KR20200081176A - Apparatus for Heat Delivery - Google Patents

Abstract

The present invention relates to a thermal energy delivery apparatus. More specifically, the present invention relates to an apparatus capable of accumulating waste heat so as to be used in a thermal energy delivery business and radiating the heat at a place of use after moving. The thermal energy delivery apparatus according to the present invention has an effect of supplying the heat stored in a heat storage device used in the thermal courier business to the heat use place, and easily replacing the heat storage device having heat dissipation completed. The thermal energy delivery apparatus includes a heat storage module, a heat storage tank, a circulation unit, and a supply unit.

Description

Heat courier supply device {Apparatus for Heat Delivery}

The present invention relates to a heat courier supply device, and more particularly, to a device capable of heat-dissipating at a place of use after moving heat by storing heat for use in a heat courier business.

A thermal courier business that stores waste heat generated by factories such as steel mills and supplies it to greenhouses or houses has been attempted and has been recently used.

Such a heat courier business stores and uses waste heat generated by a chimney of a furnace or incinerator in a factory such as a steel mill. As a medium for storing such waste heat, a phase change material (PCM) or a chemical heat storage material called latent heat storage material is used. Heat is stored while the phase change material is changed to a liquid phase through a fluid such as fruit oil heated by waste heat in a heat storage container in which the phase change material is stored.

A device that stores heat using such a phase change material is called a heat storage device. The heat storage device is a device that stores heat through a phase change material filled therein.

In order to supply heat to a greenhouse or a house through a heat storage device, a heat storage device is installed and a device for transferring heat of the heat storage device is required. In order for the heat storage device to be widely used, it is essential to develop a heat delivery system that can easily replace the heat storage device.

Meanwhile, the heat storage device needs to be replaced after heat dissipation is completed. If the user directly checks whether the heat dissipation of the heat storage device has been completed and requests a replacement, the accessibility of the heat delivery service is significantly reduced. Therefore, there is a need for a heat courier supply solution capable of automatically replacing the heat storage device when heat dissipation of the heat storage device is completed.

The present invention has been made in order to solve the above-described need, and an object of the present invention is to provide a heat courier supply device capable of easily replacing a heat storage device.

A heat courier supply device according to the present invention for achieving the above object includes a plurality of heat storage units storing heat, a heat exchange chamber accommodating the plurality of heat storage units, and an inlet and an outlet formed to communicate with the heat exchange chamber. A heat storage module provided; A heat storage tank formed to receive the heat storage module; A circulation pipe connecting a heat use place receiving heat through the heat storage module and an inlet of the heat storage module, and installed on a path of the circulation pipe to supply air from the heat use place to the inlet of the heat storage module through the circulation pipe A circulation unit including a circulation pump to move; A supply pipe connecting the heat use place and the outlet of the heat storage module, and a supply pump installed on a path of the connection pipe to move air from the heat use place via the heat storage module to the heat use place through the supply pipe. It characterized in that it comprises a; supply unit comprising a.

The heat courier supply device according to the present invention has an effect of easily supplying heat stored in a heat storage device used in a heat courier business to a heat user, and easily replacing the heat storage device after heat dissipation is completed.

1 is a structural diagram of a heat courier supply device according to an embodiment of the present invention.
2 is a conceptual diagram of a heat courier supply system according to an embodiment of the present invention.
3 is a perspective view of the heat storage module shown in FIG. 1.
4 is a perspective view of the heat storage unit shown in FIG. 3.
5 is a front view of the heat storage unit shown in FIG. 4.
6 is a cross-sectional view taken along line VI-VI of the heat storage unit illustrated in FIG. 4.

Hereinafter, a heat courier supply device according to an embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 1, the heat courier supply device according to the present embodiment includes a heat storage module 200, a circulation unit 10, a supply unit 20, and a heat storage tank 30. The heat courier supply device according to the present embodiment is a device that transfers heat stored in the heat storage module 200 to a heat use destination through the circulation unit 10 and the supply unit 20. Here, the use of heat means a building or facility that requires heating, such as a house or greenhouse.

The heat storage module 200 includes a plurality of heat storage units 100, a heat exchange chamber 201, an inlet 210 and an outlet 220.

The heat storage unit 100 is a minimum unit that stores and discharges heat, and is filled with heat storage material therein. The detailed structure of the heat storage unit 100 used in this embodiment will be described later.

The heat exchange chamber 201 is formed to accommodate the heat storage unit 100. In the present embodiment, the heat exchange chamber 201 of the heat storage module 200 is formed in a rectangular parallelepiped shape. In the heat exchange chamber 201, an inlet 210 and an outlet 220 are formed so that heat exchange fluid exchanging heat with the heat storage unit 100 can be introduced or discharged into the heat exchange chamber 201.

The circulation unit 10 includes a circulation pipe 12 and a circulation pump 11.

The circulation pipe 12 is a pipe that connects the heat source and the heat storage tank 30. In consideration of heat transfer efficiency, the circulation pipe 12 is preferably insulated. Through the circulation pipe 12, the air of the heat use destination flows into the inlet 210 of the heat storage module 200 via the heat storage tank 30. The circulation pump 11 is installed on the path of the circulation pipe 12. The circulation pump 11 generates an air flow so that the air of the heat application is introduced into the inlet 210 of the heat storage module 200 through the circulation pipe 12.

The supply unit 20 includes a supply pipe 22 and a supply pump 21.

The supply pipe 22 is a pipe that connects the heat-using place and the heat storage tank 30. Like the circulation piping 12 of the circulation unit 10, it is preferable that the supply piping 22 is insulated by considering heat transfer efficiency. The air of the heat use where heat exchange is performed via the heat storage module 200 flows out to the outlet 220 of the heat storage module 200, and this air is used through the supply pipe 22 via the heat storage tank 30 Is supplied to. The supply pump 21 is installed on the path of the supply pipe 22. The supply pump 21 generates an air flow so that the air passing through the heat storage module 200 is supplied to the heat use place through the supply pipe 22. In addition, the supply pump 21 includes an external air passage 23. The supply pump 21 may intake external air through the external air passage 23 to add external air to the above-described air flow.

The heat storage tank 30 is formed to accommodate the heat storage module 200. As described above, the heat storage module 200 is formed in a cuboid shape, so the heat storage tank 30 is also formed in a cuboid shape.

The heat storage tank 30 is provided with a slide door 31 and a roller 32. The slide door 31 opens and closes one side of the heat storage tank 30. The heat storage module 200 may be mounted on or removed from the heat storage tank 30 while the slide door 31 is raised and the heat storage tank 30 is opened. The roller 32 is installed on the bottom surface of the heat storage tank 30. The roller 32 is a plurality of bars installed rotatably with respect to the heat storage tank 30. The roller 32 rotates in contact with the heat storage module 200 to facilitate mounting and removal of the heat storage module 200.

Meanwhile, the heat storage tank 30 includes a circulation flow path 33 and a supply flow path 34. The circulation passage 33 is formed to connect the circulation pipe 12 of the circulation unit 10 and the circulation pipe 41 of the circulation docking unit 40 to be described later. The supply flow passage 34 is formed to connect the supply pipe 22 of the supply pipe 22 and the supply pipe 51 of the supply docking unit 50 to be described later.

The circulation docking unit 40 includes a circulation pipe 41, a circulation operation part 42, and a circulation airtight part 43.

The circulation pipe 41 is a pipe formed to be connected to the inlet 210 of the heat storage module 200. In the case of the present embodiment, the circulation pipe 41 is manufactured in the form of a corrugated pipe to allow length deformation. The diameter of the circulation pipe 41 is larger than the diameter of the inlet 210. The circulation operation part 42 changes the length of the circulation pipe 41. By the operation of the circulation operation unit 42, the circulation pipe 41 moves forward or backward with respect to the inlet 210 of the heat storage module 200. The circulation hermetic portion 43 is formed at the end of the circulation pipe 41. The circulation airtight portion 43 is airtight between the circulation pipe 41 and the inlet 210 while the circulation pipe 41 is connected to the inlet 210 of the heat storage module 200.

The supply docking unit 50 includes a supply pipe 51, a supply operation part 52, and a supply airtight part 53.

The supply pipe 51 is a pipe formed to be connected to the outlet 220 of the heat storage module 200. In the case of this embodiment, the supply pipe 51 is manufactured in the form of a corrugated pipe so that the length can be deformed like the circulation pipe 41 described above. The diameter of the supply pipe 51 is larger than the diameter of the outlet 220. The supply operation part 52 changes the length of the supply pipe 51. By the operation of the supply operation unit 52, the supply pipe 51 moves forward or backward with respect to the outlet 220 of the heat storage module 200. The supply hermetic portion 53 is formed at the end of the supply pipe 51. The supply airtight part 53 is airtight between the supply pipe 51 and the outlet 220 while the supply pipe 51 is connected to the outlet 220 of the heat storage module 200.

Hereinafter, a description will be given of a process of providing heating to a heat use place by using the heat courier supply device configured as described above.

First, the process of installing the heat storage module 200 in the heat storage state to the heat storage tank 30 will be described.

When the slide door 31 of the heat storage tank 30 rises, the heat storage tank 30 is opened. With the heat storage tank 30 open, the heat storage module 200 is pushed into the heat storage tank 30. At this time, the bottom surface of the heat storage module 200 contacts the roller 32 installed in the heat storage tank 30. The roller 32 rotates and the heat storage module 200 enters into the heat storage tank 30.

When the heat storage module 200 is seated inside the heat storage tank 30, the slide door 31 of the heat storage tank 30 rises to close the heat storage tank 30. In this state, the circulation operation unit 42 of the circulation docking unit 40 is operated so that the circulation pipe 41 advances toward the inlet 210 of the heat storage module 200. The circulation operation portion 42 of the circulation docking unit 40 advances the circulation pipe 41 until the circulation airtight portion 43 is in full contact with a surface adjacent to the inlet 210 of the heat storage module 200. 1, the diameter of the circulation pipe 41 is larger than the diameter of the inlet 210, so that the circulation pipe 41 completely covers the inlet 210 in a state where the circulation pipe 41 is fully advanced. do. At the same time, the supply operation unit 52 of the supply docking unit 50 operates, and the supply pipe 51 advances toward the outlet 220 of the heat storage module 200. The supply operation part 52 of the supply docking unit 50 advances the supply pipe 51 until the supply airtight part 53 completely contacts the surface adjacent to the outlet 220 of the heat storage module 200. Since the diameter of the supply pipe 51 is larger than the diameter of the outlet 220, the supply pipe 51 completely covers the outlet 220 while the supply pipe 51 is fully advanced.

Through the above process, the heat storage module 200 is installed in the heat storage tank 30. The connection between the circulation pipe 41 and the inlet 210 and the connection between the supply pipe 51 and the outlet 220 are automatically performed, so the heat storage module 200 can be easily installed in the heat storage tank 30.

Next, a description will be given of a process in which heating is performed at a heat use place.

The circulation pump 11 of the circulation unit 10 is operated. Due to the operation of the circulation pump 11, air from the heat source is transferred to the heat storage tank 30 through the circulation pipe 12 of the circulation unit 10. The air delivered to the heat storage tank 30 is moved to the circulation pipe 41 through the circulation flow path 33 of the heat storage tank 30. As described above, since the circulation pipe 41 is connected to the inlet 210 of the heat storage module 200, air flows into the heat storage module 200 through the inlet 210 of the heat storage module 200. The air of the heat use place introduced into the heat storage module 200 is heated through heat exchange with the heat storage unit 100. The air heated through the heat storage module 200 is discharged from the heat storage module 200 through the outlet 220 of the heat storage module 200.

The supply pump 21 of the supply unit 20 is operated. The air heated by the operation of the supply pump 21 is moved along the supply pipe 51 connected to the outlet 220 from the outlet 220 of the heat storage module 200. The supply pipe 51 flows to the supply pipe 22 of the supply unit 20 connected to the supply flow path 34 via the supply flow path 34 of the heat storage tank 30. The heated air is delivered to the heat use through the supply pipe 22 and this air raises the temperature to the heat use. Meanwhile, the supply pump 21 of the supply unit 20 also sucks external air through the external air passage 23. This external air is mixed with the heated air via the heat storage module 200. As a result, outside air and heated air are mixed and supplied to the heat application. The outside air serves to lower the heated air to an appropriate temperature. The heating temperature may be determined according to the ratio of external air to heated air. In this way, the heat courier supply device according to the present embodiment can heat a heat use place to an appropriate temperature.

Facilities such as greenhouses need to be kept at a constant temperature for the cultivation of crops. In this case, the thermometer installed in the heat use place and the heat courier supply device may be operated in conjunction. That is, the operation degree of the supply pump 21 and the amount of external air sucked by the supply pump 21 may be varied according to a desired temperature set in the heat use place. When the heat courier supply device according to the present embodiment is configured to control the desired temperature of the heat use destination as the target value, the temperature of the heat use destination can be maintained at the desired temperature.

When the heat dissipation of the heat storage module 200 is completed, the heat storage module 200 is removed from the heat storage tank 30. The removal of the heat storage module 200 proceeds in the reverse order of installation. First, the circulation operation unit 42 of the circulation docking unit 40 is operated so that the circulation pipe 41 retracts with respect to the inlet 210 of the heat storage module 200. With the retraction of the circulation pipe 41, the inlet 210 and the circulation pipe 41 are separated. Similarly, the supply operation unit 52 of the supply docking unit 50 is operated so that the supply pipe 51 retracts with respect to the outlet 220 of the heat storage module 200. With the retraction of the supply pipe 51, the outlet 220 and the supply pipe 51 are separated. In this state, the slide door 31 of the heat storage tank 30 rises, and the heat storage tank 30 is opened. The heat storage module 200 is moved out of the heat storage tank 30 by the roller 32 of the heat storage tank 30.

If continuous heating is required, the heat storage module 200 may be replaced to continue heating. As described above, the heat courier supply device according to the present embodiment has an advantage configured to easily replace the heat storage module 200 to perform heating.

Next, the operation of the heat courier supply system according to the present embodiment will be described with reference to FIG. 2.

Referring to FIG. 2, the heat courier supply system according to the present embodiment includes a management module 2000 and a control module 1000. Configurations other than the management module 2000 and the control module 1000 are the same as the heat courier supply device according to the present embodiment described above, so a description thereof will be omitted.

The management module 2000 includes a temperature sensor 2100 and a communication unit 2200. The temperature sensor 2100 is installed in the heat storage tank 30 to measure the temperature inside the heat storage tank 30. The temperature information measured by the temperature sensor 2100 is transmitted through the communication unit 2200.

The control module 1000 includes a receiving unit 1100, a requesting unit 1200, and a sensing unit 1300.

The reception unit 1100 of the control module 1000 receives temperature information transmitted by the communication unit 2200 of the management module 2000. The requesting unit 1200 of the control module 1000 transmits a replacement request signal to the transportation system when the temperature information received by the receiving unit 1100 decreases below the replacement temperature. The transportation system is a system for managing a transportation means for transporting the heat storage module 200. When the requesting unit 1200 of the control module 1000 transmits a replacement request signal to the transport system, the transport system transports the heat storage module 200 to a corresponding heat use destination. The transport means managed by the transport system may transport the heat storage module 200 stored in the heat storage state to a heat use place, and may also transport the heat storage module 200 stored in the waste heat of the factory to the heat use place.

For efficient system operation, the request unit 1200 of the control module 1000 may utilize location information. The request unit 1200 of the control module 1000 transfers the heat storage module 200 from the factory or the heat storage module 200 storage adjacent to the management module 2000 that transmits the reduced temperature information below the replacement temperature. It is also possible to transmit a request signal for replacement. In this case, the heat storage module 200 can be replaced more quickly in a heat use place.

When the temperature information received by the receiver 1100 exceeds the normal temperature, the detection unit 1300 of the control module 1000 checks the location of the heat storage tank 30 in which the management module 2000 that has sent the temperature information is installed. The sensing unit 1300 transmits a danger signal to the fire department and the police station adjacent to the heat storage tank 30 exceeding the normal temperature. For this reason, the heat courier supply system according to the present embodiment can prevent an accident and minimize damage when an accident occurs.

Next, with reference to FIGS. 3 to 6, a detailed structure of the heat storage unit 100 and the heat storage module 200 described above will be described.

3 is a perspective view of a heat storage unit according to an embodiment of the present invention installed in a heat storage module, FIG. 4 is a perspective view of the heat storage unit shown in FIG. 3, and FIG. 5 is a front view of the heat storage unit shown in FIG. 4. .

The heat storage unit of the present invention is installed and used in the heat storage module 200 as shown in FIG. 3. The heat storage module 200 is provided with a plurality of heat storage units 100 of the present invention. The heat storage module 200 is formed in a closed container shape, or a plurality of heat storage modules 200 are connected to each other to form a closed container shape. The heat storage module 200 is formed with a flow path through which fluids such as water and air can flow, and an inlet 210 through which fluid flows from the outside and an outlet 220 through which fluid flows out. As the high-temperature fluid flows through the heat storage module 200, heat is exchanged with the heat storage unit 100 of the present invention to store heat in the heat storage unit 100. When the heat storage module 200 is delivered to a place where energy is required, heat stored in the heat storage unit 100 is used. Conversely, as described above, when the fluid is introduced into the heat storage module 200, the fluid is heated by receiving heat stored in the heat storage unit 100 in contact with the heat storage unit 100 while flowing through a flow path.

The heat storage unit 100 of the present invention is a minimum unit for storing and dissipating heat in such a heat delivery service.

4 to 6, the heat storage unit 100 of this embodiment includes a unit body 110, a heat storage material 120, an inner fin 130, an outer fin 140, and a guide member 150. .

The unit body 110 is formed in a cylindrical shape formed to extend in the longitudinal direction Inside the unit body 110, a heat storage chamber 111 formed of a closed space is formed. A cap member 160 is installed on the unit body 110 to open and close the heat storage chamber 111. The heat storage chamber 111 of the unit body 110 is filled with a heat storage material 120.

The heat storage material 120 is generally a material known as a phase change material (PCM). As the heat storage material 120, it is also possible to use a chemical heat storage material in addition to the phase change material. When the heat storage material 120 absorbs external heat and is high temperature, the heat storage material 120 becomes a liquid state. When the temperature of the heat storage material 120 is lowered by dissipating heat stored in the heat storage material 120 to the outside, the heat storage material 120 becomes a solid state.

The heat storage material 120 is injected into the heat storage chamber 111 in a state where the heat storage chamber 111 is opened by removing the cap member 160 from the unit body 110. The cap member 160 is coupled to the unit body 110 to close the heat storage chamber 111 of the unit body 110.

A plurality of internal fins 130 are installed in the heat storage chamber 111 of the unit body 110. The inner fin 130 is formed to protrude and extend from the inner surface of the heat storage chamber 111 toward the center of the heat storage chamber 111. In the case of this embodiment, as shown in FIG. 6, the inner pins 130 are formed to be radially arranged and projected relative to the unit body 110. Thus, when the inner fin 130 is formed to extend to the vicinity of the center of the heat storage chamber 111, there is an advantage to enable heat storage and heat dissipation to the inside of the heat storage chamber 111 effectively. In addition, as shown in FIG. 6, the inner fin 130 increases the contact area between the heat storage material 120 and the inner fin 130 by performing a serration process such that a plurality of irregularities are formed on the surface, thereby exchanging heat. Efficiency can be improved.

A plurality of external pins 140 are installed on the outer surface of the unit body 110. The outer pin 140 is arranged in a circumferential direction along the outer surface of the unit body 110 to be formed to protrude radially. Thus, when the plurality of external fins 140 are formed to protrude on the outer surface of the unit body 110, there is an advantage of increasing the heat exchange efficiency by increasing the contact area with the fluid.

A guide member 150 is formed on the outer surface of the unit body 110. The guide member 150 facilitates the installation of the heat storage unit 100 of this embodiment to the heat storage module 200. The guide member 150 allows the heat storage unit 100 of the present embodiment to be mounted on the heat storage module 200 by sliding. A guide protrusion 230 extending in the longitudinal direction is formed in the heat storage module 200, and the guide member 150 of the heat storage unit 100 of this embodiment has a length of the unit body 110 on the outer surface of the unit body 110. It is formed to extend along the direction. A guide groove 151 is formed in the guide member 150. The user makes the guide protrusion 230 fit into the guide groove 151 of the guide member 150, and pushes the heat storage unit 100 of the present embodiment into the heat storage module 200, thereby storing the heat storage unit 100 of this embodiment. ) Is installed in the heat storage module 200.

The unit body 110, the inner pin 130, the outer pin 140, and the guide member 150 as described above are all formed of a metal material. Preferably, aluminum alloy, copper alloy, stainless steel, and the like can be used as the material of the unit body 110, the inner fin 130, the outer fin 140 and the guide member 150.

Hereinafter, the operation of the heat storage unit 100 configured as described above will be described.

First, the cap member 160 is separated from the unit body 110, and the heat storage material 120 is filled in the heat storage chamber 111 of the unit body 110. The heat storage unit 100 of the present embodiment can open and close the heat storage chamber 111 using a cap member 160, so as necessary, replenish the heat storage chamber 111 with the heat storage material 120 or the heat storage material 120 It is possible to replace it.

While using the heat storage unit 100 of the present embodiment, the heat storage material 120 may leak from the heat storage unit 100. Since the heat storage unit 100 of the present embodiment uses the cap member 160, leaked heat storage It is possible to replenish material 120.

In addition, when it is necessary to change the phase change material used as the heat storage material 120, there is an advantage that the heat storage chamber 111 can be opened using the cap member 160 and the heat storage material 120 can be replaced. If it is necessary to fill the heat storage chamber 111 with a phase change material having more suitable characteristics according to the heat storage and heat dissipation environment using the heat storage unit 100 of this embodiment, the heat storage material 120 may be replaced as described above. In addition, while the heat storage unit 100 of the present embodiment is used for a long period of time, when the heat storage material 120 with better performance is developed, the heat storage unit 100 of the present embodiment can be used by replacing the heat storage material 120 at any time. There is an advantage. Since there is no need to replace the entire heat storage unit 100, only the heat storage material 120 inside the heat storage chamber 111 can be replaced, thereby improving economic efficiency.

The heat storage unit 100 filled with the heat storage material 120 inside the heat storage chamber 111 is installed in the heat storage module 200 in a sliding manner with reference to FIGS. 3 and 5. As described above, by making the guide projection 230 of the heat storage module 200 fit into the guide groove 151 of the guide member 150, the heat storage unit 100 can be easily moved by pushing the heat storage unit 100 into place. It is possible to install in the heat storage module 200. In this way, the heat storage unit 100 of the present embodiment has a structure that is easy to separate from the installation in the heat storage module 200, so that the heat storage unit 100 is damaged or the heat storage material 120 is easily leaked. It is possible to replace the heat storage unit 100 and install the heat storage module 200. Therefore, the heat storage unit 100 of this embodiment has an advantage of convenient maintenance and low cost.

In the case of heat storage or heat dissipation by flowing a fluid in the heat storage module 200, the heat storage unit 100 of the present embodiment can improve heat exchange efficiency by the outer fin 140 and the inner fin 130. The outer fin 140 increases the contact area between the fluid and the heat storage unit 100, thereby making it possible to store or discharge heat more quickly.

Typically, the phase change material filled inside the heat storage chamber 111 starts to change to a solid from a portion close to the inner wall of the heat storage chamber 111, or conversely, the solid starts to turn into a liquid. When the heat storage unit 100 is used for heat dissipation, the phase change material releases heat from the inner wall of the heat storage chamber 111 and starts to turn into a solid. As such, the phase change material changed to a solid state may act as a kind of heat insulation to prevent the phase change material in the central portion of the heat storage chamber 111 from discharging heat. In the case of the heat storage unit 100 according to the present embodiment, since a plurality of internal fins 130 are formed to extend from the inner surface of the heat storage chamber 111 to the center, there is an advantage that heat dissipation efficiency is not reduced even in such a case. That is, even if the phase change material near the inner wall of the heat storage chamber 111 changes to a solid, the inner fin 130 contacts the liquid phase change material in the central portion of the heat storage chamber 111 to transfer heat to the heat storage chamber 111. It plays a role of transmitting to the outside. Conversely, even when the heat storage unit 100 is used for heat storage purposes, heat transferred by the fluid from the outside of the heat storage unit 100 is quickly transferred to the central portion of the heat storage chamber 111 through the inner fin 130. Accordingly, there is an advantage in that the heat storage operation can be performed while rapidly changing the heat storage material 120 into a liquid state by effectively transferring heat to the solid phase change material in the central portion of the heat storage chamber 111. As such, due to the action of the inner fin 130, the heat storage unit 100 according to the present embodiment can more effectively store and release heat energy in a heat storage and heat dissipation process. In addition, the heat storage unit 100 according to the present embodiment has an advantage of increasing the capacity of heat energy stored and used in the heat storage unit 100 as a whole. Particularly, the heat storage unit 100 of the present embodiment is provided with an internal fin 130 extending to the central portion of the heat storage chamber 111, so that even when the heat capacity inside the heat storage chamber 111 is low, the heat dissipation efficiency of the heat storage unit 100 There is an advantage that can be maintained at a high level without lowering.

The present invention has been described as a preferred example, but the scope of the present invention is not limited to the above-described and illustrated forms.

For example, in the case of the heat courier supply device described above, it is possible to omit the heat storage tank 30. In this case, the inlet port of the heat storage module and the circulation pipe of the circulation unit may be directly connected, and the outlet port of the heat storage module and the supply pipe of the supply unit may be directly connected.

In addition, the heat storage unit 100 described above is an example, and various types of heat storage units capable of storing and discharging heat may be utilized in a heat courier supply device.

In addition, the supply pump 21 of the supply unit 20 of the heat courier supply device was previously described as including the external air passage 23 so that external air flows in, but the external air passage 23 can be omitted.

In addition, the circulation docking unit 40 and the supply docking unit 50 of the heat courier supply device described above can be variously modified. Since the circulation docking unit and the supply docking unit are configured to connect the heat storage module accommodated in the heat storage tank to the circulation pipe and supply pipe, the circulation docking unit and the supply docking unit are modified in various ways in which the heat storage module and the circulation pipe and the supply pipe are connected. can do.

In addition, the control module 1000 of the heat courier supply system described above was described as including the monitoring unit 1300, but it is also possible to omit the monitoring unit 1300.

In addition, although the guide member 150 of the heat storage unit described above is provided with a guide groove 151 and the guide protrusions 230 are formed on the heat storage module 200 and slide-coupled to each other, it is also possible to configure the reverse. That is, the guide protrusion may be formed on the guide member of the heat storage unit, and the guide groove may be formed on the heat storage module to be coupled to the slide.

In addition, as described above, it is also possible to configure the heat storage unit of the present embodiment to be installed in the heat storage module in a clip fastening manner, rather than being installed in the heat storage module in a slide manner. A clip in the form of a leaf spring may be formed on the heat storage module and configured to be installed on the heat storage module in such a way that the guide member of the heat storage unit of the present invention is fitted to the clip.

In addition, it is possible to configure a heat storage unit having a structure that does not include any one of the outer fin 140 and the inner fin 130 depending on the use environment, the use, and the type of phase change material.

In addition, although the unit body 110 was previously described as being formed in a cylindrical shape, it is also possible to use a structure formed in the shape of a polygonal column such as a hexagonal column or an octagonal column.

10: circulation unit 11: circulation pump
12: circulation piping 20: supply unit
21: supply pump 22: supply piping
23: outside passage 30: heat storage tank
31: slide door 32: roller
33: circulation flow path 34: supply flow path
40: circulation docking unit 41: circulation pipe
42: circulation operation portion 43: circulation air tight portion
50: supply docking unit 51: supply pipe
52: supply operation portion 53: supply airtight portion
100: heat storage unit 110: unit body
111: heat storage chamber 120: heat storage material
130: inner pin 140: outer pin
150: guide member 151: guide groove
160: cap member 171: temperature sensor
172: communication unit 173: thermoelectric element
200: heat storage module 210: inlet
220: outlet 230: turning the guide
1000: control module 1100: receiver
1200: request unit 1300: detection unit
2000: Management module 2100: Temperature sensor
2200: Communication Department

Claims (5)

A heat storage module having a plurality of heat storage units storing heat, a heat exchange chamber accommodating the plurality of heat storage units, and an inlet and an outlet formed to communicate with the heat exchange chamber;
A heat storage tank formed to receive the heat storage module;
A circulation pipe connecting a heat use place receiving heat through the heat storage module and an inlet of the heat storage module, and installed on a path of the circulation pipe to supply air from the heat use place to the inlet of the heat storage module through the circulation pipe A circulation unit including a circulation pump to move;
A supply pipe connecting the heat use place and the outlet of the heat storage module, and a supply pump installed on a path of the connection heat pipe to move air from the heat use place via the heat storage module to the heat use place through the supply pipe. Supply unit comprising a; heat courier supply device comprising a. According to claim 1,
The supply pump of the supply unit further includes an external air flow passage connected to the outside so that external air is moved to the heat use place through the supply pipe. According to claim 1,
A circulation docking unit including a circulation pipe formed to be connected to an inlet of the heat storage module; And
It further includes a supply docking unit including a supply pipe formed to be connected to the outlet of the heat storage module;
The heat storage tank includes a heat courier supply including a circulation flow path connecting the circulation pipe of the circulation unit and the circulation pipe of the circulation docking unit, and a supply flow path connecting the supply pipe of the supply unit and the supply pipe of the supply docking unit. Device. According to claim 3,
The circulation docking unit further includes a circulation operation unit for moving the circulation pipe forward and backward with respect to the inlet of the heat storage module,
The supply docking unit, a heat courier supply device further comprises a supply operation unit for moving the supply pipe back and forth with respect to the inlet of the heat storage module. According to claim 4,
The circulation docking unit further includes a circulation airtight portion that is airtight between the circulation pipe and the inlet of the heat storage module,
The circulation pipe of the circulation docking unit is formed to have a larger diameter than the inlet of the heat storage module,
The supply docking unit further includes a supply hermetic portion that seals between the supply pipe and the outlet of the heat storage module,
The supply pipe of the supply docking unit is a heat courier supply device formed to have a larger diameter than the outlet of the heat storage module.

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