TWM591598U - Fluid temperature control device - Google Patents

Abstract

This creation aims to disclose a fluid temperature control device, which includes a furnace body, a fluid pipeline, a plurality of regenerators, a burner and a gas control device. The furnace body is heated through the burner, so that the heat storage body provided inside the furnace body stores heat and conducts heat energy to the fluid line, and a heating liquid is output from the fluid line. In addition, the heat storage body further generates a heated gas and transmits it to the gas control device, and the heated gas is converted by the gas control device to output a cold air.

Description

Fluid temperature control device

This creation is about a control device, especially a temperature control device applied to fluid.

Fossil fuels are depleted energy sources. At the present stage, fossil fuels have entered a state of energy crisis in short supply with the development and demand of human society. In addition, in the process of obtaining fossil fuels, it is easy to cause damage to the environment and ecology. In the process of industrial use, fossil fuels also require additional treatment of the pollution generated to avoid excessive damage to the natural environment. For example, the greenhouse effect is a serious damage to the global environment. problem. Therefore, with the rising awareness of environmental protection and the lack of waiting for improvement in the acquisition and use of fossil fuels, how to obtain renewable energy or reduce the use of fossil fuels has become one of the most important issues in the world.

Furthermore, after conventional fossil fuels are burned, only the exhaust gas generated can be discharged into the external environment, and no consideration is given to the further treatment and reuse of exhaust gas. Therefore, if the waste gas can be reprocessed, in addition to greatly reducing pollution to the global environment, the energy generated by waste gas reuse can also be effectively used in other fields, and the effect of completely using fossil fuels can be achieved.

This is the reason why the creators made improvements in view of the problems derived from the above. I think and the idea of creative improvement started to develop solutions, hoping to develop a method that can reduce the use of fossil fuels to effectively heat the liquid and produce fossil fuels. The structural design of the waste gas reprocessing was created after a long time of conceivable fluid temperature control device to serve the public and promote the development of this industry.

One purpose of this creation is to provide a fluid temperature control device, which sets the heat storage body in the first accommodating space for fluid heat conduction heating, to replace the traditional burner to directly heat the fluid, and to shorten the heating time and reduce Pollution emitted by the heating process and reducing the consumption of heating fuel.

An object of this creation is to provide a fluid temperature control device, in which the gas discharged by heating the regenerator is further processed through the gas control device, which can effectively reuse the heated gas to generate cold air as an additional application.

In order to achieve the above-mentioned purposes and effects, this work discloses a fluid temperature control device, which includes: A furnace body includes a first accommodating space and a second accommodating space, the first accommodating space is disposed on one side of the furnace body, and the second accommodating space is disposed on the other side of the furnace body; A fluid pipeline, the ring is arranged outside the first accommodating space; A plurality of heat storage bodies are provided in the first accommodating space; A burner provided in the second accommodating space; and A gas control device is provided on one side of the furnace body; Wherein, the burner heats the first accommodating space, so that the heat storage bodies store heat and conduct heat energy to the fluid pipeline, a heating liquid is output from the fluid pipeline, and the heat storage bodies further generate a heating gas to transmit to The gas control device converts the heating gas to output a cold air.

In addition, this creation discloses a fluid temperature control device, which includes: A furnace body includes a first accommodating space, a second accommodating space and an opening, the first accommodating space is provided on one side of the furnace body, and the second accommodating space is provided on the other side of the furnace body On one side, the opening is provided between the first accommodating space and the second accommodating space, and communicates with the first accommodating space and the second accommodating space; A fluid pipeline, the ring is arranged outside the first accommodating space; A heat storage body, disposed in the first accommodating space, and including a gap, the gap corresponding to the opening; A burner provided in the second accommodating space; and A gas control device is provided on one side of the furnace body; Wherein, the burner heats the heat storage body through the opening in the gap, causes the heat storage body to store heat and conduct heat energy to the fluid line, a heating liquid is output from the fluid line, and the heat storage body further generates a heating gas for transmission To the gas control device, the gas control device converts the heated gas and outputs a cold gas.

In order to make your review committee have a better understanding and understanding of the characteristics and effects of this creation, only the examples and detailed descriptions are accompanied by the following description:

Please refer to the first figure, which is a schematic structural diagram 1 of the first embodiment of the created fluid temperature control device. As shown in the figure, the fluid temperature control device 1 of the present creation includes: a furnace body 10 including a first accommodating space 100 and a second accommodating space 102, the first accommodating space 100 is disposed in one of the furnace bodies 10 On the side, the second accommodating space 102 is provided on the other side of the furnace body 10; a fluid line 12 is provided outside the first accommodating space 100; a plurality of heat storage bodies 14 are provided on the first accommodating space 100; one The burner 16 is provided in the second accommodating space 102; and a gas control device 18 is provided on one side of the furnace body 10; wherein, the burner 16 heats the first accommodating space 100 to accumulate the heat storage bodies 14 and Conducting heat energy to the fluid line 12, a heating liquid 120 is output from the fluid line 12, the heat storage bodies 14 further generate a heating gas 140 and transmit it to the gas control device 18, the gas control device 18 converts the heating gas 140 and outputs a cold air 180.

Please also refer to the second figure, which is a schematic structural diagram 2 of the first embodiment of the created fluid temperature control device. As shown in the figure, the fluid temperature control device 1 of the present invention further includes a base 20 and at least one water storage tank 22. The furnace body 10 is disposed on one side inside the base 20, and the gas control device 18 is disposed on the other side inside the base 20. The water storage tank 22 is disposed on one side of the base 20 and communicates with the fluid line 12 to store the heating liquid 120.

The material of the heat storage body 14 is an ore with heat storage function, such as activated alumina, copper, iron, or one of the above groups.

The above-mentioned burner 16 can be any combustion equipment (such as a gas furnace) that uses natural gas, organic compounds (such as methanol), etc. as a combustion material, and is not limited thereto.

The above-mentioned gas control device 18 may be a refrigeration system (such as an air conditioner) composed of an evaporator, a condenser, a compressor, and a throttle valve. The purpose is to heat the heating gas 140 through the evaporator, condenser, compressor and throttle valve to absorb the heat of the heating gas 140 respectively, and then compress and vaporize the heating gas 140 to form the cold air 180 for the connection of other equipment/environment.

Please refer to the third to fifth diagrams, which are schematic diagrams 1 to 3 of the operation of the first embodiment of the created fluid temperature control device. As shown in the third diagram, first, the burner 16 is started in the second accommodating space 102, and is located below the first accommodating space 100 to perform the combustion heating operation. At this time, after the heat storage body 14 disposed in the first accommodating space 100 is heated, heat is generated in the first accommodating space 100, and at the same time, since the fluid line 12 is looped outside the first accommodating space 100 to contact it, it is possible The first accommodating space 100 conducts the heat generated by the heat storage body 14 to the fluid line 12 to heat the liquid (not shown) conveyed inside the fluid line 12 to form a heating liquid 120.

As shown in the fourth figure, after the liquid disposed in the fluid line 12 contacts the conductive heat energy to generate the heating liquid 120, the heating liquid 120 can be transferred to the water storage tank 22 for storage. Or, if there is no need for further processing and application at this stage, it can also be placed in the fluid line 12. Thereafter, as shown in the fifth figure, the heat storage body 14 disposed in the first accommodating space 100 will also generate heating gas 140 after being heated, and this time can be received by the gas control device 18 communicating with the first accommodating space 100 The heating gas 140 is further used. After the gas control device 18 obtains the heating gas 140, it can process the heating gas 140 according to its own structure to generate cold air 180. The gas control device 18 can also be connected to other equipment to transmit the generated cold air 180 to other equipment or to an indoor space for use as an air conditioner.

Here, the fluid temperature control device 1 of the present invention has the following advantages when activated: 1. The material of the heat storage ore of the heat storage body 14 has the effect of rapid heat storage, so the burner 16 is used to heat the heat storage body 14 of the first accommodating space 100, which is different from the traditional use of the burner 16 to directly isolate the preheated fluid from water Combustion heating method can shorten the heating time more quickly. 2. As the heating time is shortened, the pollution emitted by heating and the consumption of heating fuel are further reduced, and the temperature of the fluid is controlled in a more energy-saving and emission-reducing manner. 3. The gas discharged from the heat storage body 14 after being heated (heating gas 140) is further processed through the gas control device 18, and the heating gas 140 can be effectively reused to generate cold air 180 for additional applications, thereby enhancing additional efficiency.

Please refer to the sixth figure, which is a schematic structural diagram of a second embodiment of the created fluid temperature control device. As shown in the figure, the difference between the second embodiment and the first embodiment of the fluid temperature control device 1 of the present invention is that it further includes a processor 24 and at least one sensing element 26. The processor 24 is disposed on the base 20 On the other side, the sensing element 26 is electrically connected to the processor 24 and is disposed in the first accommodating space 100. After detecting the temperature of the first accommodating space 100, a sensing data 260 is generated. The processor 24 is based on the sensing data 260 opens and closes the burner 16; wherein, the processor 24 may be a computer, and the sensing element 26 may be a temperature sensor.

The operation method of the second embodiment of the present creation is the same as that of the first embodiment, so the differences will be described. The purpose of the sensing element 26 being disposed in the first accommodating space 100 is to detect the temperature in the first accommodating space 100, so new sensing data 260 is always transmitted to the processor 24 during operation. The processor 24 stores a standard value for the heating temperature in the first accommodating space 100. When the processor 24 receives the sensing data 260 and judges that the temperature in the first accommodating space 100 has reached the standard value (or above the standard value) ), the burner 16 can be turned off first to avoid overheating. Similarly, when the processor 24 receives the sensing data 260 and determines that the temperature in the first accommodating space 100 is lower than the standard value, or does not have the heating liquid 120 of the fluid line 12 heated to a preset value, The burner 16 is started again to heat the first accommodating space 100, and the cycle operates.

Please refer to the seventh figure and the eighth figure, which are a schematic structural diagram 1 and a structural schematic diagram 2 of the third embodiment of the created fluid temperature control device. As shown in the figure, the fluid temperature control device 1 of the present invention includes: a furnace body 10 including a first accommodating space 100, a second accommodating space 102, and an opening 104, the first accommodating space 100 is disposed in the furnace On one side of the body 10, the second accommodating space 102 is disposed on the other side of the furnace body 10, the opening 104 is disposed between the first accommodating space 100 and the second accommodating space 104, and communicates with the first accommodating space 100 And a second accommodating space 102; a fluid line 12, the ring is disposed outside the first accommodating space 100; a heat storage body 14' is disposed in the first accommodating space 100, and includes a gap 142', the gap 142' Corresponding to the opening 104; a burner 16, disposed in the second accommodating space 102; and a gas control device 18, disposed on one side of the furnace body 10, and communicating with the first accommodating space 100; wherein, the burner 16 passes through the opening 104 Heats the heat storage body 14' at the notch 142', causes the heat storage body 14' to store heat and conduct heat energy to the fluid line 12, a heating liquid 120 is output from the fluid line 12, and the heat storage body 14' further generates a heating gas 140' for transmission To the gas control device 18, the gas control device 18 converts the heating gas 140' and outputs a cold gas 180.

The operation method of the third embodiment of the present creation is the same as that of the first embodiment, so the differences will be described. The difference between the third embodiment of the fluid temperature control device 1 of the present invention and the first embodiment is that an opening 104 is opened between the first accommodating space 100 and the second accommodating space 102, so that the burner 16 faces the heat storage body 14 'When heating, the flame that can enter the notch 142' through the opening 104 is closer to the heat storage body 14' to accelerate the heating operation of the heat storage body 14'. In addition, the heat storage body 14' also defines a notch 142' to correspond to the opening 104. As shown in the eighth figure, the heat storage body 14' is a hollow cylindrical structure, so the notch 142' just corresponds to the opening 104 of the furnace body 10, and when the burner 16 is burned, the flame enters the opening 104 and the notch 142' for heating . Here, only one heat storage body 14' of the third embodiment needs to be provided, and its structural size may be the same as the first accommodating space 100, or may be slightly smaller than the first accommodating space 100, which is not limited thereto.

Please refer to the ninth figure, which is a schematic structural diagram of a fourth embodiment of the fluid temperature control device created. As shown in the figure, the difference between the fourth embodiment and the first embodiment of the fluid temperature control device 1 of the present invention is that it further includes a thermal processor 28, which is disposed inside the base 20 and on one side of the furnace body 10, and includes A first pipeline 280 and a second pipeline 282 communicate with the gas control device 18 and the second pipeline 282 communicates with the water storage tank 22.

In the fourth embodiment of the present invention, the gas control device 18 is not in communication with the first accommodating space 100 of the furnace body 10, and the fluid line 12 is not in communication with the water storage barrel 22. Instead, the furnace body 10 and the heat processor 28 circulate, and the heating liquid 120 is sent to the heat processor 28 through the fluid line 12, and the heating gas 140 is also sent to the heat processor 28 through the relevant pipe (not shown), and the heat processor 28 The heating liquid 120 and the heating gas 140 are processed so that the heating gas 140 sent to the gas control device 18 through the first line 280 maintains an appropriate temperature, and the heating liquid 120 sent to the water storage tank 22 through the second line 282 maintains a Appropriate temperature. In detail, the heating liquid 120 delivered to the thermal processor 28 is due to the movement of the relevant pipeline of the thermal processor 28, and part of the thermal energy of the heating liquid 120 is received and discharged to the external environment through the thermal conduction characteristics of the pipeline, after which it is adjusted down The heated liquid 120 at a temperature is then transferred from the second pipeline 282 to the water storage tank 22. Similarly, the heating gas 140 delivered to the thermal processor 28 is due to the movement of the relevant pipeline of the thermal processor 28, and part of the thermal energy of the heating gas 140 is received and discharged to the external environment through the thermal conduction characteristics of the pipeline, and then the temperature is reduced The heated gas 140 is then sent from the first pipeline 280 to the gas control device 18.

Since the temperature of the heating liquid 120 and the heating gas 140 transmitted by the furnace body 10 is relatively high, the heating gas 140 is reprocessed by the heat processor 28, so that the temperature of the heating gas 140 sent to the gas control device 18 can be the gas control device 18 The acceptable temperature extends the service life of the gas control device 18. Similarly, by reprocessing the heating liquid 120 through the thermal processor 28, the temperature of the heating liquid 120 delivered to the water storage tank 22 can be a temperature acceptable to the user, and the user can directly use the heating liquid 120 stored in the water storage tank 22 .

In the embodiments described in the above disclosure, the surface of the heat storage body 14/14' may include a plurality of holes (not shown), and the heat storage efficiency of the heat storage body 14/14' can be effectively improved according to the structural design of the holes. In addition, the shape of the heat storage body 14/14' can be correspondingly designed according to the first accommodating space 100, or it can be designed for hexagonal, octagonal, triangular, square, circular and other polygonal structures, and a plurality of single ones Set in the first accommodating space 100, it can be changed according to the needs of users.

1: Fluid temperature control device 10: furnace body 100: first accommodation space 102: second accommodation space 104: opening 12: Fluid line 120: heating liquid 14: Regenerative body 140: heating gas 14’: Regenerative body 140’: heating gas 142’: Notch 16: burner 18: Gas control device 180: air conditioner 20: Dock 22: water storage bucket 24: processor 26: sensing element 28: Thermal processor 280: First pipeline 282: Second pipeline

The first figure: it is a schematic structural diagram 1 of the first embodiment of the fluid temperature control device created in this; The second figure: it is the second structural schematic diagram of the first embodiment of the fluid temperature control device of this creation; The third figure: it is a schematic diagram 1 of the operation of the first embodiment of the fluid temperature control device of this creation; The fourth figure: it is the second schematic diagram of the first embodiment of the fluid temperature control device of the creation; Fifth figure: This is a schematic diagram 3 of the operation of the first embodiment of the fluid temperature control device of this creation; Figure 6: It is a schematic structural diagram of a second embodiment of the fluid temperature control device created in this; Figure 7: It is a schematic structural diagram 1 of the third embodiment of the fluid temperature control device created in this; Figure 8: Schematic diagram 2 of the third embodiment of the created fluid temperature control device; and The ninth figure: it is a schematic structural view of the fourth embodiment of the fluid temperature control device created in this invention.

1: Fluid temperature control device

10: furnace body

100: first accommodation space

102: second accommodation space

12: Fluid line

120: heating liquid

14: Regenerative body

140: heating gas

16: burner

18: Gas control device

180: air conditioner

Claims (10)

A fluid temperature control device, comprising: A furnace body includes a first accommodating space and a second accommodating space, the first accommodating space is disposed on one side of the furnace body, and the second accommodating space is disposed on the other side of the furnace body; A fluid pipeline, the ring is arranged outside the first accommodating space; A plurality of heat storage bodies are provided in the first accommodating space; A burner provided in the second accommodating space; and A gas control device is provided on one side of the furnace body; Wherein, the burner heats the first accommodating space, so that the heat storage bodies store heat and conduct heat energy to the fluid pipeline, a heating liquid is output from the fluid pipeline, and the heat storage bodies further generate a heating gas to transmit to The gas control device converts the heating gas to output a cold air. The fluid temperature control device as described in item 1 of the patent application scope further includes a base, the furnace body is disposed on an inner side of the base, and the gas control device is disposed on the other side of the base. The fluid temperature control device as described in item 1 of the patent application scope, wherein the gas control device is an air conditioner, which receives the heating gas and converts it to generate the cooling air. The fluid temperature control device as described in item 1 of the patent application scope, wherein the materials of the heat storage bodies are one of the group consisting of activated alumina, copper, iron or any combination of the above. The fluid temperature control device as described in item 2 of the patent application scope further includes a processor and at least one sensing element, the processor is disposed on the other side of the base, and the sensing element is electrically connected to the processor And it is arranged in the first accommodating space, and generates a sensing data after detecting the temperature of the first accommodating space, and the processor starts and shuts the burner according to the sensing data. A fluid temperature control device, comprising: A furnace body includes a first accommodating space, a second accommodating space and an opening, the first accommodating space is provided on one side of the furnace body, and the second accommodating space is provided on the other side of the furnace body On one side, the opening is provided between the first accommodating space and the second accommodating space, and communicates with the first accommodating space and the second accommodating space; A fluid pipeline, the ring is arranged outside the first accommodating space; A heat storage body, disposed in the first accommodating space, and including a gap, the gap corresponding to the opening; A burner provided in the second accommodating space; and A gas control device is provided on one side of the furnace body; Wherein, the burner heats the heat storage body through the opening in the gap, causes the heat storage body to store heat and conduct heat energy to the fluid line, a heating liquid is output from the fluid line, and the heat storage body further generates a heating gas for transmission To the gas control device, the gas control device converts the heated gas and outputs a cold gas. The fluid temperature control device as described in item 6 of the patent application scope further includes a base, the furnace body is disposed on the inner side of the base, and the gas control device is disposed on the other side of the base. The fluid temperature control device as described in item 6 of the patent application scope, wherein the gas control device is an air conditioner, which receives the heating gas and converts it to generate the cooling air. The fluid temperature control device as described in item 6 of the patent application scope, wherein the material of the heat storage body is one of the group consisting of activated alumina, copper, iron or any combination of the above. The fluid temperature control device as described in item 7 of the patent application scope further includes a processor and at least one sensing element, the processor is disposed on the other side of the base, and the sensing element is electrically connected to the processor And it is arranged in the first accommodating space, and generates a sensing data after detecting the temperature of the first accommodating space, and the processor starts and shuts the burner according to the sensing data.

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