JP5852779B2 - Power supply - Google Patents

Description

  The present invention relates to a power supply device and an inverter device.

The design of the current power purchase system is just a simple purchase system of surplus power, and if the surplus power is within the capacity of the utility pole transformer, this is equivalent to a few households, It accepts power supply connections from general consumers.
As a typical prior art document, Japanese Patent Application Laid-Open No. 2003-284244 (Patent Document 1) of Kansai Electric Power Co., Ltd., cited in large numbers below, can be cited.

  The main purpose of Patent Document 1 is to use the high-speed response and overload capability of the secondary battery to supply power and maintain the quality of equipment in the customer premises when the power system malfunctions. It is to realize an ancillary service providing method and system using a secondary battery that enhances and improves power generation efficiency and supports ancillary services such as instantaneous reserve capacity, operation reserve capacity and standby reserve capacity.

  Even in Europe and the United States, before power deregulation, functions (added value) related to the maintenance of power quality provided by the operation of interconnected systems such as frequency control are all integrated under the vertical integration system of the electric power business. Provided to customers.

However, after the liberalization of power, functions related to maintaining various power qualities have been separated, and interconnected grid operation services such as load frequency control are generally handled as ancillary services (auxiliary services). It was decided to trade separately.
Ancillary service is a supplementary service, but it is an indispensable service from the viewpoint of maintaining power quality. If this added value is not provided, the power system is stable and reliable. It cannot be used.

  The ancillary service is defined by the NERC (The North America Electric Reliability Council) and various ancillary service items are described below.

(A) Less than 10 minutes by providing an appropriate generator response capacity by AGC (Automatic Generation Control) so that the control area can be balanced accordingly when load fluctuations in regulation minutes occur This is a service that automatically controls the output of the generator in real time according to control signals such as ISO (Individual System Operation) so that the supply and demand imbalance of the generator matches the control performance index (CPS) of NERC.

(B) Load follow-in regulation is a service that provides the necessary power generation and capacity to cope with load fluctuations over longer hours and days.

(C) Energy imbalance The energy imbalance is a service that compensates for the difference between the planned value and the actual measured value at the power receiving point or the supply and demand point within the boundary of the controlled area, and this service is applied to both load and power generation.
In the imbalance settlement, the balance between supply and demand is ensured by performing settlement using different prices depending on whether or not an allowable deviation deviates.

  (D) This service provides a capacity that can be output within 10 minutes after receiving a command from the instantaneous reserve power ISO or the like by a generator that is synchronously parallel to the system.

(E) The generator provides a capacity that can be output within 10 minutes after receiving a command from the operating reserve ISO or the like.
Alternatively, it is a service provided by a load that can be suppressed within 10 minutes.

  (F) Backup supply Backup supply is power generation capacity, used as an alternative when power transmission is not possible due to power generation stoppage or power transmission system stoppage, and to supplement shortage when customer load exceeds power generation capacity It is a service.

  (G) System control services required to compensate for the reliability of the interconnected system, to comprise the necessary comprehensive activities, to minimize transmission constraints, and to recover after accidents or disturbances It is.

  (H) A service for controlling the reactive power generated by the reactive power compensation power source to support the operation of the transmission system, and includes the ability to continuously adjust the voltage of the transmission system according to the change of the system.

  (I) Transmission loss compensation This is a service that provides an amount of power to compensate for loss in the transmission system of the transmission line provider associated with transmission loss and replacement of transmission loss.

  (J) purchase of specific equipment, equipment, software or systems required at the power plant to enable the grid-stabilized transmission line provider or control area to meet NERC or local reliability requirements; A service that provides operation and maintenance.

  (K) Restoration of all stops This service provides the ability of a generator that can perform the process from restoration to the operating state to supplying power without any assistance from the power system at all stops.

By the way, a secondary battery such as a redox flow battery or a sodium-sulfur battery is expected to play a role as load leveling in which it is charged with electric power at night and discharged in the daytime.
A sodium-sulfur battery is a high-temperature secondary battery that uses sodium for the negative electrode, sulfur for the positive electrode, and β-alumina for the electrolyte. Also called NAS battery or NAS. It is made especially for large-scale power storage and used for day and night load leveling. By the way, NAS battery or NAS is a trademark of TEPCO. The above four lines are reference sentences.
In addition, these secondary batteries are expected to be applied to supply and demand control because of their very high response speed to output commands and little deterioration due to repeated charge and discharge.
In addition, these secondary batteries are highly resistant to short-term overloads, so they can be applied to general ancillary services such as supply and demand control that absorbs short-cycle frequency fluctuations and instantaneous reserves by using the overload region. It is also possible to do.

If we explain in Fig. 2 based on the idea of using the river flow that is often cited for easy understanding, it can be considered that the current is the amount of water and the voltage is the momentum of water.
Although it is slightly different, the understanding of the basics is as in the previous term.
Electric power (W) is a value that considers current and voltage comprehensively, and resistance is considered to be a rock that blocks the river.
If the momentum of the water is strong and the amount of water is large, tremendous electricity flows like after heavy rain.
Even if the momentum is strong, it is like a water gun if the amount of water is small, and the flow is like the Amazon River if the momentum is weak and the amount of water is large.
Resistance is rock.
If the resistance is low, the rock is small and the flow of water is blocked a little.
If the resistance value is large, a huge rock blocks the water flow.
By the way, the famous E = IR expression has a restriction that R ≠ 0, so R = 0 is not considered.

Transmission lines carry electricity itself.
Current and voltage are the units of the object.
This is also a flow of water, but there is a stretchable water pipe that leaks water little by little, and the same amount of water flows through it.
At that time, if the momentum of water is increased and water is poured little by little, the amount of leakage will be small.
On the other hand, if water is weakened and water is forced into the water pipe at once, water leaks from the water pipe.

Similar leaks occur in transmission lines.
Water leakage is the same as power loss.
Electricity is also sent to the Tokyo metropolitan area from nuclear power plants in Fukushima and Niigata prefectures, and the length of the wires is as long as 300 km.
It will decrease by about 4.8% from this far-off power plant until electricity reaches a general household.
Around 60 years ago, 24% of electricity was gone.

Imagine flowing water through a water pipe, the more powerful the pump that pumps out the water, the stronger the water flow.
In the case of electricity, if the current does not change, it is more efficient to send it out by applying a tremendous voltage of 500,000 volts.
The thicker the water pipe, the more water can flow, the thicker the wire, the more electricity can flow.
From the power station, electricity is sent out at once using a lot of wires with a thickness of about 4cm.

Electric wires near ordinary households are only 2 cm thick, and the voltage is 100 volts.
Because the wires are thin and the voltage is low, electricity is easily lost during power transmission.
Even at a distance of just a few kilometers, there will be as little electricity as it will go down through hundreds of kilometers over a thick transmission line.

JP 2003-284244 A

Nikkei Electronics October 19, 2009 issue "Special feature Smart Grid ON!-Next-generation power network created by storage batteries and sensors-" pp. 29-56

Despite the constant efforts of Japanese power companies, the electricity supplied to each household is never high-quality electricity as described below.
As described in paragraph [0019], in a conventional power transmission network, the frequency and output tend to become unstable as the distance from the power plant increases.
In addition, as described in paragraphs [0019] to [0023] in the above-mentioned constant efforts, more power is consumed in the transmission network than necessary to supply high-quality electricity to each household. There is also a side.
The technical problem at the time of purchasing solar power generation is the content as disclosed in Japanese Patent Application Laid-Open No. 2003-284244, which is presented as Patent Document 1, which means ancillary electricity that means ancillary In this way, the point of view is whether to execute control for supplying power to the transmission line in the area in charge of the distribution substation.
Some materials have the names dirty electricity and clean electricity, but they have a completely different meaning depending on the position of the speaker, so they are not used in this application.

Compared to redox flow batteries and sodium-sulfur batteries, secondary batteries installed in general consumers, such as the attached data, must naturally be guaranteed safety, but the performance required for batteries mounted in automobiles Is not expensive (reference website http://www.kyocera.co.jp/solar/prdct/power/index.html).
Secondary batteries installed in general consumers like this document can be cheaper due to the mass production effect of mass production.
Large quality stabilization circuits such as on-load tap changers used in distribution substations are expensive, but 3-5 kw class devices are not so expensive.
The electric power company grasps the power that can be supplied from each household by the wired or wireless communication while paying sufficient attention to the privacy of each household.
Each household owns a power generation device and a secondary battery, so that even if a failure occurs in the public power grid, supply the minimum amount of electricity to information and communication equipment such as refrigerators, telephones, personal computers, and TVs. Independent operation during disasters with minimal disruption.

Although not in the past, ordinary households near power consumption areas will have many small power generation facilities with the same functions as nuclear power plants and thermal power plants. The power transmission cost is reduced.
You can reduce the number of high-voltage transmission lines that are somewhat worried about electromagnetic wave problems, and when combined with other methods, you can remove the high-voltage lines that hinder the scenery in the scenic area.
If the electricity supplied by general consumers is well managed, the capacity of the utility pole transformer beyond the safety margin is not necessary.
In this device, a multiple safety device used in the case where a current more than expected such as a circuit breaker composed of a semiconductor switch or the like flows is essential. It is also important to ensure the privacy of ordinary households in terms of information.
There are three-phase 200V power sources for factories and power sources for AA and AA lamps for electricity transmitted in Japan, but in this application, three-phase 200V power sources are mainly supplied by power companies. I think so.
Of course, Japanese companies that use three-phase 200V power are also hoping to reduce carbon dioxide emissions by combining thorough energy conservation with energy creation and energy storage.

  The invention according to the present application is specified by the matters described in each claim of “Claims”.

  Means for solving the problems of the present invention will be described below.

In addition to consuming surplus electricity, we can improve the efficiency of the entire electric power grid by supplying extremely high-quality power to active and active distribution substation supply areas. The power supply quality at the time of power consumption is also improved, and the form of electricity usage, which is characterized by not only consuming surplus power but also improving transmission efficiency, is revealed.
The conventional electric power transmission system hardly assumes the provision of electric power from the end user of electricity.
The end users of electricity are general consumers in the distribution substation supply area, as shown in FIG. 3, such as general households, shops, small factories, and medium factories.
In the future, electricity is generated by solar cells or fuel cells in the home, so that electricity that exceeds the demand of the home is constantly produced, and surplus power can be sold.
In addition, by passing the secondary battery provided in the general consumer device once, it is possible to provide extremely high quality power with stable frequency and output to the distribution substation.

In the specification, claims, and drawings of this application, the term “high quality power” means power that is stable in frequency and voltage.
The frequency being stable means that the difference between the maximum frequency and / or the minimum frequency per 24 hours and the average frequency is 1% or less.
The voltage being stable means that the difference between the maximum voltage and / or the minimum voltage per 24 hours and the average voltage is 1% or less.
In the specification, claims, and drawings of this application, the meaning of the term “power supply quality” is the quality of the power to be supplied. “Quality is high”.
“Low-quality power” means, for example, that the brightness of the light bulb changes during the Second World War or for a while after the war, when the light is turned on at night, or when the total power is insufficient and long power outages occur. As an extreme example.
Such a situation can be fatal to devices that are currently vulnerable to electrical fluctuations, such as personal computers.

  Typical power generation at home is solar cell power generation, but there are other fuel cells, wind power generation, geothermal power generation, etc., which some companies call energy creation and energy creation. . A typical example of a fuel cell is Tokyo Gas ENE-FARM.

In this way, the concept of “Smooth Delivery Command of Electoric Power”, which is a feature of the present invention, is used to actively utilize surplus power to improve transmission efficiency.
The role of high-quality power does not stop there.
Since the actual power grid test has not been conducted, it is almost estimated, but 3 to 5 percent is expected to improve the transmission efficiency.
If the quality of electricity in the supply area of each distribution substation becomes ideal, the transmission efficiency from the upper power generation network will improve. In this method, since the power source is close to general consumers and the transmission distance itself is short, it is easy to reduce loss in power transmission.
This is similar to, for example, the sustainable development of a nation with many good people.

Although referred to as a home for the sake of convenience, what is envisaged in this application is an individual unit that owns an individual small-scale power generator and can supply surplus power.
Electricity consumed in the future will increase due to the declining birthrate and aging population, the sophistication of living, the spread of electric vehicles, etc. It becomes possible enough.

Elemental technologies that enable “Smooth Delivery Command of Electoric Power” include power leveling devices in distribution substations, phase control functions connected to communication devices in homes, DC / AC converters, etc. There are devices for stabilizing the quality of inverter devices and the like.
The high-frequency sound generated by this device during operation may rarely be uncomfortable for a person with high auditory sensitivity, and if there is a person who seems to have high auditory sensitivity, countermeasures are required in advance.
FIG. 1 shows a controller, a communication device, a secondary battery, an inverter device with a phase adjustment device, and the like, which are components of the power supply device installed in a general consumer.

[Inverter device with phase adjuster]
The inverter device with a phase adjusting device electronically performs phase synchronization which has been conventionally performed by a speed governor or the like. Compared to a large-scale device as described below, it can be made at a low cost. In AC electricity, positive and negative are switched at a frequency of 50 Hz in the Kanto region and 60 Hz in the Kansai region.
The synchronization device is a device that synchronizes the phase, and approximates the variation in the phase of the alternating current supplied from the secondary battery via the inverter to the waveform of the alternating current in the distribution area of the distribution substation at the transmission destination, And / or it becomes possible to exhibit the effect of preventing the consumption of the electric power at the time of power transmission by synchronizing.
By approximating the waveform of the distribution area of the distribution substation that transmits this fluctuation with the phase synchronization device, it is possible to prevent the power consumption during power transmission.
The term “phase synchronization” has been used mainly to adjust the frequency of communication until now, but in the present application, it is a term used during power transmission.
This phase adjusting device is a device for further improving the efficiency, and is not an essential device for the present application.
One of the power system parameters that power companies are most concerned about is the stability of AC frequency.
This is because the AC frequency is easily affected by fluctuations in the output of another power plant linked to the power grid and fluctuations in the magnitude of the load of power used by the user.
The change in output leads to the change in frequency because many power plants use a generator called “synchronous generator”.
In general, the generator converts the rotation of the turbine into electric power. However, when the output or load fluctuates suddenly in the synchronous generator, it reversely changes the rotation of the turbine, and the generator functions as a motor.
Depending on the degree of change, it may lead to a power outage accident.
In order to prevent this, an “AFC (Automatic Frequency Control Device)” is installed at the central power supply command center that centrally manages the power grid, and monitors fluctuations in output and load every 10 seconds.
When the change is detected, the output of the power plant is increased or decreased to cancel it.
In addition, fluctuations of less than 1 second are corrected by the “speed governor” in the generator.
Someone involved with the power company. Emphasizes high stability, “the probability that the frequency is within a certain range is 99.9999%”.
An inverter device with a phase adjustment device is a utility pole transformer that uses the optimal synchronization, frequency, voltage, and power for the power transmission destination based on a power transmission command from an electric power company that knows the power that can be supplied to each general consumer in real time. The power is transmitted to The PWM system generally used as an AC / DC inverter is also included.
[General specifications of phase adjuster]
Input voltage 28V (DC), output current 18A, output voltage 100V, frequency 50, 60Hz, with synchronous adjustment function, cooling method must not use forced air cooling.
Conventional power transmission networks are generally as follows according to TEPCO materials in Japan where the present invention is to be introduced.

Power station → Ultra high voltage substation → Primary substation → Distribution substation → One-way transmission from upstream to general consumers such as households.
In parallel with this power transmission network, TEPCO and others are carrying out an optical fiber communication service having a capacity of up to 100 Mbps in exclusive bidirectional mode.
In Japan, sensor networks and communication networks that monitor electric power similar to devices called smart meters in the United States have already been established from power plants to various distribution networks.
With reference to the trend of daily power demand, the control device of the present invention executes control for supplying only extremely high-quality power to the transmission line in the area in charge of the distribution substation.

Communication devices exchange online real-time information with distribution substations, and general consumers send information on how much high-quality power can be supplied, adjust timing at the start of power transmission, and phase To start power transmission from the secondary battery.
Rechargeable batteries such as reference materials set up a section to store the power that can be supplied, and once charged, the pumped-storage power generation that has been used to deal with small fluctuations of less than 3 minutes in the conventional power grid It serves to stabilize and level the quality of electricity generated by general consumers.

By setting a section in the secondary battery in which power that can be provided to the power company is separated, power can be supplied quickly.
Since the secondary battery such as the reference material is composed of 20 or more cells connected in parallel, the size of the compartment can be freely changed to some extent.
The secondary battery will be installed in the general customer's premises, but its capacity is as large as 3 kW or more.
Unlike large enterprises where electrical chief engineers are resident, most amateur general consumers will infringe private rights slightly rather than managing large capacity secondary batteries, so careful legal procedures are required, While paying sufficient attention to the privacy of general consumers, it is desirable that the management of secondary batteries be led by an electric power company.
In that state, it can be said that a power company uses a general customer equipped with a leveling device as a number of excellent power plants. Eventually, the electric power company will continue to distribute electricity on a national scale by adjusting the clean power produced by general consumers. The safety at the time of storage is higher than the energy sources currently stored at home, kerosene and propane.

The components of the present power supply device installed in the distribution substation are a control device, a communication device, a load tap switching device, a secondary battery, an inverter device, and the like.
Although it is expensive, it is more preferable to have a large power storage facility such as a redox flow battery or a sodium sulfur battery.
The control device performs control for supplying only extremely high-quality power to the transmission line in the area in charge of the distribution substation.
The communication device exchanges real-time information with general customers and the control room of the power company, obtains information on how much high-quality power can be supplied to individual general consumers, and transmits power from secondary batteries. To start.
The on-load tap changer adjusts the supply of electricity purchased from general consumers to the transmission line in the area in charge of the distribution substation, but it also functions to further improve the quality of power.
In actual operation, the following is shown in FIG.
Electric power generated by solar cells and fuel cells in general consumers is stored in secondary batteries when not consumed.
Information on the power stored in the power-soldable area that occupies a part of the secondary battery is constantly captured by the power company using a load frequency control system, reserve power control system, etc., using an optical communication device with the power company. ing.
When selling power to the distribution substation supply area, the necessary power is collected from the available section to the power pole transformer.
At that time, the general consumer controller adjusts the synchronization of the appropriate voltage, frequency, and phase to carry out power transmission.

  Secondary batteries are premised on the availability of large capacity devices that can be used in distribution substations, but they play a role in leveling the quality of electricity.

As is clear from the non-patent literature, the direction of power grid improvement is different in Europe and the United States and Japan, and the usage pattern of electricity is also very different.After the smart grid was put to practical use, the transmission efficiency in Europe and the United States was only slightly improved. It should lead to the same discovery as this application.
One of the reasons why smart grid initiatives are different between Japan and Europe and the United States is that in Japan, electricity retail services for general households have not been liberalized.

[Further improvements]
If the general standard of DC electrification is established and general consumers introduce it and build a power supply base based on the present invention, a great energy saving can be realized. Information required for synchronization adjustment is obtained from the electric power company, but adjustment by sensors on the general consumer side is also conceivable in the future (reference HP http://bizmakoto.jp/makoto /articles/0809/30/news091.html)
Although it does not happen much, software rewriting via the communication line by the manager of the apparatus is also possible.

[Phase adjuster (SPPC)]
A phase adjustment device (SPPC (Single Pulsed Properly Confluence)) is an inverter having both a phase control function and a DC / AC conversion function.
The present inventors use a phase adjustment device (SPPC) to safely and efficiently sell electricity stored in a secondary battery from a micro power plant such as a solar cell or a fuel cell to a power company. I came up with it.
The present inventors have come up with the idea of using a phase adjustment device (SPPC) to safely and efficiently sell surplus electricity in a hybrid vehicle to a power company.

[Performance required for phase adjuster (SPPC)]
The phase adjustment device (SPPC) is required to have a function for safely connecting to the power grid and transmitting power, and is also required to realize good power quality.
The phase adjustment device (SPPC) optimizes the power supply quality at the front end of the power transmission network, and sells more power than the conventional method although it is a small amount. It is also possible to synchronize with the latest phase state of AC provided by the power company on this machine, and it is possible to transmit power by adjusting the phase according to a command from the power company. In the basic specification, there is no drive part such as a fan, so in a device equipped with a fan used for air cooling, the temperature does not increase rapidly due to a fan failure.

[Features of phase adjuster (SPPC)]
The characteristic of the phase adjustment device (SPPC) is the pulse wave power return that does not depend on a sine wave or pseudo sine wave, unlike the PWM method that is generally used as an AC / DC inverter. In Japan, in many cases, power transmission devices for small-scale power sales such as the household level convert stored DC into AC by rectangular wave oscillation with an inverter, and the power is transmitted without changing the waveform.

[Principle of Phase Adjuster (SPPC)]
The principle of the phase adjuster (SPPC) is to use a high-frequency generator with a frequency of about 1,000 times per second, and generate alternating-current electricity that approximates a sine wave by approximating a large number of pulses to transmit power. It is to return the pulse wave power of 1 or 2 volts higher than the AC of the power company that receives it.
The inverter device according to the present application, that is, the power return device using the principle of the phase adjustment device (SPPC) is an inexpensive small device that hardly degrades the quality of the source power and has a greening control function. It has high precision characteristics.

[Advantages of using phase adjuster (SPPC)]
With the inverter device according to the present application, that is, the power return device using the principle of the phase adjustment device (SPPC), power transmission to the utility pole transformer of the power company can be realized safely.
Based on the SDCE theory (Smooth Delivery Command of Electoric Power) of the present invention, the quality of electricity at the end of the transmission network that consumes electricity is improved. DC power stored in the storage battery can be transmitted without waste. The conversion efficiency is improved as compared with the conversion of the pseudo sine wave.

[Specifications of phase adjuster (SPPC)]
The rechargeable battery (secondary battery) to be the target of the inverter device according to the present application, that is, the power return device using the principle of the phase adjustment device (SPPC) is not particularly limited, but is preferably full. The charge capacity is 1 to 5 [kW].
In the case of power transmission exceeding 5 kW, a plurality of this machine are arranged in parallel.
Usually, the transmittable voltage is 100 to 220V.
The power return device using the principle of the phase adjustment device (SPPC) has not only a phase adjustment control function but also a DC / AC conversion function.
It is also possible to transmit power by adjusting the phase and voltage according to a command from an electric power company.
A failure detection function is built-in, and power transmission to the power company's utility pole transformer can be performed safely.

[Inverter device]
An inverter device according to the present application, that is, a power return device using the principle of a phase adjustment device (SPPC) is shown in FIG. 4 and FIG.
An inverter device that supplies DC power output from a secondary battery in synchronization with commercial AC current, and includes a waveform analysis module (M1), a superposition position determination module (M2), a voltage conversion module (M3), and pulse wave generation A module (M4) and a pulse wave superposition module (M5) are included.

[Waveform analysis module (M1)]
The waveform analysis module (M1) has a function of analyzing the waveform of the commercial alternating current.

[Superposition position determination module (M2)]
The superposition position determination module (M2) determines the position of the phase at which the superposition of pulses should be started, that is, the superposition start phase θ1 and the superposition end phase θ1 ′, from the commercial alternating current waveform analyzed by the waveform analysis module (M1). And has a function of detecting the voltage Vp of the commercial alternating current in the superposition end phase θ1 ′. These functions are executed by a CPU installed in the superposition position determination module (M2) running dedicated software.

[Voltage conversion module (M3)]
The voltage conversion module (M3) has a function of converting the voltage V0 of the direct current output from the secondary battery into the voltage Vp.

[Pulse wave generation module (M4)]
The pulse wave generation module (M4) uses the pulse voltage Vp determined by the superposition position determination module (M2) for the voltage Vp converted by the voltage conversion module (M3).
The phase at which superposition should be started, i.e., between the superposition start phase θ1 and the superposition end phase θ1 ′,
A pulse wave tw is generated from the current of the voltage Vp converted by the pulse wave generation module (M4).

[Pulse wave superposition module (M5)]
FIG. 4 shows an example in which a transformer is used for connection to commercial AC current, and FIG. 5 shows an example in which a semiconductor is used for connection to commercial AC current.
The present invention is not limited to the embodiment shown in FIG. 4 and FIG.

[Description of concept of “specified waveform deformation rate (α [%])” and “tw”]
The “specified waveform deformation rate” refers to an area ratio with respect to a waveform in which a commercial AC voltage or current waveform is positive and the waveform is distorted by pulse superposition.
The reason why “regulation” is added in front of the word “waveform deformation ratio” in “regular waveform deformation ratio” is that power companies usually use AC current to maintain the quality of power to be supplied to consumers. This is because it is assumed that an original quality control standard is set when quality control is performed on the waveform.
This specified value varies depending on the power situation in each country, and the relevant organizations in each country are working on the formulation work around the 2014 fiscal year.
For example, when the current waveform area of commercial alternating current is A (FIG. 8) and the area of the region where the waveform is distorted and swollen by pulse superposition is A ′ (FIG. 8), the specified waveform deformation rate (α [%]) Is calculated by Equation (1).

[Equation 1]
A '+ A
Specified waveform deformation rate (α) = ─────── × 100 [%] (1)
A

[Equation 2]

Pulse width _{(t w) = | θ 1} '- θ 1 | (2)

In the formulas (1) and (2), the meanings of A and A ′ are as follows.

A: Area intensity for one period of trademark current A ′: Area intensity of superposition waveform θ ₁ ; Phase to start superposition, ie superposition start phase θ _{1 ′} ; Phase to end superposition, ie superposition end phase

For example, when “A = 100” and “A ′ = 10”, “α = 110%” is calculated according to Equation (1).

[Cooperative operation by multiple phase adjusters (SPPC)]
It is also possible for one phase adjuster (SPPC) to operate in concert with another phase adjuster (SPPC).
When power is transmitted from a plurality of phase adjustment devices (SPPC) to the same power pole transformer of an electric power company, it is also possible to add a device that performs an optimal shift of the pulse wave power return for cooperative operation. .
Such cooperative operation complements the function of the individual waveform analysis module (M1) for analyzing the waveform of the commercial alternating current.

FIG. 4 shows components constituting the inverter device according to the present application, that is, the phase adjustment device (SPPC).
The component which comprises FIG. 4 is one of the preferable aspects, Comprising: It is not limited to this aspect.
It is possible to replace these parts with equivalent parts according to the purpose and application.

Standards of components constituting the inverter device, that is, the phase adjustment device (SPPC) according to the present application shown in FIG. 4 are listed below.

(1) Waveform analysis module (M1)
CPU element; SH2 64F7144F50V made by Renesas
Communication element

(2) Voltage conversion module (M2)
Voltage converter Switching semiconductor Toshiba IGBT GT60M301

(3) Pulse wave generation module (M4)
Switching circuit Switching semiconductor Toshiba FET 2SK1544

(4) Pulse wave superposition module (M5)
Transformer IGBT

8 and 9 show photographs of a prototype board in which the above-described parts are assembled.

The conceptual diagram of the electric power supply apparatus (SDCE) based on this invention was shown. The conceptual diagram which contrasted and contrasted the power transmission method which concerns on a prior art, and the electric power supply apparatus (SDCE) which concerns on this invention was shown. A power supply apparatus (SDCE) according to the present invention is shown. An example (using a transformer) of a conceptual diagram of an inverter power supply device (SPPC) according to the present invention is shown. An example (using a semiconductor) of a conceptual diagram of an inverter power supply device (SPPC) according to the present invention is shown. The explanatory formula of the transmitted power is shown. An explanation of the operation of the switching circuit (pulse generation module) is shown. An explanatory view of the prescribed waveform deformation rate is shown. The main part of the prototype of the inverter power supply device (SPPC) according to the present invention is shown by a photograph. A prototype of the inverter power supply device (SPPC) according to the present invention was shown by a photograph. The logic flowchart of the inverter electric power supply apparatus (SPPC) which concerns on this invention.

Claims (2)

A power supply device including a control device, an inverter, a communication device, and a secondary battery ,
A control device that executes control for supplying power whose waveform characteristics are synchronized with commercial AC voltage by superimposing high-frequency pulses to the transmission line in the area in charge of the distribution substation;
An inverter for boosting a DC voltage supplied from a secondary battery to a pulse voltage Vp and superimposing a high frequency pulse;
A secondary battery having a power selling section and a private section, and storing power for power sale in the power selling section;
The surplus power stored in the secondary battery of the general consumer is consumed by the general consumer, and the inverter analyzes the commercial AC voltage and boosts the DC voltage of the secondary battery to Vp. By generating a high frequency pulse of voltage Vp and superimposing the high frequency pulse on the commercial AC voltage at a timing higher than the commercial AC voltage, power having a stable frequency phase is supplied to the transmission line. The power supply device is characterized by improving power transmission efficiency. The inverter includes a voltage conversion module for converting a DC voltage supplied from the secondary battery into a pulse voltage of a voltage Vp, and the voltage conversion module is a pulse supplied from the secondary battery via the inverter. The power supply device according to claim 1, wherein the voltage is synchronized with an alternating voltage in a supply area of a distribution substation as a power transmission destination .