity (power generation) so that there are no risks to safety, such as nuclear power plants. Way,

It is a method of receiving electricity (energy) brought by an electric energy transport device from the sky or the universe.

In addition, the place where the charging station that receives the electricity (generated) produced by the future energy production method and delivers to the electrical consumer is to be installed,

Among the charging stations that produce (generate) electricity more economically in a clean and safe manner, inside the intermediate storage center described in Example 7 above, or other places where electricity can be transmitted and delivered more economically and cheaply. It is any one or more places (ground, water, sea, air, or space).

And other places that can receive and deliver electricity inexpensively and economically,

In the process of receiving the electricity (energy) brought by the electric energy transport device from the sky or the space, and delivered back to the electrical consumer,

In the charging station, the cost of supplying electricity to the electric consumer using the wireless transfer method described in the above-described <Example 2> is incurred in the process of supplying electricity using the existing wired transfer method. It should be a place where you can get more economically cheaper than the cost of entry (ground, water, sea, air, or space).

In the charging station, the cost of supplying electricity to the electric consumer using the wireless transfer method described in Example 2 is in the process of supplying electricity using the existing wire transfer method. The place that enters more economically cheaply than expense to enter, and a more efficient place,

In the charging station, to transfer the charged electrical storage device to the electrical consumer, various roads, air routes, shipping routes, other transportation facilities, etc. to connect between the charging station and the electrical consumer to be made quickly and smoothly It is a place where various related infrastructures are built or infrastructure is built.

In addition, any one or more of the charging station for receiving the electricity (generated) produced by the future energy production method and delivered to the electrical consumer, or the intermediate collection station described in the <Example 7>,

The method of receiving the electricity (energy) brought by the electric energy transport device from the sky or the space and delivering it back to the electric consumer,

In the charging station or the intermediate storage center described in <Example 7>, a large-capacity secondary electric storage device (such as an ESS) having a large capacity is installed and installed in the electric energy transport device from the sky or the space. After storing (charging) the electricity (energy) brought by the secondary electric storage device again, the stored electricity is stored in the electric storage device made to perform the wireless transfer method described above in Example 2 again. A first method of supplying the battery to the electric consumer and supplying the same by using the wireless transfer method described in Embodiment 2,

The electric storage device which stores (charged) the electricity stored by the electric energy transport device from the sky or the space is transmitted to the charging station or the intermediate storage center described in the <Example 7> (to the electric energy transport device An electric storage device configured to be exchanged for loading and unloading is stored (charged) on the earth or in space, and loaded into the charging station or the intermediate storage center described in <Example 7>. Example 7> Loads the discharged electrical storage device in the electrical energy transport device by placing it in the intermediate storage center described above and replacing it with a discharged electrical storage device that consumed (discharged) electricity at the electrical consumer. After all the actions up to), the electric storage device itself received in this way using the wireless transfer method described in the <Example 2> The second method of transfer to the consumer,

Among the third method to supply by using the first method and the second method mixed,

Either way or more.

For a detailed description of the methods, please refer to the above description with examples in ④ of <Example 2>.

Example 9

The electric energy transport apparatus in the <Example 8> will be described.

The electric energy transport device,

Fly up into the earth or space (space), stay in the earth or space (space), produce (generate) and charge (store) solar electricity, and then back to the ground, water, sea, air, or Return to any specific designated charging station, such as space, to transfer the resulting electrical energy (as described above in Example 8), fly back up the earth or into space (space), and fly up After the solar cell is produced (generated) and charged (stored) while staying in space (space), it must be made of a flight device that continuously repeats the transfer of electrical energy brought back to the designated charging station again.

Here, the designated charging station is

All of the charging stations described in the above <Example 8> are all applicable to the collection (all collection) of electricity that has been stored (charged) and transported in the electric storage device provided in the electric energy transport apparatus from the earth or the universe. ), The storage (charge), or the removable electric storage device that has been charged and transported, with a facility, equipment or personnel that serves to recover and replace the removable electric storage device to be recharged, The use of a certain name (such as the designation indicated) at any location in the region refers to any one or more of the designated charging stations.

Therefore, as described above, the electric energy transport device to fly up the earth or space (space), and stay in the earth or space (space) to produce (development) and charge (store) the photovoltaic electricity, When the entire process from returning to the designated charging station installed on the ground, the sea, or the air of the earth and delivering the imported electric energy is called one electricity production and transportation cycle,

The flight device must be made of a flight device that continuously runs one or more times in a cycle of electricity production and transportation.

In addition, the electric energy transport device made of a flying device as described above is provided with a photovoltaic power generation unit, consisting of a photovoltaic power generation facility for generating (generated) electric energy by receiving light energy from the sun, over the earth or in space,

In the sky or the space is provided with an electrical storage device including the function of storing (charging) the electricity produced (generated) in the photovoltaic unit, and delivers the electricity stored (charged) to the charging station,

The electricity generated in the photovoltaic unit is generated (generated) is stored in the electrical storage device, and the electrical, control circuit for enabling the output (discharged) stored (charged) is configured to be connected to each other, You have to make it up.

So the electric energy transport device made in this way,

In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station, the earth and space,

Photovoltaic electricity produced (generated) in the photovoltaic unit from the sky and the space is stored (charged) in the electrical storage device, to be brought to the charging station to be delivered to the flying device.

In conclusion, to recap it,

The electric energy transport apparatus, including a photovoltaic power generation unit consisting of a photovoltaic power generation facility for producing (generated) electric energy by receiving light energy from the sun in the space or space,

It is provided with an electric storage device including a function of storing (charging) the electricity produced (generated) in the photovoltaic unit in the sky or space, and delivering the electricity stored (charged) in the designated charging station,

The electricity produced in the solar power generation unit (generated) is stored in the electrical storage device, and configured to include an electrical, control circuit connected to each other to enable the output (discharge) of the stored (charged) electricity So,

In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station, the earth and space,

It is a flying device that stores (charges) photovoltaic electricity produced (generated) in the photovoltaic unit from the sky or the space and delivers it to the designated charging station.

In addition, the electricity production, transportation cycle,

The electric energy transport device is flying up the earth or space (space), and stays in the earth or space (space) to produce (generated) and charge (store) solar electricity, and then return to the designated charging station It is the whole process of delivering imported electric energy.

And the designated charging station,

With all the charging stations described above in Example 8,

Collecting, storing (charging), or the charged and transportable removable electric storage device which has been stored (charged) and transported from the sky or the space to the electric storage device provided in the electric energy transport device should be recovered and recharged. Among the charging stations, which have a facility, equipment, or manpower to change and re-install a removable electric storage device, and which use a certain name (a designation, etc.) at a certain location in an area. At least one charging station.

<Example 10>

And for practical implementation of the invention,

The electric energy transport apparatuses in the <Example 8> and the <Example 9>,

Rather than the total amount of energy used (dissipated) in one cycle of electricity production and transportation, electricity is generated (generated) from the sky or space through a single cycle of electricity production and transportation to a designated charging station. It must be made in such a way that the total amount of energy brought (transported) is increased.

In more detail,

In order to implement the present invention, the electric energy transportation device generates electricity (power generation) through a photovoltaic power generation unit provided in the main body in the space or space and stores (charges) the photovoltaic electrical storage device, and brings it to a designated charging station. The total amount of energy (transported) (electric energy) must be greater than the total amount of energy (electrical energy and other energy) consumed (consumed) in all processes for production and transportation. It is possible to make it possible and to have the qualities as future energy desired in the present invention.

The purpose of the future energy generation system of the present invention is based on the limitations of the energy depletion used by humanity in the future, the problems of fossil fuels that deepen the global environmental problems due to pollution, fine dust, carbon emissions, and the recent Fukushima nuclear accident in Japan. It is to solve the problems of safety and safety of nuclear power plant that humanity became more aware of.

If the total amount of energy brought by the electric energy transport apparatus into the sky or the space and produced and stored is less than the total amount of energy consumed for this purpose, the object of the present invention cannot be achieved.

Because if the total amount of energy used to produce and import is greater than the total amount of energy produced and imported, the amount of additional energy consumed to produce and import (total energy produced and imported-total energy used to produce and import = additional energy consumed) ), So that the human race will result in the useless creation of a huge amount of demand for supplementary energy consumption.

In order to meet the demand for supplementary energy consumption, the supplementary energy (additional energy consumption) is eventually used again by fossil fuels (air fuel, etc.) or by burning fossil fuels to obtain electricity. There is no choice but to supplement the use of electrical energy obtained by operating a nuclear power plant where risks exist (such electricity can only supplement the additional energy consumed by the electrical energy transport system).

This is because it has the adverse effect of speeding up the depletion of fossil fuel energy and significantly increasing the construction of nuclear power plants.

Therefore, in order to achieve the present invention, the electric energy transport apparatus,

Rather than the total amount of energy used (dissipated) in one cycle of electricity production and transportation, electricity is generated (generated) from the sky or space through a single cycle of electricity production and transportation to a designated charging station. It must be made in such a way that the total amount of energy brought (transported) is increased.

And as a practical implementation method for realizing the above method,

In the electric energy transport apparatus of <Example 8> and <Example 9>,

A part or most of the energy required to operate (drive) the electric energy transportation device;

By making full use of the principles of nature (or the order of the universe), we make them in such a way as to handle them with the forces of nature (energy) obtained naturally.

When the electric energy transportation device is capable of operating (driving), it should be made in such a way that most of them are driven (driven) by natural force (energy) with little extra energy.

And in a way to bear part or most of the energy required for the operation (driving) of the electric energy transportation device by the force of nature,

The electric energy transport apparatus in <Example 8> and <Example 9>,

When flying over the earth or in space, when staying in the earth or in space, when returning from the earth or space to a designated charging station, or when driving (driving) a section in which other energy is consumed in large quantities Etc,

Some or most of the large amount of energy required in these sections can be handled by the forces of nature (energy) obtained naturally by using the principles of nature (or the order of the universe) even with little energy consumption. It must be made in a way.

This is because when the electric energy transport device floats over the earth or in space, stays in the earth or in space, returns to the designated charging station from the earth or in space, or travels in which other energy is consumed in large quantities. The energy consumed in at least one section, such as when driving (driving), accounts for the majority of all energy consumption for the electric energy transport system to move (drive).

Significantly reduce the amount of energy consumed in the operation in the above section, which occupies most of the energy used to move (drive) the electric energy transportation device, or zero the energy consumption itself at all (100% free) This is because the above object can be easily achieved.

In addition, the large amount of energy required for the operation in the above section should be used as energy obtained for free without separate energy consumption, but it will significantly reduce energy consumption or zero the energy consumption at all (100% free). Can be made into

The most surely feasible way of doing this is the natural force (energy) that is naturally obtained by utilizing the principles of nature (or the order of the universe). This can be reduced to zero, or zero energy consumption (100% free).

And by utilizing the principles of nature (or the order of the universe, etc.), one of the more effective types of natural forces that are naturally obtained without extra energy consumption is the buoyancy in the air trying to push it up into the air in the opposite direction of Earth's gravity. Is to use buoyancy.

The buoyancy in the air, using any one or more of natural buoyancy made using a buoyancy material, artificial buoyancy made by applying a negative pressure (-) or vacuum to artificially generate buoyancy,

The natural buoyancy is a buoyancy force in which buoyancy is naturally formed when a buoyant material is filled in a space having a constant volume (an object having a certain volume of space).

Here, the buoyancy material is a material having a density lower than the density of air to generate the effect of buoyancy in the air (air) of the earth.

Because air is creating a force (atmospheric pressure) that is attracted to the Earth's center of gravity (ground) by gravity in the Earth's atmosphere, where air and other fluids (alternative fluids) act to press the air. As a result, a substance with a lower density than air (alternative fluid) is equal to the mass per volume and the difference per mass of the air volume (the mass value of the difference value minus the mass of the fluid replaced by the air mass with the same volume). Since air buoyancy (buoyancy in the air that tries to push it up into the air in the opposite direction to earth gravity) is generated,

The buoyancy material should be a material that generates buoyancy in the air (in the air) on the ground, for this purpose must be a material having a density lower than the density of the air.

  In order to easily achieve the above object, a buoyant material having a density lower than that of the air is actually applied to the electric energy transport device so that a large amount of energy is required for driving (driving) the electric energy transport device. Most of the consumed section should use the buoyancy which is a natural force obtained by the buoyancy material as described above, in order to do so, it is necessary to use the buoyancy material which is easy to apply the buoyancy material to the electric energy transport apparatus.

Therefore, as a buoyancy materials that are easier to use by applying to the above-mentioned electric energy transportation device, as a result of actual experiments,

Helium gas, hydrogen gas, methane gas, nitrogen, etc., when applied to the electric energy transport device is easy to generate buoyancy and other convenience in use is great.

The artificial buoyancy is a buoyancy force formed by applying a negative pressure (-) or a vacuum to artificially generate buoyancy in a space having a predetermined volume (object having a predetermined space).

Because, as described above, a space having a certain volume (an object having such a space (fluid)) has a mass per volume of the whole space less than the mass of the same volume of air, that is, the object (fluid) is less than the density of air. If the density is low, the volume of space (objects having such a space (fluid)) is buoyant,

The method of artificially creating buoyancy without using buoyancy materials is to apply negative pressure (-pressure) to a space with a certain volume, or to reduce the air density by applying a vacuum (extract some air to reduce the amount of air molecules). Or by removing it (by vacuum) altogether (by vacuum)), the mass of the object (fluid) becomes smaller at the same volume, resulting in a mass difference between the same volume of air mass and the object (fluid). The buoyancy is generated by the difference value of the mass, and this buoyancy is the artificial buoyancy.

If the above description in more detail,

In order to achieve the present invention, the electric energy transportation device,

The total amount of energy brought (transported) to the designated charging station through one electricity production and transportation cycle is greater than the total amount of energy used (and consumed) during one electricity production and transportation cycle. To make it in a way to do it,

Most of the driving force of the electric energy transportation device, which is one of the important technologies of the future energy generation system of the present invention, is to use the buoyancy in the air, which is the force of nature, that is, make full use of the energy free of the nature of buoyancy, the electric energy transportation By minimizing (or zeroing out) the energy consumed by the device to travel and drive to generate and charge solar electricity in the air or space of the Earth, the electrical energy transporter moves up into the Earth's air or space, The method of minimizing the total amount of energy brought (transported) is achieved by almost zeroing the total energy used during generation, charging and bringing it to the designated station.

To this end, buoyancy, which is energy (force), which is free from nature, which is needed in the present invention, refers to natural force (without extra energy consumption) that tries to move in the opposite direction to earth's gravity.

To utilize this buoyancy to meet the needs of the present invention,

Power (energy) necessary to overcome the gravity of the earth in order for the electric energy transport device to rise into the earth's air or space (space),

The power needed to overcome the gravity of the planet while staying in the earth or in space (space) to produce and store photovoltaic electricity,

The energy needed to return the designated charging station

Most of the energy needed to travel, turn,

It makes use of buoyancy which is free energy which nature gives.

By the way, the most effective method to generate the buoyancy to the desired size to utilize in the present invention, by making the electric energy transfer device desired in the present invention to be different from the density of air to generate buoyancy.

In other words, density is the mass of a substance divided by volume, and buoyancy is the force of an object trying to move in the opposite direction of the earth's gravity, which is equal to the mass of the object that corresponds to its volume.

The electrical energy may be provided in various ways, such as by inserting a buoyant material into the electric energy transport device (natural buoyancy), artificially buoyancy (artificial buoyancy), or by installing a device (buoyancy device) in which a separate buoyancy is generated. The weight (mass) corresponding to the volume of the transport device is made less than the mass per volume of the same volume of air (by making the density of the electric energy transport device lower than the density of the ambient air at the same volume), so that the electrical The buoyancy to be obtained by the energy transport device is to be obtained, and the magnitude of the buoyancy should be adjusted by adjusting the magnitude of the density difference (mass difference) as described above.

Arithmetic detailing again, the buoyancy force applied to an object is equal to the weight (mass) of the fluid replaced by that object.

Expressed by the formula, U = Vρg.

Where U is the buoyancy force (N), V = volume of replaced fluid (m 3), ρ = density of replaced fluid (kg / m 3), g = gravity constant (N / kg).

Eventually U = W so that the buoyancy is equal to the weight (mass) of the fluid replaced.

Where W = weight of the replaced fluid (N, mass).

In addition, the replaced fluid refers to all materials existing on the earth except air among the air on the earth, and in the present invention, the object to be lifted into the air, that is, the electric energy transport device or the electric energy transport device is lifted to the air. It means buoyant materials, buoyancy devices, etc. used for the purpose.

Thus, without any extra energy consumption, once the buoyancy is increased, the replacement of the fluid to be lifted into the air (over the earth) by natural forces (the force that pushes the fluid replaced by the density difference) The weight can be increased.

That is, as the buoyancy increases, the weight of the electric energy transport device to be lifted to the earth in proportion to the buoyancy increase proportionally increases, so that the buoyancy can be lifted into the air without additional energy.

Let's explain this again with an example.

In order to produce future energy, which makes it possible to produce electric energy in the safest and cleanest way, almost infinitely largely without limit of energy depletion which is the object of the present invention (forever).

One electric energy transportation device is used as a drone. The drone is installed with a capacity to produce (generate) about 1.6 KWH of solar power equipment per hour (for example, a company called Tinkle Power Plant in Korea) The 100WH solar module that produces and sells is a curved product. It weighs 1.85kg and has a thickness of 3mm, a width of about 1m and a length of about 0.5m, and receives 100WH of electricity per hour. In the production, 16 such solar modules are installed in the electric energy transport device in a structure that can receive sunlight well, where the total weight of the 16 solar modules is about 30 kg, and in 16 solar modules The total capacity of electricity produced is 1.6 KWH per hour),

In addition, by installing an electrical storage device that can store about 50KWH (KVAH) capacity as a solar electric storage device in one drone (for example, an industrial battery produced and sold by a company called Tinkle Power Plant in Korea) Electric storage device) 50KWH (KVAH) 1 capacity class can be installed, which weighs 67㎏.),

After the drone is made by constructing an electric circuit such that electricity generated (generated) in a photovoltaic facility installed in one drone can be charged (stored) in an electric storage device installed together,

When the drone is lifted up to the earth, one drone can produce and store 1.6KWH of solar power electricity per hour, and when the drone floats only about 31 hours over the earth (24 days a day) By chasing without rest for hours and redirecting to direct sunlight to ensure that the sun shines well, a total of 50 kW (KVAH) of electricity can be stored (charged) and returned to the designated charging station.

At this time, assuming that the weight of the drone itself and other equipment is about 50 kg, the total weight of one drone is about 150 kg.

Therefore, it is assumed that the 150kg drone weighs only one buoyancy in the air, without additional energy consumption, and the buoyant material that causes buoyancy in the air is selected as helium gas among the lighter than the air density. Assuming that we intend to apply it to the purposes of this example,

In order to make one drone of the above example float (over or stay in the air) with the buoyancy of the air, the space is coated inside the drone of the example (coating treatment) and the helium gas leakage rate is Assume that zero), this space is configured to be located in the center of the center of gravity of the drone, but the volume inside the space is configured to be 120 ㎥ or more so that the total volume of one drone of the above example is at least 120 ㎥, When helium gas is filled to fill the space (at atmospheric pressure), the drone of the above example floats up to the air (above the earth) only by the force of nature (air buoyancy), and the total weight of the drone of the example target is It can be made of 150kg and can be sent to the earth only by buoyancy without any energy consumption.

If you prove it again with a formula,

Since U = W in the buoyancy formula, buoyancy is equal to the weight (mass) of the fluid replaced, i.e. buoyancy is the force of nature trying to move in the opposite direction to earth's gravity as described above (without extra energy consumption). Where buoyancy is equal to the mass of the replaced fluid corresponding to the volume of the replaced fluid (the object to be lifted into the air with buoyancy), and the Earth's gravity is pulling all matter towards Earth in the direction of gravity, Since the air surrounding the earth and forming the atmosphere is pressed down at a pressure of 1 atmosphere (atmospheric pressure) on all the earth's materials,

Materials that are less dense than air density (density is the mass of a substance divided by volume) (i.e., lighter in mass at the same volume as air) are subject to air by gravity's force (air pressure, 1 atmosphere) The force to occupy its place pushes non-air matter (replaced fluid requiring buoyancy) into the air, where the non-air replaced fluid remains on the ground by its mass per volume (density). It is the weight of all replaced fluids (mass per volume = density) that is not air, each of which has a buoyancy force that is pushed up into the air by a difference from the mass (density) per volume of air. This air buoyancy is generated by the replaced fluid (in the present invention, using the buoyancy buoyancy to lift the air to the object of the example drone The mass of air) and the mass of air.

Therefore, if the total weight of the drone is 150 kg and its total volume is at least 120 m3,

Since mass (kg) = density (kg / m 3) x volume (m 3),

Air density = 1.43 (kg / ㎥) (the density of air at 0 ° C and 1 atmosphere),

Helium density = 0.18 (kg / ㎥) (the density of helium at 0 ° C and 1 atmosphere),

Since the air buoyancy (N) = air mass (kg)-buoyancy material (helium) mass (kg), the air buoyancy (N) = 1.43 (kg / ㎥)-0.18 (kg / ㎥) = 1.25 (kg / ㎥) do.

However, the above-mentioned air buoyancy of 1.25 (kg / ㎥) is that helium gas having a volume (volume) of 1 m in width, 1 m in height, and 1 m in height has 1.25 kg buoyancy in air (at 0 ° C and 1 atm). This buoyancy is the same as lifting a lighter material (buoyant material, helium gas in this example) into the air (above the earth) as natural force (buoyancy). ,

On the contrary, to lift the electric energy transportation device having a total weight of 150 kg into the air, a buoyancy of 150 kg or more is required.

When the helium gas has a volume of 1 ㎥ 12.5kg buoyancy to have a 150kg buoyancy, 150kg ÷ 1.25kg = 120 times,

When the volume of the helium gas is increased to 120 times, it can have a buoyancy of 150 kg.

Therefore, the aerial buoyancy when the helium of buoyancy material is provided with a volume of at least 120 m 3 in one drone having a total weight of 150 kg in the above example,

The drone weighing 150 kg in the above example is to be lifted up in the state without any energy consumption only by the force of nature (without the consumption of energy separately) over the earth (air).

Next, one drone of the above example, as above, rises to the air buoyancy only above the earth, and climbs to a suitable position (a position where solar power can be well), while reducing the buoyancy provided in the drone (in the space inside the drone). If the density of the drone and the density of the surrounding air are equalized while releasing a portion of the filled helium gas to the atmosphere, the drone can stay in the air with no air buoyancy alone.

Thus, the drone stays in the air for only about 31 hours (by chasing the sun for 24 hours a day and changing its direction to direct sunlight so that the sun shines well). When the balance of buoyancy is balanced, the natural solar power alone does not consume any energy, and the 16 solar modules mounted on the drone receive sunlight strongly in direct sunlight. When 100WH of electricity is generated and 16 outputs are combined, a total of 1.6KWH of electricity is generated (generated) per hour, and 50KWH (KVAH) of industrial battery (electric storage device) mounted with 16 solar modules in the drone. One capacity class stores (charges) electricity for a total of 50 KWH (KVAH) capacity for 31 hours.

Next, one drone of the above example, which utilizes only natural buoyancy, which is a force of nature without any energy, and stores (charges) a total of 50 kW (KVAH) of electricity through photovoltaic power generation, ends electricity storage and returns to a designated charging station ( For example, return to the designated charging station installed in Seoul, Korea.

When we return, we use Earth's gravity to return with little energy consumption.

That is, if the helium gas charged inside the drone is discharged to the atmosphere and the density of the entire drone is heavier than the ambient air density (releasing a large amount of helium gas into the atmosphere, greatly reducing or eliminating the buoyancy of the drone) ,

The total density of the drones is greatly increased (by the weight of 150 kg) by the surrounding air density and is brought down (returned) to the designated charging station installed in Seoul, Korea naturally by the earth gravity.

In conclusion, the above-mentioned drone weighing 150 kg using the air buoyancy as described above is operated by using only the air buoyancy, which is the force of nature, between the earth and the designated electric energy transmission site installed on the ground. )

With purely natural power and virtually no extra energy consumption, a total of 50 kW (KVAH) of total electricity can be obtained for free.

In other words, if you take advantage of buoyancy (energy), which is nature's free energy,

Rather than the total amount of energy used (dissipated) in one cycle of electricity production and transportation, electricity is generated (generated) from the sky or space through a single cycle of electricity production and transportation to a designated charging station. This can lead to a greater total amount of energy brought (transported).

In addition, if you send 19,000 drones above the earth at the same time in the above manner, let them stay for 31 hours, and then return them to the designated charging station in Seoul, Korea, you will get a total of 950,000 KWH of electric energy. The free electric energy of 950,000 KWH is equal to the electricity produced by one Korean nuclear power plant in one hour (950,000 KWH of Hanul Nuclear Power Plant).

In addition, if the above method is continuously repeated, that is, when 589,000 drones are divided into 31 trillion units and 19,000 units per trillion are sent to the earth at an hourly interval, after 31 hours from the initial start,

The 19,000 drones store electricity of 50 kWH (KVAH) per hour and return to the ground at an hourly interval, so that electricity of 950,000 kWH per hour can be obtained free of charge.

If you keep doing this, you'll be able to get 950,000 KWH of electricity per hour for free, almost permanently (permanently) without limiting energy exhaustion throughout the year, 24 hours a day,

This result is equivalent to generating electricity by continuously operating (operating) one 950,000 KWH capacity nuclear power plant forever.

In addition, if the above-mentioned method is expanded, that is, if millions of drones, hundreds of millions, and infinitely large numbers of such drones are operated in the above-described manner, the human race will be almost permanent (eternity) without the limit of energy exhaustion in the future. Very safe and clean electrical energy (photovoltaic electricity), which can be continually obtained in an infinitely large amount.

Thus, by utilizing the present invention, in the future, human beings will constantly obtain a large amount of electric energy (photovoltaic electricity) in a permanent and almost infinite manner (forever) without the limit of energy exhaustion by a clean and safe method. Can be.

In summary, the above-mentioned bar,

The electric energy transport apparatuses in the <Example 8> and the <Example 9>,

Rather than the total amount of energy used (dissipated) in one cycle of electricity production and transportation, electricity is generated (generated) from the sky or space through a single cycle of electricity production and transportation to a designated charging station. It must be made in such a way that the total amount of energy brought (transported) is increased.

And the electric energy transportation device,

Rather than the total amount of energy used (dissipated) in one cycle of electricity production and transportation, electricity is generated (generated) from the sky or space through a single cycle of electricity production and transportation to a designated charging station. In order to make the total amount of energy brought in (transported) more,

Some or most of the energy required to operate (drive) the electric energy transportation device,

It should be a way of dealing with the forces of nature (energy) obtained naturally by utilizing the principles of nature (or the order of the universe) with little extra energy.

And a method of carrying out part or most of the energy required for the operation (driving) of the electric energy transportation device by the force of nature,

When the electric energy transport device floats over the earth or in space, stays in the earth or in space, returns to the designated electric energy delivery site from the earth or in space, or travels in which a large amount of energy is consumed (driving When running (driving) a section, part or most of the large amount of energy consumed in any one or more service sections,

With very little extra energy, it should be a way of dealing with the forces of nature (energy) obtained naturally by utilizing the principles of nature (or the universe order, etc.).

 And the power of nature naturally obtained by utilizing the principles of nature (or the order of the universe) without the separate energy consumption,

It is best to use the buoyancy in the air that is trying to push it up in the opposite direction of Earth's gravity.

And the buoyancy in the air,

At least one of natural buoyancy made by using buoyancy material and artificial buoyancy made by applying negative pressure or vacuum to artificially generate buoyancy should be used.

And the natural buoyancy is,

When buoyancy material is filled in a space having a certain volume (an object having a certain volume of space), the buoyancy is formed naturally.

And the buoyancy material,

It is a substance with a density lower than that of air.

And as a buoyancy material having a density lower than the density of the air is a buoyancy material that is easier to use and applied to the electric energy transport device,

It is more effective to use one or more of helium gas, hydrogen gas, methane gas and nitrogen.

In addition, the artificial buoyancy is buoyancy that is formed by applying a negative pressure (-) or vacuum so that the buoyancy is artificially generated in a space having a predetermined volume (object having a predetermined volume of space).

In addition, the future energy production method,

On the earth or in space, provided with a photovoltaic power generation unit, consisting of a photovoltaic power generation facility that generates (generated) electrical energy by receiving light energy from the sun,

It is provided with an electric storage device including a function of storing (charging) the electricity produced (generated) in the photovoltaic unit in the sky or space, and delivering the electricity stored (charged) in the designated charging station,

The electricity produced in the solar power generation unit (generated) is stored in the electrical storage device, and configured to include an electrical, control circuit connected to each other to enable the output (discharge) of the stored (charged) electricity So,

In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station, the earth and space,

The electric energy transport device is a flying device that stores (charges) solar power generated in the photovoltaic unit from the sky or space and stores it in the electrical storage device, and delivers it to the designated charging station. after,

The electric energy transport apparatus is made in numerous numbers in one or two or more, and in addition, the designated charging station is made in many places in one or two or more places,

Countless electric energy transport devices of one or more than two or more fly up the earth or space (space),

After staying in the air or space (space), produce photovoltaic electricity through the photovoltaic unit provided in the main body, and charge (store) it in the electrical storage device provided in the main body. Return to the designated charging station, which is made in numerous places and many, or part of or almost a large part of the energy that goes through this operation, is obtained naturally by using the principles of nature (or the order of the universe) without extra energy consumption. Power buoyancy, etc.) to return to the designated charging station, transfer the electricity thus obtained to the designated charging station,

After flying back to the earth or space (space), staying in the earth or space (space) again producing (powering) and charging (storing) solar electricity,

Returning to the designated charging station and delivering the imported electricity, through the continuous repeating process of many times one or two times a number of times, the photovoltaic electricity imported in this way is permanent (forever), infinite It is a way to ensure that humanity is supplied cleanly and safely.

And the method of making the electric energy transport device effectively,

The drone is made of a drone and used as the electric energy transportation device.

<Example 11>

In <Example 10>, the buoyancy in the air is applied to the electric energy transport apparatus by a method of bearing a part or most of the energy required for driving (driving) the electric energy transport apparatus by natural force (energy). How to apply,

Create a space having a constant volume inside the electric energy transport device and fill the buoyancy material in the space to form a natural buoyancy, or to form artificial buoyancy by applying a negative pressure (-pressure) or vacuum in the space, or A first method of providing a buoyancy device made to have any one or more buoyancy of natural buoyancy or artificial buoyancy in the electric energy transport device by any one or more of the methods,

A second method of providing a buoyancy device made to have one or more buoyancy of the natural buoyancy or artificial buoyancy as an additional configuration in an electric energy transport device;

Among the third method of adjusting the magnitude of one or more buoyancy of the natural buoyancy, artificial buoyancy, or buoyancy of the buoyancy device in the first and second methods,

It must be equipped using one or more methods to be effective.

<Example 11-1>

In more detail about the first method,

① As a method of forming a natural buoyancy by creating a space having a constant volume inside the electric energy transport device and filling the buoyancy material in the space,

Magnitude of buoyancy (buoyancy = lifting weight) corresponding to the magnitude of the weight of the electric energy transport device, in order to cause the electric energy transport device to be lifted by buoyancy which is the force of nature over the earth or the air with any desired weight. Is needed.

However, the magnitude of buoyancy per unit volume is the difference between the mass value of air per unit volume minus the mass value of the buoyant material per unit volume.

Therefore, in order to obtain a buoyancy of a size corresponding to the size of the weight of the electric energy transport device, after setting the mass difference value of the ambient air and buoyancy material per 1㎥ volume as the buoyancy reference value, the weight of the electric energy transport device weight value is buoyancy reference value Determine the value calculated by dividing by the volume size of the space to be provided with buoyancy material,

It is necessary to create a space having a volume or larger than a volume size value of the space in which the calculated buoyant material should be provided in the electric energy transport device, and fill (buy in) the buoyant material (in this case, the buoyancy material injection pressure). Shall be 1 atm equal to the ambient air pressure).

For example, such a method will be described in more detail.

As described above in <Example 10>,

When lifting an electric energy transportation device weighing 150 kg over the earth using only the buoyancy of helium gas,

In the formula of mass (kg) = density (kg / m 3) x volume (m 3),

Air density = 1.43 (kg / ㎥) (the density of air at 0 ° C and 1 atmosphere),

Since helium density = 0.18 (kg / ㎥) (the density of helium at 0 ° C and 1 atmosphere),

First, when the buoyancy reference value is calculated, the buoyancy reference value (difference value of density) = air density-helium density = 1.43 (kg / ㎥)-0.18 (kg / ㎥) = 1.25 (kg / ㎥).

By the way, the air buoyancy of 1.25 (kg / ㎥) means that helium gas having a volume (volume) of 1 m in width, 1 m in height, and 1 m in height has 1.25 kg buoyancy in air (at 0 ° C. and 1 atm). And, this buoyancy is the same as saying that it lifts the material (buoyant material, helium gas in this example) lighter than air weighing 1.25kg to the force of nature (buoyancy) in the air (over the earth),

If the volume size value of the space to be provided with the buoyancy material (helium gas) to be based on this,

To lift the electric energy transportation device having a total weight of 150 kg into the air, a buoyancy of 150 kg or more is required.

When the helium gas has a volume of 1 ㎥ 12.5kg buoyancy to have a 150kg buoyancy, 150kg ÷ 1.25kg = 120 times,

When the volume of the helium gas is increased to 120 times, it can have a buoyancy of 150 kg.

Therefore, the value of 120 times the calculated value of the space to be provided with buoyancy material (helium gas) inside the electric energy transport device to obtain the amount of buoyancy required to lift the weight 150kg of the electric energy transport device over the earth. A volume size value of 120 (m 3) is obtained, and a space having a volume of 120 m 3 or more is installed inside the electric energy transport device, and a method of injecting helium gas into the entire space (wherein the helium gas injection pressure is equal to the ambient air pressure). After the buoyancy is increased to make the electric energy transportation device, and then float it in the air, the electric energy transportation device having a weight of 150 kg is a natural force even in the absence of any energy consumption. Only buoyancy (natural buoyancy) rises above the earth.

(2) In the first method, a method of forming artificial buoyancy by applying a negative pressure or vacuum to a space having a constant volume inside the electric energy transport apparatus,

Negative pressure means that the air pressure is at a pressure below atmospheric pressure, and vacuum means a space where no material exists.

However, since vacuum is actually very difficult to make a complete vacuum, a low pressure of about 1/1000 (10-3) mmHg or less is called a vacuum, and if we use a vacuum, we usually evacuate a gas in a certain container. It refers to a state of high pressure (for example, a vacuum cleaner, which does not create a full 100% vacuum, but increases the negative pressure by releasing the air largely close to the vacuum, which is called vacuum). Is the same meaning as expressed).

Therefore, the negative pressure and the vacuum only differ in terms of the unit, and the same means that the air pressure is below the atmospheric pressure.

In the present invention, for convenience, the negative pressure is a state in which the air pressure is at or below atmospheric pressure (low pressure), but a state in which the low pressure is small is referred to as a negative pressure, and a state in which the degree of low pressure is large is called vacuum, and vacuum or negative pressure In the case of pulling air molecules so that the pressure is lower than atmospheric pressure, the amount of air being taken out is expressed as negative pressure and the state of being taken out large is vacuum.

Therefore, in order for the electric energy transport device to lift the buoyancy which is the force of nature over the earth or the air with any desired weight, the magnitude of the buoyancy (buoyancy = lifting weight) corresponding to the magnitude of the weight of the electric energy transport device is increased. As it is necessary,

To create the magnitude of such buoyancy, the weight value corresponding to the desired weight of the electric energy transport device to be lifted over the earth as described above in the above ①, the electrical energy in the mass value of air per volume of ambient air The negative pressure or vacuum is applied to the inner space of the electric energy transport device so that the difference value is the desired weight to be lifted into the air of the electric energy transport device, minus the mass value per space volume inside the transport device. The density of air is decreased in a way to reduce the amount of air molecules, so that the difference between the reduced density of the entire space having a constant volume and the density of ambient air is generated by the electric energy transport. Artificially make the difference in density to be the total weight of the device How to give.

For example, such a method will be described in more detail.

As described above in Example 10, when lifting an electric energy transportation device having a weight of 150 kg over the earth using only the buoyancy of helium gas,

In order to obtain the amount of buoyancy required to lift 150 kg over the earth, the density of helium instead of helium in the space made the volume size value 120 (m 3) of the space to be provided with helium gas inside the electric energy transport device. By applying a negative pressure or vacuum corresponding to the amount of molecules of air out of the space, the inside of the space to maintain the air density as much as the helium gas density.

That is, as described above in the embodiment of the above ①

In the formula of mass (kg) = density (kg / m 3) x volume (m 3),

Based on an enclosed space with a volume of 1 m 3, air density = 1.43 (kg / m 3) and helium density = 0.18 (kg / m 3),

The density of the space is reduced by applying a negative pressure or vacuum to reduce the amount of air molecules in the space so that the density of the space inside the electric energy transport device is the same as that of the helium gas. By adjusting the density of the gas to 0.18 (kg / m 3) (0 ° C., the air density inside the reference space when the atmospheric pressure outside the reference space is 1 atm), this object can be achieved.

Arithmetic again,

First, when the buoyancy reference value of the reference space is calculated on the basis of a closed space having a volume of 1 m 3 (having a volume of 1m in width, 1m in height and 1m in height), the buoyancy reference value of the reference space (difference value of density) ) = Air density-the density of the reference space = 1.43 (kg / ㎥)-0.18 (kg / ㎥) = 1.25 (kg / ㎥).

That is, the buoyancy reference value (difference value of density) 1.25 (kg / m 3) of the reference space has a volume (volume) of 1 m in width, 1 m in length, and 1 m in height,

In other words, an enclosed space with a volume of 1 ㎥ means that it has 1.25 kg buoyancy in air (at 0 ° C and 1 atmosphere), and this buoyancy is a material (buoyant material, in this example) It is like saying that the electric energy transportation device having the space is lifted by the force of nature (buoyancy) in the air (over the earth).

Next, to generate the buoyancy necessary to lift the electric energy transport device weighing 150kg over the earth, based on the time when the density of the volume of 1㎥, which is the calculated reference space, is 0.18 (kg / ㎥), the electric energy transport This is done by calculating the volume size of the space to be provided inside the device.

To lift the electric energy transportation device having a total weight of 150 kg into the air, a buoyancy of 150 kg or more is required.

1.25kg buoyancy is generated when the reference space has a density of 0.18 (kg / ㎥) at a volume of 1㎥,

To have a buoyancy of 150 kg, 150 kg ÷ 1.25 kg = 120 times,

After making a space having a constant volume inside the electric energy transport apparatus, the size is made to have a volume of 120㎥, which is 120 times the 1㎥ of the reference volume,

In this way, the air density is dropped in a manner of reducing the amount of air molecules in the space by applying negative pressure or vacuum to the entire space having a volume of 120m 3, and the density of the entire space is 0.18 (kg). / ㎥), the space thus increased to have a volume of 120㎥ has a buoyancy of 150㎏.

At this time, the method of applying the negative pressure or vacuum, using a facility or device (for example, a vacuum pump) for forming a negative pressure or a vacuum in the space having the volume calculated above, The internal air is discharged out of the space and the degree is adjusted to the desired negative pressure (or vacuum).

In conclusion, the value of 120 times the reference space is, by applying a negative pressure or vacuum to the space inside the electric energy transport device to obtain the amount of buoyancy necessary to lift the 150kg weight of the electric energy transport device over the earth. The volume size of the space according to the air density of the entire space is 0.18 (kg / ㎥) is 120 (㎥), and the negative pressure or vacuum is formed to adjust the internal air density to 0.18 (kg / ㎥) 120 After making the electric energy transportation device to place a space having a volume of ㎥ or more at the center of gravity of the inside, and then float it in the air, the electric energy transportation device having a weight of 150 kg, even if there is no separate energy consumption Only buoyancy (artificial buoyancy), which is the force of nature, rises above the earth.

③ In the first method, a method of installing a buoyancy device made to have a buoyancy of at least one of natural buoyancy or artificial buoyancy in the electric energy transport device,

Apart from the electric energy transportation device, to make an object having a certain volume of closed (space desired), to have a natural buoyancy in the same manner as the above ①, or to have an artificial buoyancy in the same manner as the ② The method of making a buoyancy in any one or more of the methods, such as to provide such an object in a space where the center of gravity of the inside of the electric energy transport device can be located in the center.

The method of forming buoyancy in the buoyancy device and the detailed method of increasing the magnitude of buoyancy are the same as the natural buoyancy forming method of the above ① and artificial buoyancy forming method of ②, and thus the detailed description thereof will be omitted.

<Example 11-2>

When the buoyancy device made to have one or more buoyancy of the natural buoyancy or artificial buoyancy of the second method in a separate additional configuration to the electric energy transport device will be described in more detail,

Apart from the electric energy transportation device, to make an object having a certain volume of closed (space desired), to have a natural buoyancy in the same manner as the above ①, or to have an artificial buoyancy in the same manner as the ② Of the making, to make the buoyancy in any one or more ways, such an object is provided in a separate additional configuration to the outside of the electric energy transport device, but the center of gravity is provided to be positioned in the center.

  As described above, the buoyancy device additionally provided to the electric energy transport device is used to further increase the buoyancy of the electric energy transport device, to distribute the buoyancy, or to adjust the buoyancy.

For example, such a method will be described in more detail.

As described above in the embodiment of the first method, when attempting to lift the electric energy transport device having a weight of 150kg over the earth using only buoyancy,

If the separate buoyancy device is made into a balloon, and the inner space volume of the balloon is 40 m 3, and the helium gas is filled therein (at the same pressure as the surrounding air pressure), the balloon has a buoyancy of about 50 kg. Follow the first method).

When the balloon having 50kg buoyancy is suspended by placing the center of gravity on the electric energy transport device, the total buoyancy of the electric energy transport device is added to 150kg of the main body by adding 50kg of buoyancy device. When the buoyancy becomes 200 kg, and the electric energy transport device floats in the air, the buoyancy force 50 kg of the buoyancy device is floated in the air as fast as added.

That is, if the balloon as a separate buoyancy device is utilized as described above, the buoyancy is further increased as a result.

And when the air is released to the proper position for the photovoltaic power generation to remove the helium gas of the balloon, the separate buoyancy device (for example, the rope tied by the remote control device to get off the balloon from the electric energy transport device) The electric energy transport device is stopped at a proper position in the air by losing 50 kg of buoyancy (stopping at the point where the air density at the air stop point and the total density of the electric energy transport device are balanced).

In other words, if the balloon is used as a separate buoyancy device as described above to adjust the buoyancy.

In addition, in the above example, the method for dispersing the necessary buoyancy of the electric energy transport apparatus, taking other conditions,

Assuming that the weight of the electric energy transport device to be lifted in the air is 150 kg, but the volume of the main body of the electric energy transport device should be 40 m 3, that is, one third smaller than the above example.

In the electric energy transport device having a weight of 150 kg, two helium gas balloons each filled with helium gas in a volume of 40m 3 (at 0 ° C. and 1 atm) are positioned at the center of gravity of the electric energy transport device. When suspended, the electric energy transport device main body has only 50 kg buoyancy, but two additional helium gas balloons additionally add 50 kg buoyancy per unit, the electric energy transport device actually Since the total buoyancy is 150 kg again, it is possible to lift the main body of the electric energy transport device having a weight of 150 kg without any problem to the earth as desired.

That is, if the balloon as a separate buoyancy device is utilized as described above, the buoyancy is distributed as a result.

<Example 11-3>

The method of adjusting the magnitude of one or more buoyancy among the natural buoyancy, artificial buoyancy, or buoyancy of the buoyancy device in the first and second methods of the third method,

When the natural energy buoyancy is provided in the electric energy transport device or a separate buoyancy device, any one or more of the pressure and volume of the buoyancy material used at this time is provided to be adjusted, and the pressure and volume of the buoyancy material provided as described above A first method of increasing, decreasing or dispersing buoyancy of the electric energy transport device or buoyancy device by adjusting one or more of the above,

When the artificial energy buoyancy is provided to the electric energy transportation device or a separate buoyancy device, one or more of the pressure used to apply the negative pressure or vacuum and the volume of the space to apply the negative pressure and vacuum can be adjusted. Equipped with the negative pressure of the space to apply the negative pressure and vacuum as described above, and by adjusting any one or more of the volume of the space, to increase the buoyancy of the electric energy transport device or buoyancy device, Of the second method of causing the reduction or distribution function to be performed,

It is a method of adjusting the magnitude of the buoyancy in any one or more ways.

In more detail,

At constant temperatures, the volume of gas is inversely proportional to the pressure (Boyle's law).

Therefore, in adjusting the buoyancy, by adjusting the pressure inside the space that forms the buoyancy or the volume of the space, the amount of buoyancy corresponding thereto can be adjusted.

<Example 11-3-1>

In more detail with respect to the first method,

When the buoyancy material is provided in the electric energy transport device or a separate buoyancy device in order to form a natural buoyancy, in the first and second methods of <Example 11>, buoyancy materials (helium gas, hydrogen gas, etc.) If the injected pressure is injected equal to the surrounding air pressure,

In the third method of <Example 11>, the provided (injected) pressure is injected higher than the ambient air pressure,

Alternatively, the volume for injecting the buoyancy material is also made larger (more than the volume value calculated by the calculation method described in the above <Example 11-1> and <Example 11-2>), and any one of the After having prepared by the above method,

It is a method of adjusting the magnitude of the buoyancy of the electric energy transport device or a separate buoyancy device by adjusting any one or more of the pressure or volume of the buoyancy material provided in a state of increasing the pressure or increase the volume as described above.

<Example 11-3-1-1>

In order to explain such a method in more detail with an embodiment,

First, the method of adjusting the magnitude of buoyancy by increasing the pressure of the buoyancy material in detail,

In the embodiment of <Example 11-1>, when you want to lift the electric energy transport device having a weight of 150kg over the earth using only buoyancy,

The buoyancy is increased by installing a space having a volume of 120 m 3 or more inside the electric energy transport device and injecting helium gas into the space (where the pressure in which helium gas is injected is 1 atmosphere equal to the ambient air pressure). After making the electric energy transport device to float in the air, the electric energy transport device having a weight of 150kg, floats over the earth with only buoyancy (natural buoyancy) which is the force of nature even without any energy consumption The thing is as above-mentioned.

However, in the embodiment of <Example 11-1>, the injected pressure in injecting helium gas, which is a buoyancy material, into a space having a volume of 120 m 3 is the same pressure as the ambient air pressure (atmospheric pressure). It is a premise.

However, in this method, the pressure inside the space in which the buoyancy material (helium gas) is injected into the space is higher than the surrounding air pressure (higher than the atmospheric pressure), but the pressure increases in the space filled with the buoyancy material. Since the buoyancy is reduced by increasing the density in proportion to the pressure, the volume of the space in which the buoyancy material is injected is increased to compensate for this, and thus the buoyancy material is provided in the larger space.

That is, as compared with the method in the embodiment of <Example 11-1>,

The method of the embodiment of the <Example 11-1>, the volume of the inner space of the electric energy transport device or a separate buoyancy device provided in order to lift the electric energy transport device having a weight of 150kg over the earth using only the buoyancy If it is 120㎥ and it is filled with buoyant material (helium gas), and the pressure was filled with the same atmospheric pressure as the surrounding air pressure,

In this method, the volume of the space is increased to have a volume larger than 120 m 3, and the pressure of the space is maintained higher than the ambient air pressure (atmospheric pressure) by raising the pressure of the buoyant material (helium gas) injected into the space (molecular weight of buoyant material) To make more than atmospheric pressure), the buoyancy material (helium gas) density of the space is to be higher than 0.18 (kg / ㎥), but the overall buoyancy is to be 150kg or more.

In this manner, the volume of the space filled with the buoyancy material inside the electric energy transport apparatus is larger than 120 m 3, as compared with the method of the embodiment of <Example 11-1>. The buoyant pressure is higher than the atmospheric pressure of the surrounding air, the total buoyancy is more than 150kg,

Floating buoyant material in the space that floats above the earth has the potential buoyancy, which makes it possible to further increase the buoyancy, buoyancy that can adjust buoyancy ascending, staying or descending over the earth. It will have the capacity of (the capacity of the number of molecules of buoyant material to discharge the buoyant material out of the space).

Arithmetic again,

Air density = 1.43 (kg / m 3) and helium density = 0.18 (kg / m 3),

Mass (kg) = density (kg / m 3) x volume (m 3), density = mass ÷ volume,

The Boyle law pressure and volume relationship is given by the formula P = K × 1 / V (P is pressure, K is proportional constant, V is volume).

When the volume of helium gas is 1 m 3, the weight (mass) of 0.18 kg is doubled, and when the volume is doubled, the density (kg / m 3) = mass ÷ volume = 0.18 kg ÷ 2 m 3 = 0.09 kg / m 3, You can see that the density is inversely proportional to the volume,

In addition, by filling the helium gas with a pressure of 1 atm (atmospheric pressure) in a volume of 1 ㎥ space, the pressure is doubled to 2 atm where the space pressure was maintained at 1 atm, so that the proportional constant K = P ÷ V , K = 2P ÷ 1 / 2V, so that the volume becomes smaller in inverse proportion to the pressure,

Density becomes inversely proportional to volume, volume becomes inversely proportional to pressure, resulting in density = 1 / volume, volume = 1 / pressure, density = 1 ÷ 1 / pressure = pressure, and density is proportional to pressure It can be seen that the increase or decrease.

Thus, to arithmetically prove the method,

Since the inner space of the electric energy transportation device having a total weight of 150 kg is 120 m 3 and helium gas is filled with 1 atm, the buoyancy is 150 kg,

For example, in the present method, when the volume of the space is doubled to make 240 m 3 (in this case, helium gas is additionally injected such that the internal pressure is 1 atm). Formula, buoyancy reference value (difference value of density) = air density-density of reference space = 1.43 (kg / ㎥)-0.18kg / ㎥ = 1.25 (kg / ㎥) Multiplying by the increased volume, the total buoyancy = 1.25 (kg / ㎥) × 240㎥ = 300kg will be a double buoyancy state.

In this state, if the pressure inside the doubled space is raised to 4.47 times with 4.47 atmospheres, the density is proportional to the pressure in the above formula, and the helium gas density inside the doubled space is also 4.47 times. Become bigger,

If we calculate this again, the helium density at the corresponding 4.47 barometric pressure = 0.18 (kg / ㎥) × 4.47 = 0.80 (kg / ㎥),

Formula, buoyancy reference value (difference value of density) = air density-density of reference space = 1.43 (kg / m 3)-0.80 (kg / m 3) as described in Example 11-1 above. 0.63 (kg / m 3), multiplied by the increased volume, the total buoyancy = 0.63 (kg / m 3) × 240 m 3 = 151 kg and the buoyancy is almost the same as in Example 11-1 above. It will be 151 kg.

In conclusion, the method in the embodiment of <Example 11-1> includes an electric energy transport device or a buoyancy device internal space separately provided to lift the electric energy transport device having a weight of 150 kg using only the buoyancy over the earth. If the volume of 120 ㎥, filled with buoyant material (helium gas), but the pressure was filled with the same atmospheric pressure as the ambient air pressure,

In this method, the volume of the space is increased to have a volume larger than 120 m 3 (240 m 3), and the buoyant material (helium gas) injected into the space is raised (raised to 4.47 atm), and the pressure in the space is increased. Maintained higher than air pressure (atmospheric pressure) (which makes the number of molecules of buoyancy material 4.47 times more than atmospheric pressure), the density of buoyant material (helium gas) in the space is higher than 0.18 (kg / ㎥), the overall buoyancy is 150kg To be ideal,

     As above, the electric energy transportation device having a large volume and space pressure or a buoyancy device provided separately is floated over the earth, and when the buoyancy becomes weaker as the pressure of the surrounding air decreases toward the earth, the pressure of the space is increased. When the buoyant material that has been stored at elevated pressure is released little by little as the ambient air pressure decreases out of the space, and the internal pressure of the space is reduced, the degree of buoyancy of the electric energy transport device or the buoyancy device separately provided rises to the first earth. The buoyancy can be adjusted to have the same or more buoyancy, so that buoyancy can be adjusted by reducing the internal pressure of the electric energy transport device or a buoyancy device provided separately in the air.

<Example 11-3-1-2>

Referring to the method of adjusting the size of the buoyancy in a way to control the volume of the space in which the buoyancy material is stored,

The buoyancy device, which is provided separately, maintains its volume when the pressure is applied to the balloon, or becomes larger.When the pressure is released, it is equipped with a balloon-like device that completely reduces the volume. When the buoyant material stored under pressure is removed, the volume of the buoyancy device is lost. As a result, the volume of the energy transport device is reduced as much as the buoyancy device is lost. If the volume is reduced in the buoyancy is reduced (density = mass ÷ volume, so as described above, if the volume is reduced in the same state as described above, the density increases and the density increases, the buoyancy decreases).

As a result, the buoyancy can be controlled by adjusting the volume.

<Example 12>

Referring to the step of configuring an electric consumer using (consuming) electricity supplied from the charging station of step (d) of <Example 1>,

In order to achieve the present invention, it is most important to actually use the photovoltaic electricity, which is the future energy described above, for all the embodiments so far as the electric consumer receives the supply from the charging station.

That is, according to all the embodiments, even if the photovoltaic electricity, which is the future energy of the charging station, was transferred (supplied) to the electric consumer so as to be more economical, it is not a condition for using the electric consumer. However, without the use of such good electricity, the present invention cannot be achieved.

Therefore, in order to achieve the present invention, an electrical consumer that can use electricity that has been stored (charged) in the electrical storage device from the charging station in the electrical consumer should be configured.

Currently, the method of using electricity by human beings is mostly using electricity of an existing power system network (run by a country or a power company), and has been stored (charged) in an electric storage device from the charging station according to the present invention. There was no method (technology) for constructing the electrical consumer using electricity directly,

For this reason, various inventions of all the above embodiments are currently in a situation that cannot be put into practical use.

Therefore, in order to be able to put the present invention into practical use, a more detailed description will be given of an optimal method of configuring an electric consumer using (consuming) electricity supplied from the charging station of step (d).

Any area, facility, building, facility, facility, device, customer, or other existing electricity source that uses electricity or that requires new use of electricity, or any electricity consumer that uses electricity or requires new use; In one or more electrical consumers,

The electrical storage device that stores (charges) or maintains (stores) the electricity produced (generated) or transmitted from the charging station by using the wireless transfer method based on the wireless storage means of the electrical storage device. Through the transfer to the electricity supplied from the charging station to the electrical consumer, the method of replacing or converting the electricity of the existing power system network should be used.

In addition, the electric power supplied from the charging station to the electric consumer, a method that is preferentially applicable as a method of using or replacing the electricity of the existing power system network in place of,

The direct current (DC) electricity output (discharged) from the charged electrical storage device transferred from the charging station is converted directly into alternating current (AC) electricity (using a power converter or an inverter, etc.) at the electrical consumer, and the electrical This is how the consumer uses the alternating current (AC) electricity.

Because almost all of the electricity consumers in the world currently use AC electricity, which is the electricity of the existing power system network, all the various electric loads (electric products) that all current electricity consumers use are all. These are loads that operate only on alternating current (AC) electricity.

Therefore, only electricity that is supplied from the charging station of step (d) must be matched with the existing electric loads, so that all the electric users (consumers) of the electric consumer can use the existing alternating current (AC) electric load,

A method of configuring an electric consumer firstly, converts direct current (DC) electricity output (discharged) from a charged electric storage device transferred from the charging station, directly to the alternating current (AC) at the electric consumer (power conversion device). Or an inverter or the like) to use the alternating current (AC) electricity at the electrical consumer.

However, the present invention is basically a method of supplying electricity from the electricity producer (charging station) to the consumer (electric consumer), rather than the existing power transmission method (wired transfer method) through the power system to store the electricity produced in the electrical storage device Since it is a method of charging and transferring (wireless transfer method), all the electricity stored or output in the electric storage device must be a direct current (DC) electricity (all the electric storage devices are operated by a battery. Since the basic principle of storing (charging) or outputting (discharging) electricity is a technology in which a current (electron) flows to one side only by the reaction of chemical substances (lithium, cadmium, etc.), all of them are direct current (DC; Direct). Current)), all the electricity stored or output in the electrical storage device is a battery electricity.

Therefore, if the direct current (DC) electricity is used instead of direct conversion to AC (AC) electricity, expensive equipment that needs to convert and boost the electricity, such as power converters or inverters in the middle must be added. As the incident cost increases, additional power loss occurs during the conversion process, and as a result, the power generation cost of the electricity produced (generated) by the present invention is increased, resulting in uneconomical electricity (loss of competitiveness).

On the other hand, the alternating current (AC) electricity converted to alternating current (AC) as described above is harmful to the human body because the electromagnetic waves come out of the use of residential life in each household (such as floor heating) gives a lot of rejection.

Electromagnetic waves harmful to the human body are generated only by induction electricity, such as alternating current (AC) electricity. All those that use alternating current (AC) electric low frequency (ELF) such as transmission and distribution lines and home appliances are all harmful electromagnetic waves. These harmful electromagnetic waves are classified by the UN's International Cancer Research Organization (IARC) in 1999 and classified as a carcinogenic factor 2 class.

Therefore, a method of replacing electricity of an existing power system network with electricity supplied from a charging station to an electrical consumer, in the medium to long term, direct current (DC) electricity output (discharged) from a charged electric storage device transferred from the charging station. It is to use a method of directly using direct current (DC) electricity without converting into alternating current (AC) electricity at the electrical consumer.

This makes it possible for the electrical consumers (consumers) of the electrical consumer to use cheaper and more economical electricity, and to use electricity that is not harmful to the human body, thereby ultimately enabling the practical achievement of the present invention.

In addition, a method of directly using direct current (DC) electricity without converting the direct current (DC) electricity output (discharged) from the charged electrical storage device transferred from the charging station into alternating current (AC) electricity at the electrical consumer. ,

There is only a method of using the electric load (s) used in the electric consumer as an electric load directly operated by direct current (DC) electricity output (discharged) from a charged electric storage device transferred from the charging station.

However, more than 50% of the energy used by humanity is consumed to get heat.

And to get heat with electricity (to generate heat), heating wire must be required, and the electric heating wire technology developed by mankind until now is direct current (DC) electricity, which is needed for the electric consumer (e.g. residential floor). For heating) It is not possible to generate a large amount of heat generation operation (operation in which electric heating wire consumes electricity to generate heat) (the details thereof will be described later in <Example 13>),

Therefore, to make an electric load that is directly operated by direct current (DC) electricity to ultimately achieve the present invention,

The use of all or part of the battery-operated prefabricated heating wire developed by the present invention to various electric loads (heating electric loads) that generate heat must produce an electric load that generates one or more heats (heating), It is possible to substantially configure an electrical consumer that can be directly used as direct current (DC) electricity output (discharged) in the charged electrical storage device transferred from the charging station (from the charging station at the electrical consumer, stored in the electrical storage device) Battery electricity, which is a direct current (DC) electricity, can be used directly),

Through this, the present invention can ultimately achieve practical achievement.

In conclusion, the above is summarized above,

The method of configuring an electric consumer using (consumption) of electricity supplied from the charging station of step (d) of (Example 1),

Any area, facility, building, facility, facility, device, customer, or other existing electricity source that uses electricity or that requires new use of electricity, or any electricity consumer that uses electricity or requires new use; In one or more electrical consumers,

The electrical storage device that stores (charges) or maintains (stores) the electricity produced (generated) or transmitted from the charging station by using the wireless transfer method based on the wireless storage means of the electrical storage device. Through the transfer to the electric power supplied from the charging station to the electrical consumer, there should be a method of replacing the electricity of the existing power system network.

And the electric power supplied from the charging station to the electric consumer, the method of using to replace the electricity of the existing power system network,

The direct current (DC) electricity output (discharged) from the charged electric storage device transferred from the charging station is converted into direct current (AC) electricity (using a power conversion device or an inverter, etc.) at the electric consumer, This is how the consumer uses the alternating current (AC) electricity.

In addition, the electric power supplied from the charging station to the electric consumer, a method of using the electricity of the existing power system network to replace,

It is a method of directly using direct current (DC) electricity itself without converting the direct current (DC) electricity output (discharged) from the charged electrical storage device transferred from the charging station into alternating current (AC) electricity at the electrical consumer. ,

The method uses the electric load (s) used in the electric consumer as an electric load operated directly by direct current (DC) electricity itself which is output (discharged) in the charged electric storage device transferred from the charging station.

And an electric load directly operated by direct current (DC) electricity itself is output (discharged) in the charged electrical storage device transferred from the charging station,

In the heat generating electric load, any one or more of the heat generating electric loads are used, in which all or part of the battery-operated prefabricated heating wire is used.

Example 13

The battery electric operation assembled heating wire in the above-described <Example 12> will be described.

Since the technology of the present invention supplies electricity from the charging station to the electric consumer, the electric storage device stores electricity (charging) and transfers the electricity to the electric consumer.

As described in the <Example 12>, a technology for directly using a direct current (DC) 24 V or less of direct current (DC) electricity output from the electrical storage device that has been transferred to the electrical consumer, the safe low voltage (DC) of 24,

By enabling the electric consumers (consumers) of the electric consumer to use cheaper and more economical electricity, and to the use of electricity that is not harmful to the human body, it ultimately enables the practical achievement of the present invention.

In order to directly enable the direct current (DC) electricity output from such an electrical storage device to use a safe direct current (DC) 24V or less, the battery electric operation prefabricated heating wire must be developed. .

However, since humanity has not yet used such technology, it has not made a big conversion to the solar energy of the future energy by escaping the use of fossil fuel or nuclear power that has many problems.

The main reason is that there has not yet been developed a battery-operated prefabricated heating wire.

In more detail, more than 50% of the energy used by humankind is consumed to get heat.

However, fossil fuel, which is a conventional heat-generating fuel, is depleted, and fossil fuel combustion not only causes global environmental problems such as fine dust, but also consumes too much energy because it consumes a lot of energy to obtain heat.

Therefore, in the future, humankind will have no choice but to change the direction of energy policy by using green energy (solar, wind power, electricity, etc.) as part of the solution of many energy problems. Green energy electricity produced (generated) is stored and used in battery facilities (various batteries, power storage facilities, ESS, etc.).

On the other hand, the current battery technology of humanity is developing differently every day, the battery car is surpassing the gasoline engine car, and the battery-powered electric gear is driven.

Therefore, by producing electricity from green energy, which is the solution to human energy problems in the future, this electricity is stored in batteries that are accelerating the speed of generation, and utilizing these batteries requires heat that consumes a lot of energy (eg, heating or If a technology is developed that can directly generate heat from battery electricity at all sites, human beings are currently using heat from fossil fuels, thermal power, or nuclear power plants. All sectors will be shifted to getting heat from these batteries, which will solve global warming, severe pollution, alternative energy from fossil fuel depletion, and nuclear power.

In addition, the method of obtaining heat from the battery becomes wireless, which eliminates the need for transmission lines and auxiliary power facilities, which are currently incurring enormous costs and many side effects (electric shock, electromagnetic wave hazards, etc.). It's infinitely unimaginable.

However, to date, there is no place where such a good battery is used to get heat, heat or make hot water in a site that requires a lot of heat, which consumes a lot of energy.

The reason is that the output electricity (hereinafter battery electricity) of the battery, the electrical storage device and the energy storage device (ESS) are all direct current (DC) low voltage electricity (especially when it is 24V or less). (DC) Low-voltage electricity (especially those below 24V) generates no direct energy-consuming heat (e.g., the heat needed to heat or make hot water, etc.).

In particular, a medium called a heating wire (heating element) is necessary in order to develop a technology for generating direct energy-consuming heat by using a safe low-voltage direct current (DC) electricity of 24 V or less. The medium must be a heating element (battery element) that is capable of fully performing the desired heat-generating function that consumes energy using battery electricity or battery electricity, especially safe low voltage direct current (DC) electricity below 24V.

However, all the heating wires (heating elements) developed by humans to date do not overcome the following problems, and until now, humans have not developed or put into practical use a technology for producing desired heat with battery electricity as described above. There was this.

First, it is possible to create a customized electric heating element (heating element) having a large number of low-resistance values, so that among a variety of battery electricity or battery electricity, in particular, a safe low-voltage direct current (DC) electricity of 24V or less can generate a large number of desired heat generation operations. There is no manufacturing technology and no such heating wire.

For example, in the field where energy consumption is required, install battery electricity storage facilities (various batteries, power storage facilities, ESS, etc.) and directly use the electricity output from this to obtain the heat that consumes much energy. In order to be able to use the heat freely (e.g., to heat or make hot water) as desired, all of the electricity output from the battery electrical storage facilities, as described above, is a variety of low voltage (or low voltage) battery electricity. , Due to the large variety of site conditions and forms that require heat that consumes a lot of energy,

In order to obtain the various heat generation and heat generation desired in various sites that require such a large amount of energy consuming heat, the safe low voltage direct current (DC) electricity of 24V or less, especially among various battery batteries or battery electricity, can be used to generate numerous desired specifications. There is a need for a customized electric heating element (heating element) having a large number of low resistance values and a manufacturing technology capable of operating.

The electric heating wire (heating element) developed by mankind and its manufacturing technology are all standardized to a certain voltage (110V / 220V / 380V, etc.) that uses electricity of AC 110V or higher, which is a national- or private-driven power grid system electricity. In addition, there are a large number of low-resistance customized electric heating wires that can be used to generate numerous desired specifications of heat generation, especially among various battery batteries or battery electricity, especially safe low voltage direct current (DC) electricity of 24V or less. (Heating element) and its manufacturing technology do not exist.

Secondly, the above-mentioned heating wires are developed or put into practical use, and the spread of the heat generation technology is more rapid. It is made of customized electric heating elements (heating elements) with many low resistance values, which can use a variety of battery electricity or battery electricity, especially safe low voltage direct current (DC) electricity of 24V or less, which can generate heat of many desired specifications. At the same time, it must be able to express a number of additional specific functions at the same time, it is possible to achieve the heating operation of a number of desired specifications in accordance with various conditions of the site, and the hot wire manufacturing technology that can express these specific functions at the same time There is no such heating wire.

Here are some important examples of many of these specific features:

First, among many various battery electricity or battery electricity, it is possible to use the safe low-voltage direct current (DC) electricity of 24V or less, and to generate heat of many desired specifications, and to realize actual radiant heat heating by far infrared rays. Should be additionally provided.

In the future, humanity should replace the heating method that generates and transmits energy consuming heat from the existing inefficient heating method, which is the conductive heat or convective heating method, and replace it with the radiant heat heating method by far infrared rays. The heating method is a heating method in which heat is directly transferred, and has an energy-efficiency characteristic that is excellent in heating effect compared to energy consumption.

Radiation heating by far infrared rays does not transfer heat through convection or blowing, and is a heating method that directly transfers heat according to the principle that the sun heats the earth. It can reduce energy by 30-50% and reduce noise, smell, It has the advantage of not generating dust (see daily economic glossary).

However, in order to actually implement such radiation heating by far-infrared radiation to reduce energy by 30 to 50% at the site where heating is needed,

The electric heating wire (heating element) used here must have a geometric structure in which electric dipole radiation, which emits far-infrared radiation from the heating wire itself, can be radiated much better. It must be made of a material that is emitted in large quantities (especially a material that has a good dipole moment when direct current (DC) safe low voltage electricity flows).

However, the electric heating wire (heating element) developed by mankind and its manufacturing technology, among the above-mentioned battery electricity or battery electricity, in particular, the safe low-voltage direct current (DC) electricity of 24V or less can be used to generate a large number of heat generation operations. At the same time, it was not possible to express the function to realize the actual radiant heat heating by far infrared rays.

Second, among the battery electricity or battery electricity, it is possible to use the safe low voltage direct current (DC) electricity of 24V or less, and to generate heat of many desired specifications, and to realize instantaneous ultra high heat generation, ultra fast heat generation, and high efficiency heat generation. It should have additional features.

For example, in the future, humans will convert the energy consumed for heating, which is the most energy-consuming among those that require a lot of energy, away from the current fossil fuel combustion method to use electricity stored in batteries. In the field (consumer) where energy is needed to obtain such heating heat, the battery electric heating facilities (heating devices or heating devices, etc.) are installed directly, and among the battery electric or battery electric, the safe low voltage direct current (DC) electricity of 24 V or less, If you can get a variety of heating heat at will, it is easy to solve the pollution problem, fine dust emission problem, global warming caused by deep carbon emission, which human beings currently face.

By the way, such heating electric heating wire (heating element) must be instantaneous ultra-high temperature, ultra-high heat generation, it should be a more efficient heat generation.

Because the amount of energy emitted instantly when the heating heat is obtained by burning fossil fuel is so great that it generates instantaneous high temperature and ultra-high heat, and its function is very advantageous to use for the purpose of obtaining heating heat. Rather, it is more advantageous than the pollution carbon fine dust emission problem, so that the use, scope and usage of the fossil fuel is infinitely widespread,

The battery-electric heating facility that generates energy-consuming heat by directly using safe low-voltage direct current (DC) electricity of 24 V or less, particularly among battery electricity or battery electricity, in the field where humans need energy to obtain heating heat in the future. To replace fossil fuel combustion in a way that allows you to get the heating heat you want,

Electric heating wire (heating element) required for this must be instantaneous high temperature, ultra-high heat generation, because more efficient heat generation will be more competitive than fossil fuel consumption.

However, the electric heating wire (heating element) developed by mankind and its manufacturing technology, it is possible to directly use the safe low-voltage direct current (DC) electricity of 24V or less, especially among battery electricity or battery electricity, to generate heat generation of many desired specifications. At the same time, it was not possible to express the function of realizing the instantaneous ultra high temperature heating, ultra high speed heating, high efficiency heating.

Third, among the battery electric or battery electric, in particular, the safe low-voltage direct current (DC) electricity of 24V or less can be directly used to generate a large number of desired heat generation operations, and the heating wire material itself must be equipped with a function of maintaining a constant temperature. .

Electric heating wire (heating element) is a very important technical difference whether or not the ability to maintain a constant temperature in the material itself while the heating operation is started to supply heat.

If the electric heating wire (heating element) itself does not have a function of maintaining a constant temperature, if there is a danger of overheating (if the thermostat breaks down and electricity is continuously supplied, the heating wire is folded or covered with an insulating material. Case, etc.), because the constant temperature rise leads to a fire and ultimately the safety of the heating element (heating wire) is not guaranteed.

The battery-electric heating facility that generates energy-consuming heat by directly using safe low-voltage direct current (DC) electricity of 24 V or less, particularly among battery electricity or battery electricity, in the field where humans need energy to obtain heating heat in the future. In order to replace the fossil fuel combustion method in such a way that the desired heating heat can be obtained by heating devices (heating devices or heating devices), the safety of the heating wire required for this must be one of the most important functions. Among the battery electric or battery electric, in particular, the safe low-voltage direct current (DC) electricity of 24V or less can be directly used to generate heat of many desired specifications, and the heating wire material itself must be equipped with the function of maintaining the temperature.

However, the electric heating wire (heating element) developed by mankind and its manufacturing technology, it is possible to directly use the safe low-voltage direct current (DC) electricity of 24V or less, especially among battery electricity or battery electricity, to generate heat generation of many desired specifications. At the same time, the hot wire material itself could not express the function of maintaining the temperature.

Fourth, among the battery electric or battery electric, in particular, the safe low-voltage direct current (DC) electricity of 24V or less can be directly used to generate a large number of desired heat generation operations, and the hot wire material itself has excellent tensile strength, durability, and is easily disconnected. It should be equipped with the function that there is little change of resistance value.

When an electric heating wire (heating element) is provided in a battery heating device (e.g. battery heating device) to obtain heat that consumes a large amount of energy, a tensile force is applied to the heating wire for some reason in the course of the user's use. Even when a force is applied, or a force that causes the heating wire to be folded, or an impact is applied, there is no change in resistance value or disconnection, and the presence or absence of such a function is a very important technical difference.

Because the electric heating wire (heating element) is wrinkled or folded or the tensile force is applied to the material itself, if the internal heating wire is disconnected or the resistance value changes in the heating material itself, due to short or local overheating With some battery heating devices (e.g., battery heating, etc.) to obtain the desired energy consuming heat made of hot wires that can lead to fire accidents and reduce the safety and increase the probability of failure, the future humanity The battery electric heating equipment (heating apparatus or heating) that generates energy consuming heat by directly using safety low voltage direct current (DC) electricity of 24 V or less, especially among battery electric or battery electric, in the field (water customer) where energy is needed to obtain. Device to get the heating heat you want. As because they can not continue to lead the new blue ocean market going to replace fossil fuel combustion.

Therefore, in the future, human beings will install battery electric facilities directly at many sites where energy is needed to obtain energy consuming heat, and directly use the electricity output from them. In order to switch, the safety of the heating wire required here must also be one of the most important functions. The heating wire must be used directly in the battery or battery electricity, especially the safe low voltage direct current (DC) electricity of 24V or less. At the same time, the heating wire material itself should be equipped with excellent tensile strength and durability, easy disconnection or little change in resistance value.

However, the electric heating wire (heating element) developed by mankind and its manufacturing technology, it is possible to directly use the safe low-voltage direct current (DC) electricity of 24V or less, especially among battery electricity or battery electricity, to generate heat generation of many desired specifications. At the same time, the hot wire material itself was not able to exhibit a function of excellent tensile strength and durability, easily disconnection or little change in resistance value.

Fifth, among the battery electricity or battery electricity, it is possible to directly use the safe low voltage direct current (DC) electricity of 24V or less, and to generate heat of many desired specifications, and to add the function to suppress the oxidation reaction by the heating material itself. Should be equipped with.

When an electric heating element (heating element) is provided in a battery heating device to obtain heat that consumes a lot of energy, it should be used without failure for a long time in the process of use by a user.

By the way, heating wire is usually heated and cooled down, it causes oxidation reaction and the heating wire material itself hardens as the use period elapses, and when this hardening action is intensified (more long-term use), the heating wire material itself hardens. The degree is deepened and easily broken, or broken and broken, it causes problems such as short circuit and fire.

With battery heating devices (e.g., battery heating, etc.) to obtain the desired heat made of heating wires that reduce this safety and increase the probability of recurrence of malfunctions, the future humanity needs energy to obtain heating heat. Among battery electricity or battery electricity, the fossil fuel combustion method is used to obtain desired heating heat freely with the battery electric heating equipment which generates heat that consumes energy by using the safe low voltage direct current (DC) electricity of 24V or less. This is because they cannot lead the new blue ocean market that replaces.

Therefore, the battery electric heating that generates energy-consuming heat by directly using safe low-voltage direct current (DC) electricity of 24 V or less, especially among battery electricity or battery electricity, in the field where humans need energy to obtain heating heat in the future. In order to replace fossil fuel combustion in such a way that facilities (heating devices or heating devices) can freely obtain the desired heat of heating, the safety of this oxidation of the heating wire required is one of the important functions. The heating wire required for this must be capable of generating many desired specifications of heat generation with a variety of low voltage (or low voltage) battery electricity, and at the same time, the heating wire material itself must have the function of suppressing oxidation reaction. do.

However, the electric heating wire (heating element) developed by mankind and its manufacturing technology, it is possible to directly use the safe low-voltage direct current (DC) electricity of 24V or less, especially among battery electricity or battery electricity, to generate heat generation of many desired specifications. At the same time, the hot wire material itself could not express a function of inhibiting the oxidation reaction.

Accordingly, in order to completely solve the first and second problems, which are important examples of many specific functions among the second problems, and to achieve the object of the present invention, a battery electric operation assembly heating wire is required.

<Example 13-1>

3 is a flow chart illustrating a method of manufacturing a battery-operated prefabricated heating wire used for heating in the electrical consumer shown in FIG. 2.

As shown in FIG. 3, the method for manufacturing a battery-operated prefabricated heating wire 32 may include: forming a fine wire with a single metal or an alloy metal having different strand numbers, thicknesses, materials, and functions (S30);

These microfine wires are prefabricated and assembled to have at least one of battery electricity or battery electricity, particularly low-resistance value or multi-function required to obtain desired heat by using safe low-voltage direct current (DC) electricity of 24V or less. Creating a bundle through the operation (S32);

The one bundle is configured to include a step (S34) that will soon be a strand of hot wire.

The heating wire thus made is a battery-electric operation prefabricated heating wire 32 used for heating in the electric consumer 30 of the present invention.

 The present invention is basically a method of supplying electricity from the electricity producer (charging station) to the electricity consumer, not the transmission method (wired transfer method) through the existing power system, the electricity produced (generated) is stored in the electrical storage device ( Since it is a method of charging and transferring (wireless transfer method), all electricity stored or output in the electrical storage device must be direct current (DC) electricity, and all the electrical storage devices are operated by batteries. Since the basic principle of storing (charging) or outputting (discharging) is a technology in which current (electron) flows in only one direction due to the reaction of chemicals (lithium, cadmium, etc.), all of them are only direct current (DC) electricity. I can't.

Therefore, since the electricity output from the electrical storage device according to the present invention are all battery electricity, the low resistance value or multi-function is a function of the heating wire that must be provided to generate the desired heat using the battery electricity.

In addition, the battery-operated prefabricated heating wire is a heating wire that can obtain desired heat by using a safe low-voltage direct current (DC) electricity of 24 V or less, particularly among battery electricity or battery electricity. The second problem is particularly effective in solving the first to fifth problems, which are important examples of many specific functions of the second problem.

In addition, human beings, which are necessary for constructing an electric load operated directly by direct current (DC) electricity output (discharged) in the charged electric storage device transferred from the charging station described above in Example 12, have not been developed by humanity so far Nevertheless, it is an important technique for achieving the present invention.

<Example 13-2>

Such a prefabricated heating wire 32 is a direct current (DC) electricity output (discharged) in the charged electrical storage device transferred from the charging station, the direct current (DC) without converting the AC (AC) electricity at the electrical consumer. In order to achieve a method of directly using electricity, the electric load (s) used in the electric consumer are directly operated by direct current (DC) electricity output (discharged) in a charged electric storage device transferred from the charging station. The electric load which is directly operated by direct current (DC) electricity should be used as a heating wire that generates heat by consuming electricity from the electric load that generates heat. In particular, it must be applied to all fields that require heat that consumes a lot of energy, so that the battery electricity can be used to obtain the heat (desired) required by the site. Among them, in particular, in the respective fields below, the object of the present invention may be achieved only by applying prefabricated heating wire to obtain heat with battery electricity.

In detail this,

The desired heat in <Example 13-1> is an electric load operated directly by direct current (DC) electricity output (discharged) in a charged electric storage device transferred from the charging station described in <Example 12>. In the field, heat is consumed in all areas where it is necessary to consume a large amount of energy to obtain the desired heat.

For example, when you want to heat your apartment in winter, you need a huge amount of heat to heat your apartment to a temperature where people can live.

Therefore, in order to obtain a large amount of heat for this purpose, it is necessary to consume a lot of energy to obtain the heat to warm the apartment living space. As in the case of using heat for heating the apartment living space, it is used when the desired apartment living space can obtain the desired heating heating heat only by consuming a lot of energy (fossil fuel or electricity). Saying the column is an example.

Therefore, at least the heat used in each of the following fields is the heat to obtain a desired amount of heat only if you consume a lot of energy.

(1) The heat necessary for the purpose of heating the floor of a building is included in the heat to obtain a desired amount of heat only after consuming much energy.

In order to solve the above-mentioned deepening global warming problem, serious pollution problem, alternative energy problem due to exhaustion of fossil fuel, danger of nuclear power generation, etc., a large amount of energy is generated by battery electric operation in <Example 13-1>. By applying a prefabricated heating wire that emits heat as a heating wire for heating the floor of the building, and directly supplying the battery electric (battery electric described above in Example 13-21) to the heating wire, If you generate enough heat as you want, it will be a great help in solving all the human energy problems.

The method of applying the heating wire of the present invention to the floor heating as above, if the use range is expanded, goes beyond the use only for the building floor heating as described above, in any number of fields where floor heating is needed in all the floor heating If all of the prefabricated heating wires are applied, and all the floor heating is performed by directly supplying the battery electrics (battery electrics described above in Examples 13-21) to the heating wires, the range of use thereof becomes infinitely large. Can be achieved.

② The heat necessary for the space heating application is included in the heat that the desired amount of heat can be obtained only when the large amount of energy is consumed.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for heating various heating apparatuses to be used for heating the building space, and the battery electric (battery electricity to be described later in <Example 13-21>) is applied to the heating wire. ) By directly supplying the desired heat required for heating the building space as much as desired, it is very helpful in solving all the energy problems of the human race,

The method of applying the heating wire of the present invention for heating the space as described above is applied to a variety of heating apparatus as described above, or the field requiring the heating of many different types of various spaces In the space, all the prefabricated heating wire is applied to various space heating, and the battery electric wire (battery electricity to be described in detail in the following <Example 13-21>) is directly supplied to the heating wire to heat all spaces. Is increased to infinity, and the object of the present invention can be achieved.

③ The heat necessary for melting, boiling, or warming water or other liquids or solids is included in the heat to obtain the desired amount of heat only after consuming much energy.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire that heats various water warming devices (mechanisms) to be used for boiling or warming water, and the battery electric By directly supplying the battery electricity to be described in <Example 13-21> and generating the desired amount of heat necessary for various water warming devices (mechanisms) as desired, a great help in solving all the energy problems of mankind. Become,

The method of applying the heating wire of the present invention to the use of heat for boiling or warming the water as described above is to expand the scope of use, appliances for the purpose of boiling or warming various kinds of water in countless fields (B) The prefabricated heating wire may be applied to all kinds of devices, apparatuses, and equipment for melting, boiling, or warming other liquids and solids other than water. By direct supply of the above-described battery electricity) to heat all the boiling or warming purposes, the use range is infinitely large, can achieve the object of the present invention.

(4) The heat required for thawing or snow melting is included in the heat that requires a large amount of energy to obtain the desired amount of heat.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for the purpose of not freezing or thawing a road or a parking lot floor, and the battery electric wire (see Example 13-21). By supplying the battery electricity to be described in detail) directly, the road or parking lot floor surface does not freeze or generate the desired amount of heat required to thaw as much as desired, it is a great help in solving all the energy problems of mankind,

As described above, the method of applying the heating wire of the present invention to freeze or thaw on the road or the parking lot floor surface is to expand the range of use, various roads, bridges, mountain slopes, harbors, airport runways, etc. The prefabricated heating wire is applied to various sea ice and snow melting applications in all places where heat for various sea ice and snow melting applications are required in countless places in numerous fields. By supplying the battery electricity to be described in detail in (directly) to give heat for a variety of sea ice or snow melting use, its use range is increased to infinity, it can achieve the object of the present invention.

(5) The heat necessary for the use for drying is included in the heat to obtain the desired amount of heat only after consuming much energy.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for generating heat of a heating device inside a drying facility of a drying furnace for drying agricultural and marine products, and the battery electric wire (see <Example 13-21). > By supplying the battery electricity (to be described in detail) directly, and generates the desired amount of heat required to dry the agricultural and marine products as desired, it is very helpful in solving the energy problem of the human race,

As described above, the method of applying a heating wire for generating heat necessary for drying the agricultural and marine products can be expanded to a wider range of uses, including various agricultural and marine products, various industrial drying facilities, and many other kinds of various kinds of buildings, various The prefabricated heating wire is applied to all the places where heat is required for drying of the drying equipment, and the battery electric (battery electric to be described later in <Example 13-21>) is directly supplied to the heating wire for heating purposes for various drying purposes. When the necessary heat is given, the range of use thereof becomes infinitely large, and the object of the present invention can be achieved.

(6) The heat required for the use of moving space heating is included in the heat that the desired amount of heat must be consumed only when the large amount of energy is consumed.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for generating heat of various heating devices for heating inside a moving space such as a car, and the battery electric wire (see <Example 13) By directly supplying the battery electricity to be described in detail in (21), and generating enough desired heat as desired amount inside the moving space such as a car, it is very helpful to solve the energy problem of the human race,

As described above, the method of applying a heating wire for generating heat of a heating device inside a moving space inside a vehicle, etc., can be used without increasing the number of vehicles, aircraft (airplanes), ships (ships), etc. The prefabricated heating wire is applied to all the places where the heat inside the various moving spaces of various fields in many fields is needed, and directly supply the battery electricity (battery electricity to be described in <Example 13-21>) directly to the heating wire. When the necessary heat is produced in various moving spaces, the range of use thereof becomes infinitely large, and the object of the present invention can be achieved.

⑦ Agricultural use (crop cultivation) The heat required for the internal heating of the facility house is included in the heat to obtain the desired amount of heat only after consuming much energy.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for generating heat for heating inside a farmhouse (crop cultivation) facility house, and the battery electric wire (see <Example 13-21>). By supplying the battery electricity to be described in detail in (directly), and generate the desired amount of heat required for farming (crop cultivation) inside the house as desired, it is very helpful to solve all the energy problems of the human race,

As described above, the method of applying the heating wire for the heating use in the farming (crop cultivation) facility house can be expanded for its use, for heating and cultivating various kinds of various crops in countless fields in Korea and around the world. All of the prefabricated heating wires are applied to the inside of the house for planting crops, and the battery electricity (battery electricity to be described in detail in <Example 13-21> below) is directly supplied to the heating wires to generate heat required for various crop growing spaces. The range is infinitely large, and the object of the present invention can be achieved.

(8) The heat required for heat tracing and heating jacket applications is included in the heat that requires a large amount of energy to obtain the desired amount of heat.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for heat tracing and heating jackets used in countless industrial sites, and the battery electric wire is described in detail in <Example 13-21>. It is a great help in solving all the energy problems of the human race by supplying the battery electricity directly) and generating the desired amount of heat as desired for the heat tracing and heating jacket applications used in countless industrial sites. The object of the present invention can be achieved.

⑨ Other heat of various uses that consumes a lot of energy to obtain heat in various fields requiring heat is also included in the heat to obtain a desired amount of heat only by consuming much energy.

The prefabricated heating wire in <Example 13-1> is applied as a heating wire for the purpose of obtaining heat in the case of obtaining energy by consuming a large amount of energy in various other applications in addition to the uses described in the above ① to ⑧, By directly supplying the battery electricity (battery electricity to be described later in <Examples 13-21>) to this heating wire, the desired amount of heat required for various applications in various fields where other energy is consumed to obtain heat as desired. When sufficiently generated, it is very helpful to solve all the energy problems of the human race, it is possible to achieve the object of the present invention.

<Example 13-3>

The technique implemented by the battery-electric operation prefabricated heating wire in <Example 13-1>,

① In the above <Example 13-1> required by the present invention, the battery-electric-operated prefabricated heating wire obtains the desired heat by using the battery-electric.

The battery electricity is electricity that is output (discharged) in various electrical storage devices such as a battery or an electrical storage device (an energy storage device (ESS)) (described in detail in Examples 13-21).

In addition, most of these battery electricity are safety low voltage direct current (DC) electricity, and electricity in a range of a specific voltage among voltages of 24 V or less or a voltage of 24 V or less.

Therefore, the battery-operated prefabricated heating wire is a heating wire having a low resistance value required to obtain a desired heat by using a safety low-voltage direct current (DC) electricity of 24 V or less, particularly among battery electric or battery electric.

For example, a battery heating device (heating apparatus) is developed by using the heating wire as a battery (or energy storage device) as a power supply unit, and the heating unit is provided with a prefabricated heating wire according to the present invention. When you want to use in the office,

Since the electricity supplied from such a battery (or energy storage device) is usually a DC voltage of 24V or less, which is a safety voltage, heat is generated at a low voltage of 24V or less and also of DC electricity. If you don't get well, you can't function as a heating device.

In addition, since heating devices (heating devices) usually require a lot of energy consumption, heat generated by a large amount of energy is consumed if the electric heating wire provided in the heating device (heating devices) consumes a lot of battery electricity instantaneously and does not generate a large amount of heat. The object of the present invention as described above in <Example 13-2> for obtaining heat with battery electricity in various necessary fields cannot be achieved.

However, in order to generate as much heat as desired in a heating wire, a large amount of power should be consumed in the heating wire at the moment when it meets a desired heat generation level, which means that even at a very low voltage (for example, a voltage of 24V or less), a large amount of power is consumed. In order to do this, a large amount of current with a very low voltage must flow instantaneously to the heating wire.

That is, the calorific value generated by the heating coil (heating element) is determined by the formula Q = 0.24 XI ² XRXT (where Q is the calorific value of the heating coil, I is the current supplied to the heating coil (heating element), and R is the heating coil (heating element)). ) Is the resistance value, and T is the time of supplying current to the heating wire (heating element).)

Further, since W (power consumption) = V (voltage) XI (current) and V (voltage) = I (current) XR (resistance), the expression W = I ² XR.

It can be seen from the above equation that the heat generated from the heating wire itself is proportional to the power consumption, proportional to the resistance value R and the current supply time T, and proportional to the square of the current amount I.

Therefore, in order to obtain a desired heating value (temperature) in the battery heating device (heating device) to be made in the above example, the heating wire provided in the battery heating device (heating device) must be consumed in proportion to the heating value of the heating wire itself. In order to consume the power, the current must flow through the heating wire.

However, as described above, since the heating wire must operate so that a large amount of current flows at a very low voltage (safety low voltage), the heating wire must be a heating wire having a very low resistance value so that a large amount of heat can be obtained even at a desired low voltage electricity. A large amount of current can flow in the heating wire (heating element).

For example, in the heating wire provided in the battery heating apparatus (heating apparatus) in order to obtain a large amount of heat generated (temperature) desired in the battery heating apparatus (heating apparatus) to be made in the above example, the heating power desired in 500 watts per second must be consumed. Assuming you can get

If you use the heating wire made by the prior art, you can not only use the AC 220V general electricity, so that the resistance value of the heating wire is 96.8 kW, the current amount of 2.2727A per second can flow from the heating wire, 500w of The calorific value can generate heat (W ÷ V = I at W = VXI and thus 500w ÷ 220V = 2.2727A, and R = 220V ÷ 2.2727A = 96.8Ω at V = IXR).

However, since the prefabricated heating wire of the present invention uses direct current (DC) safety low voltage electricity or battery electricity, for example, the same 500w using electricity stored in an energy storage device (ESS) in which safety low voltage electricity of 5 V or less is discharged. If you want to make a battery heating device (heating apparatus) in the above example that can generate heat of

In the prefabricated heating wire according to the present invention provided in the battery heating device (heating apparatus), the same amount as the power consumption of 500w per second should be consumed, and in the prefabricated heating wire according to the present invention, the current amount of 20A per second should be allowed to flow. The heating value can generate heat, and in order to achieve this, the resistance value of the heating wire must be 0.05 kW, which is a very low resistance value compared to the existing heating wire using 220V, so that the heating value of 500 watts per second can be obtained from the heating wire (500 watts). ÷ 5V = 100A, and R = 5V ÷ 100A = 0.05 Hz.).

Therefore, as shown in the above examples and formula calculation, if the prefabricated heating wire according to the present invention can obtain the desired heat by using battery electricity or safety low-voltage direct current (DC) electricity of 24V or less, safety of DC (24V) or less Low voltage direct current (DC) electricity or battery electricity to emit a large amount of heat at the moment, in order to do this must have a very low resistance value, it can be seen that it can cause the heating operation to obtain the desired heat .

(2) In addition, the prefabricated heating wire for battery electric operation required for the present invention shall be made of a heating wire having a low resistance value necessary to obtain desired heat by using the battery electric power of the above ① or the safety low voltage direct current (DC) electricity of 24V or less. At the same time, it is a hot wire that can express one or more additional functions.

For example, assuming that an office is heating in an office using the battery heating device (heating device) in the above example, heating by such a battery heating device (heating device) is completely different from the existing heating method. If there is far-infrared (radiant heat) heating that can be used in the future, it becomes future-oriented heating that uses energy efficiently.

This is because the radiant heat heating method by far infrared rays is a heating method of directly transferring heat, and the heating effect is superior to the energy consumption amount compared with the conventional heating method, which is the conductive heating method or the convection heat heating method, which is superior in energy efficiency.

Radiation heating by far infrared rays does not transfer heat through convection or blowing, and is a heating method that directly transfers heat according to the principle that the sun heats the earth. It can reduce energy by 30-50% and reduce noise, smell, There is an advantage that dust does not occur.

Therefore, in the future, humanity should replace the heating method that generates and transfers energy consuming heat from the existing inefficient conventional heating method, which is conductive heat or convective heating, and replace it with high efficiency and future-oriented radiant heat heating method. .

However, in order to actually implement such radiation heating by far-infrared radiation to reduce energy by 30 to 50% at the site where heating is needed,

In the above example, the electric heating wire (heating element) used in the heating device (heating device) such as the battery heating device (heating device) must have electric dipole radiation (electric dipole radiation) in which far infrared rays are emitted from the heating wire itself. It must have a geometric structure that can radiate much better, and the heating wire must be made of a material that emits a large amount of far-infrared rays (especially a dipole moment is achieved when a direct current (DC) safe low voltage electricity flows). Material).

To this end, the heating wire provided in the battery heating device (heating device) in the above example is provided with a prefabricated heating wire according to the present invention, and the desired heat using the battery electricity according to ① or the safety low voltage direct current (DC) electricity of 24V or less. At the same time, it must be made of a heating wire having a low resistance value necessary to obtain a thermal wire, and at the same time, it must have a geometric structure that can radiate electric dipole radiation which emits far infrared rays from the heating wire itself more well, and a material that emits a large amount of infrared rays. Material)

In the above example, the battery heating device (heating device) generates a desired heat by using battery electricity or safe low voltage direct current (DC) electricity of 24V or less, and at the same time, realizes a high efficiency future-oriented far-infrared (radiation heat) heating ( Heating device).

Therefore, the prefabricated heating wire according to the present invention performs the function of emitting far-infrared radiation which enables the heating of far-infrared (radiation heat) which is a high efficiency and future-oriented heating method in parallel with the expression of the above ①, or prefabricated according to the present invention The heating wire itself can be expressed more effectively in such a way that more specific one or more functions can be realized, such as the expression of the heating wire itself, so that the present invention can approach the multi-purpose more effectively.

③ prefabricated heating wire according to the present invention is flexible.

Battery-operated prefabricated heating wire implemented by the present invention,

In many sites where energy is needed to generate heat in the future, to directly install photovoltaic facilities and electrical storage devices, and to use the electricity output from them directly to obtain the desired heating heat, Since the prefabricated heating wire according to the present invention has flexibility, it is more effective for applicability and custom fabrication because it has to be made in accordance with site conditions and various desired specifications.

Therefore, the prefabricated heating wire according to the present invention becomes a more effective heating wire if it becomes a flexible heating wire in addition to the heating wire performance of any one or more of the above ① or ②.

④ Prefabricated heating wire according to the present invention is as described above in <Example 13-2>.

By applying variously in various fields that require heat that consumes a lot of energy, it is necessary to obtain the heat (desired) that is needed in many various sites by using battery electricity. And because it requires a variety of heating amount (or heating temperature), prefabricated heating wire according to the present invention can be applied in a variety of different fields that need heat in the future in a number of different cases to obtain a variety of desired heat with battery electricity The heating wire having the above-described performance (one or more of any one of ① ~ ③) desired to match all the numbers must be made precisely all one by one, but the prefabricated heating wire of the present invention requires a large amount of heat Practically applicable to a variety of sites, and only then It is possible to achieve the object, which generates substantially the required heat into electricity.

Therefore, the prefabricated heating wire manufactured according to the present invention is a heating wire having any one or more of the above ① ~ ③ as a custom heating wire as desired, as required, but in a number of various cases, each of the precisely customized heating wire If you can make it more effective heating wire.

⑤ Also, the prefabricated heating wire manufactured according to the present invention will be provided in various battery heating devices (heating devices), and will be used in numerous places, numerous customers, and many industrial sites, and thus the demand will be enormous. In many different cases, all of them are precisely tailored to the individual heating wires, and the same product with the same performance must be made into the battery-operated prefabricated heating wire manufactured by the technology of the present invention. Various applications can be made in various fields to achieve the purpose of obtaining (desired) heat required in numerous various sites using battery electricity, and these battery heating devices (heating devices) can be commercialized.

Therefore, mass production technology that enables mass production of the customized hot wire precisely made on the basis of ④ above with the same and identical products is also important for the implementation of the present invention.

However, in the conventional heating wire (heating element) manufacturing technology, if you want to make a heating element (heating element) having a certain performance, a number of kinds of specialized machinery and devices that can be precisely processed to a specific material and a number of cross-sectional sizes of pre-designed by one Since it is possible to make a pre-designed heating element (heating element) having a certain performance only to make each of them, there is virtually no economic feasibility to mass-produce a large number of kinds of customized heating elements such as ④ required by the present invention in the same product .

Therefore, the prefabricated heating wire manufactured by the present invention should be made of a technology that enables economical and easy mass production at any time as the same product having the same performance for each customized heating wire manufactured according to the above ④.

Putting it all together again,

The technique to be implemented by the prefabricated heating wire in the <Example 13-1>,

① Technology to make a heating wire with low resistance value necessary to obtain desired heat by using battery electricity or safe low voltage direct current (DC) electricity below 24V,

② technology to make a heating wire that expresses any one or more additional functions in parallel with the heating wire of ① above;

③ technology to make a flexible heating wire in parallel with at least one of the above ① or ②,

④ technology to have all of the performances of any one of the above ① ~ ③, each of which is precisely customized heating wire in the number of various cases,

⑤ Among the technologies that make each customized heating wire manufactured according to ④ above economical and easy mass production at any time with the same product with the same performance,

Which is one or more technologies,

The prefabricated heating wire of <Example 13-1> is a heating wire for implementing any one or more of the techniques of the above ① ~ ⑤.

<Example 13-4>

In order to practically use the method of manufacturing the prefabricated heating wire in <Example 13-3>, a practical implementation method of the prefabricated heating wire manufacturing method for applying the above technique to make a real hot wire is required.

In more detail, first, the prefabricated heating wire required for the present invention should generate a heating operation to release a large amount of heat instantaneously from the supplied battery electricity, which is basically a direct current, and most of the Because of this low voltage, it should be a heating wire that can perform the heating operation that easily emits a large amount of heat in low voltage direct current (DC) electricity.

However, direct current (DC) electricity flows in only one direction, so that in order to make the heating wire easily generate heat operation in battery electricity, a single metal or alloy metal, which is a material composed of only 100% R (Resistance) component, is used. Should be used as the heating material.

In addition, another reason to make the heating wire to operate the battery electricity required for the present invention using only a single metal or alloy metal, this heating wire is a safety low voltage direct current (DC) electricity that occupies most of the battery This is because it is necessary to be able to generate instantaneous high temperature heat (if it fails to generate instantaneous high temperature heat, it will not be possible to generate a large amount of heat at the moment).

Single metal or alloy metal is composed of 100% R (Resistance) component, and R (Resistance) component generates exothermic reaction in both direct current (DC) electricity and alternating current (AC) electricity.

In contrast, the C (Condenser) component generates an exothermic reaction only in an AC induced current (AC electricity whose current flow direction changes instantaneously), and does not cause an exothermic reaction in direct current (DC) electricity.

Therefore, if the C (Condenser) component is large (e.g., carbon black heating elements including conventional rubber components), or has a impedance resistance value that can be calculated as a vector sum of the R component and the C component (eg , The conventional heating element containing carbon components, heating element containing carbon components, planar heating elements, etc.) as the heating wire material of the present invention, since the heating wire of the present invention uses a low voltage direct current (battery electricity) directly, This is not at all, or the thermal reaction is slowed to solve the problem of using only the desired low-voltage direct current (DC) electricity in the present invention, it becomes a heating wire that can not achieve instantaneous high temperature heat.

In addition, the heating element (heating wire) material, which is not a single metal or alloy metal, has a very low heat generation rate, and when a high temperature heat is generated, a fire occurs as the material burns, or when it is used for a long time at a high temperature, it breaks down, breaks, and shorts. It leads to a fire accident.

Therefore, the prefabricated heating wire required for the present invention, the instantaneous high temperature heating operation in the direct current (DC) low voltage electricity (the instantaneous high temperature heating operation, it is possible to perform the heating operation to release a large amount of heat at the moment) Certain monometallic or alloying metals that occur easily shall be used as the heating material.

Next, the prefabricated heating wire required for the present invention should be able to generate a desired heating operation in a safe low voltage direct current electricity, which occupies most of the battery electricity. This is essential as described in the above-described <Example 13-3>. Therefore, it should be made of heating wire having low resistance value necessary to obtain desired heat by using battery electricity or safe low voltage direct current under 24V.

In addition, the prefabricated heating wire is made to have a heating wire having a low resistance value necessary to obtain a desired heat by using battery electricity or a safety low voltage direct current of 24V or less as described above in Example 13-3. In parallel, it must be made of a heating wire that expresses one or more additional functions (e.g., a function of instantaneous heat generation, a function of emitting far infrared rays, a function of excellent tensile strength and durability, and not easily disconnected),

In addition, since it has to be made in numerous different types as described above in Example 13-3, in order to effectively implement a variety of applications must be made of a highly flexible heating wire,

In addition, as described above in Example 13-3, the heating wire having a low resistance value should be made at the same time as the heating wire which expresses at least one specific additional function, and should be made of a flexible heating wire. All of these hot wires can be customized as needed, with custom hot wires as needed, but in a number of different cases, all of them can be customized precisely.

In addition, as described above in Example 13-3, each of the customized heating wires are made as desired as needed, but the customized heating wires are made to be precisely customized heating wires in each of numerous various cases. The same product with the same performance should be made into a technology that is economically and easily mass-produced at any time.

Therefore, in conclusion, the heating wire required in the present invention can express all of the above five performances by using a specific single metal or alloy metal as a material, which makes the instantaneous high temperature heating operation easily in a DC safe low voltage electricity. Make it work,

The hot wire manufacturing technology of a new concept that can easily make the heating wire to fully implement all of these technologies is the manufacturing method of the prefabricated heating wire according to the present invention.

However, when looking at the conventional heating wire (heating element) manufacturing technology, it is almost impossible to make the conventional heating element (heating element) to have a low resistance value required to obtain the desired heat using battery electricity or a safety low voltage direct current electricity of 24V or less. Even if it is made to have a low resistance value such as this, it will not be flexible and will have a large cross-sectional area, and if it is to be made in numerous cases with precise resistance value, it should be made by cutting the cross-sectional area one by one or developing an alloy metal for this purpose. Therefore, the difficulty is high, there is no precision, or the low resistance value as described above for most cases can not be made at all, the mass production can not be made, the biggest problem is economical.

And another problem of the conventional heating wire (heating element) manufacturing technology is that it is impossible to implement a heating wire that expresses any one or more additional functions at the same time while making the low resistance value as described above.

In more detail, the conventional heating wire (heating element) manufacturing technology has three types, the first type is the resistance value of the heating element by adjusting the cross-sectional area of the heating element (heating element) made of metal (including alloy metal) The second type is the method of making the heating wire (heating element) itself by alloying technology to have a specific resistance value, and the third type can be divided into the heating wire (heating element) type, not the metal (alloy metal).

First, the manufacturing technique of the method of controlling the resistance value of the heating element by adjusting the cross-sectional area of the heating wire (heating element) made of a conventional metal (including alloy metal) is the cross-sectional area of the metal (alloy metal) to be used as heating wire (heating element) It is a manufacturing method of heating element (heating wire) produced by adjusting the resistance value by adjusting the size.

Among the conventional materials, single metal or alloy metal material used as heating wire (heating element) material is cut to have a cross-sectional size that meets a certain resistance value by using mechanical equipment (equipment, device), or extruded and drawn. (Cold rolling method, etc.) or other mechanical equipment, all made according to the method of increasing or decreasing the size of the cross-sectional area of the metal, that is, adjusting the resistance value by adjusting the cross-sectional area,

As a conventional metal (alloy metal) heating element manufacturing method for controlling the resistance value of the heating element (heating wire) by controlling the size of the cross-sectional area of the metal by such a machine (apparatus, equipment), a number of low types of various kinds required by the present invention It is a technology that is virtually impossible to make a resistance value, and even if some parts can be made to have a low resistance value, it is not accurate or most of the difficulty is not able to mass-produce a number of low resistance values.

For example, since the single metal or alloy metal essential for the heating wire material of the present invention is too strong and fragile and cannot be easily made into a hot wire by a general easy method, a method of making a single metal or alloy metal into a hot wire by a conventional method As a matter of course, special professional mechanical equipment and specialized devices such as drawing machines and dies are made and cut or processed to make metal (alloy metal) heating wires.

However, since the heating wire required by the present invention has to be made into a variety of types of heating wire having a low resistance value, in order to do this, a conventional method of a metal (alloy metal) of a specific material according to a large number of desired resistance value types After selecting and designing a large number of cross-sectional areas, it is necessary to prepare all kinds of specialized equipment and devices for each of these pre-designed materials and numerous cross-sectional areas. Can produce.

In addition, in this process, when the heating wire to be used for any special purpose must be produced by changing it to a new resistance value minutely, new precision equipment must be designed and made accordingly. Can produce.

Therefore, it is virtually impossible to mass produce (manufacture) all the precise heating wires having various and many low resistance values by this conventional method, and there is no economic feasibility.

For this reason, conventional heating wires made of a single metal or alloy metal are generally standardized to have some kinds of resistance values (Ω / m) that are commonly distributed (nationally and globally, such as AC 110V and 220V). Standardized to a specific resistance value to be used only in) production and distribution, and limited to a few of these can not be used as a variety of types of various types of heating wires required by the present invention.

In addition, even if it is assumed that a single metal or alloy metal material and equipped with all the specialized mechanical equipment and specialized equipment as described above to produce a variety of types of heating wire, the heating wire manufactured by the technology to adjust the resistance value by adjusting the cross-sectional area In order to have a low resistance value, such a hot wire has to have a very large cross-sectional thickness of a metal (alloy metal) and a very short length to have a desired low resistance value. ) Is made of thicker, shorter, less flexible, and cannot be used for use in the low resistance multi-heater photovoltaic heating system according to the present invention.

If we explain this in detail with numerical examples,

First of all, in order to make the present invention, a DC electric current (DC) of 5 V or less is required to make a battery heating device (heating apparatus) equipped with a prefabricated heating wire according to the present invention which is safe from electric shock. It is necessary to perform the desired heating operation by using a variety of voltage bands having a certain range below the low voltage. To do this, the resistance value of the heating wire should have a resistance value of 0.1 mW / m or less, and the thickness is 2 mm2 based on the cross-sectional area. Assume that the heating wire desired in the present invention should be made below to be able to make a battery heating device (heating apparatus) equipped with the prefabricated heating wire according to the present invention.

Secondly, these heating wires have each of the above low resistance values, and at the same time, perform a specific function (a function of causing high temperature heat generation operation, a function of emitting far infrared rays, a function of excellent tensile strength and durability, which are not easily disconnected, and a function of excellent flexibility). Assuming you need to make it possible,

Among the conventional metal (alloy metal) heating elements (heating wires), a representative nichrome wire is used to make the heating wire under the primary conditions. The resistance value of the nichrome wire currently produced and distributed is 0.18 mm in diameter and 1m in length, which is 48.39 kΩ. If you convert this to the cross-sectional area, circle cross-sectional area = πr ² = 3.14 X (0.18 mm / 2) ² = 0.0254 mm 2, and has a resistance value of 48.39 mm 3 when the nichrome wire cross-sectional area is 0.0254 mm 2 and a length of 1 m.

However, since the resistance value of the heating element is inversely proportional to the size of the cross-sectional area, in order to adjust the cross-sectional area of the nichrome wire to make the resistance value less than 0.1 mW / m, the heating wire cross-sectional area = 48.39 m ÷ 0.1 m / m = 483.9 times. The actual thickness is 0.0254 mm 2 X 483.9 times = 12.29 mm 2 or more.

Therefore, even though a hot wire having a low resistance value of 0.1 mW / m or less was produced by increasing the cross-sectional area, the hot wire thickness of 12.29 mm2 should be less than 2 mm2 based on the cross-sectional area. Compared to the heating wire thickness condition satisfying the above example, by making the heating wire 12.29 mm2 ÷ 2mm2 = about 6 times thicker, the coarse, short and inflexible manufactured by adjusting the resistance value in such a way as to control the cross-sectional area The heating wires produced by the conventional single metal or alloy metal heating wire manufacturing technology, which can only be made, can not be applied to a battery heating device (heating apparatus) that is equipped with a prefabricated heating wire according to the present invention to be made in the present invention. The condition cannot be satisfied.

In addition, the conventional single metal (alloy metal) heating wire (heating element) technique cannot satisfy the secondary conditions of the above embodiment and cannot be realized.

The heating wire (heating element) required by the present invention is a function of causing the instantaneous high temperature heating operation, far infrared ray emitting function, excellent tensile strength and durability, which is not easily disconnected, excellent flexibility, etc. Automatic co-expression must be performed in parallel with one or more of them. Conventional single metal (alloy metal) heating wire (heating element) technology does not have the geometric structure or material required for this technology at all. Not only that, but there is no such technology itself.

In conclusion, such a conventional single metal (alloy metal) heating wire (heating element) manufacturing technology has a large number of various low-resistance values, including a prefabricated heating wire according to any of the present invention, a battery heating device (heating apparatus), etc. In order to make a heating wire (heating element) that can be easily applied to all kinds of battery heating devices that obtain energy consuming heat in the field, the technical limitation is clearly exposed, and at the same time, a function that generates a high temperature heating operation, The technology that generates far infrared rays, functions of excellent tensile strength and durability, which are not easily disconnected, and features of high flexibility, in addition to the heating operation in the heating wire, and various additional functions, in particular, mass production of such customized precision heating wire Implementing mass production is not even more realistic.

The second type, the alloying of the heating element itself with a specific resistance value, shows that in the manufacture of metal heating elements, every single metal has a resistivity value and the single metals found by humans Since the number of these metals is limited, it is difficult to make a variety of resistance values with these single metals alone. As a way of overcoming this problem, a single metal is mixed to form an alloy metal so that the metal having a resistance value that single metals could not have had. Alloy metal technology,

This alloy metal technology is another advantage, and withstands extremely high temperatures, and because it can make the heating element (heating wire) that generates instantaneous high temperature heat more effectively than a single metal, the conventional heating wire (heating element) manufacturing method is another one of high difficulty It is a manufacturing method of a metal (alloy metal) heating wire (heating body).

However, the biggest drawback of the heating element (heating wire) manufacturing technology by such alloys is that the alloy technology has to be found through a number of experiments and studies (material type and compounding ratio, etc.), the desired alloy having a large number of low resistance value Since the numerous alloying techniques for making tens of thousands of varieties cannot be developed many times, it is rather difficult to customize any particular low resistance value with alloys, rather than the method of controlling the resistance value by the cross-sectional control. It becomes more difficult and hard technology.

Therefore, this conventional second metal (alloy metal) heating wire (heating element) manufacturing technology is also an alloy technology, which is necessary to obtain the desired heat by using battery electricity or safe low voltage direct current of 24V or less to implement the present invention It is virtually impossible to produce a heating element (heating element) that allows each to have a specific low resistance value based on the number of cases that must be applied differently in the conditions of use.

Particularly, the technology for generating instantaneous high temperature heating operation, the far infrared ray emitting function, the function of excellent tensile strength and durability and not being easily disconnected, and the heat generating operation at the same time with various additional functions, and especially such customized precision Implementing the same mass production (mass production) of hot wires means that more and more alloying technologies have to be developed in addition and innumerable times, which is virtually impossible.

Finally, in the case of the heating wire (heating element) other than the third type of metal (alloy metal), as described above, the heating wire required by the present invention should be easily generated in direct current (DC) electricity, and particularly high temperature heat generation. In contrast, the heating wires (heating elements), which are not conventional metals (alloy metals), are all materials with a large C component (eg, carbon black heating elements containing conventional rubber components), R components, and C components. As these heating elements use materials having a synthesized resistance value (for example, conventional heating elements including carbon, heating elements including carbon, and planar heating elements), they cannot operate in direct current (DC) electricity as described above. Or the heat generation rate is too slow, and the instantaneous high temperature heat generation is not possible. By exposing the technical limitations from basic technical matters, the simultaneous implementation of other additional functions It is heating (heat rays) can not be used.

In summary, the conventional heating wire (heating element) manufacturing method (technology), using the battery electricity or the safety low-voltage direct current electricity of 24V or less required in the present invention, a number of low-resistance values required to obtain the desired heat It is impossible to make it be customized specifically, so it is necessary to make a heating wire so that it can be used (heating operation only) in some AC voltage bands already available (the existing general voltage 110V, 220V, etc.). A technology that causes high heat generation operation, far infrared ray emission function, excellent tensile strength and durability, which is not easily disconnected, and excellent function of flexibility. Implementing a technology that mass-produces precision heating wires equally is impossible at all.

Such a conventional heating wire (heating element) manufacturing technology can not implement the present invention.

Therefore, in the present invention, in order to solve the problems (limitations of the technology) of the existing heating wire (heating element) technology and to implement the present invention, a manufacturing method (technique) capable of freely implementing and implementing all desired in the present invention. Phosphorus, the method of manufacturing the prefabricated heating wire in <Example 13-1> and <Example 13-3> is required.

And in order to practically use the prefabricated heating wire manufacturing method in the above-described <Example 13-1> and <Example 13-3>, a method of realizing such a technique is required, which will be described in more detail. As follows.

First, the heating wire (heating element) material (material) for implementing the method of manufacturing a prefabricated heating wire is necessarily used as a single metal or alloy metal as described above.

Next, make a micro wire from many kinds, many single metals or alloy metals,

Make a variety of things with any specific resistance you want,

Make a variety of things with any specific thickness you want,

Make a variety of things with any specific material you want,

Make a variety of things with any specific function you want,

Alternatively, the data values of the resistance value, thickness, material, and function may be collected by collecting the data of resistance value, thickness, material, and function for the existing microfabricated wires made of a single metal or alloy metal having any specific resistance value, material, thickness, and function desired. After creating the data,

Among the prepared fine wires, a fine wire suitable for a desired specification (simultaneously implementing any one or more of the techniques of 1 to 5 described above in <Example 13-3>) is selected, and the selected fine wire is selected as 2 Combine into multiple strands or more to make one combination,

The ultrafine wires inside these one combinations are assembled in a method of energizing and synthesizing into a bundle, so that the bundle becomes a strand of hot wire desired in the present invention.

Herein, a combination of the above-described combinations is changed, a bundle is changed, and a bundle is changed, and the heating wire desired in the present invention is made to be customized to the desired specification.

At this time, the method of changing the combination,

Selected by changing the selection according to each specification (such as simultaneously implementing any one or more of the techniques of 1 to 5 described above in <Example 13-3>) to select the fine line inside the combinations Combinations of lines soon conform to changes in the desired hot wire specification in the present invention.

However, in the present invention, if the changed specification of the desired heating wire is too fine and difficult to meet only the selection of the ultrafine wires, in addition to this, while changing the number of strands of the ultrafine wires of the combinations that are changed by the selection change of these ultrafine wires alone If you meet these desired specifications, even the most difficult and demanding specifications can be met.

However, when making a heating wire in the same way as to be careful in assembling a single bundle by combining a plurality of micro-wires, the multiple strands of the micro-wires that are combined in the bundle all closely contact each other (gap) Contact should be made so tightly that it does not exist (if it does not adhere very well), there will be very fine voids between the fine wires, and when the electricity flows in the fine wires, a potential difference between the fine wires where these voids exist Local overheating may result in local high temperatures or local fires.) Throughout the length of the microwire, all surfaces in the longitudinal direction and all the microwires are in contact with each other, The micro wires are in close contact with each other to allow current to flow through the contact surfaces. Therefore, the assembly should be made so that all the fine wires are completely synthesized in the entire length direction, so that the resistance value does not change at all in practical use, as if a total compound resistance value is obtained as a mass of metal (alloy metal).

And if you combine the fine wire with a specific resistance value, function, thickness, and material and add the method of changing the number of strands to make a combination, many changes of these combinations will be the control of the synthetic resistance value. The number of changes in the combination is the number of changes in the combined resistance value, and the number of cases of the combined resistance value can be generated indefinitely, thereby synthesizing the prefabricated combination of the ultrafine wires generated by the number of such infinite cases in one bundle (bundle). ) So that the bundle itself becomes a strand of hot wire with a specific resistance per unit length,

Among the bundles consisting of an infinite number of cases of these ultrafine wires, the low resistance value or the multi-function required to obtain a desired heat by using the numerous battery electricity required by the present invention or the safe low voltage direct current (DC) electricity of 24 V or less, There are many hot wires with any one or more.

Therefore, the heating wire (heating element) manufacturing technology is a way to synthesize the ultra-fine wires to change the synthetic resistance value of the ultra-fine wires, it is possible to freely make a hot wire having a large number of resistance values, even with a precise and fine resistance value By combining specific microfiber wires or changing the number of strands, you can create hot wires with the desired resistance and the desired function, and you can customize them with fine and precise resistance values. It is very easy and easy to mass produce these same hot wires numerous times.

In addition, in this case, a heating wire having any one or more of any low-resistance value or multi-function required to obtain a desired heat by using a battery battery or a safe low-voltage direct current (DC) electricity of 24V or less according to the present invention may be customized. In addition, it is easy to make all of them precisely, and it is possible to make it precisely by prefabricating according to the resistance value, function, and performance by customizing it, and it is necessary to assemble the micro wire type and the number of strands once assembled as it is. Mass production of the same heating wire, which could not be achieved by the conventional heating wire (heating element) technology that can produce heat wire only when mechanical equipment and devices are made and manufactured by each type, can be mass-produced even with a very simple ultra-fine wire assembly equipment. Do.

In addition, by combining the ultra-fine wires having a specific resistance value, function, thickness, and material and adding a method of changing the number of strands therein to form a combination, by the combination that is changed to such a large number of cases, the present invention It can be made to have any low resistance value necessary to obtain the desired heat by using battery electricity or safety low voltage direct current (DC) power of 24V or less, and to emit far infrared rays or super fast heating. The new heating material, which is a prefabricated heating wire having multiple (complex) low resistance values that can simultaneously perform any desired function (performance), can be customized as many times as desired.

In conclusion, while changing the selection of the micro-wires and the number of strands of the micro-wires to change the combination is a prefabricated heating wire manufacturing method to change these combinations to be precisely tailored heating wire to the desired specification in the present invention By utilizing the method of manufacturing the prefabricated heating wire, the heating wires that implement all of the techniques of ① to ⑤ described above in <Example 13-3> can be manufactured according to a desired specification one by one and can be manufactured according to desired specifications. do.

<Example 13-5>

Referring to the method of changing the combination of the ultrafine wires in the <Example 13-4> again, the desired specification among all the prepared ultrafine wires in the <Example 13-4> (described in detail in the <Example 13-3> In selecting the ultra fine wires that implements all of the techniques of ① to ⑤ simultaneously, and combining the selected ultra fine wires into two or more multiple strands to form a single combination,

As a method of changing the one combination, a method of changing the fine lines inside the combination may be used. The selection of the ultra fine wire is the most suitable fine wire to be a hot wire that can realize a desired specification, and the desired specification. Since there are so many numbers, according to the change of these specifications as desired specifications are different, the selection of an ultrafine wire should also be changed to the most suitable one.

And if there is a limit to change the selection of the fine wires to become a heating wire that can implement the desired specification, the number of strands by changing the number of strands further finely divided into multiple strands as described above, or the same thickness You can add more ways to change the number of strands to fit your situation, such as reducing or increasing the number of strands, or reducing the number of strands to thicker ones. By increasing the selection width of the fine lines to make a heating wire that can be selected, if you make the best use of the increased selection, even the most demanding and difficult in the present invention to meet the desired specifications of the heating wire It can be customized more precisely.

The method of changing the combination of the fine lines in the <Example 13-4>,

In the <Example 13-4>, the ultrafine wires inside one combination are selected as one or more of all the ultrafine wires prepared in the <Example 13-4>, and the selected ultrafine wires are differently selected. The alteration is to change the combination of the ultrafine wires, but the combination of the ultrafine wires in the above Example 13-4 is changed to at least two strands of the ultrafine wires inside the combination. It becomes a way.

<Example 13-6>

In the <Example 13-5>, the method of changing the selection box more effectively,

In case of selecting one of the ultrafine wires, selecting one of the ultrafine wires as a different ultrafine wire and changing the selection of the ultrafine wires, but changing the number of strands to two or more strands of the same ultrafine wire selected do or,

If you select any two or more micro wires, select one or more micro wires from two or more micro wires as different micro wires, and change the selection of the micro wires,

If any two or more fine lines are selected, one or more fine lines among two or more fine lines are selected as different fine lines, and the selection of the fine lines is changed, even if the number of strands of the selected fine lines is changed or selected. Change it,

Of the above-described method, the method of changing the selection box is made by any one or more methods, the number of fine-wire strands in the one combination is more than two strands and the method of changing the selection box is made,

That is, the method of changing the combination of the ultrafine wires in the <Example 13-4>.

<Example 13-7>

All the ultrafine wires prepared in <Example 13-4>, for example, to implement the present invention with the single metal or alloy metal, through the actual self-test to make the actual ultrafine wires required in the present invention as follows I prepare in advance,

① As a micro wire to use a specific material as a priority, among the various kinds of micro wires having a specific material, the combination of energizing contact synthesis with other micro wires works well without problems, and the battery electric or 24V or less An ultrafine wire that represents a particular material that makes it easier to make a heating wire with a low resistance value necessary to obtain a desired heat by using a large safety low voltage direct current (DC) electricity.

①-1, in order to make it possible to change the resistance value more effectively in the process of making a heating wire having a low resistance value, almost no heat-generating operation, battery electricity or safety low voltage DC current of 24V or less is more It is a micro wire that represents a specific material that only serves as a conductor to flow a lot.

Fine wire made of silver, having a resistance value of 0.1058 Ω (fine wire thickness 0.1531mm2) per 1 m length,

①-2, in the process of making a resistance wire more effectively in the process of making a low-resistance heating wire, the middle role only (it generates a slight heat operation, but battery electricity or safe low-voltage direct-current DC (24V or less) A fine wire that represents a particular material, which acts as a conductor so that more current can flow

A fine wire made of tungsten material, a fine wire having a resistance value of 1.30Ω (fine wire thickness 0.0532mm2) per length, a fine wire made of platinum, and a resistance of 0.2058Ω per 1m length. 0.51mm thick) fine wire with

①-3, as a fine wire that represents a specific material, which only serves as a complete heating operation to easily change the resistance value more effectively in the process of making a heating wire having a low resistance value,

Fine wire with material made of steel fiber (NASLON), fine wire with resistance value of 50.5Ω (fine wire thickness 0.017229mm2) per length, fine wire with material of steel fiber (metal fiber) (NASLON) And a fine wire having a resistance value of 90.3 kW (fine wire thickness 0.009635 mm 2) per 1 m of length.

② As the fine wire for preferential use of a specific resistance value, among the various fine wires having a specific resistance value, the combination of energizing contact synthesis with other fine wires is well done without problems. Although the materials and materials themselves are different, they have similar resistance values, making it easier to make a heat wire with a low resistance value necessary to obtain the desired heat using battery electricity or a safe low voltage direct current (DC) power of 24V or less. The fine lines that represent resistance are

②-1, in order to make it possible to change the resistance value more effectively in the process of making a heating wire having a low resistance value, almost no heat-generating operation, battery electricity or a safe low-voltage direct current (DC) current of 24V or less is more It serves only as a conductor to flow a lot, but the materials of the ① and the material itself are different, but having a similar resistance value, as a fine wire representing a specific resistance value,

A fine wire made of copper, having a resistance of 0.1098Ω (fine wire thickness 0.1538 mm2) per 1m in length, a fine wire made of aluminum, and having a resistance of 0.0201Ω per micrometer in length. 1.3mm thick) with fine wire,

②-2, in the process of making the resistance wire more effectively in the process of making a low-resistance value, the intermediate role only (it generates a slight heat operation, but battery electricity or safe low-voltage direct-current DC (24V or less) ) Acts as a conductor so that more current can flow), but the materials and materials themselves in the above ① are different, but have similar resistance values, and are fine wires representing specific resistance values,

A fine wire made of nickel, a fine wire having a resistance value of 1.3018Ω (fine wire thickness of 0.053 mm2), a fine wire made of pure iron, and a resistance of 0.1886Ω per 1m length. 0.53 mm thick)

②-3, in order to easily change the resistance value more effectively in the process of making a heating wire having a low resistance value, only serves to perform a complete heating operation, the material of the ① and the material itself is different but similar resistance value While having a fine wire representing a specific resistance value,

 It is a fine wire made of SUS 316 as an alloy of stainless steel, the fine wire having a resistance value of 50Ω (fine wire thickness 0.015386 mm2) per 1m in length, and the length of the fine wire made of SUS 316 as an alloy of stainless steel It is a micro wire which has a resistance value of 90 m (microwire thickness 0.00785mm <2>) per 1m.

③ As a micro wire to use a specific function as a priority, among the various kinds of micro wires having a specific function, the combination of energizing contact synthesis with other micro wires works well without problems, Safety Low Voltage Direct Current Microwires, which represent certain functions that are more prone to performing heating wires that express one or more additional functions as desired,

③-1, battery electricity or safe low-voltage direct-current (DC) electricity of 24V or less flows, the ultrafine wire that represents a specific function to make the desired heating operation more effectively,

Fine wire made of iron chromium alumina molybdenum alloy metal (68-73% by weight of iron, 18-22% by weight of chromium, 5-6% by weight of alumina, 3-4% by weight of molybdenum), 1m long This is a micro wire having a resistance value of 48Ω (fine wire thickness 0.015386 mm2), a fine wire made of nickel copper alloy metal (alloy made of nickel compounding ratio of 20-25 wt% and 75-80 wt% copper). A fine wire with a resistance value of 11Ω (fine wire thickness 0.025434mm2) per 1m, a fine wire made of SUS 316 as an alloy of stainless steel series, and a fine wire with a resistance value of 7650Ω (fine wire thickness 0.0001005mm2) per 1m length A fine wire having a wire and a material made of steel fiber (NASLON), and having a resistance value of 7,700 kW (fine wire thickness 0.000113 mm2) per 1 m length,

③-2, battery electricity or safe low-voltage direct current (DC) electricity of 24V or less, to prevent the oxidation reaction caused by heat to be more effective to make the function to make the heating wire (microwire) life longer The micro wire which represents a function,

Of the fine wires made of an alloy metal made by adding an additional amount of molybdenum to the nickel copper alloy metal, the fine wire having a resistance value of 11.2 Ω (fine wire thickness 0.02512 mm2) per 1 m length, the iron chromium alumina molybdenum alloy Fine wire made of alloy metal made by adding at least one of manganese and carbon, and having a resistance value of 48.7Ω (fine wire thickness 0.0151mm2) per 1m length,

③-3, battery electricity or safety low-voltage direct current (DC) below 24V When the temperature rises above a certain temperature, the ultrafine wire that represents a specific function to more effectively cause the role that the resistance value drops sharply more effectively,

The material is made of silicon copper alloy metal made of 20% by weight of silicon and 80% by weight of copper. It is a micro wire having a resistance value of 50 m (1 mm thick) per 1 m length.

④ As a micro wire for preferential use of a certain thickness, a variety of micro wires having a certain thickness are used. When safe low-voltage direct current (DC) electricity flows, it is easier to reinforce, adjust, or supplement the main roles of the above ① ~ ③ by varying the thickness of the corresponding ultra fine wires. The fine line representing the specific thickness to be made,

④-1-1, representative microfine wires having different thicknesses among the ultrafine wires representing a specific material, which serves only as a conductor of the above ①-1,

A fine wire made of silver, a fine wire having a resistance value of 0.241 Ω (fine wire thickness 0.06721 mm2) per 1 m length, and a fine wire made of silver material, and a resistance value of 1.1150 Ω per 1 m length. Fine wire with a line thickness of 0.014527 mm2),

④-1-2, representative of a specific material, which acts only as a middle part of the above ①-2 (causes a little heat generation, but acts more as a conductor so that a safer low-voltage current can flow more). Among the fine wires that are different from the representative fine wires,

Among the fine wires made of tungsten, the fine wires having resistance value of 5.768Ω (fine wire thickness 0.0095mm2) and 8.179Ω (fine wire thickness 0.0067mm2) per 1m length, among the fine wires made of platinum Microwire having resistance value of 0.913Ω (fine wire thickness 0.115mm2), 2.058Ω (fine wire thickness 0.051mm2), 4.565Ω (fine wire thickness 0.023mm2), 14.999Ω (fine wire thickness 0.007mm2) per 1m,

④-1-3, the representative ultrafine wires having different thicknesses among the ultrafine wires representing a specific material, which serve only as a complete heating operation of the above ①-3,

Fine wire with material made of steel fiber (NASLON), fine wire with resistance value per 1m length of 170.5Ω (fine wire thickness 0.005103mm2), fine wire with material of steel fiber (metal fiber) (NASLON) Fine wire having a resistance value of 281 길이 (fine wire thickness 0.003096 mm 2) per 1 m length,

④-2-1, only the conductors of ②-1, but the material and the material itself of the above ① but having a similar resistance value, the representative micro-fine wires having a different thickness of the micro wires representing a specific resistance value ,

Of the fine wires made of copper, the fine wires having a resistance value of 0.235Ω (fine wire thickness 0.0718mm2) and 1.1123Ω (fine wire thickness 0.015386㎜) per 1m length, among the fine wires made of aluminum Micro wire having resistance value of 0.0315 kW (fine wire thickness 0.83 mm 2), 0.356 kW (fine wire thickness 0.0735 mm 2) per 1 m,

④-2-2, only the intermediate role of ②-2 (it generates a little heat operation, but acts as a conductor more so that a safer low-current current can flow more), but the above ① Although the materials and the materials themselves are different, but have similar resistance value, the representative fine wires having different thicknesses among the fine wires representing the specific resistance value,

Among the fine wires made of nickel, the fine wires having resistance of 6.2727Ω (fine wire thickness 0.011mm2) and 8.625Ω (fine wire thickness 0.008㎜) per 1m length, among the fine wires made of pure iron Microwire having resistance value of 0.909Ω (fine wire thickness 0.11mm2), 2Ω (fine wire thickness 0.05mm2), 4.347Ω (fine wire thickness 0.023mm2), 12.5Ω (fine wire thickness 0.008mm2) per 1m,

④-2-3, only serves to perform the complete heating operation of the ②-2, but the material and the material of the ① and the material itself has a similar resistance value, while varying the thickness of the ultra-fine wire representing a specific resistance value Representative ultrafine wires,

Of the fine wires made of SUS 316 as an alloy of stainless steel, the fine wires having a resistance value of 170Ω (fine wire thickness 0.004525mm2) per 1m in length, and the fine wires made of SUS 316 as an alloy of stainless steel, Micro wire having a resistance value of 280 Ω (micro wire thickness 0.002523 mm 2) per 1 m length,

④-3-1, when the battery electricity of the above ③-1 or the safety low-voltage direct current (DC) electricity of 24V or less flows, representative of the fine wires of different thicknesses representing a specific function to make the desired heating operation more effective Microfiber lines,

Of the fine wires made of iron chromium alumina molybdenum alloy metal, per 1m length, the fine wires having resistance value of 82Ω (microwire thickness 0.00785mm2), and of fine wires made of nickel copper alloy metal, per 1m length, Ultra fine wire with resistance value of 36Ω (fine wire thickness 0.00785mm2), fine material made of SUS 316 as alloy of stainless steel series, ultra fine wire with 17,330Ω (microwire thickness 0.00004436mm²) per 1m length, The material is a stainless steel alloy, made of SUS 316, a fine wire with a resistance of 26,375 Ω (fine wire thickness 0.00002914 mm2), a fine wire made of steel fiber (NASLON), This is a fine wire having a term value of 17,319Ω (microwire thickness 0.00005024mm2) per 1m length, and a fine wire made of steel fiber (metal fiber) (NASLON) .The resistance value per 1m length is 26,239Ω (micrometer wire thickness 0.00003316mm2) to That the ultra fine lines,

④-3-2, the thickness of the ultrafine wire that represents a specific function to more effectively suppress the oxidation reaction by the heat of the above ③-2 to make the function to make the heating wire (microwire) life longer Representative microfiber lines that are different,

Among the fine wires made of alloy metal made by adding molybdenum trace amount to nickel-copper alloy, the fine wire having resistance value of 36.5Ω (fine wire thickness 0.00770mm2) per 1m length, and the material is iron chromium alumina molybdenum An ultra fine wire made of an alloy metal made by adding at least one of manganese and carbon to an alloy, and having a resistance value of 83.7 kW (fine wire thickness 0.008785 mm2) per 1 m length,

④-3-3, when the temperature of the above ③-3 rises above a certain temperature, the representative ultrafine wires having different thicknesses among the ultrafine wires representing a specific function to cause the resistance to fall more effectively,

It is an ultrafine wire made of a silicon copper alloy metal, and has a resistance value of 104.8 kW (fine wire thickness 0.477mm2) per 1m in length.

Next, the alloy metals are made separately to have any specific resistance value, material, thickness, and function desired, and the ultra-fine wires are made according to the desired specifications with these alloy metals. As an indispensable specification, as a result of making an ultrafine wire that enables the multi-function in the following <Example 13-10> to be performed simultaneously and simultaneously,

The material is made of ultra fine wire having a thickness of 20 micrometers or less (based on the ultra fine wire diameter) of a very thin steel fiber (NASLON), and the same fine wire is bundled into multiple strands of 100 or more with the same thickness. Synthesized by energizing contact with one bundle by itself to synthesize one bundle, or multiple bundles of two or more bundles in one bundle, or combined with any one or more of the ultrafine wires suitable for the application When used in conjunction with the above-mentioned multi-use multi-function multi-function can perform a multi-function that is a very fine line (bundle) is a more effective micro-wire group.

In addition, the thickness of one strand of NASLON, a steel fiber, is 20 µm or less, and among the ones manufactured with 100 or more strands with the same thickness, the bundles bundled below are optimal as a more effective ultrafine group for performing multi-function as a result of real experiments. It becomes the state of.

In other words, the microfiber group, which is more effective in performing the optimized multi-function according to the following self-test, has a thickness of 1 micron of NASLON, which is 12 micrometers (corresponding microscopic wire diameter), and bundles 550 strands with the same thickness. Made of sun group, the thickness of 1 strand of NASLON made of steel fibers is 8㎛ (corresponding to the fine wire diameter), which is made of one micro wire group by tying 1,000 strands with the same thickness, and the thickness of 1 strand of NASLON made of steel fiber is 6, 5 micrometers (corresponding microwire diameter), which is made of one microfiber group by binding 2,000 strands of equal thickness.

<Example 13-8>

The method of changing the selection box is to change the combination of the ultra-fine wires to more effectively implement the method of manufacturing the prefabricated heating wire having the low resistance value,

That is, in order to make the heating wire required for the present invention, as described above, in accordance with the specification of the number of desired cases, the change of the internal micro fine lines is optimized to a more desired specification in order to make the combination change. Should be changed

For such an optimized change, a more effective method of changing the selection of the ultrafine wires, which is how to select the fine wires and how to change the selection according to the desired specifications, is described.

As a first method, the heating wire to be made in the present invention is one of the methods used when lowering the resistance value among the desired specifications to a low resistance value, and when a more effective combination method of ultra fine wire is required, the method of <Example 13-4> Of all the prepared ultrafine wires, the classification type group may be selected from any one of the class groups classified by resistance value, thickness, material, and function. By combining them to form a combination, the combination is made so that the total number of ultra fine wire is at least two strands, the method of changing the number of strands, the <Example 13-5> and By changing the selection in the <Example 13-6>, it is a method for more effectively made by changing the combination of the ultrafine lines of the <Example 13-4> and <Example 13-5>.

If this is described in detail by way of example,

Example 1-1 shows any one of all the ultrafine wires prepared in Example 13-4, when the resistance value of the heating wire required by the present invention is made into a heating wire having a low resistance value of 1 kW per 1 m of the heating wire. In the above-described selection, two or more strands are synthesized to make one combination, prepared in advance, or prepared through actual experiments for the present invention in <Example 13-7>, or Among the types of micro wires classified into various resistance values, thicknesses, materials, and functions in the database of micro wires in circulation,

Select (or select) the fine wire from the material that meets the specification from the fine wires made of different materials in the classification group of the material.

That is, since the flexibility is increased only when the inner microfine wire combination of the bundle (heating wire) to be made is 2 or more strands, if possible, the preliminary experiments are carried out to implement the present invention in the <Example 13-7>. As a representative fine wire corresponding to the classification group of materials among the prepared fine wires (of four classification groups), only a complete heating operation is performed to easily change the resistance value more effectively in the process of making a heating wire having a low resistance value. Microfiber representing a specific material,

As a fine wire with a material of steel fiber (NASLON), select a fine wire having a resistance value of 50.5Ω (fine wire thickness 0.017229mm2) per 1m length, and make 50 strands with the same fine wire. When the composite is assembled into a bundle by combining them into a bundle, the bundle becomes a hot wire having a low resistance value of 1 당 per 1 m length.

If this is proved again by the formula, the formula synthesized resistance value = 1 ÷ (1 / R1 + 1 / R2 + 1 / R3…) is obtained, and the selected material is steel fiber (NASLON). Since the synthetic resistance value of 50 fine wires having a resistance value of 50.5 Ω (fine wire thickness 0.017229 mm 2) per 1 m length is 1 ÷ [(1 / 50.5) X (50 strands)] = 1 ÷ 0.99 ≒ 1 ,, 50 bundles of fine wires with 50.5Ω (fine wire thickness 0.017229mm2) resistance value of the selected steel fiber (NASLON) material are combined into one bundle, and this bundle is exactly 1 원하는 per 1m length. It turns out that it becomes a heating wire which has a low resistance value of.

Example 1-2 assumes that it is necessary to change the resistance value of the heating wire which is another need in the present invention to a heating wire having a low resistance value of 0.5 kΩ per 1 meter of the heating wire. If you increase (change) the number of strands of the same fine wire to satisfy 101 strands and combine them into a combination, and then combine them into one bundle, this bundle is 0.5Ω, which is a modified hot wire according to the example 1-2 condition. It becomes a heating wire having a low resistance value.

Proving this again, the composite resistance value of the same ultrafine 101 strands satisfying the conditions of Example 1-1 = 1 ÷ [(1 / 50.5) X (101 strands)] = 1 ÷ 1.99999 = 0.5 Ω By changing (increasing) the number of strands of the same fine wire into 101 and forming a bundle into a combination, the bundle can be made into a hot wire having a low resistance value of 0.5 kΩ per 1 m length.

In conclusion, when comparing the examples 1-1 and 1-2, by selecting only one of the categories classified as resistance value, thickness, material, and function (in this example 1-1 and 1-2, the kind of material Only one type was selected), but the result of changing (increasing) only the number of strands into the same fine line as the selected fine line (from 50 strands to 101 strands), the <Example 13-4> and <Example 13-5> In order to change the combination of the fine wires, the change is made more effectively to the desired specification (purpose) (the desired purpose of this example 1-1 and 1-2 = effective change of the resistance value). I can make it,

In particular, it can be seen that, despite the same ultrafine wire, by using the method of increasing the number of strands (twice), a hot wire having a low resistance value, which is a basic object of the present invention, can be easily produced.

The second method is another method of using the heating wire to be made in the present invention when a combination method of ultra-fine wires that is more effective in lowering the resistance value among the desired specifications to a low resistance value is required.

Among all the ultra-fine wires prepared in Example 13-4, a classification type group may be selected by using only one type group classified into resistance value, thickness, material, and function, and within the selected classification type group. The fine wire becomes a fine wire again changed to any one of the classification types except the one corresponding to the selected classification type group among the resistance value, thickness, material, and function type. By further selecting by changing the number of strands, the final selected (modified) microfibers are combined into at least two strands to form a single combination, and each combination is made of a total of fine microwires at least 2 The method of making more than one strand is performed by changing the selection in the <Example 13-5> and the <Example 13-6>, and the <Example 13-4> and the <Example 13-5> Of the fine lines It must be a way to be more effectively made the change.

The fine wire in the one classification type group selected above is changed to any one of the classification types except for the type corresponding to the selected classification type group among the resistance value, thickness, material, and function type. After making it become the method of changing the number of strands again in such a fine line,

① If only one kind of classification type group is selected as the material type, the micro fine line is changed again within the classification type group selected by this material, and then changed to one or more of thickness, function and resistance value except only material change. To change the number of strands to the same extra fine line again,

② If only one kind of classification type group is selected as the resistance value type, the micro fine line is changed again within the classification type group selected by this resistance value. In this way, the final selected fine line again changes the number of strands to the same fine line,

③ If only one kind of classification type group is selected as the function type, the micro fine line is changed again within the classification type group selected by this function, and thus any one or more of the material, thickness and resistance value except the function change is changed. To change the number of strands to the same extra fine line again,

④ If the classification type group selected by only one type is selected as the thickness type, the micro fine line is changed again within the classification type group selected by this thickness, and then changed to one or more of materials, functions, and resistance values except for changing the thickness. In the final selected fine line means any one or more of the method of further changing the number of strands to the same fine line again.

To explain this in more detail, select only one classification type among the categories classified as resistance value, thickness, material, and function (select one of four types), and then change the selection from the selected group. One of the three types except for the selected one among the four types is a method of changing the fine line again, and changing only the number of strands into the same fine line. .

In other words, if the selection in the first method is a method of selecting only one type out of four types and changing the number of strands to be the same as the fine line, the selection in the second method is the selected kind group in the first method. In the following four methods, the secondary selection change is made and the final fine line is selected as one, and the same number as the fine line is the method of changing only the number of strands.

The four methods below are described in detail.

① If only one kind of classification type group is selected as the material type, the micro fine line is changed again within the classification type group selected by this material, and then changed to one or more of thickness, function and resistance value except only material change. In order to explain in detail how to change the number of strands to the same fine line again in the final selected fine line,

Looking at Example 2-1A, for example, the same as Example 1-1 of the first method, it is to make the resistance value of the heating wire required by the present invention to a heating wire having a low resistance value of 1 Ω per 1m length of the heating wire When the condition of the present 2-1A is used, the condition of Example 2-1A can be satisfied by a method different from the first method.

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation A class of group of fine wires that are representative of a specific material, which serves only as a complete heating operation, in order to make it easier to change the resistance value more effectively in the process of making a heating wire having a low resistance value among the types of fine wires classified. Choose (select) a fine wire with a material that complies with the applicable specifications.

In other words, a fine wire having a material of steel fiber (NASLON) is selected, and a fine wire having a resistance value of 50.5 Ω (fine wire thickness 0.017229 mm2) per 1 m length is selected. If you make a bundle by synthesizing (combining assembling with electricity in the length direction) by combining them into a bundle, this bundle becomes a hot wire having a low resistance value of 1 당 per 1m length, which satisfies the condition of Example 2-1A. (Same as the first method).

In the following example 2-1B, in the state in which the classification group is defined as the material according to the above example 2-1A, the thickness is secondarily changed and selected from the fine lines made of the material, that is, as compared with the first method. If the thickness is selected to be thinner (that is, selected by changing the thickness of the item again in the classification group called material), it is possible to further increase the effect (an effect in which the flexibility should be increased) desired in the first method.

In practice, the resistance value can be more easily changed in the process of making a heating wire having a low resistance value among the ultrafine wires prepared through a preliminary experiment in order to implement the present invention in Example 13-7. For a very fine wire representing a specific material, which performs only a full heating operation, the material is a fine wire made of steel fiber (NASLON),

By changing the thickness, the thickness of the ultra fine wire per 1m with thinner thickness was 0.009635mm2 (the material was the same in Example 2-1A, and the thickness was thicker with 0.017229mm2), and the resistance value per 1m length was 90.3 If you select 91 strands of fine wire with and combine them into a combination, make them into a bundle and combine them into one bundle, this bundle is a hot wire with a low resistance of 1 당 per 1m length. This satisfies this Example 2-1B,

In particular, a result of satisfying the condition of Example 2-1A (the same condition as that of Example 1-1 of the first method) is obtained by another method from the first method.

To prove this again, the selected material is steel fiber (NASLON), and the synthetic resistance value of 91 fine wires having a resistance value of 90.3Ω (fine wire thickness 0.009635mm2) per 1m length = 1 ÷ [ (1 / 90.3) X (91 strands)] = 1 ÷ 0.99 ≒ 1 되므로, which means that the selected microfiber (NASLON) material has a fine wire thickness of 0.009635 mm2 (resistance value of 90.3 kPa). If you make a bundle by synthesizing into a combination, you can see that this bundle is a hot wire having a low resistance value of 1 당 per 1 m length.

In the following Example 2-1C, it is assumed that the resistance value of another required heating wire in the present invention needs to be changed to a heating wire having a low resistance value of 0.5 kΩ per 1 meter length of the heating wire. If only the number of strands is changed (increased) to the same heating wire that satisfies Example 2-1B, it can easily be made into a heating wire having a desired low resistance value of 0.5 kΩ per 1 meter length of the heating wire.

That is, in the present Example 2-1C, the same material as steel fiber (NASLON) that satisfies the conditions of Example 2-1B is the same, and the fine wire thickness is 0.009635 mm2 (resistance value of 90.3 kPa). If only the number of strands is increased (modified) from 91 strands to 180 strands to form them as a combination, and then synthesized and assembled into a bundle, this bundle is the same as in Example 2-1C (see Example 2-1B above). A heating wire having a low resistance value of 0.5 kV, which is a satisfying heating wire (modified to have a lower resistance value than the condition).

To prove this again, the synthesis of 180 ultra-fine wire strands having the same resistance (classification of material and the same thickness as 0.009635 mm2), which satisfies the conditions of Example 2-1A, with a resistance of 90.3 kW per 1 m length Since the resistance value = 1 ÷ [(1 / 90.3) X (180 strands)] = 1 ÷ 1.9933 = 0.5 Ω, the number of strands changed from 91 strands to 180 strands was changed. (Increase) and make a bundle in a combination, this bundle can be changed to a hot wire having a low resistance value of 0.5 당 per 1m length, and thus the same low resistance value but thinner As the number of strands increases and the number of strands increases, the flexibility can be increased even more.

In conclusion, when comparing Examples 2-1A, 2-1B, and 2-1C, only one of the classification categories classified as resistance value, thickness, material, and function was selected (in this Example 2-1A, Select only one type as the type) Select the fine line, change the thickness again within the selected classification group (In this example 2-1B, if the same classification type group is selected as the material classification type, the fine line is changed. Change the thickness in changing any one or more of thickness and function and resistance value except change), and in addition, change only the number of strands for the same micro wire with the selected thickness (second example 2-1C) As a result of changing the combination to exit,

In a method different from the first method, in a method of changing the combination of the ultrafine wires of the <Example 13-4> and the <Example 13-5>, a change that more effectively fits the desired specification (purpose) ( Desired purpose of the examples 1-1 and 1-2 = effective change of the resistance value) can be achieved,

In particular, despite the ultra-fine wire in the same representative taxon (material), the thickness of the other item except for the item within the taxon is changed again (thinner), and the number of strands is changed (about 1.8 times compared to the first method). Increase), it is possible to make a heating wire having a low resistance value, which is a basic object of the present invention, more easily by the first method and another method, and at the same time, to make the heating wire flexibility as an additional object more excellent. You can check it.

② If only one kind of classification type group is selected as the resistance value type, the micro fine line is changed again within the classification type group selected by this resistance value. In order to explain in detail how to further change the number of strands to the same fine line again in the final selected fine line,

For example 2-2A, for example, the same as those of Example 1-1 and Example 2-1A of the first method, the resistance value of the heating wire required by the present invention is a low resistance value of 1 kΩ per 1 meter length of the heating wire. When we say that it is condition of this 2-2A to make with hot wire

In this example 2-2A, the prepared fine wire cannot be obtained from the material center selected in Examples 1-1 and 2-1A of the first method, and only the fine wire is prepared based on the resistance value. Assuming

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Among the types of fine wires classified, since the material centers selected in Example 1-1 and Example 2-1A of the first method cannot be obtained, and the fine wires are prepared only by the resistance value center,

In order to make it easier to change the resistance value more effectively in the process of making a heating wire having a low resistance value, a resistance value suitable for the corresponding specification in the classification group of the resistance value, which is a fine wire representing a specific resistance value, which performs only a full heating operation. Choose a fine wire with (select).

That is, a fine wire made of SUS 316 as a stainless steel alloy is selected, and a fine wire having a resistance value of 50 kW (fine wire thickness 0.015386 mm2) per 1 m length is selected. Synthetic assembly (combining assembling by energizing synthetically in the length direction) in one combination makes this bundle into a hot wire having a low resistance value of 1Ω per 1m length, which satisfies the condition of Example 2-2A. .

Proving again by the formula, the selected material is a stainless steel-based alloy made of SUS 316, and the synthetic resistance value of 50 fine wires having a resistance value of 50 m (fine wire thickness 0.015386 mm2) per length of 1 m = 1 ÷ [(1/50) X (50 strands)] = 1 ÷ 1 = 1 Ω, so the selected material is a stainless steel-based alloy made of SUS 316, with a resistance of 50 Ω per 1 m length When the 50 micro fine wires having a thickness of 0.015386 mm 2 are synthesized into one bundle to form a bundle, the bundle becomes a desired hot wire having a low resistance value of 1 kW per 1 m length.

In the following Example 2-1B, in Example 2-1A, the classification group is defined as the resistance value, and secondly, the second fine line in the classification group of the resistance value is changed again, that is, the first If the thickness is selected to be thinner than that of the method (ie, the item of the thickness is changed again within the classification group called resistance value), it is impossible to obtain it from the material center, and the fine wire is prepared only from the resistance value center. Also, the effect (the effect of improving the flexibility) which was obtained by the said 1st method can be further increased.

In practice, the resistance value can be more easily changed in the process of making a heating wire having a low resistance value among the ultrafine wires prepared through a preliminary experiment in order to implement the present invention in Example 13-7. Steel fiber (metal fiber) (NASLON), which is a material selected in Example 2-1A, which is a very fine wire representing a specific resistance value, which performs only a full heating operation, has a thickness of 0.009635 mm2 and a resistance value of 90.3 kPa. The fine wire in the resistance value classification group having a resistance value similar to that of

As the ultrafine wires having similar resistances, the fine wires having a resistance value of 90 μs (fine wire thickness of 0.00785 mm 2) per 1 m length made of SUS 316 as a stainless steel alloy are most similar. If you select 90 strands and combine them into one combination to make them into one bundle by combining them together to make them into one bundle, this bundle becomes a hot wire having a low resistance value of 1 당 per 1m length. Will satisfy 2-2B,

In particular, even in the state in which a micro fine wire is prepared only in the center of the resistance value and cannot be obtained from the material center, the condition of Example 2-2A as seen in another method from the first method (the same condition as in Example 1-1 of the first method) Results in satisfying

Proving again by the formula, the selected material is a stainless steel alloy, and the composite resistance value of 90 ultra fine wires having a resistance value of 90 mV (micro wire thickness 0.009635 mm2) made of SUS 316 is 1 ÷ [(1 / 90) X (90 strands)] = 1 ÷ 0.9999 ≒ 1 되므로, so that the selected material is a stainless steel alloy and has a resistance value of 90 당 per 1 m length made of SUS 316 (fine wire thickness 0.009635 mm2) 90 If you combine the strands into a combination to make a bundle, you can see that this bundle is a hot wire with a low resistance value of 1 kW per 1 m length.

In the following example 2-2C, it is assumed that the resistance value of another required heating wire in the present invention needs to be changed to a heating wire having a low resistance value of 0.5 kΩ per 1 m length of the heating wire.

If only the number of strands is changed (increased) to the same heating wire that satisfies Example 2-2B, it can be easily made into a heating wire having a desired low resistance value of 0.5 kΩ per 1 m length of the heating wire.

That is, the material, thickness, and resistance of the ultrafine wire (fine wire thickness 0.009635mm2) having a material of 90 저항 as resistance value per 1m of length made of SUS 316 as a stainless steel-based alloy satisfying the conditions of Example 2-2B. In the same state, in Example 2-2C, only the number of strands is increased (modified) from 90 strands to 180 strands to form them in one combination, and then synthesized and assembled into one bundle. It becomes a heating wire having a low resistance value of 0.5 kV, which is a heating wire that satisfies the condition (modified to have a lower resistance value lower than that in this example 2-2B).

If this is proved again by the formula, the composite resistance value of 180 fine wires having the same resistance value as 90m per 1m length satisfying the condition of Example 2-2B = 1 ÷ [(1/90) X (180 strands)] = 1 ÷ 1.9999 = 0.5 ,, so if the same ultrafine wire that satisfies the conditions of Example 2-2B is changed (increased) from only 90 strands to 180 strands and bundled into one combination, this bundle is immediately It is possible to make a change to a heating wire having a low resistance value of 0.5Ω per 1m length.The heating wire has the same low resistance value but the thickness becomes thinner and the number of strands increases. I can make it.

In conclusion, when comparing Examples 2-2A, 2-2B, and 2-2C, only one of the categories classified as resistance value, thickness, material, and function is selected (in Example 2-2A, Select only one type as the type) Select the ultra fine wire, change the thickness again within the selected classification group (Example 2-2B, if the same classification type group is selected as the resistance value classification type, change the ultra fine wire to change the resistance Change the thickness in changing one or more of the thickness and function and material except for the change of value only), and in addition to this, the number of strands for the same fine line with the selected thickness is changed only (Example 2-2C) As a result of changing the combination to exit,

In a method different from the first method, in a method of changing the combination of the ultrafine wires of the <Example 13-4> and the <Example 13-5>, a change that more effectively fits the desired specification (purpose) ( Desired examples of the examples 1-1 and 1-2 = effective change of the resistance value) can be achieved,

In particular, despite the ultra-fine lines in the same representative classification group (called resistance value), the thickness of another item except for the corresponding item in the classification group is changed again (thinner), thereby changing the number of strands (compared to Example 2-2A above). About 3.6-fold increase), the heating wire having a low resistance value, which is a basic object of the present invention, can be more easily produced by the first method and another method.

At the same time, it can be seen that it can make the heating wire more flexible as an additional purpose.

③ If only one kind of classification type group is selected as the function type, the micro fine line is changed again within the classification type group selected by this function, so that any one or more of the material, thickness and resistance value except the function change is changed. In order to further explain how to change the number of strands to the same fine line again in the final selected fine line,

Taking Example 2-3A, for example, the same as Example 1-1 of the first method, it is intended to make the resistance value of the heating wire required by the present invention into a heating wire having a low resistance value of 1 당 per 1 m length of the heating wire. When the condition of the present 2-3A is met, the condition of the present example 2-3A can be satisfied by the method different from the first method.

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Among the types of fine wires classified, direct current (DC) safety low voltages (especially voltages of 24 VDC or less) to facilitate the change of the resistance value more effectively in the process of making the heating wire having a lower resistance value. When selected, a micro wire with a function that meets the specification in the class of functions, which is a micro wire that represents a particular function to make the desired heating behavior more effective, is selected (selected).

That is, a fine wire having a resistance of 11 mV is selected for each 1 m length made of the nickel copper alloy metal, and the selected fine wires are the same as the one of the 11 strands in one combination. When the bundle is made into a bundle and energized and synthesized, the bundle becomes a hot wire having a low resistance value of 1 kW per 1 m length, which satisfies the condition of Example 2-3A.

To prove this again, select 11Ω as the resistance value per 1m length made of nickel-copper alloy metal, and then select the composite resistance value of 11 strands of fine wire = 1 ÷ [(1/11) X ( 11 strands)] = 1 ÷ 0.9999 ≒ 1 되므로, so that the selected material is made of nickel-copper alloy metal and selects 11 으로 as the resistance value per 1m in length, and synthesizes the 11 fine strands selected as one combination. If you make one bundle, you can see that this bundle is a hot wire with a low resistance value of 1kW per 1m length.

In the following Example 2-3B, in Example 2-3A, the material is designated as a function group, and secondly, the material is changed and selected from the fine lines selected from the functional classification group, that is, the above example 2-3A. If the material is selected to be different from that of (in other words, the item of material is changed again within the classification group of the function), the effect that the first method wants to obtain (the effect of increasing flexibility) can be further increased. have.

In practice, the resistance value can be more easily changed in the process of making a heating wire having a low resistance value among the ultrafine wires prepared through a preliminary experiment in order to implement the present invention in Example 13-7. DC, which is a safety low voltage (especially a voltage of 24V DC or less), which is different from the above example 2-3A among the ultrafine wires representing a specific function for causing the desired heating operation more effectively when electricity flows. Made of iron chromium alumina molybdenum alloy metal, which is an ultra fine wire of the material (change of material), having a resistance of 48 kΩ (fine wire thickness of 0.015386 mm2) per 1 m length (ex. The function to produce is the same, and the materials are different.) Synthetic assembly by selecting the 48 fine wires and combining them into one combination. If the bundle is made into a bundle, the bundle becomes a hot wire having a low resistance value of 1 당 per 1 m length, which satisfies this example 2-3B,

In particular, a result of satisfying the example 2-3A condition (the same condition as the first method example 1-1) is obtained in another manner from the first method.

Proving again by the formula, the synthetic resistance value of 48 strands of ultrafine wires having 48 Ω (fine wire thickness 0.015386 mm2) as resistance value per 1m length made of iron chromium alumina molybdenum alloy metal = 1 ÷ [(1 / 48) X (48 strands)] = 1 ÷ 0.99 ≒ 1 되므로, so that the selected material is made of iron chromium alumina molybdenum alloy metal, and has 48 극 (fine wire thickness 0.015386 mm2) with a resistance value of 1 길이 (fine wire thickness 0.015386 mm2) When synthesized into a combination to make a bundle, it can be seen that this bundle is a hot wire having a low resistance value of 1 kW per 1 m length.

In the following Example 2-3C, when it is assumed that the resistance value of another required heating wire in the present invention needs to be changed to a heating wire having a low resistance value of 0.5 kΩ per 1 m length of the heating wire,

If only the number of strands is changed (increased) to the same heating wire that satisfies Example 2-3B, it can be easily made into a heating wire having a desired low resistance value of 0.5 kΩ per 1 meter length of the heating wire.

That is, in the state in which all are the same as the ultrafine wires made of iron chromium alumina molybdenum alloy metal satisfying the conditions of the above examples 2-3B and having 48 kW (fine wire thickness 0.015386 mm 2) as a resistance value per 1 m length, this example 2- In 3C, the number of strands is increased (modified) from 48 strands to 96 strands to form them as a combination, and then synthesized and assembled into a bundle, and this bundle uses the conditions shown in Example 2-3C (Example 2-3B). It becomes a heating wire having a low resistance value of 0.5 kV, which is a satisfying heating wire (modified to have a lower resistance value than the condition of).

If this is again proved by the formula, the resistance value per 1m length made of iron chromium alumina molybdenum alloy metal (the same class of function and the same material) satisfying the conditions of Example 2-3B is 48 kW (fine wire The thickness of 0.015386 mm2) is 96. The combined resistance value of the 96 fine wires is 1 ÷ [(1/48) X (96 strands)] = 1 ÷ 1.9999 ≒ 0.5 Ω, so that the same fineness that satisfies the conditions of Example 2-3B is satisfied. By changing (increasing) the number of strands from 48 strands to 96 strands into bundles, the bundles can be changed into hot wires with low resistance of 0.5 당 per 1m length.

In this way, it is possible to make a heating wire having the same desired low resistance value but having a thinner thickness and increasing the number of strands.

In conclusion, when comparing the examples 2-3A, 2-3B, and 2-3C, only one of the categories classified as the resistance value, thickness, material, and function is selected (the type of function in the example 2-3A) Select only one type of fine line), but change the material again within the selected classify group (for example, in 2-3B, if the same type of class is selected as the functional class type, change the fine line to change the function only). Change the material in changing one or more of the thickness, material and resistance value except for this), and in addition, change the number of strands for the same fine wire with the material selected secondarily (Example 2-3C). As a result of changing the combination to

In a method different from the first method, in a method of changing the combination of the ultrafine wires of the <Example 13-4> and the <Example 13-5>, a change that more effectively fits the desired specification (purpose) ( Desired examples of the examples 1-1 and 1-2 = effective change of the resistance value) can be achieved,

In particular, despite being a microfiber in the same representative taxon (functional), the material is changed again, except for the sport in that taxon, to change the number of strands (approximately twice the number of strands in this example 2-3B). By using the method), it is easier to make a heating wire having a low resistance value, which is a basic object of the present invention, by another method than the first method.

At the same time, it can be seen that it can make the heating wire more flexible as an additional purpose.

④ If the classification type group selected by only one type is selected as the thickness type, the micro fine line is changed again within the classification type group selected by this thickness, and then changed to one or more of materials, functions, and resistance values except for changing the thickness. In order to explain in detail how to change the number of strands to the same fine line again in the final selected fine line,

For example 2-4A, for example, the same as in the example 1-1 of the first method, it is to make the resistance value of the heating wire required by the present invention to a heating wire having a low resistance value of 1 당 per 1m length of the heating wire Assuming that the condition of the present 2-4A, the condition of Example 2-4A can be satisfied by a method different from the first method.

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Among the types of fine wires classified, direct current (DC) safety low voltages (especially voltages of 24 VDC or less) to facilitate the change of the resistance value more effectively in the process of making the heating wire having a lower resistance value. As it flows, it selects (selects) a fine wire with a thickness that meets the specification in the class of thickness, a fine wire that represents a specific thickness to make the desired heating behavior more effective.

That is, a fine wire having a fine wire thickness of 0.00785 mm2 (per 1 m length, resistance of 36 kW) made of a nickel-copper alloy metal is selected, and synthesized using the same combination of 36 strands with the same selected fine wire. When assembled (closely assembled to be electrically synthesized in the length direction) to form a bundle, this bundle becomes a hot wire having a low resistance value of 1 kW per 1 m length, which satisfies the condition of Example 2-4A.

If this is proved again by the formula, select the ultra fine wire made of nickel-copper alloy metal with a fine wire thickness of 0.00785 mm2 (36 m resistance per 1 m length), and the synthetic resistance value of the 36 fine wires thus selected = 1 ÷ [(1/36) X (36 strands)] = 1 ÷ 0.9999 ≒ 1 ,, so the fine wire having a fine wire thickness of 0.00785 mm2 (36 저항 resistance per meter of length) made of nickel-copper alloy metal If you select and combine the 36 selected fine wires into one bundle to make a bundle, this bundle becomes a hot wire with a low resistance value of 1 당 per 1m length, which satisfies the condition of Example 2-4A. It can be seen that.

In the following Example 2-4B, according to the above Example 2-4A, while the classifier group is set to the thickness, the resistance value is changed to the second fine lines selected from the thickness classifier again, that is, the Example 2--4. If the resistance value is selected to be different from that of 4A (that is, the ultrafine wire thickness is 0.00785mm2 in the above examples 2-4A and 0.00785mm2 in the above examples 2-4B. It is possible to further increase the effect (the effect of improving flexibility), which is intended to be obtained in the first method.

In practice, the resistance value can be more easily changed in the process of making a heating wire having a low resistance value among the ultrafine wires prepared through a preliminary experiment in order to implement the present invention in Example 13-7. Among the ultra-fine wires representing a specific thickness for more effectively generating a desired heat generation operation when electricity flows, the DC safety low voltage (especially a voltage of DC 24V or less), and the thickness of the above example 2-4A Is the same, but the fine wire having a different resistance value (changing the resistance value), which is made of iron chromium alumina molybdenum alloy metal, has a fine wire thickness of 0.00785 mm 2 (per m of length, resistance of 82 kV) (see Example 2-4A). When the thickness is the same and the resistance value is different) If 82 fine strands are selected and these are combined into one combination, they are synthesized (adherently assembled to be electrically synthesized in the length direction) to form one bundle. This bundle is a hot wire having a low resistance value of 1 kW per 1 m length, which satisfies Example 2-4B.

In particular, the results of satisfying the conditions of Example 2-4A (the same conditions as those of the first method of Example 1-1) in a different manner from the first method.

Proving again by the formula, the composite resistance value of 82 ultra-fine wires having a thickness of 0.00785 mm2 (per m length, resistance of 82 kW) made of iron chromium alumina molybdenum alloy metal = 1 ÷ [(1/82) X (82 strands)] = 1 ÷ 0.9999 ≒ 1 되므로, so that the selected material is made of iron chromium alumina molybdenum alloy metal, and the 82 fine strands 82 strands having a thickness of 0.00785 mm2 (per resistance of 82 m) are combined in one combination. Synthesized into a bundle, it turns out that the bundle is a hot wire with a low resistance of 1 Ω per 1m length.

In the following Example 2-4C, it is assumed that the resistance value of another required heating wire in the present invention needs to be changed to a heating wire having a low resistance value of 0.5 kΩ per 1 meter length of the heating wire.

If only the number of strands is changed (increased) to the same heating wire that satisfies the above Example 2-4B, it can be easily made into a heating wire having a desired low resistance value of 0.5 kΩ per 1 m length of the heating wire.

That is, in Example 2, the ultrafine wire having a thickness of 0.00785 mm 2 (a resistance of 82 kPa per 1 m in length) made of iron chromium alumina molybdenum alloy metal satisfying the conditions of the above Examples 2-4B was all in the same state. In -4C, if the number of strands is increased (modified) from 82 strands to 164 strands to form them in one combination, and then synthesized and assembled into one bundle, the bundle is the condition shown in Example 2-4C (Example 2-4B). It becomes a heating wire having a low resistance value of 0.5 kV, which is a heating wire that satisfies the change) to have a lower resistance value than the condition of.

If this is proved again by the formula, it is made of iron chromium alumina molybdenum alloy metal, which is the same (the same as the classification group called the thickness and the actual thickness, and the same material and resistance value) satisfying the conditions of Example 2-4B, thickness 0.00785 mm2 Synthetic resistance value of 164 strands of ultrafine wires (per resistance length of 82 m) = 1 ÷ [(1/82) X (164 strands)] = 1 ÷ 1.9999 ≒ 0.5 Ω, so the conditions of Example 2-4B If the same ultrafine wire that satisfies the requirements is changed (increased) from only 82 strands to 164 strands and bundled into a combination, this bundle is changed into a hot wire having a low resistance value of 0.5 당 per 1m length. To meet the requirements of Example 2-4C,

In this way, it is possible to make a heating wire having the same desired low resistance value but having a thinner thickness and increasing the number of strands.

In conclusion, comparing Examples 2-4A, 2-4B, and 2-4C, selects only one of the classification categories classified as resistance value, thickness, material, and function (in Example 2-4A, the thickness is Select only one type of fine line, but select the fine line by changing the resistance value again within the selected classify group (Example 2-4B, if the same type of class is selected as the thick type, change the fine line Change the resistance value in any one or more of the functions, materials, and resistance values except bays), and in addition, change only the number of strands for the same micro wire with the selected resistance value in this example (Example 2-4C) ) As a result of changing the combination out of

In a method different from the first method, in a method of changing the combination of the ultrafine wires of the <Example 13-4> and the <Example 13-5>, a change that more effectively fits the desired specification (purpose) ( Desired examples of the examples 1-1 and 1-2 = effective change of the resistance value) can be achieved,

In particular, even though it is a fine line in the same representative classification group (called “weight”), the resistance value, which is another item except the corresponding item in the classification group, is changed again, thereby changing the number of strands (about 2 times compared to this example 2-3B). Increase), it is easier to make a heating wire having a low resistance value which is a basic object of the present invention by another method than the first method,

At the same time, it can be seen that it can make the heating wire more flexible as an additional purpose.

In the third method, the heating wire to be made in the present invention is made to perform a specific function while making the number of fine wire strands among the desired specifications smaller than the first method or the second method and at the same time lowering the resistance value to a low resistance value. One of the methods used when an effective combination of fine wires is needed,

Among all the ultrafine wires prepared in Example 13-4, any two or more classification type groups are selected from the group of categories classified by resistance value, thickness, material, and function, and each strand is selected by one strand. Each of the above-mentioned choices are made by combining at least two types of micro fine lines selected from different classification types, and a combination is made so that the total number of micro fine lines is at least two strands. In other words, the selection of the selections in the <Example 13-5> and the <Example 13-6> is changed to change the combination of the fine lines of the <Example 13-4> and the <Example 13-5>. This is a way to make it more effective.

In order to explain this in more detail, the first example 3-1 will be described. As the heating wire required by the present invention, the number of ultra-fine wire strands can be reduced as much as possible. When it is a condition of this example 3-1 to make a heating wire having a low resistance value and having a specific function (a function of causing a desired heating operation more effectively among various specific functions) in parallel,

In order to satisfy the condition of Example 3-1, a combination of ultrafine wires selected from one of the four classification groups and one of two types of resistance values is combined, and the functional classification group provides a function to more effectively generate a desired heating operation. Branches are selected by the fine wire, and the resistance value classification group selects the fine wire which can easily match the low resistance value, and combines the fine wires in the two selected classification groups to form a combination and bundle them.

In order to satisfy the conditions of the present Example 3-1, the method described above may be selected in the form of a combination of two or more classification types in a single fine line.

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Of the types of ultrafine wires to be classified, it may be selected from the ultrafine wires prepared through a preliminary experiment to implement the present invention in the <Example 13-7>,

As the first type, it is selected by the functional classification group, and it is to be selected as a micro wire having a function of causing a desired heat generation more effectively, but to be used as short as possible, so as a micro wire suitable for this,

The material is made of nickel-copper alloy metal, and 10 fine wires having a resistance value of 11 Ω (fine wire thickness of 0.025434 mm²) per 1 m length are selected, and the other second type is selected from the resistance value classification group. It is a fine wire that reduces the resistance more effectively, but the number of strands should be selected to be used as small as possible.

The fine wire is made of copper, and 1 strand of fine wire having a resistance value of 0.1098Ω (fine wire thickness 0.1538mm2) per 1m length is selected, and a total of 11 fine wires are assembled in one combination. When the bundle is made into one bundle, this bundle is a hot wire having a low resistance value of 0.1Ω per 1m of the desired heating wire, and at the same time, it performs a specific function (more heat generation among various specific functions). It becomes a hot wire having a function to effectively produce) to satisfy the condition of Example 3-1.

To prove this again, the classification of one of the selected ultrafine wires is a functional classification, a fine wire made of nickel-copper alloy metal, and has an ultrafine wire having a resistance value of 11Ω (fine wire thickness of 0.025434 mm2) per 1m in length. It is good.

The next classification group is a classification group of resistance values, which is a fine wire made of copper, and has a resistance value of 0.1098Ω (fine wire thickness 0.1538 mm 2) per 1m in length.

Therefore, each of the two types of the fine group is selected by combining the fine wires, respectively, by adjusting the number of strands selected, nickel copper alloy metal is selected to 10 strands, the fine wires made of copper selected only one strand these fine wires You can synthesize by combining

Synthetic resistance value = 1 ÷ (1 / 11X10 strands) + (1 / 0.1098X1 strands) = 1 ÷ (0.9090 + 9.1074) = 1 ÷ 10.0164 ≒ 0.1,

Example 3-1 A hot wire having a low resistance value of 0.1 kW under a condition, and at the same time a hot wire having a function of causing a desired heat generation operation more effectively (the nickel copper alloy metal is described in <Example 13-7 In order to implement the present invention in the pre-experimental experiments because it is proved to be a fine wire that is the desired heating operation).

Secondly, referring to Example 3-2, for example, Example 3-2, which has the same target as Example 3-1 but differs only in a few conditions, can be seen as a heating wire required by the present invention. The number of strands can be reduced and used as much as possible.They are wires with a low resistance value of 0.1Ω per 1m of heating wire, and at the same time, they can be used to make specific heating function more effective. Function), but the pre-prepared micro wire is not made of copper belonging to the resistance value classification group, and there is a micro wire with similar resistance but different material is prepared. When we said condition of,

In order to satisfy the condition of the present Example 3-2, a combination of ultrafine wires selected from one of the four classification groups and one of the two types of materials is combined. The functional classification group has a function of causing a desired heat generation operation more effectively. The fine wire is selected, and the material classification group selects the fine wire that can easily match the low resistance value in the material classification group having the resistance value most similar to the fine wire selected in the resistance value classification group in Example 3-1. The microfibers in the classifiers are combined to form a composite, bundled into bundles.

If the above-described method is actually implemented, in order to satisfy the conditions of the present Example 3-2, in selecting the fine line to form a combination of two or more classification types,

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Of the types of ultrafine wires to be classified, it may be selected from the ultrafine wires prepared through a preliminary experiment to implement the present invention in the <Example 13-7>,

The first type is selected from the functional classification group, which is a fine wire having a function of causing a desired heat generation more effectively, but should be selected as being able to be used if the number of strands can be reduced. Is made of nickel-copper alloy metal, and selects 6 fine wires having a resistance value of 11Ω (microwire thickness 0.025434mm²) per 1m length,

The other second type is selected from the material classification group, which should be selected as a micro wire that reduces the resistance more effectively, but can be used as short as possible. A fine wire made of silver material with a similar resistance but different material from copper fine wire in the resistance classification group selected in the method satisfying the condition of 3-1. 0.1531㎜ thick) choose one strand of ultra fine wire,

When these 7 fine wires are totally assembled into one bundle by combining them into one bundle, this bundle is a hot wire having a low resistance value of 0.1Ω per 1m of the desired heating wire. At the same time, it becomes a hot wire having a specific function (a function of causing a desired heat generation operation more effectively among various specific functions) to satisfy the condition of this Example 3-2.

To prove this again, the classification of one of the selected ultrafine wires is a functional classification, a fine wire made of nickel-copper alloy metal, and has an ultrafine wire having a resistance value of 11Ω (fine wire thickness of 0.025434 mm2) per 1m in length. It is good.

The next classification group is the classification group of the material, which is a fine wire made of silver, and having a resistance value of 0.1058Ω (fine wire thickness 0.1531mm2) per 1m length.

Therefore, the two fine groups selected from each of the two types of combinations, but by adjusting the number of strands of each selected, the copper copper alloy metal is selected to 6 strands, the fine wire made of silver is selected only one strand these microfine wires You can synthesize by combining

Synthetic resistance value = 1 ÷ (1 / 11X6 strands) + (1 / 0.1058X1 strands) = 1 ÷ (0.5454 + 9.4517) = 1 ÷ 9.9971 ≒ 0.1 되므로

In the present Example 3-2 conditions, a heating wire having a low resistance value of 0.1 kW is desired, and at the same time, a heating wire having a function of causing a desired heating operation more effectively (the nickel copper alloy metal is described in <Example 13-7>). In order to implement the present invention in the pre-experimental experiments because it has been proved to be the ultrafine wire to the desired heating operation).

Third, referring to Example 3-3, for example, in Example 3-3, the target is the same as Example 3-1 but only slightly different conditions. It is a hot wire having a low resistance value of 0.1Ω per 1m length of heat wire, and at the same time, it is intended to make a hot wire having a specific function (a function that makes a desired heating operation more effective among various specific functions), but the number of fine wires can be When it is said that the condition of this example 3-3 is to make a heating wire to increase the flexibility to increase the flexibility,

In order to satisfy the conditions of the present Example 3-3, a combination of ultrafine wires selected from one of the four classification groups and one of the two types of thickness groups, respectively, is combined, and the functional classification group has a function of causing a desired heat generation operation more effectively. Select the fine line, and in the thickness classification group, the material is the same as the fine line that satisfies the conditions in Example 3-1, but by selecting the fine line that is different in thickness belonging to the thickness classification group (so that the number of strands increases as the flexibility increases) In this way, it is possible to make a combination of the ultrafine wires in the two selected taxon groups, and then synthesize and bundle them.

When the above-described method is actually implemented, in order to satisfy the conditions of the present Example 3-3, in selecting the micro fine lines in one combination with two or more classification types,

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Of the types of ultrafine wires to be classified, it may be selected from the ultrafine wires prepared through a preliminary experiment to implement the present invention in the <Example 13-7>,

The first type is selected from the functional classification group, which is a fine wire having a function of causing a desired heat generation more effectively, but should be selected as being able to be used if the number of strands can be reduced. Is made of nickel-copper alloy metal, and selects 16 fine wires having a resistance value of 11Ω (fine wire thickness of 0.025434mm²) per 1m length,

The other second type is selected from the thickness classification group, which is a fine line that reduces the resistance more effectively, but should be selected to increase the number of strands if possible to improve flexibility, so that the fine As the wire, the material is the same as the copper fine wire in the resistance classification group selected in the method of satisfying the condition of Example 3-1, but the material is made of copper with different thickness (thinner) belonging to the thickness classification group. Among the fine wires, two fine wires having a fine wire thickness of 0.0718 mm2 (resistance value of 0.235 mW per 1 m length) are selected,

A total of 18 strands of these ultrafine wires are assembled into one bundle to make one bundle, and this bundle is a hot wire having a low resistance value of 0.1Ω per 1m length of the desired heating wire. At the same time, it becomes a hot wire having a specific function (a function of causing a desired heating operation more effectively among various specific functions) to satisfy the condition of the present Example 3-3.

To prove this again, the classification of one of the selected ultrafine wires is a functional classification, a fine wire made of nickel-copper alloy metal, and has an ultrafine wire having a resistance value of 11Ω (fine wire thickness of 0.025434 mm2) per 1m in length. It is good.

The next classification group is the classification group of thickness, which is a fine wire made of copper, and a fine wire having a thickness of 0.0718 mm2 (0.235 kW resistance per 1 m length).

Therefore, each of the two types of fine group selected by the combination of fine wires, and by adjusting the number of strands, each of the nickel copper alloy metal selected 16 strands, the fine wire made of copper is a fine wire 0.0718mm2 thick You can select only two strands and combine these microwires.

Synthetic resistance = 1 ÷ (1 / 11X16 strands) + (1 / 0.235X2 strands) = 1 ÷ (1.45454 + 8.5106) = 1 ÷ 9.9651 ≒ 0.1 ≒

In the present Example 3-2 conditions, a heating wire having a low resistance value of 0.1 kW is desired, and at the same time, a heating wire having a function of causing a desired heating operation more effectively (the nickel copper alloy metal is described in <Example 13-7>). In order to implement the present invention in the pre-experimental experiments because it is proved to be the ultrafine wire to the desired heating operation).

In conclusion, the third method, as described in all of the first to third examples, the fine lines according to the desired specifications in any two or more of the four categories classified as resistance value, thickness, material, function One or more strands are selected for each classification type to form one combination by combining two or more of the selected microfine lines, and each combination is made so that the total number of microfine lines is at least two strands. As a way to,

Even in the state where the number of strands of the ultra fine wire is significantly smaller than that of the first method or the second method, the low resistance value can be easily achieved, and in addition, it can be confirmed that it is a method of making a hot wire that can simultaneously implement a specific function. have.

In a fourth method, the wire to be made according to the present invention can be made to be finer than the first or second method while the total number of fine wires inside the bundle of one of the desired specifications is smaller than that of the first or second method. The third method is used when a method of combining fine wires which is more effective in performing a specific function and at the same time lowering the resistance value to a low resistance value while slightly increasing the number of strands is secured to some extent. Is another way,

Among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires is selected from any two or more types of classification groups classified by resistance value, thickness, material, and function. One or more strands are selected for each type, and the selected ultrafine wires are selected from the group of resistance values, thicknesses, materials, and functions in the same category. In this way, the selected microfiber line is additionally selected (changed) in such a way as to be a microfiber line that is changed back to any one of the classified categories except for the above. One combination is made through, and the combination is made so that the total amount of fine wire is made of at least two strands, that is, the < 13-5> and the method of changing the selection in the <Example 13-6> to more effectively achieved by changing the combination of the fine lines of the <Example 13-4> and <Example 13-5> It will be.

The fine wire selected in this way is changed again to any one of the classification types except for the type corresponding to the selected classification type group among the resistance value, thickness, material, and function type within the same classification type group. How to make it become

① If any one of the selected classification type groups is selected as the material type, the fine line is changed again within the classification type group selected by this material to change to one or more of thickness, function and resistance value except for material change only.

② If any one of the selected classification type groups is selected as the resistance value type, change the extra fine line again within the classification type group selected by this resistance value and change to one or more of thickness, function and material except for the change of resistance value. ,

③ If any one of the selected classification type groups is selected as the function type, the fine line is changed again within the classification type group selected by this function, and then changed to at least one of material, thickness and resistance value except for the function change.

④ When any one of the selected classification type groups is selected as the thickness type, the fine line is changed again within the classification type group selected by this thickness, so that any one or more of materials, functions, and resistance values except the thickness change are changed. Means any one or more methods.

To explain this in more detail, select from two or more kinds of classification categories classified by resistance value, thickness, material, and function (at least two kinds of four kinds), and then again from the selected classification category group. Among the two or more classification categories selected above, one of the three classification groups is different from the other three categories except the selected one.

That is, if the selection in the third method is a method of selecting from any two or more of four classification type groups and changing the selection from four types of groups to change the classification type group itself,

The selection in the fourth method is performed by selecting each of the two or more kinds of classification group groups selected in the third method, and in each of the selected classification group groups, 4 as shown in 1) to 4) below. There are additional secondary selection changes in two ways, so that at least one extra fine line is finally selected from each taxa itself, and the whole fine line inside a combination creates a bundle (one strand of hot wire). In this regard, the selected ultrafine wires are combined in at least two strands.

If the following four methods of ① ~ ④ are explained in more detail,

For example, among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires may be selected from any two or more types of classification groups classified by resistance value, thickness, material, and function. For example, using the method of ② and ③, the method of selecting a second change in each classification group is described as follows.

For example, Example 3-1 of the third method is the same as the target of the same but slightly different conditions Example 4-1, as a heating wire required by the present invention, a bundle of one of the desired specifications (heating wire Selecting that it can be used with a certain amount of flexibility by slightly increasing the total number of fine lines compared to the third method while reducing the total number of fine lines inside the first method or the second method. In this example, a heating wire having a low resistance value of 0.1Ω per 1m length of the heating wire and at the same time as a heating wire having a specific function (a function that causes a desired heat generation operation more effectively among various specific functions) is made. When we said condition of,

In the first example of the third method, one kind is selected from the functional classification group, and a fine wire having a function of causing a desired heating operation more effectively is selected.

The other one is selected from the resistance classification group, which is a fine wire that reduces the resistance more effectively, but can be used as short as possible.

In the first example of the fourth method, the method of utilizing the four methods, such as ① to ④, selects each of the two types of ultrafine wires selected as described above by the first example in the third method, and then selects the secondary change again. In a way,

In the first type, the classification group is the classification group of functions according to the first example of the third method, and according to the method 3 of the fourth method, the second selection is changed again, so that the function is changed again within the functional classification group. Change to at least one of material, thickness, and resistance value except for the final selection.

In the remaining second type, since the classification group is the classification group of the resistance value according to the first example of the third method, in accordance with the method (2) of the fourth method, the classification group selected again changes the secondary selection. As it is a classification group of, it is changed to one or more of material, thickness and function except the resistance value, and finally, the fine wire is selected to be one or more strands,

In this way, if a combination of two fine wires finally selected according to method ③ and method ② of the fourth method is combined to form a bundle in a synthetic assembly method, the bundle satisfies the condition of Example 4-1. do.

If this is actually carried out, among all the prepared ultra-fine wires of <Example 13-4>, prepared or prepared in advance, or those prepared through actual experiments for the present invention in <Example 13-7>, or existing distribution Among the ultrafine wire types classified into numerous various resistance values, thicknesses, materials, and functions which are databased of the fine wires, which are prepared in the <Example 13-7>, among the ultrafine wires prepared through a preliminary experiment to implement the present invention. You can select

In the first type, it is selected from the functional classification group. In the first example of the third method, the microfine wires made of nickel copper alloy metal have a thickness of 0.025434 mm 2 (resistance value per 1 m length is 11 kW). Compared to 10 strands,

In the first example of the fourth method, based on the above method ③, that is, a bundle of one of the desired specifications, which is a micro wire having a function of causing the desired heating operation more effectively, which is the condition of this example 4-1, ) It is selected as a micro fine wire suitable for maintaining the degree of flexibility by slightly increasing the total number of fine wires compared to the third method while reducing the total number of fine wires inside the first method or the second method. In order to,

The thickness is changed to a thinner than the first example of the third method, that is, it is an ultrafine wire made of nickel copper alloy metal, which is the same functional classification group, and has a thickness of 0.00785 mm2 (resistance per length of 36 m). Select the same micro wire with 54 strands,

In the second type, the resistance value classification group is selected. In the first example of the third method, a thickness of 0.1538 mm 2 (resistance value per 1 m length) of the ultrafine wires made of copper is used for the material belonging to the resistance value classification group. In comparison with having selected the same extra-fine wire in one strand,

In the first example of the fourth method of the present invention, based on the above method (3), i.e., it is an ultra-fine wire which reduces the resistance value which is a condition of the present example 4-1 more effectively, and is inside the bundle (heating wire) of one of the desired specifications. In order to select a micro fine wire suitable for keeping the total number of fine strands smaller than the first method or the second method, but slightly increasing the total fine number of strands than the third method, so as to obtain a certain degree of flexibility,

Compared to the first example of the third method, the thickness is 0.0718 mm 2 (resistance value per 1 m length is 0.235 kW), which is changed to a finer wire made of copper metal, which is the same functional classification group, and is thinner. , Select the same fine wire into 2 strands,

When the total of 56 strands of the first type and the second type of ultrafine wires is combined into one combination, the bundles are made into one bundle by combining them in a bundle. The heating wire having the resistance value satisfies Example 4-1.

To prove this again by the formula, in the first type of the selected ultrafine wire, the classification group is the functional classification group, and the thickness of the nickel copper alloy metal having a thickness of 0.00785 mm2 (resistance value per 1m of length is 36 kW) is changed again. I choose 54 strands of the same microfine wire of the thing made with the microfine wire,

In the other second type, the classification group is a classification group of resistance values, and the same ultra-fine wire two strands of an ultrafine wire made of copper metal having a thickness of 0.0718 mm 2 (resistance value per 1m of length is 0.235 mW), which has been changed to the second thickness again. By selecting

The final selected fine wires may be combined from each of the two types of group, and the combined resistance value = 1 ÷ (1 / 36X54 strand) + (1 / 0.235X2 strand) = 1 ÷ (1.49999 + 8.5106) = 1 ÷ 10.01 ≒ 0.1 Ω This becomes

While the total number of fine wire strands in the bundle (hot wire) of one of the desired specifications under the conditions of the example 4-1 is smaller than the first method or the second method, the total number of fine wire strands is slightly smaller than that of the third method. In the state of increasing the flexibility to a certain degree, it becomes a heating wire having a low resistance value of 0.1 kW, and at the same time a heating wire having a function of causing a desired heat generation operation more effectively (the nickel copper alloy metal is described in <Example 7 In order to implement the present invention in the pre-experimental experiments, because it is proved to be a fine wire that the desired heating operation).

For example, among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires may be selected from at least two classification type groups among the kind groups classified by resistance value, thickness, material, and function. For example, using the method of ① and ③ above, the classification of the second classification in each classification group is selected.

For example, in Example 3-2, which is the same as that of Example 3-2 of the third method, but with only a few conditions, the Example 4-2 is a heating wire required by the present invention. Hot wire) It is selected to be able to use it in a state where the total number of fine wires inside the wire is smaller than the first method or the second method, but slightly increases the total number of fine wires than the third method, while securing some flexibility. The heating wire is a heating wire having a low resistance value of 0.1Ω per 1m length, and at the same time, it is intended to be a heating wire having a specific function (a function that makes a desired heating operation more effective among various specific functions). There is no ultrafine wire made of copper belonging to the resistance classification group, and a microfine wire made of silver having a similar resistance value but having a different material is prepared. When we said condition of 2,

In the second example of the third method, one kind is selected from a functional classification group, and a fine wire having a function of causing a desired heating operation more effectively is selected.

The other type is selected from the material classification group, which can be used to reduce the resistance value more effectively, but to reduce the number of strands as much as possible.

In the second example of the fourth method, the method of utilizing the four methods as described in (1) to (4) above, selects each of the two kinds of ultrafine lines selected as described above by the second example of the third method, and selects the second change again. In a way,

In the first type, the classification group selected by the second example of the third method is a classification group of functions, and according to the method (3) of the fourth method, the secondary selection is changed again. Except for the function, change to at least one of material, thickness, and resistance value, and finally select the fine wire as one or more strands,

In the remaining second type, the classification group selected by the second example of the third method is a classification group of materials, and according to the method 1 of the fourth method, the selected classification group is again changed in the second selection. As it is a classification group of, it is changed to any one or more of resistance value, thickness and function except for material, and finally, the fine wire is selected as one or more strands,

In this way, if the combination of the two strands of the final finely selected according to the method ③ and ① of the fourth method is combined to form a bundle in a synthetic assembly method, the bundle satisfies the condition of Example 4-2. do.

If this is actually carried out, among all the prepared ultra-fine wires of <Example 13-4>, prepared or prepared in advance, or those prepared through actual experiments for the present invention in <Example 13-7>, or existing distribution Among the ultrafine wire types classified into numerous various resistance values, thicknesses, materials, and functions which are databased of the fine wires, which are prepared in the <Example 13-7>, among the ultrafine wires prepared through a preliminary experiment to implement the present invention. You can select

In the first kind, it is selected from the functional classification group. In the second example of the third method, an ultrafine wire made of nickel copper alloy metal has the same ultrafine wire having a resistance value of 11 kW (microwire thickness 0.025434 mm2) per 1 m length. Compared to 6 strands,

In the second example of the fourth method, based on the above method ③, that is, a bundle of one of the desired specifications, which is a micro wire having a function of causing the desired heating operation more effectively, which is the condition of this example 4-2, to be produced. (Hot wire) A fine wire suitable for keeping the total number of fine lines inside the wire smaller than the first method or the second method but slightly increasing the total number of fine wires than the third method so as to obtain a degree of flexibility. To choose

The thickness is changed to a thinner than the second example of the third method, that is, it is an ultrafine wire made of nickel copper alloy metal, which is the same functional classification group, and the thickness is 0.00785 mm2 (resistance value per 1m of length is 36 kW). , Select the same fine line as 61 strands,

In the second type, the material classification group is selected. In the second example of the third method, the material is different from the copper fine wire in the resistance value classification group but has a similar resistance value. While we selected one strand of microfine wire having 0.1058 Ω (fine wire thickness 0.1531mm2) of resistance,

In the second example of the fourth method, based on the above ① method, i.e., it is an ultra-fine wire which reduces the resistance value more effectively, which is the condition of the present example 4-2, but inside the bundle (heating wire) of one of the desired specifications. In order to select the fine wire which is suitable for maintaining the degree of flexibility by slightly increasing the total number of fine wires rather than the third method while reducing the total number of fine wires of the first method or the second method ,

Compared to the second example of the third method, the thickness is changed to be thinner, that is, the fine material is made of silver of the same material classification group, and the thickness is changed to 0.06721 mm2 (0.241 kΩ resistance per 1 m length). Select the line into 2 strands,

When the first type and the second type of ultrafine wire 63 strands are combined into one combination, they are synthesized into one bundle by energizing and synthesizing them in a lengthwise direction, and the bundle has a low resistance of 0.1 kΩ per 1 m length. It becomes the hot wire which has a value, and satisfy | fills this example 4-2.

To prove this again by the formula, in the first type of the selected ultrafine wire, the classification group is the functional classification group, and the thickness of the nickel copper alloy metal having a thickness of 0.00785 mm2 (resistance value per 1m of length is 36 kW) is changed again. I select 61 strands of the same micro wire of the thing made with the micro wire,

In the second type, the classification group is a classification group of materials, and is a micro fine wire made of silver, which is a material classification group, which is changed again to second thickness, and the thickness is changed to 0.06721 mm 2 (resistance value of 0.241 kPa per 1 m of length). Select 2 strands of ultra fine wire,

The final selected fine wires may be combined from each of the two types of group, and the combined resistance value = 1 ÷ (1 / 36X61 strand) + (1 / 0.241X2 strand) = 1 ÷ (1.6944 + 8.2987) = 1 ÷ 9.9931 ≒ 0.1 하면 This becomes

While the total number of fine wire strands inside the bundle (hot wire) of one of the desired specifications under the conditions of the example 4-2 is smaller than the first method or the second method, the total number of fine wire strands is slightly smaller than that of the third method. In the state of increasing the flexibility to a certain degree, it becomes a heating wire having a low resistance value of 0.1 kW, and at the same time a heating wire having a function of causing a desired heat generation operation more effectively (the nickel copper alloy metal is described in <Example 7 In order to implement the present invention in the pre-experimental experiments, because it is proved to be a fine wire that the desired heating operation).

For example, among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires may be selected from any two or more types of classification groups classified by resistance value, thickness, material, and function. For example, using the method of ③ and ④ above, a second change in each classification group is selected.

 For example, in Example 3-3 of Example 3-3, which is the same as that of the third method, but with only a few conditions, the Example 4-3 is a heating wire that is required by the present invention. In addition to being a heating wire having a low resistance value, in parallel with a specific function (a function that makes a desired heating operation more effective among various specific functions) to be made as a heating wire, the number of fine wire strands as much as possible (the third method above) When the condition of Example 4-3 is to create a heating wire that improves flexibility by having more strands than Example 3-1,

In the third example of the third method, one kind is selected from a functional classification group, and a fine wire having a function of causing a desired heating operation more effectively is selected.

The other type is selected from the thickness group, which can be used to reduce the resistance more effectively, but to reduce the number of strands as much as possible, compared to selecting the fine line belonging to the thickness group. ,

In the third example of the fourth method, the method of utilizing the four methods as described in (1) to (4) above is to secondly change and select each of the two types of ultrafine lines selected as described above by the third example of the third method. In a way,

In the first type, the classification group selected by the third example of the third method is a classification group of functions, and according to the method 3 of the fourth method, the secondary selection is changed again, and the function is again performed within the functional classification group. Except for changing the material, thickness and resistance value to any one or more, and finally selected as one or more fine wire,

In the remaining second type, the classification group selected by the third example of the third method is the classification group of the thickness, and according to the method ④ of the fourth method, the selected classification group is again changed in thickness according to the method ④ of the fourth method. As it is the classification group of, it is changed to any one or more of resistance value, material and function except thickness, and finally selected as one or more fine wires,

In this way, if the combination of the two fine-finished wires finally selected according to the method ③ and the method ④ of the fourth method is combined to form a bundle in a synthetic assembly method, the bundle satisfies the condition of Example 4-3. do.

If this is actually carried out, among all the prepared ultra-fine wires of <Example 13-4>, prepared or prepared in advance, or those prepared through actual experiments for the present invention in <Example 13-7>, or existing distribution Among the ultrafine wire types classified into numerous various resistance values, thicknesses, materials, and functions which are databased of the fine wires, which are prepared in the <Example 13-7>, among the ultrafine wires prepared through a preliminary experiment to implement the present invention. You can select

In the first kind, it is selected from the functional classification group. In the third example of the third method, an ultrafine wire made of nickel copper alloy metal has the same ultrafine wire having a resistance value of 11 kW (microwire thickness 0.025434 mm2) per 1 m length. Compared to 16 strands,

 In the third example of the fourth method, based on the above method ③, that is, the fine line belonging to the functional classification group which causes the desired heating operation more effectively, which is the condition of the present example 4-3, becomes the number of fine line strands. In order to select as a fine wire suitable to be as high as possible (having more strands than the 3rd example 3-1 above) to be in a state of improving flexibility,

Compared to the third example of the third method, the second thickness is changed to be thinner again, that is, the ultrafine wire made of nickel copper alloy metal, which is the same functional classification group, and the thickness is changed to thinner, 0.00785 mm2 (1 m in length). The sugar resistance value is 36 kW), and select the same ultrafine wire into 61 strands.

In the remaining second type, the thickness classification group is selected. In the third example of the third method, the micro wire is used to effectively reduce the resistance value, and the number of micro wires can be as large as possible (Example 3 of the third method). Since it should be selected to improve flexibility by having more strands than -1 condition, suitable fine wires include copper fine wires in the resistance classification group selected in the method of satisfying the condition of Example 3-1. Although the material is the same, it is a micro wire belonging to the thickness classification group, and among the micro wires made of copper, the micro wires having a thickness of 0.0718 mm2 (resistance value of 0.235Ω per 1m length) are selected.

In the third example of the fourth method, based on the method ④ above, i.e., the ultrafine wire which reduces the resistance value more effectively, which is the condition of the present example 4-3, can be made as many as possible. In order to select an ultrafine wire suitable for improving flexibility by having more strands than the third method example 3-1 condition, the material is changed secondarily compared to the third example of the third method, In other words, the material is a fine wire made of silver, and the material is changed to a resistance value of 0.241Ω (thickness 0.06721mm2) per 1m length.

When the first type and the second type of ultrafine wire 63 strands are combined into one combination, they are synthesized into one bundle by energizing and synthesizing them in a lengthwise direction, and the bundle has a low resistance of 0.1 kΩ per 1 m length. It becomes the hot wire which has a value, and satisfy | fills this example 4-2.

To prove this again by the formula, in the first type of the selected ultrafine wire, the classification group is the functional classification group, and the secondary copper nickel metal alloy is 0.00785 mm2 (resistance value per 1m length is 36 kW) changed to thinner again. I select 61 strands of the same micro wire of the thing made with the micro wire,

In the second type, the classification group is a classification group of thickness, and is a micro fine wire made of silver, which is a material classification group, which is changed material again in the second, and the material is changed to a resistance value of 0.241 Ω (0.06721 mm2 in thickness) per 1m in length. The same fine wire is selected in 2 strands,

The final selected fine wires may be combined from each of the two classification groups, and the combined resistance value = 1 ÷ (1/36 X 61 strands) + (1 / 0.241 X 2 strands) = 1 ÷ (1.6944 + 8.2987) = 1 ÷ 9.9931 ≒ 0.1Ω, so

Low resistance of 0.1 kW in a state of improving flexibility by increasing the number of micro fine strands desired in the present example 4-2 conditions to have as many strands as possible in the example 3-1 example 3-1. Heating wire having a value, and at the same time, a heating wire having a function of causing a desired heat generation operation more effectively (the nickel copper alloy metal is a desired heat generation through a preliminary experiment to implement the present invention in the <Example 13-7>) It is proved that it is a fine wire that is operated.

In conclusion, the fourth method is based on the third method, the micro-wires according to the desired specifications from any two or more of the four categories classified as resistance value, thickness, material, and function according to the desired method 1 To choose more than a strand,

In the fourth method, the ultrafine wires selected in this manner are any one of the classification types except for the types corresponding to the corresponding classification type group selected from among resistance value, thickness, material, and function type in each of the same classification type group. In this way, the selected microfiber line is additionally selected (modified) in such a way as to be a microfiber line that has been changed back to a type. One combination of the above methods is such that the total number of fine wires is at least two strands or more, and thus, the selection in the <Example 13-5> and the <Example 13-6> is changed. This is a method for more effectively by changing the combination of the ultrafine wires of <Example 13-4> and <Example 13-5>.

In a fifth method, the heating wire to be made in the present invention, the total number of extra fine wire strands in the bundle (heat wire) of one of the desired specifications to increase the total number of fine wire strands than the fourth method in a state of securing a great flexibility In addition, it is another method from the fourth method, which is used when a combination of micro wires which is more effective in performing a specific function and at the same time lowering the resistance value to a low resistance value is needed.

Among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires is selected from any two or more types of classification groups classified by resistance value, thickness, material, and function. One or more strands are selected for each type, and the selected ultrafine wires are selected from the group of resistance values, thicknesses, materials, and functions in the same category. After making the fine line again changed to any one of the excluded classification types, the selected fine line is added (modified) by changing the number of strands again. At least two kinds of micro fine lines selected by classification type are combined to form a single combination. The method of making more than Doc become the change of the selection in the <Example 13-5> and the <Example 13-6>, and the <Example 13-4> and the <Example 13-5> By changing the combination of the fine lines of the more effective way will be made.

The fine wire selected as described above is changed again to any one of the classification types except for the type corresponding to the selected classification type group among the resistance value, thickness, material, and function type within the same classification type group. After making it become the method of changing the number of strands again in such a fine line,

① When the same classification type group is selected as the resistance value type, additionally change the number of strands for these while changing any one or more of thickness, function, and material except for changing the resistance value by changing the ultrafine wires.

② If the same classification type group is selected as the material type, additionally change the number of strands for these by changing the ultrafine wires and changing any one or more of the thickness, function and resistance except for material change.

③ When the same classification type group is selected as the thickness type, the number of strands for these is additionally changed while changing any one or more of materials, functions, and resistance values except for changing the thickness of the micro fine lines.

④ When the same classification type group is selected as the functional type, any one of the methods of additionally changing the number of strands for these materials by changing one or more of the material, thickness and resistance value except for the functional change by changing the ultrafine wires It means the above method.

In more detail, according to the fourth method, for each of the ultrafine wires selected by the four methods such as the above ① to ④ to each of them, the four methods such as the following ① to ④ below the fifth method The process of further changing the number of strands is carried out so that at least one extra fine line can be selected from each taxon itself, and the whole fine line inside a combination is formed to form a bundle (one strand of hot wire). In this case, the selected micro fine lines are combined in at least two strands.

In more detail, the following four ① ~ ④ method is used in more detail, the first example, out of all the ultra-fine wires prepared in Example 13-4, classified as resistance value, thickness, material, function How to select each of the ultrafine lines from two or more classification type groups among the two types of classification groups, using the method of the above ② and ③ methods, will be described again. An example 5-1 is described below.

For example, the same fine wire as in Example 4-1 of the fourth method is used, but only the number of strands is changed, and the heat wire required by the present invention is a hot wire having a low resistance value of 0.05 kΩ per 1 m length of the hot wire. At the same time, it is assumed that the condition of this example 5-1 is to make a heating wire having a specific function (a function that causes a desired heating operation more effectively among various specific functions).

The method satisfying the condition of Example 4-1 of the fourth method is that, in the first type, the classification group is a classification group of functions, and the thickness is changed to secondary again, and the thickness is 0.00785 mm2 (the resistance value per length of 36 m). 54 strands of the same ultrafine wire of fine copper wire made of nickel copper alloy metal were selected,

In the remaining second type, the classification group is a classification group of resistance values, and the same ultra-fine wire two strands of the ultra-fine wire made of copper metal having a thickness of 0.0718 mm 2 (resistance value per 1 m of length is 0.235 mW), which has been changed to second thickness again. Compared to selecting the fine line,

In the first example of the fifth method, the utilization method of the four methods as described in ① to ④ is each of the two types of ultrafine wires selected as described above by the method satisfying the condition of Example 4-1 of the fourth method. Is further changed and selected to have a low resistance value of 0.05 kΩ, which is the resistance value of the example 5-1, by changing (increasing) the number of strands to the same ultrafine wire.

 In the first kind, 54 strands of the same ultrafine wire of fine copper wire made of nickel-copper alloy metal having a thickness of 0.00785 mm 2 (resistance value per 1m of length) satisfying the conditions of Example 4-1 of the fourth method. Change the number of strands from 107 to 107 strands,

In the second remaining type, two strands of the same ultrafine wire of fine wire made of a copper metal having a thickness of 0.0718 mm 2 (resistance value per 1 m of length is 0.235 kPa) satisfying the conditions of Example 4-1 of the fourth method. We change (increase) the number of the strands into 4 strands from what we used,

In this way, if only the number of strands of the fine wires corresponding to the two fine wires finally selected according to the method (3) and the method (2) of the fourth method is changed, and these are combined to form a bundle in a synthetic assembly method, the bundle is immediately The condition of Example 5-1 of the fifth method is satisfied.

If this is again proved by the formula, the first ultrafine wire of the selected first fine type, the same fine wire 54 of the fine wire made of nickel copper alloy metal having a thickness of 0.00785 mm 2 (resistance value per 1m length) was used. We change (increase) number of strands from thing to 107 strands,

In the second remaining type, the number of strands is changed (increased) from 4 to 2 strands of the same ultrafine wire, which is made of a copper metal having a thickness of 0.0718 mm 2 (resistance value per meter of 0.2mΩ).

The combination of the ultrafine wires of which the final number of strands is changed in each of the two kinds of the above classification groups may be combined, and the synthetic resistance value = 1 ÷ (1 / 36X107 strands) + (1 / 0.235X4 strands) = 1 ÷ (2.9722 + 17.0212) = 1 ÷ 19.9934 ≒ 0.05 Ω,

In this Example 5-1 condition, the same fine wire as in Example 4-1 of the fourth method is used, but only the number of strands is changed to become a heating wire having a low resistance value of 0.05 kΩ per 1 m length of the heating wire. Hot wire having a function of causing a heat generation operation more effectively (because the nickel copper alloy metal has been proved to be an ultrafine wire which is a desired heat generation operation through a preliminary experiment to implement the present invention in the <Example 13-7>) This becomes a heating wire that satisfies all the desired conditions in the example 5-1 conditions.

For example, among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires may be selected from at least two classification type groups among the kind groups classified by resistance value, thickness, material, and function. For example, using the method of the above ① and ③ method, the description of the method of selecting a second change in each classification group is as follows.

For example, the same fine wire as in Example 4-2 of the fourth method is used, but only the number of strands is changed, and the heat wire required by the present invention is a hot wire having a low resistance value of 0.05 kΩ per 1 m length of the hot wire. At the same time, to make a heating wire having a specific function (a function that causes a desired heat generation operation more effectively among various specific functions), the condition of this example 5-2,

The method of satisfying the condition of Example 4-2 of the fourth method is the first classification of the functional group, and the thickness is 0.00785 mm2 (resistance value per 1m of length is 36 kW), which is changed to the second thickness again. 61 strands of the same ultrafine wire of fine wire made of alloy metal were selected,

In the second type, the classification group is a classification group of materials, and is a micro fine wire made of silver, which is a material classification group, which is secondly changed in thickness, and the thickness is changed to 0.06721 mm2 (resistance value of 0.241 kPa per 1 m of length). Compared to selecting two fine wires,

In the second example of the fifth method, the utilization method of the four methods, such as ① to ④, is each of the two types of ultrafine wires selected as described above by the method satisfying the conditions of Example 4-2 of the fourth method. In the method of changing the number of strands to the same fine line again and increasing it to have a low resistance value of 0.05 kΩ, which is the resistance value of the example 5-2 example,

In the first kind, the same ultrafine wire 61 strands of ultrafine wire made of nickel-copper alloy metal having a thickness of 0.00785 mm 2 (resistance value per 1 m length) satisfying the conditions of Example 4-2 of the fourth method. Change (stretch) the number of strands from 122 to 1,

In the remaining second type, the same ultrafine wire 2 having an ultrafine wire made of silver, which is a material classification group satisfying the conditions of Example 4-2 of the fourth method, having a thickness of 0.06721 mm 2 (resistance value of 0.241 kPa per 1 m of length). By changing the number of strands from 4 strands to 4 strands,

In this way, if only the number of strands of the micro fine lines corresponding to the two fine strands finally selected according to the method (3) and the method (1) of the fourth method is changed, and these are combined to form a bundle in a synthetic assembly method, the bundle This satisfies the condition of Example 5-2 of the fifth method.

In the first one of the selected ultrafine wires, the same ultrafine wires made of nickel-copper alloy metal having a thickness of 0.00785 mm2 (resistance value per meter of length of 36 m) were used. Change the number of strands to 122 strands (increase),

In the remaining second type, the number of strands is changed (increased) from 4 to 2 strands of the same ultrafine wire, which is made of silver having a thickness of 0.06721 mm 2 (resistance value of 0.241 kPa per 1 m).

The combination of the fine strands with the final number of strands in each of the two groups can be combined, where the synthetic resistance value = 1 ÷ (1 / 36X122 strands) + (1 / 0.241X4 strands) = 1 ÷ (3.3888 + 16.5975) = 1 ÷ 19.9863 ≒ 0.05 Ω,

In this Example 5-2 conditions, the same fine wire as in Example 4-2 of the fourth method is used, but only the number of strands is changed, so that the heating wire has a low resistance value of 0.05 kΩ per 1 m length of the heating wire. Hot wire having a function of causing a heat generation operation more effectively (because the nickel copper alloy metal has been proved to be an ultrafine wire which is a desired heat generation operation through a preliminary experiment to implement the present invention in the <Example 13-7>) This becomes a heating wire that satisfies all desired conditions in the condition of Example 5-2.

For example, among all the ultrafine wires prepared in Example 13-4, each of the ultrafine wires may be selected from any two or more types of classification groups classified by resistance value, thickness, material, and function. For example, using the method of the above ③ method and the ④ method described above, the method of selecting a second change in each classification group is described as follows.

For example, the same fine wire as in Example 4-3 of the fourth method is used, but only the number of strands is used, and the heating wire required by the invention is a heating wire having a low resistance value of 0.05 kΩ per 1 m length of the heating wire. When it is assumed that the condition of this example 5-3 is to make a heating wire having a specific function (a function of causing a desired heating operation more effectively among various specific functions) in parallel,

The method satisfying the condition of Example 4-3 of the fourth method is a classification group of functions in the first type, and the thickness is changed to 0.00785 mm2 (the resistance value per 1m length is changed to a thinner thickness). 36 micro wires made of nickel-copper alloy metals were selected for the selection of 61 identical micro wires.

In the second type, the classification group is a classification group of thickness, and is a micro fine wire made of silver, which is a material classification group, which is changed material again in the second, and the material is changed to a resistance value of 0.241 Ω (0.06721 mm2 in thickness) per 1m in length. Compared to having selected two identical fine wires,

In the second example of the fifth method, the utilization method of the four methods, such as ① to ④, is each of the two types of ultrafine wires selected as described above by the method satisfying the conditions of Example 4-2 of the fourth method. Is further changed and selected to have a low resistance value of 0.05 kΩ, which is the resistance value of the example 5-2, by changing (increasing) the number of strands to the same ultrafine wire.

In the first kind, the same ultrafine wire 61 strands of ultrafine wire made of nickel-copper alloy metal having a thickness of 0.00785 mm 2 (resistance value per 1 m length) satisfying the conditions of Example 4-2 of the fourth method. Change (stretch) the number of strands from 122 to 1,

In the second remaining type, the ultrafine wire is made of silver, which is a material classification group, which satisfies the condition of Example 4-2 of the fourth method, and has a thickness of 0.06721 mm2 (0.241 kPa resistance per 1m length). Change the number of strands from 4 strands to 4 strands (increase),

In this way, if the number of strands of the microfine wires corresponding to the two finely selected fine wires is finally changed according to the method (3) and the method (4) of the fourth method, the combinations thereof are combined into a bundle in a synthetic assembly method, and the bundle is obtained. The condition of Example 5-3 of the fifth method is satisfied.

In the first one of the selected ultrafine wires, the same ultrafine wires made of nickel-copper alloy metal having a thickness of 0.00785 mm2 (resistance value per meter of length of 36 m) were used. Change the number of strands to 122 strands (increase),

In the remaining second type, the number of strands is changed (increased) from 4 to 2 strands of the same ultrafine wire, which is made of silver having a thickness of 0.06721 mm 2 (resistance value of 0.241 kPa per 1 m).

Combined ultrafine wires with the final number of strands changed in each of the two types of group, synthetic resistance value = 1 ÷ (1/36 X 122 strands) + (1 / 0.241 X 4 strands) = 1 ÷ (3.3888 + 16.5975) = 1 ÷ 19.9863 ≒ 0.05Ω,

In this Example 5-3 conditions, the same fine wire as in Example 4-3 of the fourth method is used, but only the number of strands is changed to become a heating wire having a low resistance value of 0.05 kΩ per 1 m length of the heating wire. Hot wire having a function of causing a heat generation operation more effectively (because the nickel copper alloy metal has been proved to be an ultrafine wire which is a desired heat generation operation through a preliminary experiment to implement the present invention in the <Example 13-7>) This becomes a heating wire that satisfies all desired conditions in the condition of Example 5-3.

In conclusion, according to the fifth method, the ultrafine wires are classified according to the desired specification in any two or more of the four categories classified as resistance value, thickness, material, and function according to the third method. Select at least one strand,

Again, the ultrafine wires selected in this manner by the fourth method are any of the classification types except for the types corresponding to the corresponding classification type group selected among the resistance value, thickness, material, and function type in each of the same classification type group. To make additional selections (changes) in such a way that it becomes a fine line

In the fifth method, the second finely selected fine line is additionally selected (changed) by changing the number of strands again, so that the final fine line selected from different classification types is at least 2 Combination of more than one kind to form a combination, one method is made so that the total amount of fine wire is made of at least two strands, the <Example 13-5> and <Example 13 -6> is a method of changing the selection of the ultrafine lines of <Example 13-4> and <Example 13-5> so that the selection is made more effectively.

In the sixth method, the heating wire to be made in the present invention is a heating wire having a state in which the complete heating operation is performed well even when the thickness of the ultrafine wire is significantly thinner than that of the first or second method, and at the same time, the resistance value One of the methods used when a combination of ultra fine wires is needed to lower the resistance to low resistance.

Among all the ultra-fine wires prepared in Example 13-4, a classification type group may be selected by using only one type group classified into resistance value, thickness, material, and function, and within the selected classification type group. In order to form a combination by allowing two different ultra fine wires to be combined in two or more strands, the combination of the two so that the total ultra fine wire quantity is at least two strands or more, the <Example 13 -5> and <Embodiment 13-6> to change the selection is made to more effectively by changing the combination of the ultra-fine lines of the <Example 13-4> and <Example 13-5> .

To illustrate this in more detail, in Example 6, it is assumed that the prepared ultrafine wires are only those of the material classification group, and only the ultrafine wires belonging to the material classification group should be used to make the heating wire required by the present invention. When the thickness of the thin wire, the heating wire having a low resistance value of 0.05Ω per 1m length of the heating wire, but to make more effectively as a heating wire that is fully heat-generating operation is a condition of Example 6,

In order to satisfy the condition of Example 6, when using the sixth method, the thickness of the heating wire becomes much thinner or longer, and the heating wire having a low resistance value of 0.05 kΩ per 1m length of the heating wire is used. You can make it easier.

For example, in the first method, when a heating wire having a low resistance value of 0.05 kW per 1 m of the heating wire, which is the condition of Example 6, is made, one of the fine wires in which the heat generation operation is well performed is performed. Only by increasing the number of strands of the same fine wire selected can produce a hot wire with a low resistance value of 0.05 당 per 1m of the hot wire.

Otherwise, it is too easy to drop to a low resistance value of 0.05 당 per 1m of the length of the heating wire, but the problem is that the heated wire becomes a conductor, not a heating wire, so that it is not heated.

Therefore, if one type is selected as a fine wire that has good desired heat, that is, a perfect heat-generating operation, and the number of strands of the same fine wire is increased to make a hot wire having a low resistance value of 0.05 kW per 1 m of the heating wire, that is, < Example 13-7> Among the ultrafine wires prepared through preliminary experiments to implement the present invention, the material of the ultrafine wires representing a specific material, which only serves to perform a full heating operation, is made of steel fiber (metal As a fine wire made of (NASLON), a fine wire having 50.5 Ω (fine wire thickness 0.017229 mm2) as a resistance value per 1m length was selected, and the same fine wires 1,010 strands were combined to form a composite assembly. To bundle it up.

Proving this by the formula, the composite resistance value = 1 ÷ (1 / 50.5X1,010 strands) = 1 ÷ (0.0198 X 1,010) = 1 ÷ 19.9999 ≒ 0.05 되어 Part manufactured).

In this case, the thickness (section area) of the heating wire is a value obtained by multiplying the total number of fine wires by the cross-sectional area of one strand, and thus the thickness of the heating wire made by the first method (the total fine wire cross-sectional area) is the total cross-sectional area of the ultra fine wire = 0.017229 mm 2. If X 1010 strands = 17.40 mm 2, which is another partial condition of Example 6, the thickness of the hot wire does not satisfy the thin state.

In contrast, the present sixth method, in order to make a heating wire having a low resistance value of 0.05 kΩ per 1 m of the length of the heating wire, which is the condition of Example 6, is made of a fine wire that is completely heat-producing among the fine wires of the pre-prepared material classification group. One type is selected, and one type of other ultra fine wire that serves only as a conductor belonging to the same material classification group is selected, that is, two kinds of ultra fine wires belonging to the same classification group are selected, and their combination is synthesized. When bundled, they are the hot wires that satisfy all of Example 6.

In this case, by selecting one type as a fine wire that is fully heat-generating in the material classification group, the heat is improved and at the same time, the fine wire that serves only as a conductor is used simultaneously, so the resistance value is not increased even when the thickness of the wire is not thick. Since it can be easily dropped to a low resistance value of 0.05Ω per 1m length of the heating wire, the condition of Example 6 is completely satisfied.

When the present sixth method is actually implemented, two different types of ultra fine wires are selected from the inside belonging to the same material classification group, and the first one is a micro fine wire with good heat generation, and the material is steel fiber (metal fiber). As the ultra fine wire to be made (NASLON), select the ultra fine wire having a resistance value of 50.5 Ω (fine wire thickness 0.017229 mm2) per 1 m length, and select the same fine wire 532 strands thus selected.

The next two types are fine wires that serve only as conductors, and are fine wires made of silver, and select the fine wires having a resistance value of 0.1058Ω (fine wire thickness 0.1531mm2) per 1m in length. If you select one strand and combine them into a bundle, these are the hot wires that satisfy all of Example 6.

Proving this by the formula, the composite resistance value = 1 ÷ (1 / 50.5 X 532 strands) + (1 / 0.1058 X 1 strand) = 1 ÷ (10.5346 + 9.4517) = 1 ÷ 19.9863 ≒ 0.05 ,, this example 6 It satisfies the part manufactured with the low resistance value of a condition.

In this case, the thickness (section area) of the heating wire is a value obtained by multiplying the total number of fine wires by the cross-sectional area of one strand, and thus, the thickness of the heating wire (fine wire total cross-sectional area) made by the sixth method is the total cross-sectional area of the ultra fine wire = (0.017229 Mm 2 X 532 strands) + (0.1531 mm 2 X 1 strands) = 9.1658 mm 2 + 0.1531 mm 2 = 9.3189 mm 2,

The thickness of the heating wire made by the first method (total cross-sectional area of the ultra fine wire) is made much thinner than 17.40 mm 2, and if the other partial conditions of the present example 6 can be made, all of the thin wire thicknesses are satisfied.

In conclusion, the sixth method selects a classification type group using only one type group classified into resistance value, thickness, material, and function. By combining more than the strands to form a single combination, this combination is a way to ensure that the total amount of fine wire is at least two strands,

Even though the thickness of the ultra fine wire is significantly thinner than the first or second method, it is a method of making a heating wire having a state in which complete heat generation is well performed and at the same time making a low resistance value. Can be.

In the seventh method, the heating wire to be made in the present invention is a heating wire having a state in which the heat generation is well performed even in a state in which the thickness of the ultrafine wire is significantly thinner than that in the first or second method. Another method to use when the need for a combination of micro wires more effective to lower the resistance to low resistance value,

Among all the ultra-fine wires prepared in Example 13-4, a classification type group may be selected by using only one type group classified into resistance value, thickness, material, and function, and within the selected classification type group. In order to select different micro fine lines in two or more strands, the selected fine lines are combined in a way that changes the number of strands again to form a combination, one combination is made of the total number of fine lines The method of making at least two strands is performed by changing the selection of the <Example 13-5> and the <Example 13-6>, and the <Example 13-4> and the <Example 13>. -5> is a way to make it more effective by changing the combination of the fine lines.

In order to explain this in more detail, in Example 7, it is assumed that the prepared fine wires are only those of the material classification group, and only the fine wires belonging to the material classification group should be used to make the heating wire required by the present invention. When the thickness of the thin wire, the heating wire having a low resistance value of 0.01Ω per 1m length of the heating wire, but to make it more effective as a heating wire that is fully heat-generating operation is a condition of Example 7,

In order to satisfy the condition of Example 7, in the state in which the initial ultrafine wires are selected by applying the sixth method, the number of strands of the ultrafine wires is changed (reduced or increased) to the same ultrafine wires as the initially selected ultrafine wires. This makes it easier to make a heating wire having a low resistance value of 0.01 kW per 1 meter of the heating wire.

In practice, in the sixth method, in order to make a heating wire having a low resistance value of 0.05 kW per 1m of the heating wire, which is the example 6 condition, the first one is an ultrafine wire having a good heat generation operation. As a fine wire made of (NASLON), a fine wire having a resistance value of 50.5 Ω (fine wire thickness 0.017229 mm2) per 1 m length was selected, and the same fine wire 532 strands thus selected were selected.

The next two types are fine wires that serve only as conductors, and are fine wires made of silver, and select the fine wires having a resistance value of 0.1058Ω (fine wire thickness 0.1531mm2) per 1m in length. Line 1 strands were selected and their combinations synthesized into a bundle.

Therefore, in using the seventh method, in order to more easily make the heating wire having a low resistance value of 0.01 kPa per 1 m of the length of the heating wire, which is the example 7 condition, the material selected as the first one of the sixth methods is steel fiber. As a fine wire made of (NASLON), a fine wire having a resistance value of 50.5 Ω (fine wire thickness 0.017229 mm2) per 1 m length was selected, and the same fine wire 532 strands thus selected were selected.

According to the seventh method, only the number of strands of the same ultrafine wire is further changed, that is, the same ultrafine wire 532 strand is further changed (reduced) to 277 strands,

A fine wire made of silver, selected from the following two types of the sixth method, was selected for the same fine wire having a resistance value of 0.1058 Ω (fine wire thickness 0.1531 mm 2) per 1 m in length, and thus selected 1 strand,

According to the seventh method, only the number of strands of the same ultrafine wire is further changed, that is, one strand of the same ultrafine wire is further changed (increased) to 10 strands,

When a combination of 287 different types of ultrafine wires totally selected in this manner is synthesized into a bundle, these are the hot wires satisfying all of the seven examples.

If this is proved by the formula, it is an ultrafine wire made of steel fiber (metal fiber) (NASLON) first selected by the seventh method, and the resistance value per 1m length is 50.5Ω (fine wire thickness 0.017229mm2) Branches have 277 fine wires and 2 fine wires selected by the seventh method, made of silver, and have 10 0 fine wires having a resistance value of 0.1058 Ω (fine wire thickness 0.1531mm2) per 1m in length. If you combine the total of 287 strands combined together to calculate one composite resistance value,

Synthetic resistance = 1 ÷ (1 / 50.5 X 277 strands) + (1 / 0.1058 X 10 strands) = 1 ÷ (5.4851 + 94.5179) = 1 ÷ 100.003 = 0.01 Ω, which satisfies all of the conditions of Example 7 .

At this time, the thickness (section area) of the heating wire is a value obtained by multiplying the total number of fine wires by the cross-sectional area of one strand, and thus the thickness of the heating wire made by the seventh method (the total fine wire cross-sectional area) is the total fine wire cross-sectional area = ( 0.017229 mm 2 X 277 strands) + (0.1531 mm 2 X 10 strands) = 4.7724 mm 2 + 1.531 mm 2 = 6.3034 mm 2, and the thickness of the heating wire made by the first method (microwire total cross-sectional area) was 17.40 mm 2 and by the sixth method. The heat wire thickness (microwire total cross-sectional area) is made much thinner than 9.3189 mm 2, and if the other partial conditions of the present example 7 can be made, all of the thin wire thickness conditions are satisfied.

In conclusion, the seventh method selects a classification type group using only one type group classified into resistance value, thickness, material, and function. The strands are selected to be more than strands, and the selected microfiber lines are combined again by changing the number of strands to form a combination. As a way to lose,

Even though the thickness of the ultrafine wire is significantly thinner than that of the first, second, and sixth methods, it is a hot wire having a state in which complete heat generation is well performed and at the same time, a low heat resistance wire can easily achieve low resistance. You can see how it is made.

<Example 13-9>

The ultrafine wires used in the above <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8> include one strand of ultrafine wires made of a single metal or an alloy metal. As described above as a standard, instead of the fine strands of the 1 strand, the material, function, and properties are all the same, but the fine strand group is made of one bundle by tying two or more strands of the fine strand which is made very thin. It can be used in many ways to achieve better effects.

That is, in order to make the heating wire required by the present invention, when the battery electricity or safety low voltage direct current (DC) electricity of 24V or less flows, the geometry (equal resistance value or In the case of the same thickness, the same material, or the same function, the ultra fine wire is divided into many strands rather than one strand (the thinner the effect, the better the effect). To make it more effective,

Battery electricity or safe low voltage direct current (DC) electricity below 24V

To be more effective at becoming a heated wire with increased flexibility,

Be sure to replace the ultrafine wires used by one strand in <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8> by using an ultrafine wire group Only then can you maximize the effect.

Therefore, in order to implement the present invention, a method of using an ultrafine wire group is necessary. Such a method includes the above-described <Example 13-4>, <Example 13-5>, <Example 13-6>, The ultrafine wires used by each strand used in <Example 13-8> have the same properties in the same classification group in place of the corresponding ultrafine wires, but have a thinner thickness than the corresponding ultrafine wires. It is a method to substitute the ultrafine wire group which synthesized the above.

In addition, the micro-fine wire group combines two or more strands of micro-fine wires with the same classification and the same property, which is thinner than the corresponding micro-wires, so that the entire surface of the micro-fine wires of two or more such strands is in the longitudinal direction. In order to make contact with each other from the beginning to the end, the electric current flows to all the micro-fine wires as a whole of the contact surface, and the composite combination is made into a single bundle to be the energized contact synthesis that is electrically synthesized with each other.

In more detail, the microfibers are made of a plurality of kinds, a plurality of single metals or alloy metals, which are all prepared ultrafine wires of Example 13-4, and are used as the respective individual strands of the above prepared ones. In the ultrafine wire, the same as the fine wire, but thicker than the finer wire to make a thinner, two or more of these ultrafine wire is combined by multiple bundles to be energized contact synthesis to make a single bundle, so It is a method used instead of the said micro fine wire.

In this way, the actual implementation of the heating wire required by the present invention, Example 9, for example, to make the resistance value of the heating wire required in the present invention, the heating wire having a low resistance value of 1 당 per 1m length of the heating wire In the case of Example 9,

When making a heating wire that satisfies the condition of Example 9 by the first method in the <Example 13-8>, the fine wire (one strand of fine wire, the length of the material is made of steel fiber (metal fiber) (NASLON), the length Select the ultra fine wire having the resistance value of 50.5Ω (fine wire thickness 0.017229mm2) per 1m, and combine the selected fine wires with the same 50 strands in one combination, If one bundle is made, this bundle is a hot wire having a low resistance value of 1 kW per 1 m length (as described in the first method of <Example 13-8>).

On the other hand, when making a heating wire that satisfies the conditions of Example 9 by the method of <Example 13-9>, the steel fiber (metal fiber) (NASLON) that is the corresponding fine wire, but the fine wire thickness 0.017229 mm2 Make a much finer wire, that is, make a micro wire with a thickness of 0.000113 mm2 made of steel (metal fiber) (NASLON), and then combine the 550 strands of these ultrafine wires into an energized contact composite If you make a bundle of these fine wire groups, put them together into one group and combine them into energized contact composites,

This bundle is a hot wire having a low resistance value of 1 kW per 1 m length, which satisfies the condition of Example 9.

In addition, when the heating wire is made by the present <Example 9> method, the heating wire is the <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13- More effective than heating wires made from microfibers used in single strands,

When battery electricity or safe low-voltage direct current (DC) electricity below 24V flows, it has a geometry that must be equipped to emit far infrared rays better,

When battery electricity or safe low voltage direct current (DC) electricity below 24V flows,

Of the heating wires that have increased flexibility, they are the heating wires that perform one or more more effective functions.

If this is proved again through the actual formula, when the hot wire satisfying the condition of Example 9 is made by using the ultrafine wires used in one strand by the first method in the <Example 13-8>, the selected material It is made of steel fiber (NASLON), and the synthetic resistance value of 50 fine wires having a resistance value of 50.5Ω (fine wire thickness 0.017229mm2) per 1m length = 1 ÷ [(1 / 50.5) X (50 strands) ] = 1 ÷ 0.99 ≒ 1Ω

In contrast, when the heating wire that satisfies the conditions of Example 9 was made by the present <Example 13-9> method, the material was steel fiber (NASLON), and the thickness (diameter) was 0.000113 mm 2 ultra fine wire 550 strands (these fine wires) The synthetic resistance value of 550 strands is 14 kV per 1m in length and is made into one group by conducting contact-synthesizing (described in Example 7) above. When these 14 groups are synthesized, the synthetic resistance value = 1 ÷ (1 / 14 x 14 groups) = 1 ÷ (0.07142857 X 14) = 1 ÷ 0.999999 ≒ 1Ω,

In this <Example 13-9> method, it is also possible to produce a heating wire that satisfies the condition of Example 9.

In conclusion, in making a heating wire according to the present invention, at the same time as a heating wire having a low resistance value required to obtain a desired heat using battery electricity or safety low voltage direct current (DC) electricity of 24V or less,

Using battery electricity or safe low-voltage direct-current (DC) electricity below 24V to enable far-infrared radiation to be emitted well, instantaneous high-temperature heating, high-efficiency heating, or heating wires with increased flexibility. In a way to become a hot wire to say,

In all the ultrafine wires used by each of the strands used in the above <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>, Instead of the ultrafine wires used, the same classification group has the same properties, but the thickness of the finer wires are made by replacing two or more finer wires that are thinner than the corresponding fine wires.

Here, the micro-fine wire group is a combination of two or more multi-stranded microfibers by combining two or more multi-stranded microfibers with the same classification and the same properties, which are thinner than the corresponding fine wires used by one strand. When the surfaces are in contact with each other from the beginning to the end in the longitudinal direction, the current can flow through all the ultrafine wires to the entire contact surface, so that a combination of the composites are used to make the energized contact synthesis where the electrical synthesis is made.

<Example 13-10>

As the most important way to make the heating wire required by the present invention,

In order to make a heating wire required by the present invention, when battery electricity or safety low voltage direct current (DC) electricity of 24 V or less flows, the heating wire enables multiple functions to be performed at the same time.

In the ultrafine wires used by each of the strands used in the <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>, the ultrafine wires and the Using the above-described ultrafine wire group in <Example 13-9>, or adding and using the above-mentioned ultrafine wire group in addition to the above-mentioned ultrafine wire groups in <Example 13-9> The way is to make a hot wire.

In addition, in the above, the multi-function is as described in the <Example 13-3>,

① Technology to make a heating wire with low resistance value necessary to obtain desired heat by using battery electricity or safe low voltage direct current (DC) electricity below 24V,

② A technique of making a hot wire expressing any one or more additional functions in parallel with the above-mentioned ① hot wire.

③ It means that it is a function to simultaneously implement the technology of making a hot wire with flexibility in parallel with any one or more of the above ① or ②.

To sum it up again, the multi-function above

The heating wire required by the present invention has a low resistance value required to obtain a desired heat by using battery electricity or safety low voltage direct current (DC) electricity of 24V or less, and at the same time, it is possible to perform at least one specific function simultaneously while providing flexibility. All of these functions, which make them excellent hot wires, mean that they are co-expressed simultaneously.

And if the above description in more detail,

The at least one specific function is a complex function implemented simultaneously by the battery-electric operation prefabricated heating wires in the <Example 13-1> to the <Example 13-4>, and the <Example 13-3> In order to make a heating wire expressing any one or more additional functions as described above in ②, it means any one or more additional functions to be expressed.

One or more of these specific additional features are the heating wires produced by the present invention, which provide the minimum resistance required to obtain the desired heat using a minimum of additional (battery electricity or safe low voltage direct current (DC) electricity below 24V). At the same time), to recapitulate them in detail,

① the function of emitting far infrared rays,

② instantaneous high temperature heating, high efficiency heating function,

③ function of maintaining the temperature,

④ Excellent tensile strength and durability, easy disconnection or little resistance value change,

⑤ Among the functions of suppressing oxidation reaction,

It means one or more functions.

When explaining the method of the present Example 13-10 in more detail, all the ultrafine wires prepared in Example 13-4 are made of a plurality of types, a plurality of single metal or alloy metal, ,

Of the prepared ones (micro wires), the micro wires used by each of the individual strands are mixed with the micro wires used by the one strand and the micro wire group described in the above Example 13-9, Substituting the ultra-fine wire used by the one strand,

In addition to the ultrafine wires used by the one strand, the microfine wire group described above in Example 13-9 is additionally included, and any one or more of the methods used by the ultrafine wires used by the single strand are replaced. The method of making a heating wire required by the present invention is referred to as.

In this way, the actual implementation of making the heating wire required by the present invention is as follows.

First, in order to explain a method of using the ultrafine wires used in the one strand and the ultrafine wire group described in the above-mentioned <Example 13-9> and replacing them with the ultrafine wires used in the single strand, If you explain this with 10-1,

As the heating wire required by the present invention, it is assumed that the prepared ultrafine wires are only those of the material classification group, and in order to cause a desired heating operation when DC (DC) safety low voltage electricity flows in a state where the thickness of the heating wire becomes thin if possible, Assuming that the condition of this example 10-1 is that the heating wire should be a hot wire having a low resistance value of 0.01 당 per 1 m of the length of the hot wire, but the heat generation is well performed in a perfect heating operation. The conditions of are the same as the conditions of Example 7 in the seventh method of <Example 13-8>.

In practice, making a heating wire that satisfies the condition of Example 10-1,

First, if implemented by the seventh method of <Example 13-8>, as described above, the first one selected by the seventh method of the <Example 13-8>, the material is steel fiber (metal fiber) With the ultrafine wire to make (NASLON), 277 strands of the ultrafine wire which have a resistance value per 1m of length 50.5Ω (fine wire thickness 0.017229mm2),

A fine wire made of silver of a material selected from the following two types according to the seventh method of <Example 13-8>, and having a resistance value of 0.1058 kW (fine wire thickness 0.1531 mm 2) per 1 m in length Strand,

Combination of 287 strands combined to calculate one composite resistance value = 1 ÷ (1 / 50.5 X 277 strands) + (1 / 0.1058 X 10 strands) = 1 ÷ (5.4851 + 94.5179) = 1 ÷ 100.003 ≒ 0.01Ω,

The condition which has a low resistance value which is a condition of this example 10-1 is satisfied,

At this time, the thickness (cross-sectional area) of the heating wire is a value obtained by multiplying the total number of fine wires by the cross-sectional area of one strand, so that the thickness of the heating wire (the total cross-sectional area of the fine wire) made by the seventh method of <Example 13-8> is , (0.017229 mm 2 X 277 strands) + (0.1531 mm 2 X 10 strands) = 4.7724 mm 2 + 1.531 mm 2 = 6.3034 mm 2,

It is made much thinner than the thickness of the heating wire made by the first method (ultra fine wire total cross-sectional area) 17.40 mm 2 and the thickness of the heating wire made by the sixth method (fine wire total cross-sectional area) 9.3189 mm 2,

If the other partial condition of the present example 10-1 can be satisfied, all the state of thin wire | line thickness is satisfied.

On the other hand, by the method of <Example 13-10>, it is used in the <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>. In the present Example 10-1, the micro fine wires used in one strand and the micro fine wire group described in the above Example 13-9 are mixed and replaced with the micro wires used in the single strand. If we implement a way to make the heating wire satisfy the condition,

A fine wire having a material of steel fiber (metal fiber) (NASLON) first selected by the seventh method of <Example 13-8>, having a resistance value of 50.5 kW (micron wire thickness 0.017229) per 1 m length. Mm 2) branch with 277 extra fine wires,

In the method of <Example 13-10>, the ultrafine wire 277 strands are replaced with the ultrafine wire group described in the above <Example 13-9>, that is, the material is steel fiber (NASLON), 550 strands of fine wires (diameter) having a thickness of 0.000113 mm 2 (synthetic resistance value of these 550 strands is 14 kW per 1m in length), as described in <Example 13-7>. Group 76 is used instead of the above 277 strands,

A fine wire made of silver of a material selected from the following two types according to the seventh method of <Example 13-8>, and having a resistance value of 0.1058 kW (fine wire thickness 0.1531 mm 2) per 1 m in length By the method of <Example 13-10>, the strand is used as it is (10 ultra fine wires),

76 selected ultra fine wire groups and 10 strand ultrafine wires using the same selected by the seventh method of <Example 13-8>, all of which were made in one synthetic combination, that is, When calculating the combined resistance value of one bundle (hot wire),

Synthetic resistance = 1 ÷ (1/14 X 76 group) + (1 / 0.1058 X 10 strands) = 1 ÷ (5.4285 + 94.5179) = 1 ÷ 99.9464 ≒ 0.01 ≒,

The condition which has a low resistance value which is a condition of this example 10-1 is satisfied,

At this time, the thickness (section area) of the heating wire is a value obtained by multiplying the total number of fine wires by the cross-sectional area of one strand, and thus the thickness of the heating wire made by the method of <Example 10> (the total cross-sectional area of the fine wire) is [( 0.000113 mm 2 X 550 strands) X 76 groups] + [0.1531 mm 2 X 10 strands] = (0.06215 mm 2 X 76 groups) + 1.531 mm 2 = 4.723 mm 2 + 1.531 mm 2 = 6.254 mm 2,

The thickness of the heating wire made by the seventh method of <Example 13-8> (fine wire total cross-sectional area) is approximately the same as the thickness of 6.3034 mm 2,

If the other partial condition of the present example 10-1 can be satisfied, all the state of thin wire | line thickness is satisfied.

In this way, the micro-wire group manufactured by the method of <Example 13-10>, that is, the micro-wires used in single strands and the same fine micro-wires, which are thinner, are grouped together and used as micro-wires of one strand to be mixed. So,

Manufactured by the method of replacing these with the ultra-fine wires used by one strand used in <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8> The heating wire to be used is a heating wire made of ultra-fine wires used by one strand used in <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>. Compared to the ultra-fine wire group performing a multi-function (the reason for being a multi-function fine group described in the above Example 13-7) is included as a mixed method compared to the multi-function can be performed more effectively It may be.

Secondly, in order to explain a method of substituting the ultrafine wires used in each of the above strands by additionally including the ultrafine wire group described in Example 13-9 in addition to the ultrafine wires used in single strands. For example, the example 10-2 is as follows.

Assuming that the resistance value of the heating wire required by the present invention is a heating wire having a low resistance value of 1 kW per 1 m length of the heating wire, it is assumed that the conditions of this Example 10-1 are used. 13-8> are the same exemplary conditions as those of Example 1-1 in the first method.

If the actual implementation of the heating wire that satisfies the condition of Example 10-1, first, in the first method in the <Example 13-8>, when making a heating wire that satisfies the condition of Example 10-1 As described above, a fine wire having a material of steel fiber (NASLON) (one strand of fine wire, having a resistance value of 50.5 Ω (fine wire thickness 0.017229 mm2) per 1m length) is selected. If the selected micro-fine wires are the same and 50 strands are combined to form one bundle by synthesizing (adherently energizing and synthesizing in the length direction), the bundle has a low resistance value of 1 Ω per 1m length. If it was to be (as described above in the first method of the <Example 13-8>),

By comparison, in the <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>, by the method of <Example 13-10> In addition to the ultrafine wires used in single strands to be used, the microfine wire group described above in <Example 13-9> is additionally included, and a method of replacing the ultrafine wires used in single strands is used.

If a method of making a heating wire that satisfies the condition of Example 10-2 is implemented,

In addition to the 47 ultrafine wires selected by the first method in <Example 13-8>, the microfine wire group 1 group described above in <Example 13-9> is further included, It can be used instead of the fine line.

If this is proved by the formula, the ultra-fine wire (the fine wire of 1 strand, the resistance value per 1m in length) which is made of steel fiber (metal fiber) (NASLON) selected by the 1st method of <Example 13-8> Choose the fine wire having 50.5Ω (fine wire thickness 0.017229mm2), and make the selected fine wire the same to 47 strands (reduce only 3 strands from 50 strands to 47 strands),

The ultra-fine wire group described in <Example 13-9>, that is, the material is steel fiber (NASLON), the thickness (diameter) of the ultra-fine wire 550 strands (0.000113 mm 2) (the synthetic resistance value of these ultra-fine wires 550 strands per 1m length 14 microseconds) to add one microfine wire group 1 group made of one ultrafine wire group described above in Example 13-7,

When the 47 ultrafine wires used in the selected strands and the 1 ultrafine wire group are added together to form a composite combination, that is, the composite resistance value of one bundle (hot wire) thus obtained is calculated, Composite resistance value = 1 ÷ (1 / 50.5 X 47 strands) + (1/14 X1 group) = 1 ÷ (0.93 + 0.0714) = 1 ÷ 1.0020 ≒ 1 ≒,

The condition which has a low resistance value which is a condition of this example 10-2 is satisfied,

The micro fine wire group manufactured by the method of <Example 13-10>, that is, the fine fine wires used in single strands, and grouped a plurality of fine fine wires, which are thinner, are used as a single fine wire. In addition,

Manufactured by the method of replacing these with the ultra-fine wires used by one strand used in <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8> Heating wire,

Compared to the heating wires manufactured by the ultrafine wires used in each of the strands used in the <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8> The ultra-fine wire group for performing the multifunction group (the reason for being the ultra-fine wire group for performing the multi-function is the same as described above in the <Example 13-7>) is included in the added method to perform the multi-function more effectively do.

In conclusion, as the most important way to make the heating wire required by the present invention,

In order to make a heating wire required by the present invention, when battery electricity or safety low-voltage direct current (DC) electricity of 24 V or less flows, the heating wire enables multiple functions to be performed at the same time.

In the ultrafine wires used by each of the strands used in the <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>,

A method of using the micro fine wires used in the one strand and the micro fine wire group described in the above Example 13-9, and substituting the fine wires in the single strand,

In addition to the ultra-fine wires used in single strands, the micro-wire group described above in Example 13-9 is additionally included, and any one or more of the above-described alternative methods are used. The way is to make a hot wire.

<Example 13-11>

In the <Example 13-11>, a method of making a heating wire required by the present invention for implementing a multi-function in a manner different from that of the <Example 13-10> will be described.

In order to implement the present invention, in order to perform a multi-function more easily in the process of making the actual heating wire,

You can actually create your own microfibre group and include only that particular microfibre group to find the microfiber group that is more effective in performing the multifunction, so that the desired multifunction is automatically performed. And I checked,

As described above in Example 13-7, the material is made of ultra fine wire having a thickness of 20 micrometers or less (based on the ultra fine wire diameter) of very thin steel fibers (metal fibers) (NASLON). Synthesize the same micro fine wire with more than 100 strands of the same thickness and make it into energized contact, and make one bundle by itself, or combine multiple bundles of two or more bundles into one bundle, or use another bundle When combined with any one or more of the fine wires suitable for the application, the fine wire group is more effective in performing the multi-function, which is a fine wire (bundle) capable of simultaneously performing the above-mentioned multi-purpose multi-function functions. I found out.

In addition, one of the strands of steel fiber NASLON having a thickness of 20㎛ or less, among those manufactured with 100 or more strands of the same thickness, the bundle bundled as follows is optimal as a more effective ultra-fine wire group more effective in performing the multi-function in the real experiment results It was also found that the state of.

In other words, the microfiber group that is more effective in performing the optimized multi-functions according to the following experiments,

One strand of NASLON, a steel fiber, has a thickness of 12 µm (corresponding to a fine wire diameter), which is made of one micro wire group by tying 550 strands of the same thickness.

One strand of NASLON, a steel fiber, has a thickness of 8 µm (corresponding to the fine wire diameter), which is made of one micro wire group by tying 1,000 strands of the same thickness.

One strand of NASLON, a steel fiber, is 6,5 µm thick (corresponding to its fine wire diameter), which is made up of a group of 2,000 micro wires of the same thickness.

Therefore, on the basis of the results of the self-test, in making the heating wire required by the present invention, the microfiber group itself is more effective in performing the multi-function obtained as a result of the above experiment, or is made of mixed with other microfibers It is sufficient to make the combination into one bundle by adding, or in addition, to make the combination into one bundle, so that the bundle becomes the desired heating wire in the present invention.

To reorganize this, in order to make a battery wire or a heating wire that can perform a multi-function at the same time when a safe low voltage direct current (DC) electricity of 24V or less flows,

In the ultra-fine wires used by each of the strands used in the above <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>, each strand is used. Instead of the microfiber becoming,

A method of replacing the micro fine lines used by the single strands by using a combination of the ultra fine wires used by the one strand and a micro wire group more effective in performing the multi-function found in the experiment;

In addition to the ultra-fine wires used in each of the strands, a method further comprising a more effective ultra-fine wire group to perform a multi-function found in the experiment, and to replace the ultra-fine wires used in each of the strands,

By using only the ultrafine wire group itself, which is more effective in performing the multi-function found in the above experiment, the method of using one or more of the alternatives to the ultrafine wire used by each strand is required in the present invention. You can make a hot wire.

The actual implementation of the above results is the same as the results of the implementations in the <Example 13-9> and the <Example 13-10>, and will not be described herein.

<Example 13-12>

As described above in <Example 13-10>, any one or more functions described in section ② of <Example 13-3> and <Example 13-10> may include any of five functions. Means more than one function.

In Examples <13-13> to <Examples 13-17>, the above five functions will be described in more detail.

<Example 13-13>

The function of emitting far-infrared ray of item (1) among any one or more functions described above in (item 13-3) and (example 13-10) is as follows.

If you want to save energy in every place where you want to get all the heat in the world, the heat you want to use should be radiant heat by far-infrared emission.

There are three methods of all heating methods: convective heat, conductive heat, and radiant heat. The double convection heat or conductive heat heating method has similar heating efficiency and has low energy efficiency, which is inferior to energy consumption. It is a heating method that transfers heat directly. It has an energy-efficient feature that has an excellent heating effect compared to the amount of energy consumed.

Far-infrared rays also have many benefits for improving human health.

Therefore, the heating wire required in the present invention must be made to be a far-infrared ray is emitted, that is, a heating wire that is well used radiant heat technology.

<Example 13-13-1>

However, in this radiant heat technology, when 1kw of electricity is consumed in the heating element (heating wire), the electric energy is changed to the wavelength of light (far infrared ray), and it is blown out of the heating element at the speed of light, absorbed into the material, and then vibrated inside the material. Is a heat generation and transmission technology in which the energy is reduced to heat, and how efficiently electric energy is changed to the wavelength of light (far infrared rays) and the wavelength of the changed light (far infrared rays) How far can you fly (degree, efficiency), how much of this light's wavelength (far-infrared) is absorbed by the material (degree, efficiency), and how much of this light's wavelength (far-infrared) is absorbed by the material and back to heat Depending on the reduction (degree, efficiency), the thermal effect varies greatly.

In addition, the most effective wavelength of light (far-infrared) action (accuracy, efficiency) is called the degree of activation of far-infrared rays. The wavelength of light with the greatest activation of such far-infrared rays is the far-infrared rays coming directly from the sun. When radiated heat is radiated, the heat can be transferred directly to heat, which can produce a greater thermal effect.

As described above, as a result of numerous experiments for the present invention, in order to make a heat ray that emits far infrared rays in a state where activation of far infrared rays is most large, such as far infrared rays coming directly from the sun,

Far-infrared rays that are generated in a general way (for example, far-infrared which claims to be generated from an electric heating element such as a conventional carbon heating element) are found to be far less than the far-infrared effect from the sun.

Far-infrared radiation helps to improve physical health like the effect of far-infrared rays from the sun, and direct heating directly transfers the heat according to the principle that the sun heats the earth. In order to achieve the advantage that dust does not occur, and to emit far infrared rays in a well-activated state with far infrared rays that generate far infrared effect that can help health promotion,

① It must have a geometric structure that can radiate electric radiation of far infrared rays in the hot wire more well,

② The heating wire should be made of a material (material) that emits a large amount of far-infrared rays (particularly, it should be a material having a good dipole moment when battery electricity or safety low voltage direct current (DC) electricity of 24V or less flows).

<Example 13-13-1-1>

The method of having a geometry in which the electric dipole radiation from which far-infrared radiation is emitted from the ① hot wire of <Example 13-13-1> can be radiated more largely.

First, electric dipole radiation refers to radiation electromagnetic waves emitted by electric dipoles that change in size with time. Such radiation electromagnetic waves are far infrared rays, and when the radiation becomes larger, they become far infrared rays and emit a large amount of far infrared rays.

Therefore, it is necessary to artificially sustain the electric dipole moment change instantaneously, and an effective method among these methods is that in the actual laboratory, the sample is made and practiced numerous times. In a way that can be repeated and sustained, the geometry of the hot wire must be achieved.

To explain this in more detail, assuming that 10 heating wires having the same resistance value are combined at regular intervals, even though electricity flows through the 10 heating wires at the same time, each of the heating wires transfers heat generated by the body to the other party. The heat generated by the partner is heat balanced by itself, but when it sees its internal microscopic state, there is a constant temperature difference.

If you observe this condition more microscopically, ten heating wires having the same resistance value generate heat at the same temperature, but they heat each other instantaneously, but they receive heat upside down, so when they heat up, After cooling down, the temperature rises above its exothermic temperature, even a second, thousands of times a very minute temperature change is occurring.

As such, when the temperature change occurs in ΔT time, assuming that the material constituting the heating wire is made of a material in which the dipole moment occurs when electricity flows, such a material is particularly frequently used when the temperature change occurs instantaneously. When this occurs, the electron flow increases / decreases / decreases in one direction, and the magnitude of dipole moment is continuously changed, and the electric dipole radiation is generated, and far infrared rays are emitted.

When this temperature change is intensified, the radiation becomes larger, which results in more intense and larger emissions out of the hot wire as it changes to far-infrared.

In view of these results, it is necessary to make the geometry of the heating wire into a structure in which such micro thermal change can occur.

In the conventional manufacturing method, that is, when a heating wire having a predetermined resistance value is made into a single cylinder having a single cross-sectional area, heat is generated by flowing a current therein so that the heating wire itself is one body. As a result, minute and very frequent heat changes do not occur.

However, if this hot wire is internally divided into a plurality of fine wires and made into ones having a plurality of ultra fine cross-sections, put them together to have a synthetic resistance value equal to one cross-sectional area, there is no difference in resistance value, but the internal hot wire body has one body. It is not a plurality of torso, it is possible to constantly maintain the temperature change action at ΔT time in the hot wire material itself by the principle described above.

Therefore, the geometry of a heating wire that has a structure that generates a number of continuous minute temperature changes at an instant in the heating wire itself has a predetermined resistance value, and when the electricity is flowed, the microfibers of the multiple strands that emit far infrared rays, the total area of each other Combined in a parallel structure to make contact, the combined resistance value is the same as that of one cross section, but each strand should have a certain resistance value, and the smaller the cross-sectional area of each strand (the more the number of strands of split microfiber) It is a good structure.

In conclusion, in order to emit far infrared rays more effectively, it is necessary to continuously generate a change in the magnitude of the dipole moment to generate electric dipole radiation and to make it larger so that the infrared rays can emit an effective and large amount of heat rays.

As such a method (technology), all the ultrafine wires prepared in Example 13-4, all the ultrafine wire groups prepared by the above-described method in Example 13-9, or the Example 13- 9) After preparing the micro wire groups more effective in performing the multi-function described above, among all the prepared micro wires, the micro wire groups, and the micro wire groups more effective in performing the multi-function,

Battery electricity or safe low-voltage direct-current (DC) power of 24V or less, many of which are multi-stranded microwires, multiple-group ultrafine wire groups, or a mixture of ultrafine wires and ultrafine wire groups that emit far infrared rays while generating heat due to resistance After selecting one or more of dogs, a composite combination is made by combining one or more of the multiple strands of the selected micro strand, the multiple group of the micro strand group, or a combination of the micro strands and the micro strand group in contact with each other. A composite combination of any one or more of these multiple strands, multiple groups of multiple strands, or a combination of multiple strands of microfine and fine strands, into one bundle, and such bundles, one strand When you have a geometry that makes a hot wire of,

In these hot wires, the geometry of the electric dipole radiation that emits far-infrared radiation can be better radiated.

In addition, as a method of making the geometry more efficiently, the electric dipole radiation from which the far infrared rays are emitted from the hot wire can be radiated much better.

Synthetic combinations inside the bundle,

When the resistance value, material or thickness of one or more of a plurality of micro wires, a plurality of micro wire groups, or a mixture of a micro wire and a micro wire group are one or more, the same condition may be used. Make different number of strands (or number of groups, or the number of mixtures) of one or more of the same, or the same, of the combination of the micro- and micro-wire groups, or a detailed description of these methods. Is described in detail in <Example 13-13-3-1>),

One or more of two or more groups having different resistance values and having a same resistance value for each group having a different resistance value, or a mixture of micro wires and micro wire groups having a same resistance value 1 It is a method of making the strand (or one group, one mixed one) or two strands (or two groups, two mixed ones) or more (for a detailed description of such a method, refer to Example 13-13-2 below. Details).

<Example 13-13-1-2>

② The heating wire of <Example 13-13-1> should be made of a material (material) that emits a large amount of far-infrared rays (especially, when the battery electricity or safety low voltage direct current (DC) electricity of 24V or less flows, the dipole moment is well achieved). Material).

As a result of experiments with samples made in real laboratories, when a heating wire is used as electricity (especially battery electricity or safe low voltage direct current (DC) electricity of 24V or less), a dipole moment occurs and a lot of far infrared rays are emitted. An effective material was to use a single metal or an alloy metal.

Among these single metals or alloy metals, in particular, when battery electricity or safe low voltage direct current (DC) electricity of 24 V or less flows, a dipole moment occurs and a far-infrared ray emits a good single metal or alloy metal.

When the material itself is heated to a temperature of 50 ℃, far infrared rays having a wavelength length in the range of 3 to 200 microns (μm), the metal or alloy metal that emits more than 60% emissivity,

Alloy metal containing pure iron,

Alloy metal containing carbon,

SUS 316, SUS 304, stainless steel alloy metal

Steel fiber (metal fiber) (NASLON),

Nickel copper alloy metal made from 20-25 wt% nickel and 75-80 wt% copper,

Among the alloy metals made of 68 to 73 wt% iron, 18 to 22 wt% chromium, 5 to 6 wt% alumina, and 3 to 4 wt% molybdenum, it is most effective.

<Example 13-13-2>

As described above in the <Example 13-13-1-1>, when the temperature change action is intensified, the radiation becomes larger, and at this time, the radiation is changed to far-infrared and more intensely and a large amount of emission occurs out of the hot wire. The method which can deepen the temperature change effect | action in T time is as follows.

Microwires are synthesized into multiple bundles to form one bundle and used as a single strand (bundle), while the microwires inside the bundle are divided into two or more groups to have different resistance values for each of the two or more groups. It is possible to combine two or more groups into a bundle of one body.

For example, one bundle of strands is divided into three groups, and the first group is made of one strand or two or more strands of a material having a high resistance value, and the second group is a medium resistance value. The fine wire of the material (material) is made of multiple strands of one or two strands or more, and the third group makes the ultrafine wire of the material (material) having low resistance value from one or two strands or more. Combine 1,2,3 groups into a bundle.

When electricity is supplied to one bundle made in this way, the first group has a high resistance value, so that a little current flows due to a small current, and the second group has a medium temperature as the resistance value is medium, and the third group has a resistance value. The low current causes a large amount of current to flow, resulting in high heat.

In this case, the temperature difference becomes larger in each group, so that the heat convergence process is carried out in order to overcome the temperature difference in each group. The speed and effect of heat change in ΔT time are further exacerbated by the deepening of trains in three groups than when the ultra fine wire is composed only of materials generating the same heat.

In addition, in the same manner as described above, by synthesizing a plurality of ultra-fine wire group group into a bundle and using it as a single strand of wire (bundle), the ultra-fine wire group in the bundle is divided into two or more groups, each of two or more Each group is composed of ultra-fine wire groups having different resistance values, and the same effect is obtained even when using two or more groups as a bundle of one body.

In addition, in the same manner as described above, a plurality of microwires and microfiber groups are mixed to form a bundle and used as a single strand of wire (bundle), while the microfibers and microfiber groups inside the bundle are mixed By dividing a large number of things into two or more groups, each of the two or more groups is composed of a mixture of micro wires and micro wire groups having different resistance values. The same effect will come out.

In conclusion, one bundle (hot wire) made by the method of <Example 13-13-1-1> is used for a micro strand of a plurality of strands, a micro group of a plurality of groups, or a mixture of an ultra fine line and an ultra fine group In a heating wire synthesized by any one or more of a plurality of wires, one bundle (heating wire) is made by dividing into two or more groups having different resistance values, and each group having a different resistance value internally uses the same resistance value. Branches have one or more strands (or one group, one mixed) or two strands (or two, two or more mixed) of the micro wire, the micro wire group, or a mixture of the micro wire and the micro wire group. By making it the above method, the effect of temperature change can be deepened.

In addition, a more effective way of varying the resistance value of each group, it is divided into two or more groups having different heating function, or divided into two or more groups of different materials or different thicknesses Branches are divided into two or more groups, and made by any one or more of these methods, in which different groups have a micro wire, a micro wire group, or a mixture of micro wires and micro wire groups having the same resistance value. If one or more of them are made of one or more strands (or one group, one mixed) or two strands (or two, two or more), the resistance value of each group is more effectively You can do this differently, and this will exacerbate the temperature change.

And when this temperature change is intensified, the far-infrared radiation becomes larger, and the change to far-infrared causes more intense and larger emissions out of the hot wire.

<Example 13-13-3>

Far infrared rays are emitted from the bundles (hot wires) by the method of <Example 13-13-1> to <Example 13-13-2>, wherein the emission effect (far infrared ray emission amount and retaining size) of such far infrared rays is controlled. How to do this.

As a more effective way to control the emission effect of far infrared,

① In any of the above-described <Example 13-13-1> to <Example 13-13-2>, any of a plurality of micro strands of a plurality of strands, a group of micro strands of a plurality of groups, or a mixture of a micro strand and a micro strand group A method of changing (adjusting) at least one of the number of strands of the ultrafine wire, the number of groups of the ultrafine wire group, or the number of mixtures of the ultrafine wire and the ultrafine wire group in a hot wire synthesized with at least one;

② In the above-mentioned <Example 13-13-1> to <Example 13-13-2>, any of a plurality of micro strands of a plurality of strands, a micro group of a plurality of groups, or a mixture of a micro wire and an ultra fine group In the heating wire synthesized by one or more, a method of controlling the heating temperature of the bundle (heating wire) itself,

③ By changing (adjusting) any one or more of the number of strands of the ultrafine wire group, the number of groups of the ultrafine wire group, or the number of mixtures of the ultrafine wire and the ultrafine wire group by a method combining the method of ① and ② above. At the same time, there is a method of controlling the heating temperature of a bundle (heating wire) itself.

<Example 13-13-3-1>

① of <Example 13-13-3> In the above <Example 13-13-1> to <Example 13-13-2>, a plurality of micro-fine wires, a group of micro-fine wires, or a micro-fine wire and an ultra-fine wire Changes in any one or more of the number of strands of the micro wire, the number of groups of the micro wire group, or the number of mixtures of the micro wire and the micro wire group in the hot wire synthesized by any one or more of the mixture of the line groups. The following describes in more detail how to (adjust).

Assume that there is an ultrafine wire made of a single metal or an alloy metal, having a predetermined resistance value and emitting far infrared rays when electricity flows.

In the first method, it is assumed that ten extra fine wires having the same resistance value are combined at regular intervals.

In the second method, it is assumed that 20 micro wires having the same resistance value are combined at regular intervals.

Assuming that the values of the ten ultrafine hot wire composite resistances of the first method and the twenty ultrafine hot wire composite resistances of the second method are the same,

Even though electricity flows through 10 ultrafine heating wires and 20 ultrafine heating wires at the same time, each of the heating wires transmits heat generated by the body to the partner, and heat generated from the counterpart is heat balanced by itself, but internally balanced. When you see the microscopic state of phosphorus, there is a constant temperature difference and it converges to the thermal equilibrium state repeatedly.

If you observe this condition more microscopically, ten microfine heating wires of the first method and 20 microfine heating wires of the second method generate heat at the same temperature, but they heat each other instantaneously, but also heat upside down. When it heats, it cools down to its own heating temperature, and when it receives heat, it rises above its heating temperature, and the temperature change occurs thousands of times more than a second.

If you observe this more closely, the temperature change quantity at ΔT time causes more temperature change in the case of 20 ultrafine heating wires of the second method than the 10 ultrafine heating wires of the first method.

Because the number of individuals that heats 20 times more than when 10 heat wires is 10 times, the number (heat) of heat wires to each other in △ T time also increases, which is more temperature change within △ T time May cause

In addition, if this temperature change can be caused within this ΔT time, as described above in the above embodiment, the radiation becomes larger when this temperature change action is intensified, at which time it changes to far-infrared rays in a larger amount and more out of the hot wire. As it is released effectively,

When 20 ultrafine heating wires of the second method are synthesized, the far infrared radiation dose (emission amount) becomes larger than when 10 ultrafine heating wires of the first method are synthesized.

In conclusion, the method (technology) to control the emission effect of far infrared rays,

All the ultrafine wires prepared in Example 13-4, all the ultrafine wire groups prepared by the method described in Example 13-9, or the multi-function described in Example 13-9 After preparing the microfiber groups that are more effective to perform, among all the microfibres, the microfiber groups, and the microfiber groups that are more effective in performing the multi-function,

The number of strands of the micro wire, the micro wire group of which is composed of at least one of a plurality of micro wires having the same conditions, a plurality of micro wire groups, or a mixture of a micro wire and a micro wire group. By changing (adjusting) one or more of the number of groups of, or the number of mixtures of the ultrafine wires and the ultrafine wire groups, the amount of far-infrared radiation in the heating wire can be adjusted.

Thus, the number of strands of the micro fine wire, the micro fine wire, in the hot wire synthesized by any one or more of a plurality of micro wires having the same conditions, a plurality of micro wire groups of a plurality of groups, or a mixture of a micro wire and a micro wire group. A more detailed description of how to change (adjust) one or more of the number of groups of line groups, or the number of mixed fine and fine line groups,

① Synthetic resistance per unit length of the entire bundle of one bundle (hot wire) in a hot wire synthesized by any one or more of a plurality of micro wires, a plurality of micro wire groups, or a mixture of a plurality of micro wires and a micro wire group. A method of adjusting the number of strands (or the number of groups, or the number of mixtures) of any one or more of the same, but the inside of the fine wire, the fine wire group, or a mixture of the fine wire and the fine wire group;

(2) Any one or more of a plurality of micro fine wires having a plurality of strands having the same material, the same resistance value, or the same thickness among the same conditions, a plurality of fine wire groups of a plurality of groups, or a mixture of a fine wire and a fine wire group In a heating wire composed of two or more multiple groups and made of one bundle, the combined resistance value per unit length of one bundle (heating wire) is the same, but within each corresponding group, the fine wire and the fine wire inside the bundle There is a method of individually controlling the number of strands (or the number of groups, or the number of mixtures) of one or more of the groups, or a mixture of the ultrafine wires and the ultrafine wire groups, respectively.

Here, the same condition of any one or more of the ultrafine wire, the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group refers to the same one which is at least one of resistance value or material or thickness of the ultrafine wire.

<Example 13-13-3-2>

② In <Example 13-13-1> to <Example 13-13-2> of <Example 13-13-3>, a plurality of micro strands, a group of micro strands, or a group of micro strands and micro strands Among the plurality of mixed sun groups, a method of controlling the heating temperature of the bundle (heat wire) in a heating wire made of one bundle by synthesizing one or more of them in more detail will be described below.

Molecules (atoms) of all materials are always vibrating with their own vibration width (radius) at a constant temperature. As the heat increases, the natural vibration width of these molecules increases.

On the other hand, all atoms consist of small particles, particles, neutrons, and protons. These nuclei have their own periodic cycles, which always rotate in a certain direction and have a constant momentum.

The sum of the momentum of these nuclei is called nuclear-spin, which increases proportionally as the intrinsic oscillation width of the atoms increases.

As a result of experiments with samples made in the laboratory, the amount of energy retained in the heating wire manufactured by the method of <Example 13-13-1> to <13-13-3-1> is such that As you increase the size, you will find it gets bigger.

Therefore, the larger the nuclear-spin of the atoms that make up the material of the multi-strand microfiber inside the bundle (heat wire), the more powerful effects such as far-infrared rays from the sun (how effective are they changed? How far the wavelength (far infrared) can fly (accuracy, efficiency), how much the wavelength (far infrared) of this light is absorbed by the material (accuracy, efficiency), and the wavelength of this light (far infrared) The difference in how much heat is reduced back to the heat (degree, efficiency).

Therefore, if the self-heating temperature is raised in one bundle manufactured by the method of <Example 13-13-1> to <Example 13-13-3-1>, the atomic nucleus-spin of the hot wire material is accordingly increased. This rises, which increases the energy retained by the far-infrared rays emitted from the heating wire, and the heat of the bundle itself causes an increase in the energy size, and the corresponding bundle (heating wire) itself. Exothermic temperature control is a method of controlling energy size.

Here, the bundle (heating wire) heating rate is not directly proportional to the amount of energy possessed by the far-infrared rays that radiate, and when the bundle (heating wire) heating temperature is 80 ℃ to 600 ℃, the energy size according to the temperature rise is most effectively. It can be seen that the degree rises in proportion to a certain degree, and the energy retention degree is significantly reduced or not retained at 80 ° C. or lower or 600 ° C. or higher.

In conclusion, all the prepared ultrafine wires of <Example 4>, all the ultrafine wire groups prepared by the method described in the above <Example 13-9>, or the multi-function described in the above <Example 13-9> After preparing the micro wire groups more effective in carrying out the above, among all the prepared micro wires, the micro wire groups, and the micro wire groups more effective in performing the multi-function,

Battery electricity or safe low-voltage direct-current (DC) power of 24V or less, many of which are multi-stranded microwires, multiple-group ultrafine wire groups, or a mixture of ultrafine wires and ultrafine wire groups that emit far infrared rays while generating heat due to resistance And select one or more of them, and then combine the selected one or more of the multiple strands of the multiple strands, the multiple group of the fine strands, or a mixture of the micro and the ultrafine group to contact each other to form a composite combination. A composite combination of any one or more of these multiple strands of microfibers, multiple groups of microfibres, or a mixture of micro and microfibers, into one bundle, such a bundle being one strand In the bundle (heating wire) manufactured by the method of making the heating wire of

By adjusting the self-heating temperature of the bundle (heating wire) to adjust the amount of energy retained by the far-infrared rays emitted here, the control temperature is most effective when the temperature is 80 ℃ ~ 600 ℃.

 In addition, the method of controlling the self-heating temperature of the bundle (heating wire) is a method of controlling the amount of current flowing into the bundle (heating wire) by adjusting a resistance value per unit length of the bundle (heating wire). By adjusting the self-heating temperature of

 The method for adjusting the resistance value per unit length of the bundle (heat wire) itself, the safety of the battery or 24V or less of the bundle (heat wire) itself described in Examples 13-3 to 13-4 By using a low voltage direct current (DC) electricity made of a customized heating element having a variety of low resistance value required to obtain the desired heat, the bundle (heating wire) itself, that is, through the combination change described in the <Example 13-5> One heating wire is adjusted in such a way that the desired low resistance value per unit length can be customized as desired with one resistance value.

<Example 13-14>

The instantaneous high temperature heating and the high efficiency heating function of ② in <2> of <Example 13-3> and any one or more functions described above in <Example 13-10> will be described. For this purpose, it must be a structure that is high resistance and can flow more current during ΔT, and reduce the skin effect of the resistance.

In more detail, the skin effect is generated as in the conductor when the resistance is tested.

In other words, the larger the cross-sectional area through which the current flows through the resistor, the less the surface of the resistor acts as a resistance due to the skin effect, which is extremely just a conductor, and the current flowing through the skin just flows without doing work (heating) and wastes the current. It causes.

This skin effect greatly reduces the heat generation efficiency as a resistor, and generates much less heat than Joule's Low as power is consumed.

Therefore, in order to minimize the inefficient structure due to the skin effect, the surface area of the resistor should be small.

For example, assuming that a heating wire having a resistance value of 1 mW is made at 1 m, assuming that a cross section for passing current is required to have a thickness of 1, a plurality of sections having a smaller cross-sectional area than those made of a single cylinder are finer than many. When dogs are synthesized and made into one bucket, the epidermal effect can be eliminated much more, resulting in a more efficient heating structure.

Therefore, the structure of a heating wire (heating element) having an efficient heat generation structure synthesizes a plurality of ultrafine wires having a high resistance value into a parallel structure in which the entire area is brought into contact with each other, while reducing the combined resistance value, The smaller the cross-sectional area is, the better the structure should be.

In this way, heating wires (heating elements) can flow a large amount of current in the ultrafine set of high-strength multi-strands and at the same time minimize the skin effect. It is a highly efficient structure that can consume a small amount (efficiently) and obtain a large amount of heat.

Therefore, the principle of manufacturing a high-efficiency heating wire or heating element (which generates a large amount of heat with small power consumption) is that if a plurality of ultra-fine wires having high resistance values are bundled (synthesized), the actual resistance value of each fine wire Although the high state is high, the multiple strands of fine wires are combined in a parallel structure, resulting in a drop in the composite resistance value, which lowers the resistance value in the entire heating wire, and has a high resistance value and allows a large amount of current to flow. It generates a high efficiency heating operation.

In fact, it is possible to maintain a high resistance value in a state where a large amount of current is present in each of one strand and one strand of the ultrafine wire, thereby instantly generating a high calorific value (high temperature) in one strand. It has a structure.

In addition, each of the multiple strands of the ultra-fine wire is instantaneous high-speed, ultra-high heat generation operation is instantaneous, which is combined with the heat generated instantaneously generated in the entire bundle, resulting in a high-efficiency heat generation state, the higher the structure is strengthened ultra-high heat generation operation Will cause.

This instantaneous instantaneous ultra-fast, ultra-high temperature heating operation, a method for making a heating wire (heating element) having a high-efficiency heating structure, for example, first of a single metal or alloy metal with a fine thickness to the line (thread) Make multiple strands

When the single metal or alloy metal is made into a fine wire, the resistance of the fine wire is naturally high.

Then, by combining the multiple strands of these multiple strands into one bundle, a heating wire (heating element) having the same thickness and shape as one strand of thread is manufactured.

Then, if current is flowed to the electric wires of both ends, it generates instantaneous ultra-fast and ultra-high efficiency heat.

In conclusion, in order to make a heating wire desired in the present invention to generate instantaneous high temperature heating, high efficiency heating, <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13- In the finer wires used by the strands used in

The fine lines used by the single strand can be divided into more finely divided into multiple strands, or the finer wires are made in such a way that the number of strands is increased while making the thickness of the fine lines thinner. If you make a bundle by synthesizing into a combination, this bundle has the desired instantaneous high temperature heating function and becomes a heating wire that generates high efficiency heat.

Therefore, as a result of confirming the above contents through actual own experiments, 1 used in <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8> For the micro wires used in strands,

The micro fine wires used by each strand are made of ultra fine wires having a very thin thickness of 20 μm or less (based on the ultra fine wire diameter), and then the same fine wires are bundled in a plurality of strands of 100 or more strands with the same thickness and conducting contact Synthesized into one bundle, instead of the ultrafine wires used by one strand, one bundle or two or more bundles by themselves are synthesized into one bundle or used as a single bundle, or by the single strands Combination and use of any one or more micro wires suitable for the intended use (mixed with the micro wires used by the one strand, or used in addition to the micro wires used by the one strand) as described above It has a function of instantaneous high temperature heating and becomes a heating wire for high efficiency heating.

<Example 13-15>

If the constant temperature holding function of item ③ of any one or more of the above-mentioned function of item ② of <Example 13-3> and <Example 13-10> is described,

The heating element (heating wire) is a very important technical difference whether or not the ability to maintain a constant temperature in the material itself while the heating is started and the electricity is continuously supplied.

This is because if the heating element itself does not have a constant temperature function, if it is in danger of overheating (if the thermostat fails and electricity is supplied continuously, the heating wire is folded or covered with an insulating material). This is because the safety of the heating element is not guaranteed because it leads to fire due to the constant temperature rise.

For this purpose, the heating elements of the polymer conductive powder (carbon, etc.) are mixed in a liquid binder, inkized, coated on a thread or coated on a cotton, and used in various combinations, and the PTC principle is operated by the powder. In the long-term use, however, the powder may fall out due to the difference in the expansion / expansion coefficient between the liquid component and the powder component, causing local breakage, causing current draw phenomenon (well effect), and causing a fire.

In the present invention, the heat wire is composed of a plurality of fine wires for the function of maintaining the temperature of the heating wire itself, the first type group is composed of a micro-wire group having two kinds of heat generating function to generate heat continuously when current flows unconditionally The second type of group has two functions, which generate less heat after reaching a predetermined temperature and allow the current to flow just like a conductor, rather than generating heat as a conductor. It is used to make a bundle of 1 strand of a body by synthesizing a group of ultra-fine wires with a wire.

To introduce this in more detail, for example, the first type group uses an alloy, and uses an alloy material having a small change in resistance value even when the temperature increases, such as steel fiber, to make a fine wire.

The steel fiber of the alloy shows a small change in the resistance value even when the temperature rises (the resistance value increases slightly when the temperature rises), and generates electricity continuously while electricity flows, and the temperature continuously rises.

Therefore, when the supply voltage is constant, the steel fiber microfibers of the first type group have a slight increase in the resistance value even when the temperature increases, so that the current value will decrease only slightly, and as the current flows steadily as the temperature increases, The steel fiber microfibers of the first group continuously increase the temperature (strictly, as the temperature increases, the resistance increases slightly, so that the amount of current decreases slightly. As the amount of current decreases, the temperature increase rate decreases slightly and the temperature decreases. Is elevated).

At this time, the temperature will be increased steadily until the heat that is taken away to the surroundings and the heat that continuously raises the temperature (heat generated from the first class steel fiber microfibers) are in equilibrium. Proportional to the amount of calories and will drop gradually).

Next, the second type group also uses an ultrafine wire made of an alloy material, and the alloy used here exhibits a large change in the resistance value as the temperature increases (the resistance is completely different from that of the first type group as the temperature increases). Alloy material), which has a significantly lower value.

As such, when the temperature rises, a silicon copper alloy including a certain ratio of intrinsic semiconductor is used as an alloy having a low resistance value.

The intrinsic semiconductor has a large change in resistance value when the temperature rises, but the resistance value drops significantly when the temperature rises.

In particular, in a certain temperature range, the temperature and the resistance value are completely inversely proportional to each other, and the resistance value is rapidly reduced when the temperature reaches a certain temperature, thereby becoming a conductor.

Silicon is a typical material that makes good use of intrinsic semiconductor properties.Since silicon alone is difficult to make a metal (particularly because it is difficult to make an ultrafine wire), it is a more efficient method, which is made of copper and alloy. The copper copper alloy metal is used to make an ultrafine wire.

The silicon copper alloy ultrafine wires made in this way have intrinsic semiconductor components only in a certain state in the state of many conductor components, which are the essence of copper, and heat is generated when current starts to flow at first, and when the temperature is below a certain temperature, It has the property of resistance (heating element, heating wire) and generates heat continuously.

Then, as the temperature rises, the silicon component begins to drop the resistance value, and when the temperature rises above a certain temperature, the resistance value drops rapidly to become a conductor (the resistance value drops like a conductor).

For example, at 20 ° C ambient, the silicon copper alloy (20% silicon and 80% copper alloy) has a resistance of 50 (Ωmm2 / m). Copper is a conductor and the resistivity becomes 0.0169 (Ωmm2 / m) at a temperature of 20 ° C.

The two grouped conductors play the role of conductors that flow current with almost no heat.

The fall of the resistance value is based on the ratio of the total silicon content based on the total amount of silicon mixed in the silicon copper alloy ultrafine wires of the second group, and the resistance value drops and is completely conductive when a certain temperature is reached.

On the other hand, the variable that determines the degree of the fall of the resistance value is a state in which impurities inside the crystals constituting the silicon crystals are mixed. Thus, as the temperature rises depending on how much impurities are mixed with the silicon crystals to form, How much the resistance can be drastically reduced in the temperature range varies greatly.

Therefore, how much the resistance value can be drastically lowered at which temperature as the temperature rises in the entire ultrafine wire forming the second type group, how much is the total content of silicon and how much impurities are contained in the silicon itself crystals. It can be adjusted according to whether or not to include, and the degree of resistance, that is, the degree of conduction, can be adjusted in such a manner that the resistance value drops rapidly from which temperature value as the temperature rises.

When current flows through the heating wire made as above, both the first type and the second type groups generate heat and rapidly rise up to a certain temperature, and then, in a certain temperature section, the second type group stops heating and switches to the role of a conductor. By letting the water just flow, the heat generated from the heating wire is rapidly reduced, and the heat balance is taken out of the surrounding heat, so that the constant heat is maintained without the regulator in the heating material itself.

In conclusion, as described above, when the heating wire required in the present invention, when equipped with a heating device, is crushed and folded, and the tensile force is also applied, and the risk of fire accidents are often present because the situation is often overheated,

During the heating operation and the electricity is continuously supplied, the constant temperature function is always expressed in the material itself, so that there is no change in the temperature of the surrounding environment in the heating wire (sides) material itself without using a separate control device. After rising to the temperature, the temperature at which the rising stops must be implemented to keep the constant constant.

Therefore, in order to make the heating wire required in the present invention have the function of maintaining the temperature as described above, all the ultrafine wires prepared in Example 13-4 and all the ultrafine wire groups prepared by the method described above in Example 13-9 Or, after preparing the micro wire groups more effective in performing the multi-function described in Example 13-9, all the micro wires, the ultra-fine wire groups, and the microfiber more effective in performing the multi-function are prepared. Select any one or more of the linegroups,

Any one or more of the selected ultrafine wires, the ultrafine wire groups, or a mixture of the ultrafine wires and the ultrafine wire groups may be two or more strands (or a plurality of groups, or a plurality thereof). In synthesizing to create a combination,

Prepared in advance or prepared by the actual experiment for the present invention in the above Example 13-7, or a variety of resistance values, thicknesses, materials, functions in the database of the existing ultra fine wires in circulation Microwires (or microwire groups, or microwire groups, or microwire groups) made of different materials in the classifier of a material among the types of fine wires classified (or groups of microwires and microwires). The fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group) of a material suitable for the specification is selected (selected).

That is, the combination of the inner micro fine wires (or the ultra fine wire group, or a mixture of the ultra fine wires and the ultra fine wire groups) of the bundle (heat wire) to be produced is Mixed use)

A plurality of strands (or a plurality of groups) of two or more (or two or a combination of two or more) of an ultrafine wire (or a combination of an ultrafine wire group or an ultrafine wire group) having a predetermined resistance value selected above. Or a plurality of blends) to form a combination and such a combination becomes a heating wire required by the present invention.

The multiple strands (or plural groups, or plural mixtures) of the ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wires and the ultrafine wire group) are groups having two kinds of functions having different heating functions. The first type group continues to generate heat when current flows, and the second type group generates less heat after reaching a predetermined temperature and conducts current as a conductor rather than generating heat. You just need to make the function that makes it run bigger.

And the material of the ultra-fine wire (or the ultra-fine wire group, or a mixture of the ultra-fine wire and the ultra-fine wire group) having the two kinds of heat generating function, the first type group is a steel fiber, the second type group is made of a copper alloy It is more effective to make it have the function of maintaining the temperature required for the present invention.

<Example 13-16>

Among the above-mentioned functions (2) of <Example 13-3> and <Example 13-10>, the function of excellent tensile force and durability of item (4) and easily disconnecting or hardly changing the resistance value of item (4) To explain,

The heating wire required in the present invention is wrinkled, folded and exerted when the low-resistance multi-heat solar photovoltaic heating system made by the present invention is applied, and the inner heating wire is disconnected or the resistance value of the heating wire material itself. Changes can lead to fire accidents due to short or local overheating.

Therefore, when the heating wire required in the present invention is provided in the low resistance multi-heat solar power generation heating system, the resistance value change or disconnection should not occur easily even if it is folded, bent, and used infrequently.

However, in order to more effectively implement the function that the heating wire required by the present invention has excellent tensile strength and durability, and is easily disconnected or little change in resistance value, the tensile strength of the material (material) of the ultrafine wire constituting the heating wire itself. , Flexibility, the fineness of the fine wires, and the number of strands of the fine wires constituting the heating wire are variables.These variables cannot be measured by estimation or estimation. There is no choice but to depend.

Therefore, in order to implement the present invention, as a result of experiments, it was possible to find out the material, thickness and number of strands of the ultrafine wires that have a function of excellent tensile strength and durability, and easily disconnected or little change in resistance value. The contents are as follows.

First, in fact, as a result of in-house experiment (experiment 1), the material is steel fiber (NASLON) and the thickness of one strand is 20㎛ or less, and the bundle is made by energizing synthetic combination with 100 or more strands of the same thickness. ,

In order to test whether or not it was easily disconnected, the folding test was not conducted even after folding and retracting 100,000 times, and there was no change in resistance value.

Second, in fact, in the laboratory itself (Experiment 2), NASLON 1 strand of steel fiber was 12㎛ thick (correspondingly fine wire diameter), and it is a very fine wire group composed of 550 strands with the same thickness, or NASLON which is steel fiber. The thickness of one strand is 8 µm (the corresponding fine wire diameter), the number of strands is the ultrafine wire group consisting of 1,000 strands with the same thickness, or the thickness of one strand of NASLON, which is steel fiber, is 6,5 µm (the corresponding fine wire diameter), Of the ultra-fine wire group consisting of 2,000 strands with the same thickness, any one or more groups are combined into one or more groups to form one bundle with an energized synthetic combination,

In order to test whether the wire was easily disconnected, the folding test was not performed even after folding and removing 700,000 times, and there was no change in resistance value.

Third, in fact, in a laboratory (Experiment 3), the first group of steel fibers, NASLON 1 strand is less than 12㎛ (approximately fine wire diameter) and the same thickness, the number of strands are more than 550 strands The fine wire group that combines the group into one or more groups and the second fine wire made of a metal or alloy metal, the thickness of which is less than 140 μm (the corresponding fine wire diameter), and the number of strands is equal to 1 A micro wire or a micro wire group consisting of more than one strand, or one micro wire made of nickel-copper alloy metal having a thickness of 180 µm or less (corresponding micro wire diameter), and having the same thickness, A micro wire group, or one micro wire made of iron chromium alumina molybdenum alloy metal, has a thickness of 140 μm or less (corresponding micro wire diameter) or less, and the number of strands having the same thickness is 1 or more Any one or more of the ultrafine wire group is a bundle of energized synthetic combinations of a combination of the ultrafine wire group of any one or more of the first group and the ultrafine wire or ultrafine wire group of any one or more of the second group. After creating

In order to test whether or not it was easily disconnected, the folding test was not conducted even after folding and retracting 100,000 times, and there was no change in resistance value.

In conclusion, a method of making a hot wire which has a function of excellent tensile strength and durability, easily disconnected or little change in resistance value based on the results of the laboratory's own experiment, is based on the results found in Experiments 1 to 3 above. Only when you make a hot wire can you be sure of its function.

<Example 13-17>

The function of inhibiting the oxidation reaction of item (5) of the above item (2) of <Example 13-3> and <Example 13-10> described above will be described.

The heating wire required by the present invention should be used without failure for a long time when used in a low-resistance multi-heat photovoltaic heating system made by the present invention.

By the way, heating wire is usually heated and cooled down, it causes oxidation reaction and the heating wire material itself hardens as the use period elapses, and when this hardening action is intensified (more long-term use), the heating wire material itself hardens. The degree is increased and easily broken or broken, causing a problem of disconnection.

Therefore, in order to solve the problem of the oxidation reaction of the heating wire, the material (material) of the heating wire to be used is selected by using less oxidation reaction, or the material (material) made by using a method in which the oxidation reaction is suppressed. Should be used.

However, finding or realizing a material (material) having a function of suppressing such an oxidation reaction cannot measure its effectiveness by calculation or estimation, and only depends on the results of actual experiments.

Therefore, in order to implement the present invention, as a result of experiments, it was possible to find a material (material) and a part of the method of making a minimal fine wire having a function of suppressing oxidation reaction (found).

First, all the heating wires required in the present invention are made of a single wire or an ultrafine wire of an alloy metal, but must be coated and used.

As a result of in-house experiment, in all the ultrafine wires used by one strand used in <Example 13-4>, <Example 13-5>, <Example 13-6>, and <Example 13-8>, The actual experiments (when the heat is applied to the sample heating wire and the cooling cannot be repeated) are used for the random samples and when the coating is used without the coating, and the coated state is harder than the uncovered state. The period of absence showed a difference of more than 100 times.

Second, the ones made of the ultrafine wires using any one or more of the following materials of the ultrafine wires used in the hot wire, it was confirmed that the effect of inhibiting the oxidation reaction is very excellent.

In other words, it is an ultrafine wire having the function of suppressing the oxidation reaction,

SUS 316, SUS 304, stainless steel alloy metal,

Steel fiber (metal fiber) (NASLON),

Alloy metal made by adding a small amount of molybdenum to nickel copper alloy,

The material is an iron chromium alumina molybdenum alloy, an alloy metal made by adding at least one of manganese and carbon, and using an ultrafine wire made of at least one material,

Making the heating wire necessary for this nickname becomes a heating wire having a function of suppressing oxidation reaction.

<Example 13-18>

Referring to the method of making the hot wire having excellent flexibility described in section ③ of the <Example 13-3> and the <Example 13-10>,

In order to be able to obtain future energy indefinitely at many sites where mankind needs energy for heating heat in the future, we need to increase photovoltaic facilities, and install these photovoltaic facilities and electric storage devices directly on sites that need heat. And use it directly to get the heating heat you want, and to do this, you have to make an electric heating wire, and you need to make it according to the site conditions and various specifications. , The prefabricated heating wire according to the present invention is more flexible for applicability and custom fabrication.

Therefore, the method of making the flexible hot wire,

After numerous experiments,

The heating wire required by the present invention is made the same as the resistance value when one strand is made, but when the thinner fine wire is made by synthesizing a plurality of strands, it has the same resistance value as the one strand but is flexible. Is excellent,

In particular, while having the same resistance value as when made of one strand, the finer the thinner the finer wire and the more the number of strands is more flexibility is more excellent.

<Example 13-19>

In the above ① of <Example 13-1> and <Example 13-3>, among the battery electricity or battery electricity, a low resistance value necessary for obtaining desired heat by using a safe low voltage direct current (DC) electricity of 24 V or less, in particular, If we talk about another effective way of making things,

The electricity produced (generated) by the technology of the future energy power generation system according to the present invention is stored in the electric storage device as all the electricity in the charging station as described in the <Example 1> to <Example 12> (charge) The electricity output from the electrical storage device is all direct current (DC) electricity, almost all of the low voltage electricity of direct current (DC) 24 V or less, and all the electrical storage devices are internal. Since the battery is mounted on the battery, the electricity output (discharged) from the electrical storage device, which is an essential component of the present invention, is all battery electricity.

Therefore, in the above ① of <Example 13-1> and <Example 13-3>, the battery electricity is electricity output from the electrical storage device which is stored (charged) at the charging station and brought to the electrical consumer. Is direct current (DC) electricity,

 In addition, in (1) of <Example 13-1> and <Example 13-3>, the battery electricity is a low voltage electricity of 24 VDC or less and is a battery electricity.

Therefore, the battery-operated prefabricated heating wire should be made to have the low resistance value required to obtain the desired heat using battery electricity or battery electricity, especially safe low voltage direct current (DC) electricity below 24V,

It should be a heating wire that generates a large amount of heat at a very low ultra low voltage below 24V.

However, in order for the heating wire to generate a large amount of heat at a very low ultra low voltage of 24V or less, since the voltage is very low, the resistance value of the heating wire must be very low so that a current that can generate a large amount of heat can flow. Example 13-3> is as described above in ①).

In particular, the longer the length of one circuit (current flowing simultaneously) of the heating wire to be used, the lower the resistance value per unit length of the heating wire should be.

However, when one circuit of the heating wire is too long, when the voltage becomes very low, the heating wire must flow like or below the conductor so that the current can flow, and the resistance value is as low as the conductor. The heating wire is not a heating wire, but a conductor (not having a predetermined resistance value that prevents the flow of current and generates heat, so that the heating can be carried out, and the function of flowing the current is much larger. These heating wires are not able to generate a large amount of heat enough to obtain the desired heat (only conductors).

Therefore, the resistance value per unit length of the heating wire to be used should be made by using any one or more of the following five methods as a method of making the heating wire that can generate the desired heat at a very low state. .

To this end, first, all the prepared ultrafine wires of <Example 13-4>, all the ultrafine wire groups prepared by the method described in the above <Example 13-9>, or described in the above <Example 13-9> After preparing the microfiber groups that are more effective in performing a multi-function,

In a first method, among all the prepared ultrafine wires, ultrafine wire groups, and more effective ultrafine wire groups more effective in performing a multi-function, a fine wire (or ultrafine wire group, or ultrafine wire) having a resistance value per unit length higher than a conductor The number of strands (or the number of groups, or the number of strands) of a micro wire (or a group of micro wires or a mixture of micro wires and micro wire groups) having a higher resistance value than these conductors after selecting a combination of a wire and a micro wire group. ) Are synthesized so that they are energized in contact with each other in the longitudinal direction (to allow current to flow freely from each other in contact with each other), but when the total combined resistance value is dropped with or below the conductor,

In the synthesized materials, each of the micro fine wires (or a combination of the ultra fine wire groups, or a combination of the ultra fine wires and the fine wire groups) individually has a higher resistance value than the conductor, so that the resistance value is high to flow more current than the conductor. Although it is not sent, it is a state that has a resistance value that heat is generated to some extent if only current flows, so the heat state is a state that generates more heat than the conductor,

While increasing the number of strands (or the number of groups, or the number) of each of the micro wires (or a combination of micro wires and groups of micro wires and micro wires), the synthetic resistance value is lowered to obtain a lower synthetic resistance value than the conductor. If you make it (increase the amount of synthesis), the current flows through each of the micro wires (or the combination of the micro wire group, or a combination of the micro wire and the micro wire group), the heat generated rather than the conductor is combined, the desired battery Among the electricity or battery electricity, it is possible to make the low resistance value required to obtain the desired heat by using the safe low voltage direct current (DC) electricity of 24 V or less,

A bundle of composites produced by lowering the composite resistance value while increasing the number of strands (or the number of groups, or the number) of each of the micro fine wires (or a combination of the micro fine wires and the ultra fine wire group). If the bundle is made of a single strand of wire, the hot wire will have a low resistance value necessary to obtain the desired heat using the safe low voltage direct current (DC) electricity of the battery electricity or battery electricity, especially 24V or less. It becomes a hot wire.

And a micro wire (or a micro wire group, or a mixture of micro wire and micro wire group) having a higher resistance value than the conductor used as described above is closer to the conductor than the resistance value is too high, or slightly resistance to the conductor. The higher the value is, the more effective it is in making the hot wire having the low resistance value.

In a second method, among the prepared ultrafine wires, the ultrafine wire groups, and the ultrafine wire groups more effective in performing a multi-function, the method is divided into two or more plural groups,

The first group selects a micro wire (or a micro wire group or a mixture of micro wires and micro wire groups) having a resistance value per unit length having the same resistance as or similar to that of a conductor,

After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than the conductor,

The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is When a single heating wire is used, the heating wire is a heating wire having a low resistance value necessary for obtaining desired heat by using a safety low voltage direct current (DC) electricity of 24 V or less, particularly among the battery electricity or battery electricity.

Because the resistance value per unit length of the heating wire to be used according to the present invention in order to make the heating wire that can generate the desired heat in a very low state, the use voltage is very low as described above, the resistance of the heating wire If the value is very low, enough current can flow. If the resistance of the heating wire becomes very low, as in a conductor, there is no heat in the heating wire (the resistance decreases, so the current just flows without generating heat). Increasing the resistance value of the heating wire prevents sufficient current flow into the heating wire, which also prevents a large amount of heat from being generated in the heating wire. A fine wire (or a combination of a fine wire group and a fine wire group) Focusing mainly on the ability to flow the current well, and in many groups of the second group or more, use a micro wire (or a combination of a micro wire group or a combination of a micro wire and a micro wire group) having a higher resistance value than a conductor. Thus, the focus is mainly on the function of generating heat well when current flows, and then the first group and the second group or more of the multiple groups of the ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wires and ultrafine wire groups) are used. ) Into a bundle by energizing in the longitudinal direction

In the bundle, when the battery electricity is supplied with safety low voltage direct current (DC) electricity of 24V or less, among battery electricity,

As the current flows toward the enhanced conductor function of the first group, heat is generated by flowing some current to the enhanced heat generation function of the multiple groups of the second group or more, and the remaining current continues to flow through the conductor to generate heat. Since the current is continuously transmitted to the reinforced side to generate heat, the conductor side of Group 1 has a low resistance value even when the voltage having the very low voltage is low, so that the current flows well through the conductor. Since the resistance value is higher than the conductor side and the ability to heat well is enhanced in this case, the current does not flow directly (in the direction of the series), but the current in the longitudinal direction of the first group Part of the current flowing into the conductor is transferred in parallel to generate heat-

Even at a very low voltage, it is possible to generate a large amount of heat generated by flowing a sufficient amount of current through some of the fine wires (or the combination of the fine wire group and the micro wire group) having a high resistance value. ,

As a result, even if the desired heating wire in the present invention is a heating wire having a very low length and a very low resistance value per unit length, the heating wire can generate a large amount of heat with electricity having a very low voltage. Battery-powered prefabricated heating wires can be made.

In the third method, the heating wire made by the present invention is suitable for use in a place or a facility having a high ambient temperature.

Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups more effective in performing a multi-function, the method of selection is divided into two or more plural groups,

The first group is a micro wire (or micro wire group, or micro wire) that generates less heat after reaching a predetermined temperature and performs a function of allowing the current to flow just like a conductor rather than generating heat while being conductive. A mixture of lines and microfiber groups)

After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than the conductor,

The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is When the heating wire is made of a single strand, the heating wire becomes a heating wire having a low resistance value required to obtain desired heat using a safety low voltage direct current (DC) electricity of 24 V or less, particularly of battery electricity.

Because the resistance value per unit length of the heating wire to be used according to the present invention in order to make the heating wire that can generate the desired heat in a very low state, the use voltage is very low as described above, the resistance of the heating wire Only a very low value will allow enough current to flow.

When the safety electric wire of the battery electric or battery electric, such as 24V or less, especially in the heating wire made as described above,

In the first few hours, since the resistance value of the heating wire is higher than that of the conductor, the current does not flow or finely flows, so that little heat is generated. The temperature at which the temperature is constant according to the ambient temperature (the temperature that allows the current to flow like a conductor rather than to generate heat while conducting less heat after reaching the predetermined temperature of the first group). Since the first group is conductive, the resistance of the first group is greatly reduced, so that sufficient current can flow through the first group to generate a large amount of heat, and such a sufficient current flows. It generates heat by flowing some current to the side of the heat generation function of the second group or more, which is strengthened. If current is going to flow haejueo continue to ride the current conductor passes continuously into a heating feature enhanced doemeuro to remind the heat,

Even at very low voltages, it is possible to flow a sufficient amount of current through some microwires (or microwire groups, or a mixture of microwires and microwire groups) with high resistance values, so that a large amount of heat can be generated. ,

As a result, even if the heating wire desired in the present invention is a heating wire having a very low length and a very low resistance value per unit length, the battery desired in the present invention can generate a large amount of heat with electricity having a very low voltage in such heating wire. It is possible to make an electrically operated prefabricated heating wire.

In addition, the method of implementing the function of allowing the first group to simply flow current like a conductor rather than to generate heat while conducting less heat after reaching a predetermined temperature is described in Example 13-15. It is as described above in the constant temperature holding function of.

In the fourth method, the heating wire made by the present invention is a method suitable for use in generating a large amount of heat generated in a place or a facility having a low ambient temperature,

Among the prepared ultrafine wires, ultrafine wire groups, and more effective ultrafine wire groups, which are more effective in performing a multi-function, there are divided into three or more groups in a method of selecting,

The first group is a micro wire (or micro wire group, or micro wire) that generates less heat after reaching a predetermined temperature and performs a function of allowing the current to flow just like a conductor rather than generating heat while being conductive. A mixture of lines and microfiber groups)

The second group selects a micro wire (or a micro wire group or a mixture of micro wires and micro wire groups) having a resistance value per unit length having a resistance value similar to that of a conductor or substantially similar to that of a conductor,

After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,

The first group, the second group, and the third or more groups of microfibers (or microfibers, or a mixture of microfibers and microfibers) are combined into a single bundle by energizing and contacting each other in the longitudinal direction. When the bundle is made of a single strand of heating wire, the heating wire is a heating wire having a low resistance value necessary to obtain a desired heat by using a safety low voltage direct current (DC) electricity of 24 V or less, particularly the battery electricity or battery electricity. do.

Because the resistance value per unit length of the heating wire to be used according to the present invention in order to make the heating wire that can generate the desired heat in a very low state, the use voltage is very low as described above, the resistance of the heating wire Only a very low value will allow enough current to flow.

When the safety electric wire of the battery electric or battery electric, such as 24V or less, especially in the heating wire made as described above,

The second group is composed of ultrafine wires (or ultrafine wire groups, or a mixture of ultrafine wires and ultrafine wire groups) having a resistance value per unit length having the same or substantially the same resistance as a conductor. Since many groups are composed of ultrafine wires (or ultrafine wire groups, or mixtures of ultrafine wires and ultrafine wire groups) in which the resistance value per unit length has a higher resistance value than the conductor,

In the first time period, the current flows through the second group, and the current flows in parallel to the third or more groups, and heat is generated little by little in the heating wire. At a certain temperature (at a temperature that allows the current to flow like a conductor, rather than generating less heat and conducting heat as it becomes conductive after reaching the predetermined temperature of the first group). After being raised, the first group is conductorized with a large drop in the resistance value, so that sufficient current can flow through the first group to generate a large amount of heat, and this sufficient current flows to the second group. Combined with the amount of current already flowing into the group, more current flows into the instant at the third or more groups As a result, a larger amount of current is flowed in parallel in parallel, and a large amount of heat is instantaneously generated in the heating wire.

Therefore, in the present invention, even if the desired heating wire in the present invention is a heating wire having a very low length and a very low resistance value per unit length, the heating wire can generate a large amount of heat with electricity having a very low voltage. It is possible to make the desired battery electrical operation prefabricated heating wire.

Also here, the method of implementing the function of allowing the first group to simply flow current like a conductor rather than to generate heat while conducting less heat after reaching a predetermined temperature is described above. The same as described above in the function of maintaining the temperature of 15>.

As a 5th method, the said 1st method-the 4th method are used mixedly.

For example, a hot wire made by the present invention, which generates a large amount of heat in a place or a facility having a low ambient temperature, is made of a lower resistance value (for example, the hot wire is made into a very long hot wire, If you need to make the current of flow instantaneously)

Among the prepared ultrafine wires, ultrafine wire groups, and more effective ultrafine wire groups, which are more effective in performing a multi-function, there are divided into three or more groups in a method of selecting,

The first group is a micro wire (or micro wire group, or micro wire) that generates less heat after reaching a predetermined temperature and performs a function of allowing the current to flow just like a conductor rather than generating heat while being conductive. A mixture of lines and microfiber groups)

The second group selects a micro wire (or a micro wire group or a mixture of micro wires and micro wire groups) having a resistance value per unit length having a resistance value similar to that of a conductor or substantially similar to that of a conductor,

After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,

The first group, the second group, or the third or more groups of the ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) are synthesized in energized contact with each other in the longitudinal direction to form a bundle. To make these bundles a single strand of heat,

In addition, the number of strands of the ultrafine wire (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) belonging to any one or more groups among the first group, the second group, or the third or more multiple groups. (Or the number of groups, or number),

In the case of generating a large amount of heat in a place or a facility where the ambient temperature is low, which is the exemplary condition, the resistance wire is made to have a lower resistance value (for example, to make the heating wire become a very long heating wire but allow a large amount of current to flow momentarily. If you need to create) you can create a hot wire.

Because the resistance value per unit length of the heating wire to be used according to the present invention in order to make the heating wire that can generate the desired heat in a very low state, the use voltage is very low as described above, the resistance of the heating wire Only a very low value will allow enough current to flow.

When the safety electric wire of the battery electric or battery electric, such as 24V or less, especially in the heating wire made as described above,

The hot wire made by the fifth method is operated as described above in the fourth method and at the same time as described above in the first method, thereby making it possible to produce a hot wire having a lower resistance value. .

In order to achieve the first to fifth methods, in order to achieve the first to fifth methods, the resistance value per unit length has the same resistance value as that of or similar to that of the conductor, or the resistance value per unit length is higher than that of the conductor. Branches are materials of the micro wire (or micro wire group, or a mixture of micro wire and micro wire group), and more effective ones are single metal or alloy metal.

More effective as a single metal are metals such as gold, platinum, silver, copper, aluminum, pure iron, tungsten and nickel,

More effective as alloy metals include nickel copper alloy alloy metals, nickel chromium alloy alloy metals, iron chromium alloy alloy metals, iron carbon alloy alloy metals, hard copper or light copper alloy alloy metals, and steel fibers (metal fibers) ( NASLON), graphene or series alloy metals mixed with graphene, stainless steel (particularly SUS 316 and SUS 304) alloy metals, alloy metals containing pure iron or pure iron, alloy metals containing carbon, and the like,

Nickel and copper alloy metals made from 20-25 wt% nickel and 75-80 wt% copper,

Alloys made of 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum are effective.

In addition, in order to effectively implement the third method to the fifth method, it generates a less heat after reaching the predetermined temperature and performs a function of allowing a current to flow just like a conductor rather than generating heat while being conductive. As the material of the ultra fine wire (or the ultra fine wire group, or a mixture of the ultra fine wire and the ultra fine wire group), the more effective ones are alloy metals,

More effective as the alloy metal, silicon copper alloy series alloy metal, silicon bronze alloy series alloy metal, silicon iron alloy series alloy metal and the like is effective.

<Example 13-20>

All of the prefabricated heating wires 32 manufactured by the present invention are as shown in FIG. 4, two strands (or two groups, or two groups or two mixtures) of the ultra fine wire (or the combination of the ultra fine wire group or the ultra fine wire group). Or a plurality of strands (or a plurality of groups, or a plurality of mixtures) 32a together to form a bundle by coating or coating 32b.

Therefore, when these micro wires are not energized in contact with each other, contact resistance occurs at the contact area, resulting in non-uniformity of resistance value, which ultimately leads to local overheating accident (burning of local overheating part, fire accident, etc.). .

Therefore, all the heating wires produced by the present invention, the bundle made of a bundle of a plurality of ultra-fine wires combined with a covering or tightly split coating of the bundle to be energized synthetically split, any one or more of You should use a bundling method to make it permanently tight.

And a more effective way to do this bundling is to synthesize a combination of microwires, all the hot wires produced by the present invention,

A first method of wrapping a plurality of micro fine wires with high temperature fibers by wrapping the high temperature fibers overlapping with the high temperature fibers in a longitudinal direction,

The second method of bundling itself into a body by twisting itself through a combine machine,

A third method of extracting and bundling while coating the coating machine,

A fourth method of bundling the third method two or more times,

A fifth method using a different coating material for each coating number as the fourth method,

A sixth method of extracting and bundling one or two or more coatings made of the first method or the second method into a coater;

The first or second method is made by coating the coating machine once or twice or more, the coating material is the same by the number of times, or the number of parts by the same part is different, the number of times pulled while coating all differently The seventh method of bundling out,

Eighth method to insert between the upper and lower plates of the plate-shaped material, inject the adhesive, then melt the adhesive bundle

Of the ninth method of putting any one or more of the bundles made by the first to eighth method between the upper and lower plates of the plate-shaped material, and put the adhesive, and then melt and bundle the adhesive

It is most effective to do this bundling in one or more ways.

In the first, sixth, and seventh methods, as the high temperature fiber coating material, any one or more of aramid, polyarylate, or gyrone, or a fiber made of graphene (such as carbon fiber) is used. It is desirable to.

Further, in the third, fourth, fifth, sixth, seventh, and ninth methods, the coating material is Teflon, PVC, or silicon, or graphene, or ceramics, or ceramics, or carbon black, or REFRACTOCOAT. Ceramic coating material from Accumet Materials), or tetraethylortho (putty obtained by dispersing zircon silicate powder in a liquid binder reacted with silicate (TEOS) + silica sol), or cerakool, or aerogel. It is preferable to use any one or more of them.

<Example 13-21>

A heat wire having a low resistance value necessary to obtain desired heat by using battery electricity or safe low voltage direct current (DC) electricity of 24V or less in the above-described <Example 13-1> and <Example 13-3> will be described.

Future energy generation system according to the present invention,

Basically, the method of supplying electricity from the electricity producer (charging station) to the consumer (electric consumer) is not the existing transmission system (wired transfer method), but the electricity produced (generated) is stored in the electric storage device. Since it is a method of charging and transferring (wireless transfer method), all electricity stored or output in the electrical storage device must be direct current (DC) electricity, and all the electrical storage devices are operated by batteries. Since the basic principle of storing (charging) or outputting (discharging) is a technology in which current (electron) flows in only one direction due to the reaction of chemicals (lithium, cadmium, etc.), all of them are only direct current (DC) electricity. It can't be.

Therefore, since the electricity output from the electrical storage device according to the present invention are all battery electricity,

As described above in Example 12, the direct current (DC) electricity output from the electrical storage device transferred to the electrical consumer is a low voltage among them, the technology to directly enable the use of safe direct current (DC) 24V or less directly this,

By enabling the electric consumers (consumers) of the electric consumer to use cheaper and more economical electricity, and to the use of electricity that is not harmful to the human body, it ultimately enables the practical achievement of the present invention.

In addition, a method of directly using direct current (DC) electricity without converting the direct current (DC) electricity output (discharged) from the charged electrical storage device transferred from the charging station into alternating current (AC) electricity at the electrical consumer. ,

There is only a method of using the electric load (s) used in the electric consumer as an electric load directly operated by direct current (DC) electricity output (discharged) from a charged electric storage device transferred from the charging station.

However, at least 50% of the energy used by humankind is consumed in order to obtain heat, and in order to obtain heat with electricity (to generate heat), heating wire is required. (DC) Electricity cannot generate a large amount of heat generation operation (operation that generates electricity by consuming electric electricity) for the purposes required by the electric consumer (e.g. residential floor heating). As described above in <Example 13>).

Therefore, to make an electric load operated directly by direct current (DC) electricity to ultimately achieve the future energy generation system of the present invention,

The use of all or part of the battery-operated prefabricated heating wire developed by the present invention to various electric loads (heating electric loads) that generate heat must produce an electric load that generates one or more heats (heating), It is possible to substantially configure an electrical consumer that can be directly used as direct current (DC) electricity output (discharged) from the charged electrical storage device transferred from the charging station (from the charging station at the electrical consumer, while stored in the electrical storage device). Battery electricity, which is the direct current (DC) electricity that has been transferred, can be used directly).

In addition, as described above in Example 13, in the most important energy problem in future human life, the speed of power generation is accelerated by producing electricity with green energy, which is the solution of human energy problem in the future. Stored in batteries and used in all areas where energy is consumed by these batteries (including all areas where humans are currently using heat from fossil fuels, thermal power or nuclear power plants) to obtain heat. By converting these batteries into a way to get heat, the problem of global warming, severe pollution, alternative energy from fossil fuel depletion, and the dangers of nuclear power generation can be solved.

Therefore, in conclusion, the battery electricity is electricity that is output (discharged) in various electrical storage devices capable of charging or discharging electricity.

In addition, the battery electricity is any one or more of the direct current (DC) electricity of the various voltage bands output (discharged) from the electrical storage (s).

In addition, the battery electricity, using direct current (DC) electricity, any one or more of any voltage of a voltage of 24V or less, or a specific range of voltage of 24V or less voltage.

The various electrical storage devices are any one or more of the electrical storage device (s).

In addition, the various electrical storage device is any one or more of various electrical storage device (s) capable of charging or discharging electricity.

In addition, the various electrical storage devices output (discharge) direct current (DC) electricity, and output any one or more of electricity at a specific range of voltages of a voltage of 24 V or less or a voltage of 24 V or less (discharge). ) Is an electrical storage device.

Next, the safe low voltage direct current (DC) electricity of 24 V or less uses direct current (DC) electricity, and is any one or more of any specific voltage of voltages of 24 V or less or electricity of a specific range of voltages of 24 V or less.

The safe low voltage direct current (DC) electricity of 24 V or less may include any one of a voltage of 24 V or less or a voltage of a specific range of voltage of 24 V or less of the electricity output from the electrical storage device (s). That's it.

Next, the low resistance value is a resistance value through which a current amount that can cause a desired heat generation operation can flow into the battery electricity.

In addition, the low resistance value is the electricity output (discharged) in any one or more of the electrical storage device (s), and is a resistance value that can flow the amount of current that can cause a desired heat generation operation.

In addition, the low resistance value is electricity that is output (discharged) in various electric storage devices capable of charging or discharging electricity, and is a resistance value capable of flowing a current amount that can cause a desired heat generation operation.

In addition, the low resistance value is a direct current (DC) electricity, the current of any one or more of any voltage of 24V or less voltage or electricity of a specific range of voltage of 24V or less voltage, which can cause a desired heat generation operation. It is the resistance value that can flow.

In addition, the low resistance value is the electricity generated by any one or more of any specific voltage among voltages of 24 V or less or electricity of a specific range of voltages of 24 V or less among the electricity output from the electrical storage device (s). It is a resistance value that can flow the amount of current that can cause an operation.

Next, in the above <Example 1>, <Example 3>, <Example 21> and <Example 23>, the desired heat is a heat generation amount or temperature desired within a desired time in a battery electric operation prefabricated heating wire manufactured by the present invention. In order to obtain the power, a power amount proportional to the heat generation amount is consumed within the corresponding time in the prefabricated heating wire, and the current value (current amount) calculated by dividing the power value (power amount) by the corresponding voltage for this purpose corresponds to the corresponding voltage. It is the heat that is generated when the heating action flows to all the prefabricated heating wires in time.

Although the technical spirit of the present invention has been described above with reference to the accompanying drawings, the present invention has been described by way of example and is not intended to limit the present invention.

In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

10: charging station 20: electric storage device
30: electric consumer 32: prefabricated heating wire
40: wireless transport means

Claims (171)

(a) Either of producing (generating) economical electricity in a clean and safe manner and storing (charging) it in an electrical storage device, or receiving and delivering electricity generated (generated) by a future energy production method to an electrical consumer. Configuring a charging station that performs one or more roles;
(b) constructing an electrical storage device for transferring electricity of the charging station by a wireless transfer method;
(c) configuring an electrical storage device wireless transfer means to enable the electrical storage device to perform a wireless transfer method;
(d) constructing an electrical consumer using (consuming) electricity supplied from the charging station; And
(e) An electric storage device which stores (charges) or maintains a charge (stored) state of electricity produced (generated) or transmitted from the charging station, is transferred to an electric consumer by a wireless transfer method by the electric storage device wireless transfer means. Making a step;
Future energy generation system implementation method comprising a. The method of claim 1,
The wireless transfer method,
The method of implementing a future energy generation system, characterized in that for supplying the electricity produced (generated) or transmitted from the charging station to the electric consumer by realizing the charging, transfer, consumption, recovery, recharge cycle of electricity. The method of claim 2,
The charge, transfer, consumption, recovery, recharge cycles of the electricity,
One or two or more of the plurality of the electrical storage devices are stored (charged) or stored (charged) while at least one of the electricity generated (generated) or transmitted from the charging station, Including the entire process of transporting to the electric consumer, and consumed (discharged) the electricity stored (charged) at the electric consumer, and then recovered to the charging station to re-save (recharge), 1 Method of implementing a future energy generation system, characterized in that the cycle of performing a plurality of times or two or more times repeatedly. The method of claim 1,
The electrical storage device wireless transfer means,
The method of implementing a future energy generation system, characterized in that between the charging station and the electrical consumer, a variety of means, including any one or more of the role that the electrical storage device is transferred or recovered. The method of claim 4, wherein
Method for configuring the various means of the electrical storage device wireless transfer means,
The producer and the consumer of the electric storage device are configured, and the charged electric storage device produced by the producer is configured to be exchanged and distributed at various stages, and the sale is made by buying and selling the charged electric storage devices. The method is made so that the consumer (consumer) is reached, and after the consumer (consumer) consumes (discharges) the electricity of the charged electric storage device thus reached, the discharged electric storage device is again returned to the consumer (consumer). A distribution structure including sales, including all such processes, in which a method of exchanging and distributing at various stages from a plurality of stages is carried out, and a method of selling and selling the charged electric storage devices is included, and collected to a producer. Through the formation of
The one or more electricity, which is produced (generated) or delivered at the charging station, is stored (charged) or stored (charged) while being transferred to a distribution method including sales to the electric consumer, It includes one or more steps including consuming (discharging) the stored (charged) electricity at the electricity consumer, and then recovering and restoring (recharging) the distribution method including sales to the charging station. To ensure that all processes of continuous and repeated multiple or more times are achieved,
A first method comprising a distribution method including sales;
When the producer and the consumer of the electric storage device are configured and the consumer orders the charged electric storage device, the producer delivers the charged electric storage device to the consumer, and the discharged electric storage device consumed by the consumer is the producer. By retrieving an order and delivery structure that includes all of these processes,
At least one of the electricity produced or generated at the charging station is stored (charged) or stored (charged) while being transferred to the electric consumer in an order and delivery method. Once or twice including the process of consuming (discharging) the stored (charged) electricity at the consumer, and then recovering and restoring (recharging) to the charging station again by the order and delivery method. So that all the processes can be performed continuously and repeatedly several times,
A second method consisting of an order and a delivery method,
The producer and the consumer of the electrical storage device are configured, and the consumer to be transferred from the producer to the consumer through any one or more of the methods to enable the transfer of the charged electrical storage device that the consumer needs, The discharged electrical storage device that has been consumed (discharged) causes other transportable structures to be formed, including any such process, to be returned to the producer by one or more of the other methods that enable transport. through,
At least one of the electricity produced or generated at the charging station is transferred to the electric consumer through other transferable methods while being stored (charged) or stored (charged), and the It includes one or more steps including consuming (discharging) electricity stored in the electricity consumption station, and then recovering and restoring (recharging) the battery through other transferable methods. To ensure that all processes of continuous and repeated multiple or more times are achieved,
The third method constituted by other transferable methods,
Among the fourth method using a mixture of the first method to the third method,
The future energy generation system implementation method characterized in that at least one method. The method of claim 5,
The method of configuring the electrical storage device wireless transfer means by the other transferable method of the third method,
The electrical storage device is transferred from the charging station to the electrical consumer, and recovering from the electrical consumer to the charging station,
A first method of loading, transporting, transferring, transferring and moving the electric storage device in a general vehicle;
After reconstructing the general transport means into a transport means dedicated to the electric storage device so that it can be used only for the purpose of handling only the electric storage device, the electric storage device is loaded on the transport means dedicated to the electric storage device, and then transported and transported. The second way to transfer, transfer,
As an electric only transportation means for storing (charging) electricity and outputting (discharging) electricity, a method of equipping or mounting an electric storage device therein, the superconducting power storage device and the superconducting power storage device. Ships, superconducting power storage aircraft, superconducting power storage devices trains, large-capacity power storage systems (large-capacity power storage systems) cars, large-capacity power storage systems (large-capacity power storage systems) Massive power storage system (large-capacity power storage system) Train, battery (electrical storage or ESS) train, battery (electrical storage or ESS) car, battery (electrical storage or ESS) ship, battery (electrical storage or ESS) Develop (or make) by aircraft,
The vehicle is transformed (made) into a vehicle for exclusive use of electricity so as to be used exclusively for storing (charging) electricity and outputting (discharging) electricity.
By directly operating the electric dedicated transport means itself,
After the electricity is stored (charged) in the electric dedicated transportation means, the charging station goes to the electric consumer, and the electric consumption stored in the electric dedicated transportation means itself (charged) outputs (discharges) the electricity to the charging station. A third method of using the electricity-only transportation means only for the purpose of continuously repeating a cycle of re-storing (charging) the electricity-only transportation means once or more than two times,
Among the fourth method using a mixture of the first method to the third method,
The future energy generation system implementation method characterized in that at least one method. The method of claim 5,
Distribution method including the sale of the first method,
The energy storage system implementation method of the future, characterized in that the electric storage device to have a structure that can be bought and sold to each other between producers, consumers and third parties through the distribution process. The method of claim 7, wherein
The method of making the electrical storage device has a structure that can be bought and sold to each other between producers, consumers and third parties through the distribution process,
The structure makes it easy to identify the value (price) of the electric storage device between the seller and the buyer, so that the value (price) of the electric storage device can be formed differently according to the degree of use and the amount of electric storage according to various specifications. Future energy generation system implementation method characterized in that the method. The method of claim 8,
In order to be able to easily identify the value (price) of the electrical storage device between the seller and the buyer, so that the value (price) of the electrical storage device can be formed differently according to the degree of use and the amount of electrical storage according to various specifications. How to make,
The method of displaying the number of times of charging and discharging the electricity to the electrical storage device, or the number of times of charging and discharging the electricity is displayed at the same time and the remaining capacity of the electricity is also displayed. A method of implementing a future energy power generation system characterized by the above. The method of claim 1,
The electrical storage device,
At least one of the electricity produced or generated at the charging station is transferred (charged) or stored (charged) while being stored (charged) or transferred from the charging station to the electrical consumer through an electrical storage device wireless transfer means. The electricity consumption (discharge) in the electrical consumer is a method of implementing a future energy generation system, characterized in that the function of recovering back to the charging station through the electrical storage device wireless transfer means, all can be performed smoothly. The method of claim 1,
The electrical storage device,
Future energy power generation, characterized by standardization and standardization, with the function and structure capable of continuously and repeatedly performing the charge, transfer, consumption, recovery, and recharge cycles of electricity one or two or more times. System implementation method. The method of claim 11,
Method for making the electrical storage device standardized and standardized,
The size and weight are to be standardized to a certain standard, but in accordance with the site use conditions to make a number of types by each standard, the same type of each type of the above-described multiple types of electrical storage devices is a method for forming the same electrical specifications of the same Future energy generation system implementation method characterized in that. The method of claim 11,
Method for making the electrical storage device standardized and standardized,
A first method of using a product, an article, a facility, or a device that performs any one or more functions of storing (charging) or outputting (discharging) existing electricity,
One or two charge, transfer, consumption, recovery and recharge cycles of electricity to products, articles, equipment and devices that perform one or more of the functions of storing (charging) or outputting (discharging) the existing electricity. A second method used by reinforcing, changing (modifying) to further provide a structure (device) capable of continuously and repeatedly performing a plurality of times;
Make new products, articles, equipment, and devices capable of performing any one or more of the functions of storing (charging) or discharging (discharging) electricity, but do not charge, transfer, consume, recover, recharge cycles of electricity. To be equipped with the function and structure to continuously and repeatedly perform many or more times,
In the process of continuously or repeatedly performing the charge, transfer, consumption, recovery, and recharge cycles of the electricity many times one or two times, the size of the transfer and recovery can be made smoothly by using the electric storage wireless transfer means And the third to be standardized to a certain standard, but to make a number of types to meet the site use conditions, the same type of each of the standardized electrical storage devices to be made (developed) to use the same electrical specifications of the standard type Way,
Among the fourth method using a mixture of the first method to the third method,
The future energy generation system implementation method characterized in that at least one method. The method of claim 13,
The second method is
Existing, currently developed, produced and sold distribution
Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Transfer of any one or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or various products, articles, equipment, devices that store (charge) electricity and output (discharge) electricity. The future energy generation system implementation method characterized in that the reinforcement and use so that it is convenient and trouble-free during the recovery and recovery process. The method of claim 13,
The third method,
Existing, currently developed, produced and sold distribution
Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Same as any one or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or various products, articles, facilities, and devices that store (charge) electricity and output (discharge) electricity. Or create a new dedicated electrical storage device with similar functionality and structure,
It is made by reinforcing and making it convenient and trouble-free in the process of transportation and recovery.
The specification is made of a number of types to suit the reality of charging stations or electrical consumers, but to a certain size and weight standardized, the standardized electrical storage device is used to make a standardized electrical specifications, or
Equipped with the new dedicated electric storage device in various means of transportation, superconducting power storage car, superconducting power storage device ship, superconducting power storage device aircraft, superconducting power storage device train, large capacity power storage system (large capacity power storage system) car, Massive power storage system (large-capacity power storage system) ships, large-capacity power storage system (large-capacity power storage system) aircraft, large-capacity power storage system (large-capacity power storage system) trains, batteries (electrical storage or ESS) trains, batteries (electrical storage Device or ESS) car, battery (electrical storage device or ESS) ship, battery (electrical storage device or ESS) aircraft, transportation equipment with the function of storing (charging) and outputting (discharging) electricity. Future energy generation system implementation method characterized in that. The method of claim 1,
The electric consumer,
The first consumer who has no place (space) to install a charging station or a place where space is inexpensive, or an electric mass consumer that is good at consuming (discharging) electricity in large quantities, and where there is no place (space) to install a charging station or is inexpensive In the case of one or more of the second consumer where there is only a place (space),
The method of receiving economical electricity produced (generated) in a clean and safe manner at the first or second consumer,
Is installed at a location spaced apart from the first or second consumer and at any one or more of the charging station or intermediate storage station that produces (generated) economical electricity in a clean and safe manner, the method of receiving electricity through a wireless transfer method Future energy generation system implementation method characterized in that. The method of claim 1,
The electric consumer,
It is a first consumer where there is no place (space) to install a charging station or a place where space is inexpensive, or an electric mass consumer that is good at consuming (discharging) electricity in large quantities, and there is no place (space) or economical to install the charging station. In the case of one or more of the second consumer where there is only a place (space) to fall off,
The method of receiving electricity generated (generated) by the future energy production method in the first or second consumer,
Installed at a location separated from the first or second consumer, at least one of the charging station or the intermediate station receiving the electricity generated (generated) by the future energy production method and delivered to the electrical consumer, through a wireless transfer method A method of implementing a future energy power generation system, characterized in that the method of receiving electricity. The method of claim 17,
At least one of the charging station or the intermediate collection point,
The method of receiving electricity (energy) brought by the electric energy transport device from the sky or the space and delivering it back to the electric consumer,
By installing a large-capacity secondary electric storage device in the charging station or intermediate storage, and storing (charge) the electricity (energy) brought by the electric energy transport device from the sky or the space again in the large-capacity secondary electric storage device (charge) Thereafter, the first method of storing (charging) the electricity thus stored in the electrical storage device made to perform the wireless transfer method and supplying the stored electricity to the electric consumer using the wireless transfer method,
After receiving the electric storage device, which is stored (charged) by the electric energy transport device from the sky or the space, is delivered from the charging station or the intermediate storage station, and then wirelessly transfers the charged electric storage device itself. A second method of supplying to the electric consumer using a method,
Among the third method of supplying a mixture of the first method and the second method,
Implementation method of the future energy generation system, characterized in that any one or more methods. The method of claim 1,
The future energy production method,
A method of implementing a future energy power generation system, characterized in that a method of receiving electricity (energy), which is produced (generated) in the sky or the space, by the electric energy transport device from the sky or the universe. The method of claim 19,
The electric energy transport device,
It is equipped with a photovoltaic power generation unit composed of photovoltaic power generation facilities that generate (generate) electrical energy by receiving light energy of the sun over the earth or in space.
It is provided with an electrical storage device including a function of storing (charging) electricity produced by the photovoltaic unit in the sky or space and delivering electricity that has been stored (charged) at a designated charging station.
The electricity produced in the photovoltaic unit (generated) is stored in the electrical storage device, and configured to be connected to each other, the electrical and control circuits to enable the output (discharged) of the stored (charged),
In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station and the earth or space,
Future energy power generation system, characterized in that the flying device that stores (charges) the photovoltaic electricity produced (generated) in the photovoltaic power generation unit from the sky and space to the electrical storage device, bringing it to the designated charging station and deliver it Implementation method. The method of claim 20,
The electric energy transportation device,
Rather than the total amount of energy consumed (consumed) in a single cycle of electricity production and transportation, electricity is generated (generated) from the sky and space through a single cycle of electricity production and transportation, and brought to a designated charging station. A method of implementing a future energy generation system, characterized by making the total amount of energy (transported) more. The method of claim 21,
Energy required for operation (driving) of the electric energy transportation device,
A method of implementing a future energy power generation system, characterized in that it is obtained by a method of dealing with the natural force (energy) obtained naturally by utilizing the principle of nature (or the order of the universe) without introducing extra energy. The method of claim 22,
The method for handling the energy required for the operation (driving) of the electric energy transportation device with the force of nature,
When the electric energy transport device floats over the earth or in space, stays in the earth or in space, returns to the designated electric energy transmission site from the earth or in space, or drives a large amount of energy. When running (driving) a section, a large amount of energy consumption necessary for any one or more running sections,
A method of implementing a future energy power generation system, characterized in that it is obtained by a method of dealing with the natural force (energy) obtained naturally by utilizing the principle of nature (or the order of the universe) without introducing extra energy. The method of claim 23, wherein
The method of applying the buoyancy in the air as a method of bearing the energy required for the operation (driving) of the electric energy transportation device with the force of nature,
Create a space having a certain volume inside the electric energy transport device to form a natural buoyancy by filling a buoyancy material in the space, or to form artificial buoyancy by applying a negative pressure (-pressure) or vacuum to the space, or A first method of providing a buoyancy device made to have one or more buoyancy of the natural buoyancy or artificial buoyancy in the energy transport device by any one or more of the methods,
A second method of providing a buoyancy device made to have one or more of buoyancy of the natural buoyancy or artificial buoyancy as an additional configuration in an electric energy transport device;
Among the third method of adjusting the magnitude of one or more buoyancy among the natural buoyancy, artificial buoyancy, or buoyancy of the buoyancy device in the first and second methods,
The future energy generation system implementation method characterized in that at least one method. The method of claim 24,
The method of adjusting the magnitude of buoyancy in the third method,
The buoyancy of any one or more of the natural buoyancy, artificial buoyancy formed in the electric energy transport device, or buoyancy of the buoyancy device provided separately to the electric energy transport device,
In the pressure of a buoyant material, negative pressure (-pressure), vacuum or in the volume of space in which the buoyancy is to be formed,
A method of implementing a future energy power generation system, characterized in that the method of applying or adjusting any one or more of them. The method of claim 24 or 25,
The buoyancy device,
An object having a closed volume of a constant volume, the mass per volume of the object has a lower mass than the air per the same volume of the surrounding air, making the effect of buoyancy over the earth (air) How to implement an energy generation system. The method of claim 26,
The method of making the mass per volume of the object have a mass lower than the air per equal volume of the surrounding air,
Implementation of a future energy power generation system, characterized in that any one or more of the method of inserting (injecting), applying negative pressure (-pressure), or applying vacuum to an object having a constant volume of closed space. Way. The method of claim 22 or 23,
The power of nature,
A method of implementing a future energy power generation system, characterized in that the buoyancy in the air to push up into the air in the opposite direction of the earth's gravity. The method of claim 1,
The future energy production method,
It is equipped with a photovoltaic power generation unit composed of photovoltaic power generation facilities that generate (generate) electrical energy by receiving light energy of the sun over the earth or in space.
It is provided with an electrical storage device including a function of storing (charging) electricity produced by the photovoltaic unit in the sky or space and delivering electricity that has been stored (charged) at a designated charging station.
The electricity produced in the photovoltaic unit (generated) is stored in the electrical storage device, and configured to be connected to each other, the electrical and control circuits to enable the output (discharged) of the stored (charged),
In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station and the earth or space,
The electric energy transportation device is a flying device that stores (charges) solar power generated in the photovoltaic unit from the sky or the space and generates (charges) the electricity in the electrical storage device, and delivers it to the designated charging station. after,
The electric energy transport apparatus is made into one or two or more, and the designated charging station is also made into one or two or more places,
Countless electric energy transport devices of one or more than two or more fly up the earth or space (space),
While staying in the sky or in space (space), it produces (generates) photovoltaic electricity through the photovoltaic unit provided in the main body, charges (stores) the electrical storage device provided in the main body, and returns to the designated charging station,
Fly back up to the earth or space (space), stay in the earth or space (space), produce (generate) and recharge (store) solar electricity again, return to the designated charging station and deliver the electricity A method of implementing a future energy power generation system, characterized in that the photovoltaic electricity is brought to humanity by repeating the cycle continuously or repeatedly a plurality of times one or more times. The method of claim 29,
A method of implementing a future energy generation system, characterized in that the flying device is made of a drone and used as an electric energy transportation device. The method of claim 1,
The method of configuring the electrical consumer of step (d),
At least one of the areas, facilities, buildings, facilities, equipment, devices, customers, or existing electricity sources that use existing electricity or require new use of electricity, or all electricity consumption sources that use existing electricity or require new use. In the electricity consumer,
The electrical storage device that stores (charges) or maintains the charging (stored) state of electricity generated (generated) or transmitted from the charging station is transferred to the electric consumer using a wireless transfer method based on the wireless storage means of the electrical storage device. Through the electric power supplied from the charging station to the electrical consumer, the method of implementing the future energy generation system, characterized in that it is used to replace the electricity of the existing power system network. The method of claim 31, wherein
The method for replacing the electricity of the existing power system network with electricity supplied from the charging station to the electric consumer,
A method of converting direct current (DC) electricity output (discharged) from a charged electric storage device transferred from the charging station into direct alternating current (AC) electricity at the electrical consumer, and using alternating current (AC) electricity at the electrical consumer. Future energy generation system implementation method characterized in that. The method of claim 31, wherein
The method for replacing the electricity of the existing power system network with electricity supplied from the charging station to the electric consumer,
It is a method of directly using the direct current (DC) electricity itself without converting the direct current (DC) electricity output (discharged) in the charged electrical storage device transferred from the charging station to the alternating current (AC) electricity at the electrical consumer. Future energy generation system implementation method characterized in that. The method of claim 33, wherein
The method of directly using the direct current (DC) electricity itself,
Characterized in that the electrical load (s) used in the electrical consumer is a method of using an electrical load directly operated by direct current (DC) electricity itself output (discharged) in the charged electrical storage device transferred from the charging station. How to implement future energy generation system. The method of claim 34, wherein
An electrical load directly operated by the direct current (DC) electricity itself,
A method of implementing a future energy generation system, characterized in that any one or more heat generating electric loads, using all or part of prefabricated heating wires (battery electric operation prefabricated heating wires) operated by battery electricity as the electric load for heat generation. 36. The method of claim 35 wherein
The method for manufacturing the battery electric operation prefabricated heating wire,
Making an ultrafine wire from a single metal or an alloy metal having different number of strands, thickness, material, and function;
By combining and bundling the ultra-fine wires prefabricated to have at least one of low resistance value or multi function required to obtain desired heat by using battery electricity or safe low voltage direct current (DC) electricity of 24V or less. Bundling of; And
Making said one bundle become a strand of hot wire soon;
Future energy generation system implementation method comprising a. The method of claim 36,
The prefabricated heating wire,
Microfiber wires can be made of many, many, single or alloy metals,
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,
Implementing a future energy power generation system, characterized in that any one or more of the prepared ultra-fine wires are selected, synthesized into two or more multiple strands, and made into a single combination, and the combination is manufactured to be a single hot wire. Way. The method of claim 37,
The combination of the above,
Combine all the microfibers inside to be in contact with each other and make a composite assembly in a bundle,
The microfibers in the bundle are brought into intimate contact with each other, and the entire surfaces of all the microfibers in the bundle are in contact with each other in the longitudinal direction from the beginning to the end of the bundle, so that the current flows to all the microfibers throughout the contact surface. A method of implementing a future energy power generation system, characterized in that the composite combination is made in such a way that the energized contact is made, and the bundle is made again through a bundle operation. The method of claim 36,
The prefabricated heating wire,
First, a heating wire having a low resistance value necessary to obtain a desired heat using battery electricity or a safe low voltage direct current (DC) electricity of 24V or less,
Secondly, a battery wire or a heating wire that exhibits one or more additional functions with the low resistance required to obtain the desired heat using a safe low voltage direct current (DC) electricity of less than 24V;
Third, any heating wire of at least one of the first and second heating wires, and a flexible heating wire,
Fourth, customized heating wires each of which is precisely matched to each other in various cases so as to have any one or more functions of the first to third heating wires,
Fifth among the heating wires that can be economically and easily mass-produced at any time with the same product with the same performance as the customized heating wires made by the fourth above,
A method of implementing a future energy power generation system, characterized in that the manufacture of any one or more heating wire. The method of claim 39,
The customized heating wire,
A method of implementing a future energy power generation system, characterized by changing a combination of ultra fine wires into a bundle in which a combination change of ultra fine wires is made through a bundling operation. The method of claim 40,
To change the combination of the fine lines,
Microfiber wires can be made of many, many, single or alloy metals,
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,
By selecting any one or more of all the ultrafine wires prepared, changing the selection of the selected ultrafine wires differently may be a combination change of the ultrafine wires, but synthesizing the microfine wires into at least two strands in one combination A method of implementing a future energy power generation system, characterized in that for making. The method of claim 41, wherein
To change the selection box,
In case of selecting one micro fine line, select one fine line as different fine line and change the selection of fine line, change the number of strands to 2 or more strands of the same fine line selected
If you select any two or more fine lines, select one or more of the two or more fine lines as different fine lines, and change the selection of the fine lines,
If any two or more fine lines are selected, select one or more fine lines among two or more fine lines as different fine lines and change the selection of the fine lines, but change or select the number of strands of the selected fine lines. How to change
A method of implementing a future energy power generation system, characterized in that made in any one or more ways, wherein the number of fine wire strands in the combination is two or more. The method of claim 41, wherein
To change the selection box,
Among all the prepared ultrafine wires, a classification type group may be selected from only one kind group classified as resistance value, thickness, material, and function, but in the selected single classification type group, the same ultrafine wires are combined into two or more strands. To form a combination, and the combination of the first and second combinations allows the total number of ultrafine wires to be at least two strands, the first method of changing the number of strands,
Among all the prepared ultrafine wires, a classification type group is selected from any one of a kind group classified into resistance value, thickness, material, and function. Select the additional fine line by changing the number of strands again after changing the fine line to any one of the classification types except for the type corresponding to the selected classification type group among the material and function types. In this way, the final selection (modification) is a combination of at least two strands by combining at least two strands to form a single combination, the combination is made in the second method for the total number of ultrafine lines to be at least two strands ,
Among the prepared ultrafine wires, any two or more classification type groups are selected from among the group of types classified by resistance value, thickness, material, and function, and each of the selected classification types is selected by one or more strands in different classification types. A third method in which the selected ultrafine wires are combined into at least two types to form a single combination, and the combination of the three fine wires includes at least two strands of total fine wires;
Among the prepared ultrafine wires, each of the ultrafine wires is selected from any two or more types of classification groups classified into resistance values, thicknesses, materials, and functions, and at least one strand is selected for each of the selected classification types. In this case, the selected fine wire is changed back into any one of the classification types except for the one corresponding to the selected classification type group among the resistance value, thickness, material, and function type. In addition, it is possible to make an additional selection (change) in such a way as to make an ultrafine line, thereby forming one combination by combining at least two kinds of ultrafine lines selected from different classification types. Is a combination of the fourth method, such that the total amount of fine wires is at least two strands,
Among the prepared ultrafine wires, each of the ultrafine wires is selected from at least two classification type groups among the types of groups classified into resistance values, thicknesses, materials, and functions. In this case, the selected fine wire is changed back into any one of the classification types except for the one corresponding to the selected classification type group among the resistance value, thickness, material, and function type. After the fine line becomes the fine line, the selected fine line is further selected (changed) by changing the number of strands again, so that the final fine line selected at least two kinds of fine lines selected from different classification types are selected. Combination to form a combination, one combination is composed of at least two strands of total micro fine wire Fifth way to lose,
Among all the prepared ultrafine wires, a classification type group may be selected from any one of the kind groups classified by resistance value, thickness, material, and function, but within the selected classification type group, two or more different fine wires may be used. The sixth method of the present invention is to make a combination through the combination, wherein the one combination is such that the total amount of micro fine lines is at least two strands.
Among all the prepared ultrafine wires, a classification type group is selected from any one of the kind groups classified by resistance value, thickness, material, and function. And the selected micro fine lines are combined again by changing the number of strands to form a single combination, and the combination of the two fine lines enables the total micro fine line number to be at least two strands. Of the methods,
A method of implementing a future energy power generation system, characterized by using any one or more methods. The method of claim 43,
The ultrafine wire in the one classification type group selected in the second method is changed back to any one of the classification types except for the one corresponding to the selected classification category group among the resistance value, thickness, material, and function type. After making it become one micro wire, the method of changing the number of strands again in this selected micro wire,
If only one classification type group selected as one is selected as the material type, change the micro fine lines within the classification type group selected with this material to one or more of thickness, function and resistance value except for material change. In the final selected fine line, again change the number of strands to the same fine line,
If only one kind of classification type group is selected as the resistance value type, in changing the ultrafine lines again within the classification type group selected by this resistance value, change to one or more of thickness, function and material except for the change of resistance value. In this way, the final selected fine line again changes the number of strands to the same fine line,
If only one classification type group is selected as the function type, change the micro fine lines within the classification type group selected by this function to one or more of the material, thickness and resistance value except for the function change. In the final selected fine line, again change the number of strands to the same fine line,
If only one classification type group is selected as the thickness type, within the classification type group selected with this thickness, change to one or more of materials, functions, and resistance values except for the thickness change in changing the fine lines again. In the final selected fine line, you can change the number of strands to the same fine line again.
Implementation method of the future energy generation system, characterized in that any one or more methods. The method of claim 43,
In the fourth method, the ultrafine wires selected in this manner are again classified into any one of the types of classification except for the types corresponding to the selected classification type group among resistance values, thicknesses, materials, and function types. The way to make it change again is
If any one of the selected classification type groups is selected as the material type, within the classification type group selected by this material, a method of changing to one or more of thickness, function, and resistance value except for material change only in changing the fine lines again,
When any one of the selected classification type groups is selected as the resistance value type, within the classification type group selected by this resistance value, a method of changing to one or more of thickness, function, and material except for the change of resistance value in changing the ultrafine lines again. ,
If any one of the selected classification category groups is selected as a function type, within the classification category group selected by this function, a method for changing to one or more of materials, thicknesses, and resistance values except for the functional change in changing the fine lines again,
If any one of the selected classification type groups is selected as the thickness type, within the classification type group selected with this thickness, one of the methods of changing to one or more of materials, functions, and resistance values except for the thickness change in changing the fine lines again,
Implementation method of the future energy generation system, characterized in that any one or more methods. The method of claim 43,
In the fifth method, the ultrafine wires selected in this manner may be classified into any one of the classification types except for the types corresponding to the selected classification type group among resistance values, thicknesses, materials, and function types. After the fine line is changed again, the method of changing the number of strands is again selected.
When the same classification type group is selected as the resistance value type, the method of additionally changing the number of strands for these by changing one or more of thickness, function, and material except for changing the resistance value in changing the ultrafine wires,
If the same classification type group is selected as the material type, the method of additionally changing the number of strands for these by changing one or more of the thickness, function, and resistance value except for changing the material in changing the ultrafine wires,
When the same classification type group is selected as the thickness type, the method of additionally changing the number of strands of these materials by changing any one or more of materials, functions, and resistance values except for changing the thickness in changing the fine lines,
If the same classification type group is selected as a function type, in changing the micro fine lines, one or more of the material, thickness, and resistance values except for the function change are changed, and the number of strands for these is additionally changed.
Implementation method of the future energy generation system, characterized in that any one or more methods. The method of claim 36,
The prefabricated heating wire,
By using battery electricity or safe low voltage direct current (DC) electricity of 24V or less, it becomes a heating wire having a low resistance value necessary to obtain desired heat,
Using battery electricity or safe low voltage direct current (DC) electricity below 24V,
Is a hot wire that emits far infrared rays,
It is a heating wire that generates instantaneous high temperature heating and high efficiency heating,
Among the heated wires that increased flexibility,
In a way that makes it a hot wire
Microfiber groups can be made of many, many, single or alloy metals,
Prepare by making a variety of ultra-fine wire groups having a specific resistance value but different resistance values,
Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,
Prepare a variety of ultra-fine wire groups having a specific material but different materials,
Prepare a variety of ultra-fine wire groups with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,
Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. After collecting the values to create big data,
Implementing a future energy power generation system, characterized in that any one or more selected among all the ultra-fine wire groups prepared above are synthesized into two or more groups to form a single combination, such that one combination becomes a single strand of hot wire. Way. The method of claim 47,
A method of implementing a future energy power generation system, characterized in that for changing the combination of the ultra-fine wire groups to make a customized heating wire in a bundle made by changing the combination of the ultra-fine wire groups. The method of claim 48,
The combination change of the ultra fine wire groups,
By selecting any one or more of the prepared ultrafine wire groups, changing the selected ultrafine wire group to be different from each other is a combination change of the ultrafine wire groups, and synthesizes the ultrafine wire group into at least two groups. Future energy generation system, characterized in that to make a combination. The method of claim 49,
To change the selection box,
In case of selecting one ultrafine wire group, select one ultrafine wire group as a different ultrafine wire group and change the selection of the ultrafine wire group, but change the number of groups of the same ultrafine wire group selected to 2 or more groups. Change it,
If you have selected any two or more fine wire groups, select one or more fine wire groups among two or more fine wire groups as different fine wire groups, and change the selection of the fine wire groups,
If you select any two or more fine wire groups, select one or more fine wire groups among two or more fine wire groups as different fine wire groups and change the selection of the fine wire groups, but select Change or select How to change the number of groups of the micro fine line group,
A method of implementing a future energy generation system, characterized in that made in any one or more ways, wherein the number of groups of the ultrafine wire groups in the one combination is two or more. The method of claim 49,
To change the selection box,
Among the prepared ultrafine wire groups, a classification type group may be selected from only one kind group classified as resistance value, thickness, material, and function, and the same ultrafine wire group is classified into two groups within only one selected classification type group. Through the above combination to form a single combination, the combination of the above is to make the total number of ultra-fine wire group of at least two groups, the first method of changing the number of groups,
Among the prepared ultrafine wire groups, a classification type group may be selected from any one of the types of groups classified into resistance values, thicknesses, materials, and functions, and the ultrafine wire groups within the selected single classification group group may again have resistance values. Change the number of groups in the selected fine line group again after changing it to one of the classification types except for the one corresponding to the selected classification type group among the thickness, material, and function type. In this way, the final selected (modified) microfiber group is finally combined into at least two groups to form one combination. Second method to make it,
Among the prepared ultrafine wire groups, any two or more classification type groups are selected from the group of categories classified by resistance value, thickness, material, and function. A third method in which a combination of at least two types of ultra fine wire groups selected by type forms one or more combinations;
Among the prepared ultrafine wire groups, each ultrafine wire group is selected from at least two classification type groups among the types of groups classified by resistance value, thickness, material, and function. The ultra-fine wire group selected in this way is selected from the group of any one of the classification types except for the type corresponding to the selected classification group among the resistance value, thickness, material, and function type. In order to make the selected ultrafine wire group changed again, it is possible to combine the final selected ultrafine wire group by combining at least two kinds of ultrafine wire groups selected from different classification types. In one combination of the above, the fourth method for the total number of ultra fine wire groups to be at least two groups,
Among the prepared ultrafine wire groups, each ultrafine wire group may be selected from at least two classification type groups among the types of groups classified by resistance value, thickness, material, and function. The ultra-fine wire group selected in this way is selected from the group of any one of the classification types except for the type corresponding to the selected classification group among the resistance value, thickness, material, and function type. After the result is changed to the ultra fine wire group, the selected ultra fine wire group is further selected (changed) by changing the number of groups again, and thus the fine selected fine wire group is finally selected from different classification types. The sun group combines at least two types to form one combination. A fifth method of this quantity be made of at least two groups,
Among the prepared ultrafine wire groups, a classification type group may be selected from any one of the types of groups classified by resistance value, thickness, material, and function, and within the selected classification type group, two different ultrafine wire groups may be selected. The sixth method of the present invention is to combine one or more groups to form one combination, and the one combination thus constitutes at least two groups in total.
Among the prepared ultrafine wire groups, a classification type group may be selected from any one of the types of groups classified by resistance value, thickness, material, and function, and within the selected classification type group, two different ultrafine wire groups may be selected. Selected to be more than a group, and the selected ultra-fine wire groups are combined again by changing the number of groups to form a combination, and the combination of the two combinations of the above-described ultra fine wire groups is at least two groups. Among the seventh methods to make it happen,
A method of implementing a future energy power generation system, characterized by using any one or more methods. The method of claim 47,
The ultra fine wire group,
Combine the two or more strands of the microfibers with the same classification and the same properties, making them thinner than the corresponding microwires used in single strands. A method of implementing a future energy power generation system, characterized in that a bundle is formed by combining a combination of electric currents and electric currents that are electrically synthesized with each other so that current flows to each other as a whole from the beginning to the end. The method of claim 36,
The prefabricated heating wire,
Battery Electricity or Safety Low Voltage Direct Current (DC) below 24V
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having any specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,
It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,
Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,
Prepare a variety of ultra-fine wire groups having a specific material but different materials,
Prepare a variety of ultra-fine wire groups with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,
Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. After collecting the values to create big data,
The micro fine wires used by one strand of the prepared micro fine wires and any one of the prepared ultra fine wire groups may be used in combination,
A method of implementing a future energy generation system, characterized in that one of the prepared ultrafine wire groups is added to the ultrafine wires used by one strand of the prepared ultrafine wires. The method of claim 36,
The prefabricated heating wire,
Battery Electricity or Safety Low Voltage Direct Current (DC) below 24V
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,
One of the prepared ultrafine wires is used in combination with the ultrafine wires which are more effective in performing a multi-function with the ultrafine wires used by one strand, or
In addition to using a micro wire group more effective in performing a multi-function to the micro wires used by one strand of the prepared micro wires,
A method of implementing a future energy power generation system, characterized in that any one or more methods are used, among which only a micro wire group is more effective in performing a multi-function. 55. The method of claim 54,
A micro wire group more effective in performing the multi-function,
One strand of NASLON, which is a steel fiber, has a thickness of 20 µm or less, and 100 or more strands with the same thickness, so that the entire surfaces of these multiple strands of microfibers are in contact with each other from the beginning to the end in the longitudinal direction, so that the currents are all fine lines throughout the contact surface. A method of implementing a future energy power generation system, characterized in that a bundle is formed by combining and combining the energized contact with each other so that they can flow to each other. The method of claim 47,
The heating wire that emits the far infrared,
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having any specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,
It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,
Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,
Prepare a variety of ultra-fine wire groups having a specific material but different materials,
Prepare a variety of ultra-fine wire groups with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,
Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. Collect the values to create and prepare the big data,
In addition, a fine fiber group made of one bundle may be prepared by making one strand of NASLON, which is a steel fiber, having a thickness of 20 μm or less with 100 or more strands having the same thickness.
NASLON 1 strand of steel fiber has a thickness of 12㎛ (corresponding ultrafine wire diameter), and prepare the ultrafine wire group consisting of 550 strands with the same thickness,
Prepare a microfiber group consisting of 1 strand of NASLON, which is steel fiber, having a thickness of 8 μm (correspondingly fine wire diameter), and having 1,000 strands of the same thickness.
One strand of NASLON, a steel fiber, has a diameter of 6,5 µm (correspondingly fine wire diameter), and a microfine wire group consisting of 2,000 strands with the same thickness is prepared.
Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups, which are more effective in performing a multi-function,
Battery electricity or safe low-voltage direct-current (DC) electricity of 24V or less, many of which are multi-stranded fine wire, multiple-group ultrafine wire group, or a mixture of ultrafine wire and ultrafine wire group that emit far infrared rays while generating heat by resistance value And select one or more of them, and then combine the selected one or more of the multiple strands of the multiple strands, the multiple group of the fine strands, or a mixture of the micro and the ultrafine group to contact each other to form a composite combination. A composite combination of any one or more of these multiple strands of microfibers, multiple groups of microfibres, or a mixture of micro and microfibers, into one bundle, such a bundle being one strand Electric dipole radiation, which emits far-infrared rays. A method of implementing a future energy generation system, characterized in that it is manufactured with a geometric structure that can be radiated more largely. The method of claim 66,
A more effective method of making the electric dipole radiation have a geometric structure that can be radiated larger and better,
Synthetic combinations inside the bundle,
When the resistance value, the material, or the thickness of one or more of a plurality of micro wires, a plurality of micro wire groups, or a mixture of a micro wire and a micro wire group are one or more, the same condition is used. Make the number of strands (or the number of groups, or the number of mixtures) of one or more of the same, or the same as the combination of the very fine wire and the same fine wire group, or
One or more of two or more groups having different resistance values and having the same resistance value for each group having different resistance values, or at least one of a mixture of the micro wires and the micro wire groups. A method of implementing a future energy generation system, characterized in that the method is made of strands (or one group, one mixed) or two strands (or two groups, two mixed). The method of claim 57,
Two or more groups having different resistances,
Divided into two or more groups with different heating functions, divided into two or more groups with different materials, or divided into two or more groups with different thicknesses, and made by any one or more of these methods, For each different group, one or more strands (or one group, one mixed substance) or two strands (or one or more of the fine wire, the fine wire group, or a mixture of the fine wire and the fine wire group having the same resistance value) are used. Two groups, two mixed ones)
A method of implementing a future energy power generation system, characterized by having different resistance values. The method of claim 56, wherein
The method of controlling the far infrared emission of the prefabricated heating wire,
The number of strands of the microfibers of the bundle synthesized by any one or more of a plurality of microfibers, a plurality of microfibers group, or a mixture of microfibers and microfibers group, the number of groups of the microfibers group, Or a first method of changing (adjusting) any one or more of the number of mixtures of the ultrafine wires and the ultrafine wire groups,
A second method of changing (adjusting) the self-heating temperature of the bundle synthesized by any one or more of a plurality of micro strands, a plurality of micro strand groups, or a mixture of a micro strand and a micro strand group,
The bundle of the bundle synthesized by any one or more of a plurality of micro fine wires, a plurality of fine wire groups, or a combination of a fine wire and a fine wire group by a combination of the first method and the second method. It modifies one or more of the number of strands of the micro wire, the number of groups of the micro wire group, or the number of mixtures of the micro wire and the micro wire group, and simultaneously controls the heating temperature of one bundle (heat wire) itself. Among the third method,
Implementation method of the future energy generation system, characterized in that any one or more methods. The method of claim 59,
The method of changing (adjusting) any one or more of the number of strands of the ultrafine wires of the bundle, the number of groups of the ultrafine wire groups, or the number of mixtures of the ultrafine wires and the ultrafine wire groups,
The fine wire of the bundle, the fine wire of the bundle in a state in which at least one of the resistance value, material or thickness of any one or more of the fine wire, the fine wire group, or a mixture of the fine wire and the fine wire group has the same conditions A method for implementing a future energy generation system, characterized by changing (adjusting) the number of strands (or the number of groups, or the number of mixtures) of at least one of a group or a mixture of an ultrafine wire and an ultrafine wire group. The method of claim 60,
The fine wire of the bundle, the fine wire of the bundle in a state in which at least one of the resistance value, material or thickness of any one or more of the fine wire, the fine wire group, or a mixture of the fine wire and the fine wire group has the same conditions The method of changing (adjusting) the number of strands (or the number of groups or the number of mixtures) of any one or more of a group or a mixture of an ultrafine wire and an ultrafine wire group,
The combined resistance value per unit length of one bundle (heat wire) is the same, but the number of strands (or number of groups, or groups of any one or more of the fine wire, the ultra fine wire group, or a mixture of the fine wire and the fine wire group), or A method of implementing a future energy power generation system, characterized in that the method of changing (adjusting) the number of mixed ones). The method of claim 59,
The method of changing (adjusting) any one or more of the number of strands of the ultrafine wires of the bundle, the number of groups of the ultrafine wire groups, or the number of mixtures of the ultrafine wires and the ultrafine wire groups,
Two or more of a plurality of micro fine wires, a plurality of micro wire groups, or a mixture of micro wires and micro wire groups having at least one of the same material, the same resistance value, or the same thickness, two or more In a heating wire made of multiple groups and made of one bundle, the combined resistance value per unit length of the entire bundle (heating wire) is the same, but inside each corresponding group, the inside fine wire, fine wire group, or fine wire Future energy power generation system characterized by the method of individually controlling the number of strands (or the number of groups, or the number of mixtures) of one or more of the mixed lines and the ultrafine wire groups (same or different groups). Implementation method. The method of claim 59,
In the method of adjusting the self heating temperature of the bundle (heating wire) of the second method and the third method, the amount of current flowing into the bundle (heating wire) is controlled by adjusting the resistance value per unit length of the bundle (heating wire) itself. Future energy power generation system characterized in that the method. The method of claim 63, wherein
The method for adjusting the resistance value per unit length of the bundle (heat wire) itself,
The bundle (heating wire) itself is made of a customized heating element having various low resistance values necessary to obtain desired heat by using battery electricity or safe low voltage direct current (DC) electricity of 24V or less, and the bundle (heating wire) is changed through a combination change. A method of implementing a future energy power generation system, characterized in that the method to be adjusted in such a way that it can be customized to have a desired low resistance value per unit length as one resistance value as desired. The method of claim 59,
The method of implementing a future energy generation system, characterized in that the self-heating temperature of the bundle (heating wire) of the second method and the third method is changed (controlled) within a range of 80 ° C to 600 ° C. The method of claim 47,
The heating wire having the instantaneous high temperature heating, high efficiency heating function,
By splitting the prepared fine lines into more thin strands, or by making the thickness of the fine lines thinner, the number of strands is made by increasing the number of strands, and synthesizing these fine lines into a prefabricated bundle A method of implementing a future energy generation system, characterized in that the bundle is made so that the bundle is a strand of heating wire. The method of claim 66,
In making the one bundle,
One strand is made of a micro wire having a thickness of 20 μm or less (based on the diameter of a micro wire), and the same micro wire is bundled into a plurality of strands of 100 or more strands of the same thickness and synthesized so as to be in electrical contact.
Or used in combination with the ultrafine wires used by the one strand,
In addition to the extra fine wire to be used by one strand or used,
Use only one bundle itself instead of the fine wire,
In the method of using two or more bundles instead of the fine wire,
Implementation method of the future energy generation system, characterized in that to increase the instantaneous high temperature heating, high efficiency heating function by any one or more methods. The method of claim 36,
By the prefabricated heating wire to be a heating wire having a constant temperature maintaining function,
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having any specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,
It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,
Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,
Prepare a variety of ultra-fine wire groups having a specific material but different materials,
Prepare a variety of ultra-fine wire groups with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,
Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. Collect the values to create and prepare the big data,
In addition, a fine fiber group made of one bundle may be prepared by making one strand of NASLON, which is a steel fiber, having a thickness of 20 μm or less with 100 or more strands having the same thickness.
NASLON 1 strand of steel fiber has a thickness of 12㎛ (corresponding ultrafine wire diameter), and prepare the ultrafine wire group consisting of 550 strands with the same thickness,
Prepare a microfiber group consisting of 1 strand of NASLON, which is steel fiber, having a thickness of 8 μm (correspondingly fine wire diameter), and having 1,000 strands of the same thickness.
One strand of NASLON, a steel fiber, has a diameter of 6,5 µm (correspondingly fine wire diameter), and a microfine wire group consisting of 2,000 strands with the same thickness is prepared.
Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups, which are more effective in performing a multi-function,
Multiple strands (or multiple groups, or multiple strands) of two or more fine strands (or two or more mixed groups) Choose a combination), and make a group with two functions with different heating function,
The first type group continues to generate heat when current flows, and the second type group generates less heat after reaching a predetermined temperature and conducts current just like a conductor rather than conducting heat to generate heat. To make the function larger, it is possible to combine these two types of micro-wires (or a combination of micro-wires, or a mixture of micro-wires and micro-wires) into one bundle, so that these bundles A method of implementing a future energy power generation system, characterized in that the manufacturing to be a hot wire. The method of claim 36,
By the prefabricated heating wire to be a heating wire having a function of excellent tensile strength and durability, and easily disconnected or little change in resistance value,
First, the material is steel fiber (NASLON) and the thickness of one strand is 20㎛ or less, the method of using one or more groups of ultrafine wire groups made of 100 or more of the same thickness,
The second material is steel fiber (NASLON), the thickness of one strand is 12㎛ (corresponding microwire diameter), the microwire group consisting of 550 strands with the same thickness, or more than one group,
One or more microfiber groups consisting of 1,000 strands of the same thickness as one strand of steel fiber (NASLON) having a thickness of 8 μm (corresponding ultrafine wire diameter), or
Any one or more of the method of using one or more groups of ultra-fine wire groups consisting of 2,000 strands having the same thickness as one strand of steel fiber (NASLON) having a thickness of 6,5 μm (the corresponding fine wire diameter),
Third, one or more microfine wire groups having a thickness of 1 strand of NASLON, which is a steel fiber, which is the first group, are 12 μm or less in diameter, and the number of strands is equal to or greater than 550.
The second group, a single fine wire made of a single metal or an alloy metal, is a fine wire or an ultra fine wire group having a thickness of 140 μm or less and corresponding strands having the same thickness or more;
The thickness of one fine-wire strand made of nickel-copper alloy metal (alloy made of 20-25 wt% of nickel and 75-80 wt% of copper) is 180 μm or less, and the number of strands is 1 A micro wire or micro wire group consisting of more than one strand,
140 micro-wires made of iron chromium alumina molybdenum alloy metal (alloy 68 ~ 73% by weight, chromium 18 ~ 22%, alumina 5-6% by weight, molybdenum 3-4% by weight) Among the ultrafine wires or ultrafine wire groups each having a thickness of equal to or less than μm (corresponding fine wire diameter) and having the same thickness, the number of strands is 1 or more strands.
Of the method of using a combination of any one or more of the ultra-fine wire group of the first group, and one or more of the ultra-fine wire or ultra-fine wire group of the second group,
A method of implementing a future energy power generation system comprising combining a micro wire, or a group of micro wires formed by any one or more methods, into a bundle to be electrically synthesized and combined to manufacture such a bundle as a single strand of wire. The method of claim 36,
The method of implementing the future energy generation system, characterized in that for producing a heating wire having a function of suppressing the oxidation reaction by covering the prefabricated heating wire. 48. The method of claim 39 or 47,
The flexible heating wire
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having a specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. After you have collected and created big data,
In the prepared ultrafine wires, the fine wire is made thinner and the number of strands is further increased, while having the same resistance value as when the heating wire is made into one strand,
A method of implementing a future energy power generation system, characterized in that the manufacture of ultrafine wires. The method according to any one of claims 36, 39, 47 or 64,
Using the battery electricity or safe low voltage direct current (DC) electricity of less than 24V to have a low resistance value required to obtain the desired heat,
Prepare by making a variety of micro wires having a specific resistance value but different resistance values,
Prepare by making a variety of ultra fine wire having a certain thickness but different thickness,
Prepare a variety of microfiber wires having a specific material but different materials,
Prepare a variety of ultra-fine wire with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the fine wires to meet the desired specifications with such a single metal or alloy metal, and prepare them in a variety of different ways,
For any specific resistance value, material, thickness, or function of a single metal or alloy metal having any specific resistance value, various different data values for resistance value, thickness, material, and function can be obtained. Aggregate and create big data,
It is also possible to prepare a variety of ultra-fine wire groups having a specific resistance value but different resistance values,
Prepare a variety of ultra-fine wire groups having a specific thickness but different thickness,
Prepare a variety of ultra-fine wire groups having a specific material but different materials,
Prepare a variety of ultra-fine wire groups with a specific function but different functions,
By making a single metal or alloy metal having any specific resistance value, material, thickness, or function desired, separate the ultra fine wire groups to the desired specification with such a single metal or alloy metal, and prepare them by varying differently,
Different data on resistance, thickness, material, and function for a variety of existing prefabricated or distributed microwire groups made of a single metal or alloy metal with any specific resistance, material, thickness, or function desired. Collect the values to create and prepare the big data,
In addition, a fine fiber group made of one bundle may be prepared by making one strand of NASLON, which is a steel fiber, having a thickness of 20 μm or less with 100 or more strands having the same thickness.
NASLON 1 strand of steel fiber has a thickness of 12㎛ (corresponding ultrafine wire diameter), and prepare the ultrafine wire group consisting of 550 strands with the same thickness,
Prepare a microfiber group consisting of 1 strand of NASLON, which is steel fiber, having a thickness of 8 μm (correspondingly fine wire diameter), and having 1,000 strands of the same thickness.
One strand of NASLON, a steel fiber, has a diameter of 6,5 µm (correspondingly fine wire diameter), and a microfine wire group consisting of 2,000 strands with the same thickness is prepared.
Among all the prepared ultrafine wires, the ultrafine wire groups, and the more effective ultrafine wire groups, which are more effective in performing a multi-function,
After selecting a micro wire (or a group of micro wires or a mixture of micro wires and micro wire groups) having a resistance value per unit length higher than that of a conductor, the micro wire (or a micro wire group having a higher resistance value than such a conductor), or A bundle of composites produced by increasing the number of strands (or the number of groups or the number) of a mixture of ultra fine wires and ultra fine wires, and synthesizing them in energized contact with each other in the longitudinal direction to lower the composite resistance value. The first method to make these bundles a single strand of heat,
Dividing the selection into two or more groups, the first group is a micro wire (or a combination of a micro wire group or a combination of a micro wire group and a micro wire group) having a resistance value equal or similar to that of a conductor per unit length. Select it,
After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,
The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The second method of making a strand of hot wire,
Dividing the selection into two or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group),
After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,
The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The third method of making a strand of hot wire,
Dividing the selection into three or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor, rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group),
The second group selects a micro wire (or a micro wire group or a mixture of micro wire and micro wire groups) having a resistance value equal to or similar to a conductor per unit length,
After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than that of the conductor,
The first group, the second group, and the third or more groups of microfibers (or microfibers, or a mixture of microfibers and microfibers) are combined into a single bundle by energizing and contacting each other in the longitudinal direction. , The fourth method of making these bundles a single strand of heat,
Among the fifth method using a mixture of the first method to the fourth method,
Implementation method of the future energy generation system, characterized in that any one or more methods. The method according to any one of claims 36, 38, 39, 48, 57, 59-65, 67, 68, or 69,
The bundling operation,
The method of implementing a future energy generation system, characterized in that the combination of the ultra-fine wires are covered by a split coating or split coating so as to conduct electricity synthesis. The method according to any one of claims 36, 38, 39, 48, 57, 59-65, 67, 68, or 69,
The bundling operation,
All the fine wires in the bundle are brought into close contact with each other, and the entire surface of all the fine wires in the bundle from the start to the end of the bundle are in contact with each other in the longitudinal direction, so that the current can flow to all of the fine wires across the contact surface. Composite combination of ultra fine wires,
A first method of lapping a plurality of strands of ultrafine wires with high temperature fibers by wrapping the high temperature fibers overlapping with the high temperature fibers,
A second method of bundling by twisting itself into a body through a jointer,
A third method of bundling and bundling the coating into the coater,
A fourth method of bundling the third method two or more times,
A fifth method using a different coating material for each coating number as the fourth method,
A sixth method of extracting and bundling the coating made by the first method or the second method by coating the coating machine once or twice or more;
The first or second method is made by coating the coating machine once or twice or more, but the coating material is the same by the number of times, or the number of parts by the same part is different, the number of times pulled while coating all differently The seventh method of bundling out,
Eighth method of inserting the adhesive between the upper and lower plates of the plate-shaped material, and then melted and bundled with the adhesive,
Among the ninth method of inserting any one or more of the bundles made by the first method to the eighth method between the upper and lower plates of the plate-shaped material, injecting the adhesive and then melting and bundling the adhesive,
A future energy generation system implementation method characterized in that carried out by any one or more methods. At least one of the methods of producing (generating) economical electricity in a clean and safe manner and storing (charging) it in an electrical storage device or receiving electricity generated (generated) by a future energy production method and delivering it to an electric consumer. Charging station to play a role;
An electrical storage device for storing (charging) electricity of the charging station;
An electricity consumption unit using (consuming) electricity supplied from the charging station; And
Electrical storage means for transferring the electrical storage device stored (charged) or maintained (charged) the electricity produced or generated at the charging station to the electrical consumer by a wireless transfer method:
Future energy generation system comprising a. 76. The method of claim 75,
The wireless transfer method,
The future energy generation system, characterized in that for supplying the electricity produced (generated) or delivered in the charging station to the electric consumer by realizing the charge, transfer, consumption, recovery, recharge cycle of electricity. 77. The method of claim 76,
The charge, transfer, consumption, recovery, recharge cycles of the electricity,
One or more than one electrical storage device transfers any one or more of the electricity produced or generated at the charging station to the electrical consumer while remaining stored (charged) or stored (charged). One or two or more times, including the process of consuming (discharging) the stored (charged) electricity at the electrical consumer, and then recovering and restoring (recharging) the battery again. The future energy generation system, characterized in that the cycle of performing a plurality of times repeatedly. 76. The method of claim 75,
The electrical storage device wireless transfer means,
The future energy generation system, characterized in that between the charging station and the electrical consumer, the electrical storage device is a means for performing any one or more of the role of being transferred or recovered. The method of claim 78,
The various means,
The producer and the consumer of the electrical storage device is configured, the charged electrical storage device produced by the producer is exchanged and distributed at various stages of the activity, the method is made by selling and selling the charged electrical storage device to each other After the consumer (consumer) consumes (discharges) the electricity of the charged electric storage device, the discharged electric storage device is again subjected to several steps from the consumer (consumer). A distribution structure is formed that includes a sale including all of these processes, in which a method of exchanging and distributing at a location is performed, and a method of selling and selling the charged electric storage devices is included, and is returned to the producer. Through letting
The one or more electricity, which is produced (generated) or delivered at the charging station, is stored (charged) or stored (charged) while being transferred to a distribution method including sales to the electric consumer, It includes one or more steps including consuming (discharging) the stored (charged) electricity at the electricity consumer, and then recovering and restoring (recharging) the distribution method including sales to the charging station. A first means of a distribution method including a sale in which all processes of continuously performing a plurality of times more than two times are performed;
When the producer and the consumer of the electric storage device are configured and the consumer orders the charged electric storage device, the producer delivers the charged electric storage device to the consumer, and the discharged electric storage device consumed by the consumer is the producer. By retrieving an order and delivery structure that includes all of these processes,
At least one of the electricity produced or generated at the charging station is stored (charged) or stored (charged) while being transferred to the electric consumer in an order and delivery method. Once or twice including the process of consuming (discharging) the stored (charged) electricity at the consumer, and then recovering and restoring (recharging) to the charging station again by the order and delivery method. Second means of the order and delivery method is made of all the processes to continuously and repeatedly performing a plurality of times,
The producer and the consumer of the electrical storage device are configured, and the consumer to be transferred from the producer to the consumer through any one or more of the methods to enable the transfer of the charged electrical storage device that the consumer needs, The discharged electrical storage device that has been consumed (discharged) causes other transportable structures to be formed, including any such process, to be returned to the producer by one or more of the other methods that enable transport. through,
At least one of the electricity produced or generated at the charging station is transferred to the electric consumer through other transferable methods while being stored (charged) or stored (charged), and the It includes one or more steps including consuming (discharging) electricity stored in the electricity consumption station, and then recovering and restoring (recharging) the battery through other transferable methods. The third means of other transferable methods, in which all processes are carried out continuously and repeatedly several times or more,
Among the fourth means using a mixture of the first to third means,
The future energy generation system, characterized in that any one or more means. The method of claim 79,
The third means,
Third a means for loading, transporting, transferring, transferring, and transporting the electrical storage device in a general means of transportation so that the electrical storage device is transferred from the charging station to the electrical consumer, and recovered from the electrical consumption station to the charging station;
After reconstructing a general vehicle into a vehicle for exclusive use of the electric storage device so that it can be used only for a purpose that can handle only the electric storage device, the electric storage device is transferred from the charging station to the electric consumer, and is recovered from the electric consumer to the charging station. 3b means for carrying, transporting, transferring, transferring and moving the electric storage device in the electric storage device-only vehicle;
As an electric only transportation means for storing (charging) electricity and outputting (discharging) electricity, it is a method of fixedly equipped or fixedly equipped with an electric storage device therein,
Superconducting power storage car, superconducting power storage ship, superconducting power storage aircraft, superconducting power storage train, large capacity power storage system car, large capacity power storage system ship, large capacity power Storage (large-capacity power storage systems) Aircraft, large-capacity power storage (large-capacity power storage systems) trains, batteries (electrical storage or ESS) trains, batteries (electrical storage or ESS) cars, batteries (electrical storage or ESS) Developed (made) by ships, batteries (electrical storage or ESS) aircraft,
Any one or more of the other means of transportation is developed (made) by transforming it into an electric only means of transportation so that it can be used exclusively for storing (charging) electricity and outputting (discharging) electricity.
By directly operating the electric dedicated transport means itself,
The electricity is stored (charged) in the electric dedicated transportation means and goes to the electric consumer at the charging station, and after outputting (discharged) the electricity stored (charged) in the electric dedicated transportation means itself at the electric consumer, the power is returned to the charging station. Third c means for continuously repeating a plurality of times one or two or more cycles of restoring (charging) the dedicated transport means itself;
Among the 3d means which uses the said 3a means-3c means,
The future energy generation system, characterized in that any one or more means. The method of claim 79,
The first means,
The future energy generation system, characterized in that the electrical storage device has a structure that can be bought and sold to each other between producers, consumers and third parties through the distribution process. 82. The method of claim 81 wherein
The future energy, characterized in that the value (price) of the electric storage device is formed differently according to the degree of use and the amount of electricity storage for each specification to identify the value (price) of the electric storage device between the seller and the buyer in the distribution process. Power generation system. 83. The method of claim 82,
The value (price) identification of the electrical storage device,
The future energy, characterized in that any one or more of displaying the number of times of charging and discharging the electricity in the electrical storage device, or the number of times of charging and discharging the electricity and also displays the remaining capacity of electricity. Power generation system. 76. The method of claim 75,
The electrical storage device,
Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Storage (ESS), power storage (device), DC power supply (equipment), battery (electric storage or ESS) car, battery (electric storage or ESS) ship, battery (electric storage or ESS) aircraft, One or more of various transportation means having a function of storing (charging) and outputting (discharging) electricity, or various products, articles, facilities, and apparatuses that store (charge) and output (discharge) electricity. Future energy generation system. 76. The method of claim 75,
The electrical storage device,
Future energy power generation system characterized in that it is standardized and structured with a function and structure capable of continuously and repeatedly performing the charge, transfer, consumption, recovery, and recharge cycles of electricity one or two or more times. . 86. The method of claim 85,
The standardized and standardized electrical storage device,
Standardize the electrical storage device to a standard with a constant size and weight, but make a plurality of types according to the specifications to meet the site use conditions, and the same type of each of the standardized types of electrical storage devices to make the same electrical specifications of each other The future energy generation system characterized by. 86. The method of claim 85,
The standardized and standardized electrical storage device,
The first device as it is, a variety of general products, articles, equipment, devices that perform any one or more functions of storing (charging) or outputting (discharging) existing electricity,
One or more cycles of charging, transporting, consuming, recovering and recharging electricity to general products, articles, equipment and devices that perform any one or more functions of storing (charging) or discharging (discharging) electricity. A second device that is reinforced or modified (modified) so that the structure (device) is further equipped to continuously and repeatedly perform a plurality of times more than two times,
Make new, dedicated products, articles, equipment and devices capable of performing any one or more of the functions of storing (charging) or discharging (discharging) electricity, and charging, transporting, consuming, recovering, recharging cycles of the electricity. In the process of repeatedly performing a number of times more than once or twice, standardize the size and weight to a certain standard so that the transfer and recovery can be performed smoothly by using the wireless storage means of electric storage device. A third device made of a plurality of types according to the standard, and the same type of each of the standardized types of electrical storage devices is standardized to have the same electrical specifications;
Among the fourth devices using the first to third devices,
Future energy power generation system, characterized in that any one or more devices. 88. The method of claim 87 wherein
The first device,
Existing, currently developed, produced and sold
Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy At least one of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or a variety of products, articles, equipment, devices that store (charge) and output (discharge) electricity. Future energy power generation system. 88. The method of claim 87 wherein
The second device,
Existing, currently developed, produced and sold
Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy One or more of a storage device (ESS), a power storage device (device), a DC power supply device (equipment), or a variety of products, articles, facilities, and devices that store (charge) and output (discharge) electricity. Future energy power generation system, characterized in that the reinforcement so that it is convenient and trouble-free during the recovery process. 88. The method of claim 87 wherein
The third device,
Existing, currently developed, produced and sold
Large capacity energy storage device, large capacity storage battery, large capacity power storage battery, high temperature superconducting power storage (HTS SMES) device, high temperature superconducting power storage system, superconducting power storage device, power storage system, large capacity power storage device, battery, industrial battery, energy Storage device (ESS), power storage equipment (device), DC power supply (equipment), or any one or more of various products, articles, equipment, devices that store (charge) and output (discharge) electricity; It has a similar function and structure, but reinforces the existing ones to make a new dedicated electric storage device so that it is convenient and trouble-free in the process of transportation and recovery.
Superconducting power storage device car, superconducting power storage device ship, superconducting power storage device aircraft, superconducting power storage device train, large capacity power storage system (large capacity power storage system) car, large capacity Power storage device (large capacity power storage system) Ship, large capacity power storage device (large capacity power storage system) Aircraft, large capacity power storage device (large power storage system) Train, battery (electric storage device or ESS) train, battery (electric storage device) Or ESS) a vehicle, a battery (electric storage device or ESS) ship, a battery (electric storage device or ESS) aircraft, and a device made to be a means of transportation having a function of storing (charging) and outputting (discharging) electricity. Future energy power generation system, characterized in that. The method of claim 1,
The electric consumer,
The first consumer has no place (space) to install the charging station or only has a low economy (space), and an electric mass consumer that is good at consuming (discharging) electricity. In the case of one or more of the second consumers with only a place (space),
Is installed at a location away from the first or second consumer and at least one of the charging station or intermediate storage station that produces (generated) economical electricity in the clean and safe manner, the electricity is supplied via a wireless transfer method Future energy generation system. 92. The method of claim 75 or 91,
The charging station,
It is a charging station for generating (generating) electricity that is stored (charging) stored in the electrical storage device by installing a power generation facility with lower cost of electricity among the power generation facilities generated by green energy or power generation facilities generated by renewable energy. Future energy power generation system, characterized in that. 92. The method of claim 75 or 91,
The charging station,
The solar energy generation system is installed, the future energy generation system, characterized in that the charging station for producing (power generation) photovoltaic electricity stored in the electrical storage device. 92. The method of claim 75 or 91,
The charging station,
It is economical place to install photovoltaic power generation facilities, or the installation cost of photovoltaic electricity generated by installing photovoltaic power generation facilities is cheaper than one of the existing power system electricity generation costs. ,
The future energy generation system, characterized in that the charging station for producing (generated) the photovoltaic electricity stored in the electrical storage device is installed one or more than two solar power equipment. 95. The method of claim 94,
Location condition of the economical place to install the photovoltaic power generation equipment,
Locational first condition that the land price of the place where the photovoltaic power generation equipment is installed is economically inexpensive or does not enter,
Locational second condition, which is a place where solar light is strong or shines long, so that the amount of photovoltaic electricity is generated.
Locational third condition, which is a spacious place to install the photovoltaic power generation equipment in a large size,
The electricity (generated) produced in the photovoltaic facility is stored (charged) in an electrical storage device and transferred to an electrical consumer. Of the fourth condition,
The future energy generation system, characterized in that any one or more location conditions. 97. The method of claim 95,
Where the location conditions of the economical place to install the photovoltaic power generation facilities,
The land where the photovoltaic facility is installed is economically inexpensive land, reservoirs, rivers, lakes, dams, uninhabited islands, uninhabited beaches, small uninhabited islands, uninhabited lands, other uninhabited areas, Among other places that don't cost land,
Future energy power generation system, characterized in that any one or more places. 95. The method of claim 94,
The installation condition of the photovoltaic electricity that is produced (generated) by installing the photovoltaic power generation facility is a location condition of a place where the power generation cost of the existing power system electricity is cheaper,
The amount of photovoltaic electricity (power) produced (generated) at the photovoltaic power generation facilities is higher than the amount of electricity (power) generated at various power plants generated by consuming fossil fuels such as existing nuclear power plants or thermal power plants. Future energy generation system, characterized in that it is a good place to install large-scale photovoltaic power generation equipment. The method of claim 97, wherein
The place with the location condition mentioned above,
Sea, desert, plateau, polar area, distant sea, wide desert, wide plateau, distant sea of broad lake, distant sea of broad river, distant sea of wide dam, uninhabited tundra, wide desert island, uninhabited Other large areas, among other large and spacious places that don't cost land,
Future energy power generation system, characterized in that any one or more places. 92. The method of claim 75 or 91,
The charging station,
Transfer the charged electrical storage device from the charging station to the electrical consumer, one or more places equipped with various infrastructures that can be made quickly and smoothly, the intermediate storage house where the electrical storage device (charged or discharged) is collected 1 Many places are installed more than two places or two places,
The future energy generation system, characterized in that the charging station for transferring and recovering the electrical storage device (charged or discharged) between the intermediate station and the charging station by a wireless transfer method. The method of claim 99,
The intermediate collecting station,
Various roads, air routes, shipping routes, and other transportation facilities that connect between the intermediate storage station and the electrical consumer, which can be made quickly and smoothly to transfer the electrical storage device (charged) from the intermediate storage station to the electrical consumer. Related infrastructure is built,
The future energy generation system, characterized in that the cost of the process of supplying electricity from the charging station to the electric consumer using the wireless transfer method is lower than the cost of using the conventional wire transfer method. 76. The method of claim 75,
The electric consumer,
The first consumer has no place (space) to install the charging station or only has a low economy (space), and an electric mass consumer that is good at consuming (discharging) electricity. In the case of one or more of the second consumers with only a place (space),
Installed at a location away from the first or the second consumer, at least one of the charging station or intermediate storage station for producing (generated) electricity in the future energy production method, characterized in that the electricity is supplied via a wireless transfer method Future energy power generation system. 101. The method of claim 75 or 101,
The electricity produced (generated) by the future energy production method,
Future energy power generation system, characterized in that the electricity is produced without endless exhaustion of energy and produced without the risk of environmental pollution and safety problems. 103. The method of claim 102,
The electricity is produced without endless depletion of energy and produced without endangering environmental problems and safety risks,
A future energy generation system, characterized in that it is electricity brought by an electric energy transportation device from the earth or the space. 101. The method of claim 75 or 101,
The place where the charging station for receiving the electricity (generated) produced by the future energy production method and delivering the electricity to the consumer is to be installed.
Inside charging stations that produce (generate) economical electricity in a clean and safe way,
Involvement of various roads, air routes, shipping routes, and other transportation facilities connecting the intermediate storage station with the electrical consumption station, which can be quickly and smoothly transferred from the intermediate storage station to the electrical storage station. The infrastructure is established so that the cost of supplying electricity from the charging station to the electric consumer using the wireless transfer method is lower than the cost of using the conventional wire transfer method.
Or where you can get and receive electricity at low cost,
Future energy power generation system, characterized in that any one or more places. 105. The method of claim 104,
The place where the electricity can be delivered cheaply,
In the process of receiving electricity (energy) brought by the electric energy transport device from the sky or the space and delivering it to the electric consumer,
The future energy generation system, characterized in that the cost of the process of supplying electricity to the electric consumer using the wireless transfer method in the charging station is cheaper than the cost of the process using the existing wire transfer method. 105. The method of claim 105,
In the charging station, the place where the cost of supplying electricity to the electric consumer using the wireless transfer method is lower than the cost of the process using the existing wire transfer method,
Relevant infrastructure of roads, air routes, shipping routes, and other transportation facilities connecting the charging station with the electrical consumption station, which makes it possible to quickly and smoothly transfer the electrical storage device (charged) from the charging station to the electrical consumption station. Future energy power generation system, characterized in that the place. 103. The method of claim 103,
The electric energy transport device,
It is equipped with a photovoltaic power generation unit composed of photovoltaic power generation facilities that generate (generate) electrical energy by receiving light energy of the sun from above the earth or space,
It is provided with an electrical storage device including a function of storing (charging) the electricity produced (generated) in the photovoltaic unit in the sky or space, and delivering the electricity stored (charged) in a designated charging station,
The electricity produced in the photovoltaic unit (generated) is stored in an electrical storage device, and configured to be connected to each other, the electric, control circuits that enable the output (discharged) of the stored (charged),
In a method of continuously or repeatedly performing a plurality of times, one or two cycles of electricity production and transportation between the charging station and the earth or space,
The future energy power generation system, characterized in that the flying device that stores (charges) the photovoltaic electricity produced (generated) in the photovoltaic power generation unit from the sky and the space, bring it to the designated charging station and deliver it. . 107. The method of claim 107,
The electricity production, transportation cycle,
The electric energy transport device flies up and flows over the earth or space (space), stays in the earth or space (space), produces (generates) and charges (stores) photovoltaic electricity, and then returns to the designated charging station. Future energy generation system, characterized in that the entire process to deliver the electric energy. 108. The method of claim 107 or 108,
The designated charging station,
Collecting (collecting), storing (charging), or the detachable electric storage device, which has been charged and transported, is collected and stored in the electric storage device provided in the electric energy transport device from the sky or the space. Of the designated charging stations that use the location, location and name, with facilities, facilities or personnel to replace removable electrical storage devices to be recharged,
The future energy generation system, characterized in that any one or more charging station. 107. The method of claim 107,
The electric energy transport device,
Rather than the total amount of energy consumed (consumed) in a single cycle of electricity production and transportation, electricity is produced (generated) from the sky or space through a single cycle of electricity production and transportation and brought to a designated charging station. A future energy generation system characterized by a higher total amount of energy (transported). 112. The method of claim 110,
Energy required for operation (driving) of the electric energy transportation device,
Future energy power generation system, characterized by the natural force (energy) obtained naturally by utilizing the principles of nature without the need for extra energy. 112. The method of claim 111,
The natural force (energy),
When the electric energy transport device floats over the earth or in space, stays on earth or in space, returns to the designated electric energy delivery site from the earth or in space, or travels in large amounts of energy. A future energy generation system, characterized in that it takes energy in any one or more of the sections of operation (driving). 112. The method of claim 111 or 112,
The power of nature,
The future energy generation system, characterized in that the buoyancy in the air to push up into the air in the opposite direction of the earth's gravity. 113. The method of claim 113,
The buoyancy in the air,
The future energy generation system, characterized in that any one or more of natural buoyancy made by using a buoyancy material, artificial buoyancy made by applying a negative pressure (-) or vacuum to artificially generate buoyancy. 119. The method of claim 114, wherein
The natural buoyancy is,
Future energy power generation system, characterized in that the buoyancy is formed naturally by filling the buoyancy material in the space having a certain volume (object having a certain volume of space). 116. The method of claim 114 or 115,
The buoyancy material,
The future energy generation system, characterized in that the material having a density lower than the density of the air. 116. The method of claim 116 wherein
The material having a density lower than that of the air,
Future energy generation system, characterized in that any one or more of helium gas, hydrogen gas, methane gas, nitrogen. 119. The method of claim 114, wherein
The artificial buoyancy is a future energy generation system, characterized in that the buoyancy formed by applying a negative pressure (-) or a vacuum to artificially generate buoyancy in a space having a certain volume (object having a certain volume of space). 112. The method of claim 112,
Create a space having a certain volume inside the electric energy transport device to form the natural buoyancy by filling the buoyancy material in the space, or to form artificial buoyancy by applying a negative pressure (-pressure) or vacuum in the space, or A first method comprising any one or more of the method of installing a buoyancy device made to have one or more buoyancy of natural buoyancy or artificial buoyancy in the electric energy transport device,
A second method of providing a buoyancy device having one or more buoyancy of the natural buoyancy or artificial buoyancy as an additional configuration separately to the electric energy transport device;
Among the third method of adjusting the magnitude of the buoyancy of any one or more of the natural buoyancy, artificial buoyancy, or buoyancy device in the first method and the second method,
The future energy generation system, characterized in that to handle the energy required for the operation (drive) of the electric energy transportation device in any one or more ways. 121. The method of claim 119 wherein
In the third method, the adjustment of the magnitude of buoyancy is
Buoyancy of any one or more of the natural buoyancy, artificial buoyancy, or buoyancy of the buoyancy device provided separately to the electrical energy transport device to be formed in the electrical energy transport device,
In the pressure of a buoyant material, negative pressure (-pressure), vacuum, or the volume of space in which the buoyancy is to be formed,
Future energy power generation system characterized by applying or adjusting any one or more of them. 121. The method of claim 119 or 120, wherein
The buoyancy device,
An object having a closed volume of a constant volume, the future energy generation system, characterized in that the mass per volume of the object has a mass lower than the air per the same volume of the surrounding air to generate the effect of buoyancy in the air (air). 121. The method of claim 121, wherein
In one or more of the methods of inserting (injecting), applying negative pressure (-pressure), or applying vacuum to an object having a constant volume of closed space,
The future energy generation system, characterized in that the mass per volume of the object to have a lower mass than the air per equal volume of ambient air. 107. The method of claim 107,
The future energy generation system, characterized in that the flying device is made of a drone and used as an electric energy transportation device. 76. The method of claim 75,
The electric consumer is an electric load that generates heat among electric loads that are directly operated by direct current (DC) electricity itself that is output (discharged) from an electrical storage device. system. 124. The method of claim 124 wherein
The battery electric operation prefabricated heating wire,
Low-resistance value or multi-function required to obtain the desired heat using ultra-fine wires made of single metal or alloy metal with different strands, thicknesses, materials, and functions. Among them, the future energy generation system, characterized in that the bundle is made of one strand through the bundling operation by synthesizing prefabricated so as to have any one or more. 126. The method of claim 125,
The desired column is,
The future energy generation system, characterized in that the heat is required to consume a lot of energy in the place where the desired heat is obtained. 126. The method of claim 126,
Where the heat is needed to consume a lot of energy to get the desired amount of heat,
Heat required for building floor heating, heat required for space heating, water or other liquids, heat required for melting, boiling or warming solids, heat required for thawing or melting snow, heat required for drying Energy required for space heating applications, farming (crop cultivation) facility heat for house heating, heat tracing, heating jackets, or other fields that require heat. Among the heat of various uses that consume a lot and get heat,
Future energy power generation system, characterized in that any one or more heat. 126. The method of claim 125,
The prefabricated heating wire,
First, a heating wire having a low resistance value necessary to obtain a desired heat using battery electricity or a safe low voltage direct current (DC) electricity of 24V or less,
Secondly, a battery wire or a heating wire that exhibits one or more additional functions with the low resistance required to obtain the desired heat using a safe low voltage direct current (DC) electricity of less than 24V;
Third, any heating wire of at least one of the first and second heating wires, and a flexible heating wire,
Fourth, customized heating wires each of which is precisely matched to each other in various cases so as to have any one or more functions of the first to third heating wires,
Fifth among the heating wires that can be economically and easily mass-produced at any time with the same product with the same performance as the customized heating wires made by the fourth above,
Future energy power generation system, characterized in that any one or more hot wire. 129. The method of claim 128,
The customized heating wire,
Future energy power generation system, characterized in that the bundle of the change of the combination of the ultra fine wire is made by changing the combination of the ultra fine wire. 126. The method of claim 125,
The ultra-fine wire group of the heating wire to perform the multi-function,
One strand of NASLON, a steel fiber, having a thickness of 20 µm or less, having 100 or more strands of the same thickness, the entire surface of these multiple strands of microfibers contacting each other from the beginning to the end in the longitudinal direction, so that all the fine lines of the entire contact surface The future energy generation system, characterized in that the bundle is made by combining a combination so that the electrical contact with each other, the electrical synthesis is made to flow to each other. 126. The method of claim 125,
The ultra-fine wire group of the heating wire to perform the multi-function,
One strand of NASLON, a steel fiber, has a thickness of 12 μm (correspondingly fine wire diameter), and the number of strands having the same thickness is 550.
One strand of NASLON, a steel fiber, has a thickness of 8 µm (correspondingly fine wire diameter), and the number of strands having the same thickness is 1,000, or
The thickness of 1 strand of NASLON, which is a steel fiber, is 6,5 µm (correspondingly fine wire diameter), and the number of strands having the same thickness is 2,000 strands,
Future energy power generation system, characterized in that made in any one or more groups. 131. The method of claim 125 or 130-131, wherein
The multi-function heating wire,
With prefabricated heating wires, all of these features are flexible, with the low resistance required to achieve the desired heat using battery electricity or safe low-voltage direct current (DC) electricity below 24V, and at the same time performing any one or more functions simultaneously. Future energy power generation system, characterized in that the complex expression of the hot wire. 133. The method of claim 132,
The heating wire having at least one specific function is
Heat rays that emit far infrared rays,
Instant high temperature heating, heating wire with high efficiency heating function,
Heating wire with constant temperature function,
Hot wire with excellent tensile strength and durability, easy disconnection or low resistance value change,
Among the hot wires having a function of suppressing oxidation reactions,
Future energy power generation system, characterized in that any one or more hot wire. 133. The method of claim 133,
The heating wire that the far infrared rays are emitted,
Battery electricity or safe low-voltage direct-current (DC) power of 24V or less, many of which are multi-stranded microwires, multiple-group ultrafine wire groups, or a mixture of ultrafine wires and ultrafine wire groups that emit far infrared rays while generating heat due to resistance And select one or more of these, and then combine one or more of the selected micro strands of the multiple strands, the multiple groups of the micro strands, or a mixture of the micro strands and the micro strands group so as to be in contact with each other. A composite combination of any one or more of these multiple strands of microfibers, multiple groups of microfibers, or a mixture of microfibers and microfibers, into one bundle, It is a method of making a strand of heating wire, which can be more easily radiated by electric dipole radiation from which far infrared rays are emitted. Future energy generation system characterized by having a geometric structure. 135. The method of claim 134,
The geometry through which the electric dipole radiation can be radiated much better is
Synthetic combinations inside the bundle,
When the resistance value, the material, or the thickness of one or more of a plurality of micro wires, a plurality of micro wire groups, or a mixture of a micro wire and a micro wire group are one or more, the same condition is used. Make the number of strands (or the number of groups, or the number of mixtures) of one or more of the same, or the same as the combination of the very fine wire and the same fine wire group, or
One or more of two or more groups having different resistance values and having a same resistance value for each group having a different resistance value, or a mixture of micro wires and micro wire groups having a same resistance value 1 A future energy generation system characterized by having at least one strand (or one group, one mixed) or two strands (or two groups, two mixed). 135. The method of claim 134 or 135, wherein
The micro wire, the micro wire group, or a mixture of the micro wire and the micro wire group,
The future energy generation system, characterized in that the dipole moment occurs when electricity flows, and the material (material) that emits a large amount of far infrared rays. 138. The method of claim 136,
When the electricity flows, the dipole moment is formed and the material (material) that emits a large amount of far infrared rays,
When the material itself is heated to a temperature of 50 ℃, far-infrared rays have a wavelength length in the range of 3 to 200 microns (μm), which are mono- or alloy metals that emit more than 60% of emissivity,
Pure iron or alloy metal containing pure iron,
Alloy metal containing carbon,
SUS 316, SUS 304, stainless steel alloy metal,
Steel fiber (metal fiber) (NASLON),
Nickel and copper alloy metals made from 20-25 wt% nickel and 75-80 wt% copper,
Among alloy metals made from 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum,
Future energy power generation system, characterized in that any one or more. 133. The method of claim 133,
The heating wire having the temperature keeping function,
Multiple strands (or multiple groups, or multiple strands) of two or more fine strands (or two or more mixed groups) Choose a combination), and make a group with two functions with different heating function,
The first type group continues to generate heat when current flows, and the second type group generates less heat after reaching a predetermined temperature and conducts current just like a conductor rather than conducting heat as it is conductored. The future energy generation characterized by a bundle made by synthesizing these two ultrafine wires (or a combination of the ultrafine wire groups, or a combination of the ultrafine wire lines and the ultrafine wire groups) into one to make a larger function. system. 138. The method of claim 138, wherein
The heating wire having the temperature keeping function,
After the heating operation is started and the electricity is continuously supplied, the temperature-keeping function is expressed in the material itself, and once it has risen to a certain temperature unless there is a temperature change in the surrounding environment in the heating wire (bundle) material itself without a separate temperature control device, Future energy power generation system, characterized in that the heating wire is a constant temperature is constantly rising. 138. The method of claim 138, wherein
The first type group is steel fiber (NASLON), the second type group is a future energy generation system, characterized in that the silicon copper alloy. 133. The method of claim 133,
The hot wire having a function of suppressing the oxidation reaction,
SUS 316, SUS 304, stainless steel alloy metal,
Steel fiber (metal fiber) (NASLON),
Alloy metal made by adding a small amount of molybdenum to a nickel copper alloy made of 20-25 wt% nickel and 75-80 wt% copper,
Mixing ratio 68% to 73% by weight of iron, 18% to 22% by weight of chromium, 5% to 6% by weight of alumina, and 3% to 4% by weight of molybdenum iron chromium alumina molybdenum alloy, by adding at least one of manganese and carbon Among the alloy metals made,
Future energy power generation system, characterized in that the manufacture of ultra-fine wire made of any one or more materials. 133. The method of claim 132,
The low resistance value required to obtain a desired heat by using the battery electricity or safe low voltage direct current (DC) electricity of 24V or less,
After selecting a micro wire (or a group of micro wires or a mixture of micro wires and micro wire groups) having a higher resistance value per unit length than a conductor, the micro wire (or a micro wire group having a higher resistance value than the conductor), or A bundle of composites produced by increasing the number of strands (or the number of groups or the number) of a mixture of ultra fine wires and ultra fine wires, and synthesizing them in energized contact with each other in the longitudinal direction to lower the composite resistance value. The first method to make these bundles a single strand of heat,
Dividing the selection into two or more groups, the first group is a micro wire (or a combination of a micro wire group or a combination of a micro wire group and a micro wire group) having a resistance value equal or similar to that of a conductor per unit length. Select it,
After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,
The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The second method of making a strand of hot wire,
Dividing the selection into two or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group),
After selecting the micro wire (or the micro wire group or a mixture of the micro wire and the micro wire group) in which the resistance value per unit length has a higher resistance value than the conductor,
The ultrafine wires (or the ultrafine wire group, or a mixture of the ultrafine wire group and the ultrafine wire group) of the first group and the second or more multiple groups are synthesized to be in electrical contact with each other in the longitudinal direction to form a bundle, and the bundle is The third method of making a strand of hot wire,
Dividing the selection into three or more multiple groups, the first group has a greater ability to allow current to flow just like a conductor, rather than generating less heat and conducting heat after reaching a predetermined temperature. Select the fine wire (or the fine wire group, or a mixture of the fine wire and the fine wire group),
The second group selects a micro wire (or a micro wire group or a mixture of micro wire and micro wire groups) having a resistance value equal to or similar to a conductor per unit length,
After selecting the micro wire (or the micro wire group, or a mixture of the micro wire and the micro wire group) having the resistance value per unit length higher than that of the conductor,
The first group, the second group, and the third or more groups of microfibers (or microfibers, or a mixture of microfibers and microfibers) are combined into a single bundle by energizing and contacting each other in the longitudinal direction. , The fourth method of making these bundles a single strand of heat,
Among the fifth method using a mixture of the first method to the fourth method,
Future energy generation system, characterized in that obtained in any one or more ways. 142. The method of claim 142 wherein
Microwires (or microwire groups, or microwires and microwires) in which the resistance value per unit length is the same as or similar to the conductor in the first to fifth methods, or the resistance value per unit length is higher than the conductor. As a material (material) of the mixed group),
Future energy generation system, characterized in that any one or more of gold, platinum, silver, copper, aluminum, pure iron, tungsten, or nickel. 143. The method of claim 142, wherein
Microwires (or microwire groups, or microwires and microwires) in which the resistance value per unit length is the same as or similar to the conductor in the first to fifth methods, or the resistance value per unit length is higher than the conductor. Alloy metals as materials of the mixed group),
Nickel copper alloy alloy metal, nickel chromium alloy alloy metal, iron chromium alloy alloy metal, iron carbon alloy alloy metal, hard copper or hard alloy alloy metal, steel fiber (metal fiber) (NASLON), graphene or graphene Alloy metals, stainless steels (SUS 316 and SUS 304) alloy metals mixed with, alloy metals containing pure iron or pure iron, alloy metals containing carbon,
Nickel and copper alloy metals made from 20-25 wt% nickel and 75-80 wt% copper,
Among alloy metals made from 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum,
Future energy power generation system, characterized in that any one or more. 143. The method of claim 142, wherein
In the third method to the fifth method, a fine wire (or less heat is generated after reaching a predetermined temperature and conducts a function of allowing a current to simply flow like a conductor rather than generating heat while being conductively formed (or The alloy metal is a material of a fine wire group or a mixture of an ultrafine wire group and an ultrafine wire group),
A future energy generation system, characterized in that any one or more of silicon copper alloy series alloy metal, silicon bronze alloy series alloy metal, silicon iron alloy series alloy metal. 141. The method of any one of claims 125, 129, 138 or 142, wherein
The bundling operation,
All the fine wires in the bundle are brought into close contact with each other, and the entire surface of all the fine wires in the bundle from the start to the end of the bundle are in contact with each other in the longitudinal direction, so that the current can flow to all of the fine wires across the contact surface. Composite combination of ultra fine wires,
A first method of lapping a plurality of strands of ultrafine wires with high temperature fibers by wrapping the high temperature fibers overlapping with the high temperature fibers,
A second method of bundling by twisting itself into a body through a jointer,
A third method of bundling and bundling the coating into the coater,
A fourth method of bundling the third method two or more times,
A fifth method using a different coating material for each coating number as the fourth method,
A sixth method of extracting and bundling the coating made by the first method or the second method by coating the coating machine once or twice or more;
The first or second method is made by coating the coating machine once or twice or more, but the coating material is the same by the number of times, or the number of parts by the same part is different, the number of times pulled while coating all differently The seventh method of bundling out,
Eighth method of inserting the adhesive between the upper and lower plates of the plate-shaped material, and then melted and bundled with the adhesive,
Among the ninth method of inserting any one or more of the bundles made by the first method to the eighth method between the upper and lower plates of the plate-shaped material, injecting the adhesive and then melting and bundling the adhesive,
Future energy generation system, characterized in that any one or more methods. 146. The method of claim 146 wherein
The high temperature fiber coating material of the said 1st, 6th, 7th method,
Aramid, polyarylate (POLYARYLATE), the future energy generation system, characterized in that any one or more of the fibers (carbon fibers) made of graphene. 146. The method of claim 146 wherein
The coating material of the third, fourth, fifth, sixth, seventh, nineth methods,
Teflon, PVC, silicon, graphene, ceramics, ceramics, carbon black, ceramic coating material REFRACTOCOAT (reflector coat), tetraethylortho [silicate (TEOS) + silica zirconium silicate powder dispersed in liquid binder Putty], Cerakwool (Cerakwool), or Aerogel (Aerogel), any one of the future energy generation system characterized in that. 141. The method of any one of claims 125, 128, 134 or 142, wherein
The battery electricity,
The future energy generation system, characterized in that the electricity output (discharged) from various electrical storage devices capable of charging or discharging electricity. 149. The method of claim 149,
The various electrical storage device,
86. The future energy generation system, characterized in that any one or more of the electrical storage device according to any one of claims 75 and 77 to 83. 149. The method of claim 149,
The various electrical storage device,
An electric storage device that outputs (discharges) direct current (DC) electricity and outputs (discharges) any one or more of electricity at a specific range of voltages of 24V or less voltage or voltage of 24V or less. Future energy power generation system. 141. The method of any one of claims 125, 128, 134 or 142, wherein
The battery electricity,
86. The future energy generation system, characterized in that any one or more of the direct current (DC) electricity of the various voltage bands output (discharged) in the electrical storage device according to any one of claims 75, 77-83. 141. The method of any one of claims 125, 128, 134 or 142, wherein
The battery electricity,
A future energy generation system using direct current (DC) electricity, wherein any one or more of a voltage of 24V or less, or a voltage of a specific range of voltages of 24V or less. 141. The method of any one of claims 125, 128, 134 or 142, wherein
The safe low voltage direct current (DC) electricity of the 24V or less,
A future energy generation system using direct current (DC) electricity, wherein any one or more of a voltage of 24V or less, or a voltage of a specific range of voltages of 24V or less. 141. The method of any one of claims 125, 128, 134 or 142, wherein
The safe low voltage direct current (DC) electricity of the 24V or less,
The electrical power output from the electrical storage device according to any one of claims 75 and 77 to 83, wherein any one or more of any voltage of 24V or less or electricity of a specific range of voltage of 24V or less. Future energy power generation system, characterized in that. 129. The method of claim 125 or 128,
The low resistance value is,
The future energy generation system, characterized in that the resistance value that can flow the amount of current that can cause the desired heat operation by the battery electricity. 129. The method of claim 125 or 128,
The low resistance value is,
86. The future energy generation system, characterized in that the electric current output from the electrical storage device according to any one of claims 75 and 77 to 83 is a resistance value through which an amount of current that can cause a desired heating operation can flow. 129. The method of claim 125 or 128,
The low resistance value is,
The future energy generation system, characterized in that the electric current is output (discharged) from a variety of electrical storage devices capable of charging or discharging electricity, the resistance value that can flow the amount of current that can cause a desired heating operation. 129. The method of claim 125 or 128,
The low resistance value is,
It is a direct current (DC) electricity, but any one or more of a voltage of 24V or less, or electricity of a specific range of voltages of 24V or less, which is a resistance value capable of flowing an amount of current that can cause a desired heating operation. Future energy power generation system characterized by. 129. The method of claim 125 or 128,
The low resistance value is,
83. An electric furnace of any one or more of any voltage of 24 V or less output from the electrical storage device according to any one of claims 75 and 77 to 83 or electricity of a specific range band voltage of 24 V or less. Future energy power generation system, characterized in that the resistance value that can flow the amount of current that can cause the desired heating operation. 145. The method of any one of claims 125-128, 32, 142, or 147, wherein
The desired column is,
In order to obtain a desired heat generation amount or temperature within the desired time in the prefabricated heating wire, the amount of power proportional to the heat generation is consumed within the corresponding time in the prefabricated heating wire, and for this purpose, the power value (power amount) is calculated by dividing by the corresponding voltage to be used. A future energy generation system, wherein the current value (amount of current) is heat generated when a heat generation action flows to the prefabricated heating wire at a corresponding voltage within a corresponding time. 126. The method of claim 125,
The material (material) of the low resistance value prefabricated heating wire,
Any one of silver, tungsten, platinum, aluminum, copper, nickel, pure iron,
SUS 316, SUS 304, stainless steel alloy metal,
Steel fiber (metal fiber) (NASLON),
Nickel copper alloy metal made from 20-25 wt% nickel and 75-80 wt% copper,
Iron chromium alumina molybdenum alloy metal made from 68 to 73% by weight of iron, 18 to 22% by weight of chromium, 5 to 6% by weight of alumina, and 3 to 4% by weight of molybdenum,
Among the silicon copper alloy metals made of 20% by weight of silicon and 80% by weight of copper,
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The micro fine wire,
Among the ultrafine wires made of the above-mentioned silver and having a resistance value of 0.1058 kPa (fine wire thickness 0.1531 mm 2), 0.241 kPa (fine wire thickness 0.06721 mm 2), or 1.1150 kPa (fine wire thickness 0.014527 mm 2),
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The micro fine wire,
An ultrafine wire made of tungsten and having a resistance value of 1 m 3 (length of ultra fine wire 0.0532 mm 2), 5.768 mm (fine wire thickness 0.0095 mm 2) or 8.179 mm (fine wire thickness 0.0067 mm 2),
It is made of platinum and the resistance value per 1m length is 0.2058Ω (fine wire thickness 0.51mm2), 0.913Ω (fine wire thickness 0.115mm2), 2.058Ω (fine wire thickness 0.051mm2), 4.565Ω (fine wire thickness 0.023mm2) Or 14.999 Ω (fine wire thickness 0.007mm2),
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The ultra fine wire,
The steel fiber (metal fiber) (NASLON) and the resistance value per 1m length is 50.5Ω (microwire thickness 0.017229mm2), 90.3Ω (microwire thickness 0.009635mm2), 170.5Ω (microwire thickness 0.005103mm2) or 281Ω ( In the ultra fine wire having a fine wire thickness of 0.003096 mm2),
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The ultra fine wire,
An ultrafine wire made of copper and having a resistance value of 0.1098 kPa (microwire thickness 0.1538 mm 2), 0.235 kPa (microwire thickness 0.0718 mm 2) or 1.1123 kPa (microwire thickness 0.015386 mm 2),
Among the ultrafine wires made of the above-mentioned aluminum and having a resistance value of 0.0201 mW (fine wire thickness 1.3 mm 2), 0.0315 mW (fine wire thickness 0.83 mm 2) or 0.356 mW (fine wire thickness 0.0735 mm 2),
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The micro fine wire,
An ultrafine wire made of nickel and having a resistance value of 1,018 mW (fine wire thickness 0.053 mm 2), 6.2727 mW (fine wire thickness 0.011 mm 2) or 8.625 mW (fine wire thickness 0.008 mm 2),
It is made of pure iron and the resistance value per 1m length is 0.1886Ω (fine wire thickness 0.53mm2), 0.909Ω (fine wire thickness 0.11mm2), 2Ω (fine wire thickness 0.05mm2), 4.347Ω (fine wire thickness 0.023mm2) or Of the fine wire which is 12.5Ω (fine wire thickness 0.008mm2),
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The ultra fine wire,
The fine wire made of SUS 316 and having a resistance value of 1 m in length of 50 mW (fine wire thickness 0.015386 mm 2), 90 mW (fine wire thickness 0.00785 mm 2), 170 mW (fine wire thickness 0.004525 mm 2) or 280 m (fine wire thickness 0.002523 mm 2) medium,
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The micro fine wire,
An ultrafine wire made of the above-mentioned iron chromium alumina molybdenum alloy and having a resistance value of 48 mW (fine wire thickness 0.015386 mm 2) or 82 mW (fine wire thickness 0.00785 mm 2),
An ultrafine wire made of the nickel-copper alloy and having a resistance value of 11 mW (fine wire thickness 0.025434 mm 2) or 36 mW (fine wire thickness 0.00785 mm 2),
The ultra fine wire made of SUS 316 and having a resistance value of 1,650 m (fine wire thickness 0.0001005 mm 2), 17,330 mW (fine wire thickness 0.00004436 mm 2) or 26,375 m (fine wire thickness 0.00002914 mm 2),
Microfiber wire made of the steel fiber (NASLON) and having a resistance value of 1,700 mW (fine wire thickness 0.000113 mm 2), 17,319 mW (fine wire thickness 0.00005024 mm 2) or 26,239 mW (fine wire thickness 0.00003316 mm 2) medium,
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The micro fine wire,
A fine wire made by adding a small amount of molybdenum to the nickel copper alloy and having a resistance value of 11.2 kW (micro wire thickness 0.02512 mm 2) or 36.5 kW (micro wire thickness 0.00770 mm 2) per 1 m length,
Among the ultrafine wires made by adding at least one of manganese and carbon to the iron chromium alumina molybdenum alloy and having a resistance value of 48.7 Ω (fine wire thickness 0.0151 mm 2) or 83.7 Ω (fine wire thickness 0.008785 mm 2) per 1 m length,
Future energy power generation system, characterized in that any one or more. 162. The method of claim 162,
The ultra fine wire,
Among the ultrafine wires made of the above-mentioned silicon copper alloy and having a resistance value of 50 m (fine wire thickness 1 mm 2) or 104.8 m (fine wire thickness 0.477 mm 2) per 1 m length,
Future energy power generation system, characterized in that any one or more.

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