KR20110069639A - Container paper for total heat exchanger element - Google Patents

Abstract

PURPOSE: A cooling and warming container using a heating element is provided to enable a user to selectively perform a cooling or heating process of the container. CONSTITUTION: A cooling and warming container using a heating element includes a container unit(100) and a temperature offering unit(200). The container unit includes an internal space for installing a filler with the heat insulating and cooking function. The temperature offering unit is installed on the outside of the container for selectively cooking and heating the container using the Peltier effect.

Description

Cold and hot container using heating element {CONTAINER PAPER FOR TOTAL HEAT EXCHANGER ELEMENT}

The present invention relates to a cold container using a heating element, and more particularly to a cold container using the Peltier effect principle.

Generally, thermos such as thermos such as foamed styrofoam or a thermos, portable lunch box, and thermos that can be carried by using a vacuum, may be used for storing hot beverages or foods, especially in the cold weather of winter, due to natural temperature differences. As the temperature went down, it could not be prevented from cooling down after a few hours, and there was a limit to the time shown.

In addition, as the drink or food to keep warm over time, even if it is a high temperature of 100 degrees Celsius, for example, the temperature continues to drop to 80 degrees to 50 degrees Celsius in just a few hours, There was a problem that could not be stored for a long time at a constant temperature changed.

Moreover, if the thermos open state increases, the contents easily change to room temperature, and even after opening for a certain time, the cold water becomes hot, and the hot water becomes cold, so that the user cannot drink in a desired state.

Accordingly, it is an object of the present invention to mount a heating element on a cold container to selectively perform a cold and warm function.

In addition, the object of the present invention is to apply the Peltier effect on the principle of the cold temperature function to selectively set the temperature in the cold and hot container to improve the storage properties irrespective of the kind of the storage article or food stored in the cold container.

In addition, an object of the present invention is to maximize the heat dissipation effect with the combination of the container and the heating element to significantly reduce the volume of the cold and hot container to improve the portability.

Furthermore, the object of the present invention is insulated. It is to make it easy to control the operation of the power and temperature control of the cold and hot container that keeps warm function.

In addition, an object of the present invention is to install a circulation tube inside the cold container, so that the heat retention liquid filled in the circulation tube can be circulated by the provided temperature to further improve heat preservation.

In order to achieve the above object, the cold and hot container using the heating element of the present invention is provided with an inner space, the container portion and the outside of the container portion provided to circulate the filling having a thermal insulation and cold storage function to the outside of the interior space; Installed in the Peltier effect to selectively have a cooling or heating function to change the temperature of the filling material includes a temperature providing unit for providing the temperature to the internal space.

According to the present invention, the container portion is formed inside the inner container having an upper opening and an outer space of the inner container to surround the outside of the inner container and formed to be spaced apart from the outer surface of the inner container. Filled in the container and the circulation space to keep the temperature of the inner container. The cooling material and the spiral pipe filled with the heat dissipating liquid in the circulation space are installed to be in close contact with the temperature providing unit to radiate heat to the outside during operation. It consists of a circulation pipe for quickly discharging the temperature to the outside to the outside, and a cover for opening the outer container.

According to the present invention, the temperature providing unit is arranged to separate the low-temperature module and the heat generating module made of a heterogeneous metal at a predetermined interval, and coupled to the heat transfer module between the low temperature module and the heat generating module to generate a DC current provided from the outside of the heat generating module or The temperature providing portion is endothermic by selectively applying to the low temperature module side. It is possible to switch the heat generation, but during cooling, when applied from the low-temperature module to the heating module side, the DC current absorbs heat in the inner space of the inner container and releases the heat absorbed to the outside through the heat generating module to dew point the temperature of the inner space. It can be maintained below the temperature, and when the heat generation is applied to the low-temperature module side DC current from the heat generating module is configured to generate heat to the internal space through the low temperature module.

According to the present invention, a lower portion of the outer container is coupled to a pedestal equipped with a control unit, and the pedestal is detachably coupled to the outer container, and the pedestal has a mounting space and a heat generating space, the upper and lower openings of which are respectively opened up and down. Each compartment is formed to be partitioned, and the partition formed between the mounting space and the heat generating space is configured to puncture the vent holes.

According to the present invention, a control unit for controlling the temperature providing unit is further installed in the mounting space of the pedestal, the control unit is a battery for supplying power to the temperature providing unit, and controls the on and off of the power supply A power switch, a display window for displaying the current temperature outside by the temperature control of the power switch, a temperature switch for controlling the cooling temperature and the heating temperature, the current intensity by the application signal of the power switch and the temperature switch And a circuit board which converts a current supply direction or controls a power cut or supply.

According to the present invention, the heat generation module of the temperature providing unit is exposed to the mounting space through the external container, the circulation pipe of the part in close contact with the temperature providing unit can be piped to the mounting space to radiate heat from the circulation tube and the heat generating module The temperature is configured to be vented to the vent hole.

According to the present invention, the lower portion of the outer container extends to the lower portion of the joint but the fixing jaw having a length formed in the lower jaw at the same interval to form an opening in the lower portion, the coupling portion formed around the mounting space of the pedestal The fixed jaw protrudes outwardly and is fitted into the fixing groove so that the fixing jaw is rotated within the fixing groove length so that the pedestal is interlocked so that the communication hole formed at the outer periphery of the coupling part selectively communicates with the opening hole. It is configured to selectively lower or increase the temperature generated in the heat generating module and the circulation tube by flowing into the mounting space through the communication hole and the open hole to enhance the heat efficiency.

According to the present invention, the temperature providing unit is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container at the same time the spiral circulating pipe in the circulation space is installed in a single pipe, the circulation pipe is a plurality of The heat dissipation of the heat generating module and the heat transfer module by being in close contact with the heat generating module. The heat dissipating liquid filled in the circulation tube is circulated due to the temperature difference of the cold, and the temperature generated from the heat generating module is discharged to the outside.

According to the present invention, the temperature providing unit is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container side, the circulation space is installed in a pair of circulation pipes, the circulation pipe is inside the circulation space It has an arc shape and is formed to be repeatedly circulated in a zigzag manner so that the lower part is in close contact with a pair of heat generating modules to dissipate the heat generating module and the heat transfer module. The heat dissipating liquid filled in the circulation pipe is circulated by the temperature difference of the cold protection, and the temperature generated from the heat generating module is discharged to the outside.

According to the present invention, the temperature providing unit is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container side, the circulation space is installed in close contact with each of the temperature providing unit independently of each other, Purifying pipe has an arc shape in the circulation space and is repeatedly circulated in a zigzag manner to dissipate the heat generating module and the heat transfer module. The heat dissipating liquid filled in the circulation pipe is circulated by the temperature difference of the cold protection, and the temperature generated from the heat generating module is discharged to the outside.

According to the present invention, the inner container is made of magnesium material.

As described above, the cold and hot container using the heating element of the present invention is equipped with a temperature providing unit using the Peltier effect principle in the container to cool in the cold and hot container itself. The thermal insulation function can be selectively performed, thereby enabling easy storage of articles having various storage temperatures.

In addition, the cold and hot container using the heat transfer element of the present invention by removably equipped with a temperature providing unit having a Peltier effect principle in the lower portion of the container to significantly reduce the volume of the cold and hot container, can improve the portability and storage of the cold and hot container. It is effective.

In addition, the cold and hot container using the heat transfer element of the present invention has the effect of maximizing thermal efficiency by filling the inside of the cold and hot container to maintain the heat preservation capacity for a long time.

Furthermore, cold and cold containers using the heat transfer element of the present invention is cold. It is possible to easily change the temperature control and on / off control of the cold / hot water container having a heat insulation function, thereby improving the operability of the cold / hot water container.

In addition, the cold and hot container using the heat transfer element of the present invention is installed in the cold-heated container to circulate the heat dissipating liquid filled with a circulation tube to keep warm in the temperature providing unit. There is an effect to improve the thermal efficiency by effectively discharging the heat generated when performing the cold storage function to the outside.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, it should be noted that the same components or parts in the drawings are indicated by the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

1 is a perspective view showing a cold and hot container using the heating element of the present invention, Figure 2 is a bottom perspective view showing a cold and hot container using the heating element of the present invention, Figure 3 is an exploded perspective view showing a cold and hot container using the heating element of the present invention. 4 is a schematic view showing a cold and hot container using the heating element of the present invention, Figure 5a, b is a configuration diagram showing another embodiment of the circulation tube in the cold and hot container using the heating element of the present invention, Figure 6 7 is a block diagram showing a temperature providing unit in a cold / hot container using the heat transfer element of the present invention, and FIG. 7 is a block diagram showing the principle of the Peltier effect applied to the present invention.

First, as shown in Figures 1 to 7, the cold and hot container using the heating element of the present invention is installed on the container portion 100 containing the food, the outer surface of the container portion 100 is selectively heated or cooled by the Peltier effect It consists of a temperature providing unit 200 to change the temperature of the container unit 100 to have a.

That is, the container part 100 is formed between the inner container 110 with an inner space 111 having an upper portion formed therein to surround the outside of the inner container 110 and spaced apart from the outer surface of the inner container 110 to circulate between the inner container 110. The outer container 120 is provided with a space 125, and the inner space of the inner container 110 is filled in the circulation space 125. Filled material 127 to maintain the cold temperature and the spiral pipe filled with the heat dissipating liquid 131 in the circulation space 125 while being installed in close contact with the temperature providing unit 200 to the temperature that the temperature providing unit 200 is radiated to the outside during operation. It consists of a circulation pipe 130 for quickly discharging to the outside, and a cover 126 for opening the outer container 120.

Here, the inner container 110 of the container part 100 is made of a magnesium material having a high thermal conductivity to improve the conductivity of the cooling or heating temperature provided from the temperature providing unit 200 to provide a quickly selected temperature.

At the same time, the filler 127 filled in the circulation space 125 formed between the inner container 110 and the outer container 120 keeps the temperature provided for the inner container 110 to be maintained for a longer time while minimizing heat loss.

In addition, the filler 127 allows to preserve the cooling or heating temperature provided through the temperature providing unit 200 for a long time, and the filler includes phenol and tertiary butylenol, but there is a problem with bisphenol A, which has a controversial anti-branching estimator. Polycarbonate and epoxy resins to complement. In the dissolution test of polyesterimide, the total amount of phenol, secondary butylphenol, and bisphenol A is 2.5 mg, and bisphenol is limited to 0.6 mg / min to minimize the damage from environmental hormones.

In addition, the heating temperature by combining the pedestal 140 of the lower 120 outer container. Mount the controller 150 to control the cooling temperature.

That is, the controller 150 controls the temperature of the current situation to the outside by the battery 151 for supplying power to the temperature providing unit 200, the power switch 152 for controlling the on / off of the power, and the temperature control of the power switch 152. The display window 155 for displaying, the temperature switch 153 for controlling the cooling temperature and the heating temperature, and the application signal of the power switch 153 and the temperature switch 153 change the current intensity and the current supply direction, or control the power cut off or supply. The circuit board 154 is formed.

In addition, the bottom of the outer container 120 is detachably coupled to the pedestal 140, the control unit 150 is mounted on the pedestal 140.

The pedestal 140 is detachably coupled to the outer container 120, and the pedestal 140 defines a mounting space 141 and a heat generating space 143 each having an upper portion and a lower portion opened up and down, respectively, and the mounting space 141 and the heat generating space 143. A vent hole 142 is drilled into the partition wall 147 formed therebetween.

In particular, the battery 151 and the circuit board 154 of the controller 150 are installed in the mounting space 141, and the display window 155, the power switch 152, and the temperature switch 153 are installed on the bottom surface of the partition wall 147 on the side of the heating space 143.

Here, the temperature generated by the heat generating module of the temperature providing unit 200 exposed in the mounting space 141 and the heat generated from the battery 151 and the circuit board 154 are discharged to the outside through the vent hole 142.

Next, the temperature providing unit 200 is as follows.

The temperature providing unit 200 is arranged to separate the low-temperature module 210 and the heating module 220 made of a heterogeneous metal at a predetermined interval, and combines the heat transfer module 230 between the low-temperature module 210 and the heating module 220 to generate a DC current provided from the outside. The temperature providing unit 200 absorbs heat by selectively applying to the module 220 or the low temperature module 210. Allows you to switch over heat.

As a result, when cooling through the temperature providing unit 200, when a DC current is applied from the low temperature module 210 to the heating module 220 side, it absorbs heat in the inner space 111 of the inner container 110 and releases the heat absorbed to the outside through the heating module 220. Ensure that the temperature in the space is below the dew point temperature.

On the contrary, when the DC current is applied from the heating module 220 to the low temperature module 210 during the heat generation, the DC current is generated to the internal space 111 through the low temperature module 210.

As shown in Figure 7 to enable this, looking at the principle of the Peltier effect as follows.

First, when direct current flows in the direction of the arrow, the temperature decreases at the point of contact A where the current flows from the A conductor to the B conductor, and the temperature rises at the B point.

If the current flows in reverse, the temperature rises at point A and decreases at point B.

This is because in other types of metals, the potential energy of the electrons in the metal is different, so it is necessary to obtain energy from the outside to transfer the electrons from the metal with the low potential energy to the metal with the high state. Is deprived of heat energy and vice versa.

By the Peltier effect principle, the low temperature module 210 made of dissimilar metals absorbs the temperature of the internal space 111 and heats the temperature to the heating module 220.

In other words, the low temperature module 210 absorbs heat from inside to maintain the temperature of the inner space of the inner space 111 at the dew point temperature, so that the water vapor contained in the air is kept at the dew point temperature so that the water vapor condenses to the front of the low temperature module 210. This bears on the front.

Here, the dew point temperature means the temperature (cooling) when the water vapor reaches saturation when the air temperature drops without changing the atmospheric pressure and the water content of the air including water vapor.

This occurs when two metals with different properties are joined and a direct current flows, whereby heat is generated at one junction and heat is absorbed at the other junction.

Eventually, the metal needs energy for the movement of the electrons inside and is provided externally to convert from the low energy state (the bismuth characteristic) to the high energy (the antimony characteristic).

Therefore, the generation of heat can have a cooling or heating temperature on the principle that it releases energy when transitioning from the high energy state (characteristic of antimony) to the low energy state (characteristic of bismuth).

Thus, it is possible to provide a heat dissipation temperature or a cooling temperature in accordance with the direction of the current delivered to the low temperature module 210 and the heating module 220 can provide a low temperature, high temperature according to the type of goods stored in the cold container 10.

The cold and hot container 10 using the heating element configured as described above exposes the heat generating module 220 of the temperature providing part 200 to the mounting space 141 through the external container 120, and the circulation pipe 130 of the portion closely contacted with the temperature providing part 200 is the mounting space 141. The heat radiated from the circulation pipe 130 and the heat generating module 220 is vented to the ventilation hole 142 so that the heat exchange is performed by the temperature difference between the external temperature and the heat generating module 220 of the mounting space 141. To improve.

In order to maximize the heat exchange function, the lower portion of the outer container 120 extends the connecting portion 121 to the lower portion, but forms a fixing groove 122 having a length in the connecting portion 121, and forms opening holes 123 at equal intervals thereunder. .

In addition, the coupling part 144 formed around the mounting space 141 of the pedestal 140 protrudes outwardly from the fixing jaw 145 to fit into the fixing groove 122 to rotate the fixing jaw 145 in the fixing groove 122 so that the pedestal 140 interlocks. The communication hole 146 formed at the outer periphery of the coupling part 144 selectively communicates with the opening hole 123 so that the outside air flows into the mounting space 141 through the communication hole 146 and the opening hole 123 so that the heat generating module 220 and the circulation tube 130 By selectively lowering or raising the temperature generated from the heat, it is possible to maximize the thermal efficiency.

Here, the handle 148 is further provided to the outer periphery of the coupling portion 144 to help the rotation of the pedestal 140, the handle penetrates through the fixing groove 122 of any one of the plurality of fixing grooves 122 through the handle 148 This makes it easier to rotate the 140.

In detail, when the cold temperature container 10 maintains the cold function, when the outside temperature is lower than the loading space 141 temperature, the open air 123 and the communicating hole 146 communicate with each other to introduce external cool air into the mounting space 141 to generate the heating module 220. Cool the heat generated in the to ensure effective heat exchange.

On the contrary, if the outside temperature is higher than the mounting space 141 when the cold / hot container maintains the cooling function, the stand 140 is rotated to prevent the open hole 123 of the outer container 120 and the communicating hole 146 of the stand 140 from communicating with each other. It does not flow into the space 141 to more effectively maintain the heat dissipation of the light emitting module 220.

This case is likewise applied to maintaining the warmth function of the cold container.

In addition, as shown in Figure 5a, b, the embodiment of the circulation tube 130 installed in the cold and hot container 10 using the heat transfer element of the present invention.

In the first embodiment, at least one temperature providing unit 200 is installed to provide a cooling temperature or a heating temperature to the inner container 110, and at the same time, the spiral circulation pipe 130 is connected to one pipeline in the circulation space 125. do.

At this time, the circulation tube 130 is in close contact with the heat generating module 220 of the plurality of temperature providing unit 200 heat dissipation of the heat generating module 220 and the heat transfer module 230. The heat dissipating liquid 131 filled in the circulation tube 130 is circulated due to the temperature difference of the winter, and the temperature generated from the heat generating module 220 is discharged to the outside.

As a result, the temperature difference between the circulating tube 130 and the other circulating tube 130 in which the helical circulation tube 130 penetrates through the plurality of temperature providing parts 200 so that the heat dissipating liquid 131 filled in the circulation tube 130 passes through the temperature providing part 200 It is circulated by and allows the temperature to be transferred to the filler 127. {(FIGs. 5a, 5b).

In a second embodiment, the temperature providing unit 200 is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container 110 side.

In this case, the circulation space 125 is installed to be divided into a pair of the circulation tube 130, the circulation tube 130 has an arc shape in the circulation space 125 and is formed to be repeatedly circulated in a zigzag form to the lower portion of the pair of heating module 220 Install in close contact.

Thus, heat dissipation of the heating module 220 and the heating module 230. The heat dissipating liquid 131 filled in the circulation tube 130 is circulated due to the difference in temperature of the winter, and the temperature generated from the heat generating module 220 is discharged to the outside. {(FIGS. 5A and 5B (b))

In a third embodiment, the temperature providing unit 200 is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container 111 side.

In addition, the circulation space 125 is installed in each of the temperature providing unit 200 to be in close contact with each other independently, the circulation pipe 130 has an arc shape in the circulation space 125 and is formed to be repeatedly circulated in a zigzag pattern to generate the heat Heat dissipation of module 220 and heating module 230. The heat dissipating liquid 131 filled in the circulation tube 130 is circulated due to the difference in temperature of the winter, so that the temperature generated from the heat generating module 220 is discharged to the outside. ((C) of FIGS. 5A and 5B).

As described above, by implementing the arrangement of the circulation pipe 130 in various embodiments, it is possible to selectively control the plurality of temperature providing units 200 to operate the corresponding temperature providing unit 200 in accordance with the storage temperature of the goods stored in the cold and hot container. By doing so, proper power consumption can be achieved.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have the knowledge of.

1 is a perspective view showing a cold and hot container using a heating element of the present invention.

Figure 2 is a bottom perspective view showing a cold and hot container using the heating element of the present invention.

Figure 3 is an exploded perspective view showing a cold and hot container using the heating element of the present invention.

Figure 4 is a schematic view showing a cold and hot container using the heating element of the present invention.

Figure 5a, b is a block diagram showing another embodiment of the circulation tube in the cold and hot container using the heating element of the present invention.

Figure 6 is a block diagram showing a temperature providing unit of the cold and hot container using the heating element of the present invention.

Figure 7 is a block diagram showing the principle of the Peltier effect applied to the present invention.

<Description of the symbols for the main parts of the drawings>

10: food container 100: container

110: inner container 111: inner space

120: outer container 121: joint

122: fixing groove 123: opening hole

125: circulating space 126: cover

127: filling 130: circulation tube

131: heat dissipating liquid 140: pedestal

141: mounting space 142: ventilation hole

143: heat generating space 144: coupling portion

145: fixed jaw 146: communication hole

147: bulkhead 148: handle

150: control unit 151: battery

152: power switch 153: temperature switch

154: circuit board 155: display window

200: temperature providing unit 210: low temperature module

220: heating module 230: heating module

Claims (11)

An inner space is provided, and a container part circulating to install a filler having a heat insulating / cold function outside the inner space; The cold temperature container using a heating element, characterized in that it comprises a temperature providing unit which is installed outside the container portion to provide a selected temperature to the internal space by selectively having a cooling or heating function using the Peltier effect. The method of claim 1, The container portion, An inner container provided therein with an inner space having an upper portion opened therein; An outer container provided with a circulation space between the inner container to surround the outside of the inner container and to be spaced apart from the outer surface of the inner container; Insulating the inner container is filled in the circulation space. Filling to maintain the cold temperature, Heat dissipation to the outside when the temperature providing unit is installed to be in close contact with the temperature providing unit while being installed as a spiral pipe filled with a heat radiation liquid in the circulation space. A circulation pipe for quickly discharging the cold temperature to the outside, Cold container using a heating element, characterized in that the cover configured to open the outer container. The method of claim 1, The temperature providing unit, The low temperature module and the heating module made of dissimilar metals are spaced apart at regular intervals, and the direct current supplied from the outside is selectively applied to the heating module or the low temperature module side by combining the heating module between the low temperature module and the heating module. Temperature provision endotherm. To allow the generation of fever When cooling, direct current is applied from the low temperature module to the heat generating module to absorb heat from the inner space of the inner container and release the heat absorbed to the outside through the heat generating module so that the temperature of the inner space can be kept below the dew point temperature. Cooling container using a heating element, characterized in that configured to generate heat to the internal space through the low-temperature module when a direct current is applied to the low-temperature module side during the heating. The method of claim 1, The bottom of the outer container is detachably coupled to the pedestal mounted on the control unit, the pedestal is formed to partition the mounting space and the heat generating space each of the upper and lower openings in the upper and lower respectively, partition wall formed between the mounting space and the heating space The cold and hot container using a heating element, characterized in that configured to puncture the vent hole. The method according to claim 1 or 4, Further comprising a control unit for controlling the temperature providing unit is installed in the mounting space of the pedestal, The control unit, A battery for supplying power to the temperature providing unit; A power switch for controlling the on / off of the power supply; A display window for displaying the temperature of the current situation to the outside by temperature control of the power switch; A temperature switch for controlling the cooling temperature and the heating temperature, Cooling container using a heating element, characterized in that consisting of a circuit board for converting the current intensity and current providing direction, the power cut off or supply control by the power switch and the application signal of the temperature switch. 5. The method according to any one of claims 1 to 4, The heat generating module of the temperature providing unit is exposed to the mounting space through the external container, and the circulation pipe of the part in close contact with the temperature providing unit can be piped to the mounting space so that the heat radiated from the circulation tube and the heat generating module is vented. Cold container using a heating element, characterized in that configured to be vented. The method according to any one of claims 2 to 4, The lower portion of the outer container extends to the lower portion of the joint portion, but forming a fixing groove having a length in the joint portion, and forming an opening hole in the lower portion at equal intervals, the fixing jaw in the coupling portion formed around the mounting space of the pedestal Protrude outwardly and fit into the fixing groove to rotate the fixing jaw in the fixing groove length so that the pedestal is interlocked so that the communication hole formed at the outer periphery of the coupling part selectively communicates with the opening hole so that the outside air communicates with the communication hole. The cold temperature container using the heat transfer element, characterized in that configured to improve the heat efficiency by allowing the flow into the mounting space through the open hole to selectively lower or increase the temperature generated in the heat generating module and the circulation pipe. The method according to any one of claims 1 to 3, The temperature providing unit is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container at the same time to install a spiral circulation pipe in a single pipe in the circulation space, Heat dissipation of the heat generating module and the heat transfer module by closely contacting the circulation tube with a plurality of temperature providing unit heat generating modules. Cold temperature container using a heat transfer element, characterized in that configured to discharge the temperature generated from the heat generating module to the outside while the heat dissipating liquid filled in the circulation tube by the temperature difference of the cold. The method according to any one of claims 1 to 3, The temperature providing unit is provided with at least one or more to provide a cooling temperature or a heating temperature to the inner container side, The circulation space is installed in a pair of circulation pipes, but the circulation pipe has an arc shape in the circulation space and is formed to be repeatedly circulated in a zigzag manner so that the lower part is in close contact with a pair of heat generating modules to generate the heat. Heat dissipation of module and heating module. Cold temperature container using a heating element, characterized in that configured to discharge the temperature generated from the heat generating module to the outside while the heat dissipating liquid filled in the circulation tube due to the temperature difference of the cold. The method according to any one of claims 1 to 3, The temperature providing unit is provided with at least one or more to provide a cooling temperature or heating temperature to the inner container side, The circulation space is installed to be in close contact with each of the circulation pipes independently of each temperature providing unit, The purifying pipe has an arc shape in the circulation space and is repeatedly circulated in a zigzag manner to dissipate the heating module and the heating module. Cold temperature container using a heating element, characterized in that configured to discharge the temperature generated from the heat generating module to the outside while the heat dissipating liquid filled in the circulation tube due to the temperature difference of the cold. The method of claim 1, The inner container is a cold container using a heating element, characterized in that made of magnesium material.

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