KR20200127517A - Heating structure using polyurethanum - Google Patents

Abstract

The present invention relates to a heating structure using polyurethane resin mortar, and more specifically, to an eco-friendly heating structure using ocher and polyurethane resin mortar. The metabolism of a human body according to a residential life is promoted, waste products harmful to a human body can be neutralized, and a healthy life can be promoted by providing the eco-friendly heating structure using ocher and polyurethane resin mortar through the present invention. In addition, heating costs can be drastically reduced, installation costs are reduced, heating is possible immediately after construction, a semi-permanent life is secured, electromagnetic waves are removed, and electric charges are saved in half when compared to ordinary electric panels.

Description

Heating structure using polyurethanum}

The present invention relates to a heating structure using polyurethane sunjit mortar, and more particularly, to provide an eco-friendly heating structure using ocher and polyurethane sunjit mortar.

In general, unlike European culture, the Ondol culture in which the floor is heated to maintain the temperature is widely used in the East.

On the other hand, when an auxiliary place such as an apartment veranda or a commercial building such as an office or store is composed of ondol, there is a problem that it takes a lot of cost and time for the ondol construction compared to the purpose, and there is a problem that heating costs are high. In order to improve the problem, research on a heating structure using an electric heating element that can be easily installed according to a purpose, has a low manufacturing cost, and requires a low maintenance cost is currently being actively conducted.

However, the heating structure using the electric heating element of the conventional type adopts a heating line such as a nichrome heating line or a copper-nickel alloy heating line, a heating line obtained by etching a thin metal plate such as aluminum, a carbon black thick film, etc. as a heating line. Although the heating wires are configured to be heated, the heating wires have a problem in that electricity flows through one line, so if any one part is cut off, electricity does not pass through to the entire heating wire, and the function as a heating element is lost. Since it is a partial heating method in which only heat is generated, there is a problem in that the temperature distribution is formed unevenly.

In addition, if the heating wire is short-circuited in the electric heating element, there is a risk of fire because the electric resistance is greatly reduced in that part and heat is severely generated.Therefore, in order to prevent the short circuit of the heating wire, the surface layer of the heating wire must be insulated with an electric insulator of sufficient thickness However, since the electric nonconductor is a thermal nonconductor, the heat conduction property is poor, so that the efficiency of heat generation is greatly reduced.

In another conventional form, there has been heating using a hot water pipe in which a pipe is buried in the floor and a cement mortar is covered thereon.

However, this heating method has low thermal efficiency, and if heating is temporarily suspended in winter, there is a risk of freezing.

Korean Registered Patent Publication No. 10-1655863 (2016.09.02)

Therefore, the present invention was devised to solve the above conventional problems,

An object of the present invention is to provide an eco-friendly heating structure using ocher and polyurethane sunjit mortar.

Another object of the present invention is to provide an eco-friendly heating structure using a polyurethane sunjit mortar that eliminates the risk of freezing, increases thermal efficiency, and is easy to construct.

In order to achieve the problem to be solved by the present invention, the heating structure using a polyurethane pure mortar according to an embodiment of the present invention,

With the slab base (100),

A primer 200 applied on the upper part of the slab base,

An ocher material layer 300 formed at a certain height of ocher material on top of the primer,

As a heating element on the top of the loess material layer, a carbon fiber 400 is installed, and both ends of the carbon fiber extend to the outside of the loess material layer, including a polyurethane pure mortar 600 applied on the carbon fiber,

Laminate the loess heat diffusion plate 500 before applying the polyurethane sunjit mortar on the top of the carbon fiber,

The loess heat diffusion plate 500 is characterized in that it is manufactured using loess.

The heating structure using the polyurethane pure mortar according to the present invention,

By providing an eco-friendly heating structure using loess and polyurethane sunjit mortar, it promotes the metabolism of the human body according to the residential life, and at the same time, it can neutralize the wastes harmful to the human body and provide the effect of promoting a healthy life.

In addition, the heating cost can be drastically reduced and installed inexpensively during installation, heating is possible immediately after construction, has a semi-permanent life, there is no electromagnetic wave, and it has the effect of saving half of the electricity cost compared to ordinary electric panels.

In addition, it is possible to reduce the heating cost by providing an effect of removing the risk of freezing and increasing thermal efficiency.

1 is an overall configuration diagram of a heating structure using a polyurethane sunjit mortar according to an embodiment of the present invention.
2 is an overall configuration diagram of a heating structure using a polyurethane sunjit mortar according to another embodiment of the present invention.
Figure 3 is a configuration diagram of a yellow earth heat diffusion plate 500 of a heating structure using a polyurethane sunjit mortar according to an embodiment of the present invention.
4 is an exemplary view of thermal conductivity of a thermally conductive material applied to a heating structure using a polyurethane pure mortar according to an embodiment of the present invention.
5 is a conceptual diagram of a temperature sensor unit 2000 and a temperature controller configured on one side of a carbon fiber of a heating structure using a polyurethane pure mortar according to an embodiment of the present invention.
6 is a block diagram of a temperature controller of a heating structure using a polyurethane sunjit mortar according to an embodiment of the present invention.

The heating structure using a polyurethane sunjit mortar according to an embodiment of the present invention,

With the slab base (100),

A primer 200 applied on the upper part of the slab base,

An ocher material layer 300 formed at a certain height of ocher material on top of the primer,

As a heating element on the top of the loess material layer, a carbon fiber 400 is installed, and both ends of the carbon fiber extend to the outside of the loess material layer, including a polyurethane pure mortar 600 applied on the carbon fiber,

Laminate the loess heat diffusion plate 500 before applying the polyurethane sunjit mortar on the top of the carbon fiber,

The loess heat diffusion plate 500 is characterized in that it is manufactured using loess.

At this time, the loess heat diffusion plate 500,

Bottom loess reheat diffusion unit 510 formed at the lowermost side at a certain height using loess; And

A filler loess material heat diffusion unit 520 positioned above the bottom loess material heat diffusion unit and formed at a predetermined height by using loess and a heat conductive material; And

It characterized in that it comprises a; is located on the top of the filler loess material heat diffusion unit 520, the top loess material heat diffusion unit 530 formed to a predetermined height using loess.

At this time, the carbon fiber 400 is attached to the temperature sensor unit 2000 as a heating element,

It is configured to further include a temperature controller 1000,

The temperature controller turns the power ON/OFF with a power key, and a power on/off unit 1100 during a power outage that maintains an operating state as ON after returning to the previous operation state when the previous operation state is ON, and OFF when it is OFF; and

When the power switch is pressed for a few seconds, "initialization" flashes several times on the display window, and the initialization unit 1200 is initialized; and

A driving display unit 1300 that is displayed in red when it is currently driving; and

A high temperature prevention unit 1400 that obtains a temperature detection value from the temperature detection sensor unit, and automatically turns off the power when the obtained temperature detection value is 60 degrees Celsius or more; And

A setting method selection unit 1500 for setting a temperature setting type or a method through a timer with a toggle button; And

In the case of temperature setting type, pressing the down arrow key (↓) or the up arrow key (↑) displays the set target temperature, and the green LED turns on during display, and if there is no key input for a few seconds, the green LED turns off and the current temperature is displayed. A temperature setting unit 1600; and

In the case of the timer method, pressing the down arrow key (↓) or the up arrow key (↑) displays the step of setting the temperature setting intensity step by step, and the green LED turns on during the display. It characterized in that it comprises a; timer step unit 1700 for displaying the current stage while the LED is turned off.

At this time, the temperature controller 1000,

Optionally, a Bluetooth communication unit 1800 may be provided, through which access to the Internet by accessing the Internet by accessing a router or a Wi-Fi dongle located in a short distance. When the user installs the app through the Internet, the user terminal 3000 can be connected and communicated. It is characterized by having.

As the present invention can be implemented through various changes, the rights are formed, including all changes, equivalents, and substitutes included in the spirit and scope of the present invention even for modified embodiments not shown in the described embodiments. Must see.

Hereinafter, it will be described in detail through an embodiment of a heating structure using a polyurethane pure mortar according to the present invention.

1 is an overall configuration diagram of a heating structure using a polyurethane sunjit mortar according to an embodiment of the present invention.

2 is an overall configuration diagram of a heating structure using a polyurethane sunjit mortar according to another embodiment of the present invention.

As shown in Figures 1 to 2, the heating structure using the polyurethane pure mortar,

With the slab base (100),

A primer 200 applied on the upper part of the slab base,

An ocher material layer 300 formed at a certain height of ocher material on top of the primer,

As a heating element on the top of the loess material layer, a carbon fiber 400 is installed, and both ends of the carbon fiber extend to the outside of the loess material layer, including a polyurethane pure mortar 600 applied on the carbon fiber,

Laminate the loess heat diffusion plate 500 before applying the polyurethane sunjit mortar on the top of the carbon fiber,

The loess heat diffusion plate 500 is characterized in that it is manufactured using loess.

To describe in detail with reference to FIG. 1, the slab base 100 is configured on the lowermost side, and a primer 200 is applied on the upper portion of the slab base, and a layer of loess material at a predetermined height with loess material on the top of the primer ( 300).

And, as a heating element on the top of the loess material layer, a carbon fiber 400 is formed, a loess heat diffusion plate 500 is laminated on the carbon fiber, and a polyurethane pure mortar is applied on the top of the loess heat diffusion plate 500 It is done.

In this case, the carbon fiber 400 may be in the form of a plate in the form of a mesh or may be in the form of a cable.

In addition, in the present invention, a carbon fiber 400 is described as an example, but a graphene heating element using graphene instead of carbon may also be applied.

In addition, as shown in FIG. 1, plate-shaped carbon fibers in a mesh form may be formed, or carbon fibers in a cable form may be formed as shown in FIG. 2.

The following will be described in detail with respect to the components constituting each layer of the heating structure using the polyurethane sunjit mortar of the present invention.

The slab base 100 means a general base, for example, may mean a concrete surface, and each building is generally finished with concrete.

At this time, a primer 200 is applied on the upper part of the slab base, which is applied to the slab base for waterproofing or adhesion.

In addition, an ocher material layer 300 is formed at a predetermined height using ocher material on the upper part of the primer.

In this case, the loess material layer may mean any one of a loess material floor plate, a loess brick, or a loess tile.

On the other hand, the ocher material layer (ocher tile or ocher brick) has a wall and a space during construction, and is constructed by attaching between bricks and bricks, but when separate heating is performed, the space is spaced at least 30 cm apart.

Meanwhile, according to an additional aspect, a heat dissipation layer is formed on the lower portion of the loess material layer 300 by using any one of graphite, asbestos, glass fiber, cork, diatomaceous earth, and foamed plastic.

That is, as described above, when the heat dissipation layer is formed, heat can be diffused upward and heat can be prevented from moving in an unnecessary direction.

Although there is no particular limitation on the material of the heat sink, it is preferable to be formed of a material having high thermal conductivity as described above.

In addition, the carbon fiber 400 is constructed as a heating element on the top of the loess material layer.

In this case, the carbon fiber 400 may be in the form of a plate in the form of a mesh, as shown in FIG. 1, and may be in the form of a cable, as in FIG. 2.

If the carbon fiber in the form of a cable is formed, a groove is formed in a position to be buried in the loess material layer 300 so that the cable carbon fiber can be safely buried, and the loess heat diffusion plate 500 in contact with the upper surface of the cable carbon fiber ) Is to form a groove in the same way in the bottom ocher reheat diffusion 510.

On the other hand, according to an additional aspect, in order to eliminate voids when the cable carbon fiber is embedded, it is characterized in that it is filled with loess soil between the groove and the cable carbon fiber.

In addition, the carbon fiber 400 described in the present invention is preferably a carbon fiber having improved high-temperature heating characteristics, and is a carbon fiber heating element having improved high-temperature heating characteristics having excellent high-temperature heating characteristics, such as stably heating even at 180°C or higher. , It is characterized in that it is produced by forming a polymeric polyurethane layer on the surface of the carbon fiber heating element by electrophoretic deposition.

Specifically, it is prepared by depositing and depositing polyurethane in the polymer polyurethane electrolyte solution to form a polymer polyurethane layer. The polymer polyurethane electrolyte solution is prepared by stirring the polyurethane solution and 1-Methyl-2-pyrrolidinonne at room temperature, and then triethylamine. It is a carbon fiber heating element with improved high-temperature heating characteristics, characterized in that it is prepared by adding and stirring, and then adding methanol and N,N-dimethylacetamide.

For example, a polymer polyurethane was deposited by electrophoretic deposition on the surface of a carbon fiber having a length of 50 mm using a polyurethane electrolyte solution.

The carbon fiber on which the polymer polyurethane layer was formed was separated from the electrolyzer and then heat-treated under a nitrogen atmosphere to prepare a carbon fiber heating element.

In the present invention, the carbon fibers manufactured as described above may be arranged to be constructed in a mesh form or a zigzag form (cable form).

These carbon fibers have a far-infrared emissivity of 90% or more, do not have electromagnetic waves, and have a function of discharging wastes in the body as sweat by radiant heat, and the far-infrared rays are invisible to the eye, but are radiated from the sun at a wavelength of 2 to 25 micrometers. It is the same as the light and has a long wavelength, so it easily penetrates the human body.

In addition, beneficial negative ions are released along with the radiant heat of the far-infrared rays, which has excellent deodorization and antibacterial effects.

The carbon fiber on which the polyurethane layer is formed is a flame-retardant fiber, which is lightweight and eco-friendly, is easy to install, and has semi-permanent properties by preventing oxidation of the heating element, and has moisture resistance and spark prevention effects.

Figure 3 is a configuration diagram of a yellow earth heat diffusion plate 500 of a heating structure using a polyurethane sunjit mortar according to an embodiment of the present invention.

On the other hand, before applying the polyurethane sunjit mortar on the carbon fiber of the present invention, the loess thermal diffusion plate 500 is laminated, and the loess thermal diffusion plate 500 is manufactured using ocher.

As shown in Figure 3, the loess heat diffusion plate 500,

The bottom (Bottom) red soil reheat diffusion unit 510 formed at the lowermost side at a certain height using the loess; And

A filler loess reheat diffusion unit 520 positioned above the bottom loess reheat diffusion unit and formed at a predetermined height using ocher and a thermal conductive material; And

It is located on the upper portion of the filler loess material heat diffusion unit 520, and characterized in that it comprises a top (Top) loess material heat diffusion unit 530 formed to a predetermined height using loess.

Specifically, the bottom ocher reheat diffusion unit 510 is formed at the lowermost side at a predetermined height using ocher.

For example, it will be formed to a height of about 5 ~ 20mm.

In addition, a filler loess material heat diffusion unit 520 is formed on the top of the bottom loess material heat diffusion unit, and is preferably formed to a predetermined height by using loess and a heat conductive material.

For example, it will be formed to a height of about 1 ~ 10mm.

According to an additional aspect, the thermally conductive material is graphene, carbon, carbon, silver, gold, galvanized, aluminum, or a mixture of at least two.

For example, a mixture of 20 parts by weight of loess, 10 parts by weight of copper powder, 10 parts by weight of aluminum powder, and 5 parts by weight of an adhesive is used.

As another example, a mixture of 20 parts by weight of loess, 20 parts by weight of graphene, and 5 parts by weight of an adhesive is used.

In addition, a top loess material heat diffusion unit 530 is formed on an upper portion of the filler loess material heat diffusion unit 520 to a predetermined height using loess.

For example, it will be formed to a height of about 10 ~ 30mm.

On the other hand, as shown in FIG. 4, in the present invention, it would be preferable to form the filler loess material heat diffusion unit 520 using graphene having the highest thermal conductivity as a thermal conductive material.

The following will describe the process of manufacturing the loess heat diffusion plate 500.

For example, in a container having a width of 30 cm and a length of 30 cm, after stacking 10 mm of the bottom ocher reheat diffusion unit 510 using ocher at the bottom, the filler ocher reheat diffusion unit 520 on the top of the bottom ocher reheat diffusion unit 20 parts by weight of loess, 20 parts by weight of graphene, and 5 parts by weight of an adhesive are mixed and 5 mm is stacked, and then a top loess reheat diffusion unit 530 is stacked 30 mm using loess on the top of the filler loess material heat diffusion unit 520 After that, when baked for a certain time at a temperature of 800° C. or higher, the loess heat diffusion plate as shown in FIG. 3 is completed.

In addition, it may be completed by pressing at a temperature of 800°C or higher.

On the other hand, according to another additional aspect, the loess material layer 300 and the loess heat diffusion plate 500 are characterized in that a plurality of holes 900 are formed at regular intervals.

As described above, when a plurality of holes are formed at regular intervals, for example, when the floor material is liquid, the bottom slab base 100 and the passage are connected to each other and are integrally combined to enhance the binding force. There will be.

In the end, if configured as described above, the heat and far-infrared rays obtained from the carbon fiber heating element are stored using the loess heat diffusion plate 500, the function for stably maintaining the heating temperature, and the fire prevention effect using non-combustible materials Will be provided.

In addition, the effectiveness of the loess ingredient, such as water veins and harmful electromagnetic wave blocking, antibacterial and fungal removal, deodorization, removal of harmful substances and neutralization of heavy metals, far-infrared germanium (Ge) effect, radon and formaldehyde inhibitory effect, budding It can promote metabolism and drive meridian circulation, neutralize cement toxicity, create a healthy environment, and provide insulation, warmth, moisture-proof and soundproof effects.

That is, while supplementing the disadvantages of the conventional silver foil mat and aluminum mat, eco-friendly materials can be replaced at low cost, and the spread of goodeuljang can be expanded and public health promotion effects are provided.

And, it is characterized in that the polyurethane sunjit mortar 600 is applied to the upper portion of the carbon fiber.

Specifically, the polyurethane pure mortar is a polyol containing 10 to 20 parts by weight of a mixture of isocyanate, polyol, and additives, 5 to 15 parts by weight of filler, and 1 part by weight of net and 65 to 85 parts by weight of aggregate. As a urethane pure mortar, it provides a polyurethane pure mortar, characterized in that it has an elastic recovery performance of more than 65% deformation recovery measured under a load condition of 5% by the method according to ASTM D 695.

In addition, the polyurethane sunjit mortar has a function of sterilizing bacteria within 24 hours, has a 100% waterproof function, has no foreign matter or penetration, and is restored to its original state by simply removing and washing the last finishing material.

It has good floor strength and heat resistance, so it can be used semi-permanently, reduces impact sound by 12 to 20 decibels, and acts smoothly on knee joints to prevent human accidents.

It can be used as a flooring material, and polyurethane pure mortar is recommended, but reinforced flooring and tiles can also be used.

In addition, when applying the polyurethane mortar, the carbon fiber 400, the loess material layer (ocher tile or loess brick) on the slab base 100, the loess heat diffusion plate 500, etc. are firmly bonded and separated between each layer. It has the effect of preventing it from becoming.

In particular, the polyurethane sunjit mortar has the property of being more closely bonded to the carbon fiber 400 having a polymer polyurethane layer formed on the surface, which is a component of the same system, to prevent peeling.

Polyurethane sunjit mortar is a flooring material (refrigeration, freezing, quenching) and can be applied to chemical resistance (acid resistance) and high temperature, so it is used as a protective flooring material for pollutants oil or stains from machinery and equipment.

In addition, it may be used in a thickness of 3 to 4 mm on the carbon fiber 400, and can be applied to meat processing companies, aquatic products processing companies, food processing companies, schools, kitchens, hospitals, electronic companies, and clean industries.

Polyurethane sunjit mortar has excellent mechanical and chemical resistance properties due to the presence of a thick polyurethane coating, and has resistance to organic acids, dilute acids and inorganic acids, vegetable fats and animal fats, petroleum oils and solvents, and is between -10℃ and 130℃. It is suitable for use in conditions of a wide range of temperatures.

With excellent chemical resistance, it has resistance to organic acids, dilute acids and inorganic acids, vegetable fats and animal fats, petroleum-based oils and solvents. It has high impact resistance/abrasion resistance and resistance to mechanical abrasion and heavy vehicle traffic, and high thermal shock resistance is hot. It can withstand water and steam cleanliness, can be applied to a slightly moist surface with moisture resistance, and can pass within 24 hours, it is easy to maintain and manage clean and maintains gloss, does not contaminate food, is odorless, and rain There is no ductility or fire risk.

In addition, the polyurethane sunjit mortar must be adjusted according to the temperature conditions of the site before construction, and the liquid urea is mixed using a spiral mixer at a speed of 750 rpm until the polyurethane sunjit mortar and the hardener become a homogeneous mixture. (1.5 to 2 minutes).

Goun silica is gradually added to the mixture by acting a mixer on the polyurethane pure mortar and curing agent mixture.

Move the mixer from side to side from top to bottom and ensure that the sides of the mixing vessel are evenly and completely mixed.

A mixture of polyurethane pure mortar, hardener and fine silica sand is poured onto the prepared floor.

Spread it on the floor application area with a specified thickness (3-4mm) using a push rod or a grooved trowel.

Whenever you pour the mixture, try to maintain the connection between the pour intervals.

The surface is rolled using a spike roller to remove trapped air.

Use a tool cleaner or thinner to clean work tools or other contaminants.

In case of additional application, the additional application after application must be re-applied within 24 hours after applying the polyurethane pure mortar.

After 24 hours, the surface needs to be slightly polished prior to further application.

The heating according to the present invention is 30% cheaper than electric heat and 60% cheaper than oil boilers.

Due to the highly efficient radiant heat heating method, fuel costs are drastically saved, and there is no difference in indoor temperature for radiant heat due to far-infrared rays, and a pleasant heating effect can be obtained with low power consumption compared to the general convection heating method.

In addition, partial heating is possible, so it is possible to save heating costs because it does not heat the parts that are not needed or when there is no person.

On the other hand, the floor finishing layer may be finished with reinforced flooring, flooring, etc., and in addition, it may be formed of steel flooring, plywood, PVC, ceramic, granite, marble, asbestos, polishing, polyethylene, and non-crete PU-MF materials.

The floor finishing material can be selectively used in consideration of strength, hardness, heat resistance, cold resistance, and flame retardancy, and additionally, waterproofness, sterilization, foreign matter penetration, and harmlessness to the human body can be considered.

On the other hand, in place of the loess material of the present invention, sericite, illite, and epoxy mortar may be used, and two or more types may be mixed and used.

The upper carbon fiber is reinforced so that there is no heat loss, and a thick layer can be formed so that heat can stay.

Carbon fiber is easily warmed up and cooled down easily, so it has some drawbacks, but it is only possible to maintain the thermal insulation power by sufficiently warming in the lower layer of carbon fiber.

On the other hand, according to an additional aspect, the carbon fiber 400 is characterized in that the temperature sensor unit 2000 is attached as a heating element, and is configured to further include a temperature controller (1000).

At this time, the temperature controller is either an analog temperature controller or a digital temperature controller.

And, as shown in FIG. 5, a temperature sensor unit 2000 is configured on either side of the carbon fiber in the form of a mesh or a cable, and a temperature controller is additionally configured.

Specifically, if the temperature controller is configured as described above, both ends of the carbon fiber may be formed to extend to the outside of the loess material layer.

At this time, as shown in Fig. 6, the temperature controller 1000 turns the power ON/OFF with the power key, and when the previous operation state is ON during a power failure, it is turned ON after returning, and when the power supply is OFF, the operating state is maintained at OFF. A power on-off unit 1100; and

When the power switch is pressed for a few seconds, "initialization" flashes several times on the display window, and the initialization unit 1200 is initialized; and

A driving display unit 1300 that is displayed in red when it is currently driving; and

A high temperature prevention unit 1400 that obtains a temperature detection value from the temperature detection sensor unit, and automatically turns off the power when the obtained temperature detection value is 60 degrees Celsius or more; And

A setting method selection unit 1500 for setting a temperature setting type or a method through a timer with a toggle button; And

In the case of temperature setting type, pressing the down arrow key (↓) or the up arrow key (↑) displays the set target temperature, and the green LED turns on during display, and if there is no key input for a few seconds, the green LED turns off and the current temperature is displayed. A temperature setting unit 1600; and

In the case of the timer method, pressing the down arrow key (↓) or the up arrow key (↑) displays the step of setting the temperature setting intensity step by step, and the green LED turns on during the display. It characterized in that it comprises a; timer step unit 1700 for displaying the current stage while the LED is turned off.

Specifically, the power on/off unit 1100 in case of a power failure turns on/off the power with a power key. During a power failure, if the previous operation state is ON, the operation state is maintained as ON after returning, and if it is OFF, the operation state is maintained.

This is to provide a function for convenience in use.

In addition, when the power switch is pressed for a long time for a few seconds, the initialization unit 1200 recognizes this when the power switch is pressed for a long time, for example, for 2 seconds or more, and processes "initialization" to flash several times on the display window, and performs initialization.

In addition, when the operation display unit 1300 is currently operating, the red color is displayed, and when the operation is stopped, the operation display unit 1300 is displayed in a color other than red.

This allows the user to visually check.

Further, the high temperature prevention unit 1400 obtains a temperature detection value from the temperature detection sensor unit, but automatically turns off the power when the obtained temperature detection value is 60 degrees Celsius or higher.

That is, when a temperature sensing value equal to or higher than the set temperature is obtained, an accident may occur due to high temperature, so that the power is immediately turned off.

In addition, the setting method selection unit 1500 performs a function of setting a temperature setting type or a method through a timer with a toggle button.

In addition, the temperature setting unit 1600 displays the set target temperature by pressing the down arrow key (↓) or the up arrow key (↑) when the method selected by the setting method selection unit is a temperature setting type. During the process, the green LED turns on, and if there is no key input for a few seconds, the green LED turns off and the current temperature is displayed.

Therefore, the user can set the desired temperature while viewing the screen.

And, the timer step unit 1700, when the method selected by the setting method selection unit is a method through a timer, pressing the down arrow key (↓) or the up arrow key (↑) step by step The setting step is displayed, and the green LED turns on during the display, and if there is no key input for several seconds, the green LED turns off and the current step is displayed (see Table 1).

step Came time Off time One 45 seconds 2 minutes 15 seconds 2 1 min 2 minutes 3 1 minute 15 seconds 1 minute 45 seconds 4 1 minute 30 seconds 1 minute 30 seconds 5 1 minute 45 seconds 1 minute 15 seconds

There is also a method that can be adjusted while turning left and right through a dial other than the down arrow key (↓) or the up arrow key (↑) as the key for controlling the temperature described above. It will be said that such a case is also included in the idea of the present invention.

On the other hand, according to an additional aspect, the temperature controller 1000,

Optionally, a Bluetooth communication unit 1800 may be provided, through which access to the Internet by accessing the Internet by accessing a router or a Wi-Fi dongle located in a short distance. When the user installs the app through the Internet, the user terminal 3000 can be connected and communicated. It is characterized by having.

Specifically, users can download the app, set their own thermostat and communication settings, set a security key, and remotely connect to the thermostat to control it.

The user's app can have all the control buttons of the thermostat, and can share status indications.

Meanwhile, a pressure sensor unit having two or more pressure sensors installed on the floor of the indoor entrance may be selectively installed, and the electrical signals of the pressure sensors are connected to the temperature controller through wires at both ends of the carbon fiber.

An alarm signal unit may be selectively configured in the temperature controller, and the alarm signal unit may generate a loud sound.

The pressure sensor can detect the entry of the human body, and if the temperature is detected while being calm, it determines whether or not an alarm is generated through the set password.

The two or more pressure sensors can detect a pattern, which is the same as the conventional DDR method and can be set in advance.

When a person approaches the heated room for the first time, the temperature control unit checks when the temperature has been operated, and if it has not been operated for a certain period of time, it sounds an alarm of an appropriate size and displays the'password' on the thermostat to display the password pattern to the person. Demand.

At this time, if a preset pattern such as DDR is input, the temperature controller starts operating as set immediately before.

If the input of the predetermined pattern is not performed or the input time is exceeded, the temperature controller generates a loud sound and sounds an alarm.

If the user has the app, it operates selectively depending on whether the alarm is set or not, and stops the alarm by entering the appropriate password into the thermostat.

Through the present invention, by providing an eco-friendly heating structure using ocher and polyurethane sunjit mortar, it is possible to promote the metabolism of the human body according to residential life, and at the same time neutralize wastes harmful to the human body, and promote a healthy life. Will be provided.

In addition, the heating cost can be drastically reduced and installed inexpensively during installation, heating is possible immediately after construction, has a semi-permanent life, there is no electromagnetic wave, and it has the effect of saving half of the electricity cost compared to ordinary electric panels.

Among the above-described contents, the contents not indicated in the drawings are contents that can be sufficiently understood by those skilled in the art based on the contents described above, and should be included in the rights of the present invention even if not indicated in the drawings below.

Those skilled in the art to which the present invention with the above contents pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, it should be understood that the embodiments described above are exemplified in all respects and not limiting.

The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. .

100: slab base
200: primer
300: loess material layer
400: carbon fiber
500: loess heat diffusion plate
600: polyurethane pure mortar

Claims (4)

In the heating structure using polyurethane pure mortar,
With the slab base (100),
A primer 200 applied on the upper part of the slab base,
An ocher material layer 300 formed at a certain height of ocher material on top of the primer,
As a heating element on the top of the loess material layer, a carbon fiber 400 is installed, and both ends of the carbon fiber extend to the outside of the loess material layer, including a polyurethane pure mortar 600 applied on the carbon fiber,
Laminate the loess heat diffusion plate 500 before applying the polyurethane sunjit mortar on the top of the carbon fiber,
The ocher heat diffusion plate 500 is a heating structure using a polyurethane sunjit mortar, characterized in that manufactured using ocher.
The method of claim 1,
The loess heat diffusion plate 500,
Bottom loess reheat diffusion unit 510 formed at the lowermost side at a certain height using loess; And
A filler loess material heat diffusion unit 520 positioned above the bottom loess material heat diffusion unit and formed at a predetermined height by using loess and a heat conductive material; And
A heating structure using a polyurethane sunjit mortar, characterized in that it comprises a top loess material heat diffusion unit 530, which is located above the filler loess material heat diffusion unit 520 and is formed at a predetermined height using loess.
The method of claim 1,
The carbon fiber 400 has a temperature sensor unit 2000 attached as a heating element,
It is configured to further include a temperature controller 1000,
The temperature controller turns the power ON/OFF with a power key, and a power on/off unit 1100 during a power outage that maintains an operating state as ON after returning to the previous operation state when the previous operation state is ON, and OFF when it is OFF; and
When the power switch is pressed for a few seconds, "initialization" flashes several times on the display window, and the initialization unit 1200 is initialized; and
A driving display unit 1300 that is displayed in red when it is currently driving; and
A high temperature prevention unit 1400 that obtains a temperature detection value from the temperature detection sensor unit, and automatically turns off the power when the obtained temperature detection value is 60 degrees Celsius or more; And
A setting method selection unit 1500 for setting a temperature setting type or a method through a timer with a toggle button; And
In the case of temperature setting type, pressing the down arrow key (↓) or the up arrow key (↑) displays the set target temperature, and the green LED turns on during display, and if there is no key input for a few seconds, the green LED turns off and the current temperature is displayed. A temperature setting unit 1600; and
In the case of the timer method, pressing the down arrow key (↓) or the up arrow key (↑) displays the step of setting the temperature setting intensity step by step, and the green LED turns on during the display. A heating structure using a polyurethane sunjit mortar, characterized in that comprising; a timer step unit 1700 that displays the current stage while the LED is turned off.
The method of claim 3,
The temperature controller 1000,
Optionally, a Bluetooth communication unit 1800 may be provided, through which access to the Internet by accessing the Internet by accessing a router or a WiFi dongle located in a short distance. Heating structure using polyurethane sunjit mortar, characterized in that there is.

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