CN109194197B - Thermoelectric power generation equipment - Google Patents

Abstract

The application discloses thermoelectric generation equipment, including furnace and two heat transfer plates, the heat transfer plate is including being heated by heat and heat transfer portion, and two heat transfer portions that mutually paste form the group that generates heat still include: one side of the thermoelectric generation piece is abutted against the corresponding heat transfer part; the cooling element is abutted against one side of the thermoelectric generation piece, which is opposite to the heat transfer part; a pressing plate; a controller; the two pressing plates on two sides of the heating group are fixed through a first fastening piece and a second fastening piece, the first fastening piece is in line contact with the through hole, and the second fastening piece is positioned on the outer sides of the heat transfer plate and the cooling element and is not in contact with the heat transfer plate and the cooling element. The second fastener of this application does not contact with heat transfer plate and cooling element, can not influence the heat transfer of heat transfer portion, also can not influence cooling element's heat dissipation work, and first fastener is through the form with the through-hole line contact, for current face contact, can effectively reduce the heat of transfer, can reduce the influence to heat transfer portion and cooling element as far as possible.

Description

Thermoelectric power generation equipment

Technical Field

The invention relates to the field of power generation, in particular to thermoelectric power generation equipment.

Background

With the development of scientific technology, various illuminators and portable electronic products are more and more abundant, people are more and more dependent on the illuminators and the electronic products, but in the field or in the condition of power failure, etc., the power supplies of the illuminators and the electronic products are often not used because the illuminators and the electronic products cannot be supplemented with electric energy.

The seebeck effect refers to a thermoelectric phenomenon that causes a voltage difference between two substances due to a temperature difference of two different electrical conductors or semiconductors. The thermoelectric generation sheet converts heat energy into electric energy by utilizing the Seebeck effect, and in order to generate electric energy in places such as the field, the thermoelectric generation sheet can be used for designing a biomass fuel thermoelectric generator by utilizing the characteristics of the thermoelectric generation sheet.

In the prior art, a thermoelectric generator generally comprises a heat transfer plate, the heat transfer plate is abutted against the hot end of a thermoelectric generation sheet, and the cold end of the thermoelectric generation sheet is abutted against a cooling element, so that the heat transfer plate and the cooling element are fixed by a fastener for fixing the structure reliably, and the thermoelectric generation sheet is clamped. Under this kind of structural style, the fastener is the face contact with the heat transfer board, and area of contact is big, has a large amount of heat energy to pass through the fastener conduction to cooling element, not only extravagant heat energy, can reduce cooling element's cooling efficiency moreover, and then reduces the generating efficiency of thermoelectric generation piece.

Disclosure of Invention

The invention aims at solving the problems and overcomes the defects, and provides temperature difference power generation equipment.

The technical scheme adopted by the invention is as follows:

the utility model provides a thermoelectric power generation equipment, includes furnace and installs two heat transfer plates in furnace upper portion, the heat transfer plate is including being located the heat portion in the middle and being located the heat transfer portion at heat portion both ends, and the heat transfer portion of two heat transfer plates is mutually leaned on, and two heat transfer portions that mutually lean on form the group that generates heat, and the heat portion that is heated of two heat transfer plates forms hollow columnar structure, and hollow columnar structure is located the furnace directly over for receive the heat of flame transmission, thermoelectric power generation equipment still includes:

the thermoelectric generation pieces are arranged on two sides of the heating group, and one side of each thermoelectric generation piece is abutted against the corresponding heat transfer part;

the cooling element is abutted against one side of the thermoelectric generation piece, which is opposite to the heat transfer part;

the pressing plate is arranged on one side of the cooling element, which is opposite to the thermoelectric generation sheet, and the two pressing plates on the two sides of the heating group are mutually fixed; and

the controller is electrically connected with the thermoelectric generation sheet;

the heating group is provided with a through hole penetrating through the two heat transfer plates, the two pressing plates on two sides of the heating group are fixed through a first fastening piece and a second fastening piece, the first fastening piece penetrates through the through hole, the first fastening piece is in line contact with the through hole, and the second fastening piece is positioned on the outer sides of the heat transfer plates and the cooling elements and is not in contact with the heat transfer plates and the cooling elements.

Working principle of thermoelectric generation equipment: the furnace is used for supplying fuel to burn, flame produced by burning can heat the heated part of the heat transfer plate, the heated part transfers heat to the heat transfer part, the heat transfer part is attached to the hot end of the thermoelectric generation piece, the cooling element is attached to the cold end of the thermoelectric generation piece, thus the temperature difference can be produced at two sides of the thermoelectric generation piece, the voltage difference can be produced, and the controller electrically connected with the thermoelectric generation piece can provide electric energy to the outside.

The utility model provides a two clamp plates are used for compressing tightly cooling element, thermoelectric generation piece, heat transfer portion and fix, wherein can inject the position of heat transfer plate through first fastener, prevent to go up and down left and right sides drunkenness, can firmly fix two clamp plates through the second fastener, the second fastener does not contact with heat transfer plate and cooling element, can not influence the heat transfer of heat transfer portion, also can not influence cooling element's heat dissipation work, first fastener is through the form with through hole line contact, for the current face contact, can effectively reduce the heat of transmission, can reduce the influence to heat transfer portion and cooling element as far as possible.

In practice, it is preferred that there be only one first fastener, or only two first fasteners.

In one embodiment of the invention, the cooling element comprises a cooling body, a heat dissipation channel which is bent back and forth is arranged in the cooling body, a water inlet and a water outlet are respectively arranged at two ends of the heat dissipation channel, the thermoelectric power generation equipment further comprises a water tank, a heat exchanger and a water pump, the water outlet of the water tank is communicated with the water inlet of each cooling body through a pipeline, the water outlet of each cooling body is communicated with the water inlet of the heat exchanger, the water outlet of the heat exchanger is communicated with the water inlet of the water tank, and the water pump is used for driving the water tank, the cooling element and the water in the heat exchanger to circularly flow.

The water tank can store more water, makes the water circulation flow through the water pump, can dispel the heat and cool down to the thermoelectric generation piece after the water gets into cooling element, and the hot water that comes out from cooling element gets into the heat exchanger, can carry out heating operation through the heat exchanger, and the water that finally comes out from the heat exchanger gets into the water tank. With the use of the thermoelectric power generation equipment, the water in the water tank can be heated slowly, and the user can use the warm water or the hot water in the water tank.

In one embodiment of the present invention, the water pump is electrically connected to the controller.

In one embodiment of the invention, the heat exchanger comprises a heat exchange pipeline and a fan arranged at one side of the heat exchange pipeline and used for blowing air to the heat exchange pipeline, the heat exchange pipeline comprises a flat water pipe which is bent back and forth, and the outer side wall of the water pipe is provided with heat exchange fins; the fan is electrically connected with the controller.

The flat water pipe of reciprocal buckling, and set up heat transfer fin on the lateral wall of water pipe, this kind of structure can improve heat exchange efficiency, and the fan is at the during operation, and the wind that passes through the heat transfer pipeline can be reliably rapid heating to the wind that the heat exchanger blew out is hot-blast. The heating mode is safe and reliable, and the problem of harmful gas is avoided.

In one embodiment of the invention, the thermoelectric power generation device further comprises a housing sleeved outside the hollow columnar structure, wherein an installation space is formed between the inner side wall of the housing and the outer side wall of the hollow columnar structure, and a heat insulation material is installed in the installation space.

Through setting up the shell and can forming installation space and install insulating material, can prevent like this that cavity columnar structure from influencing the high-efficient work of thermoelectric generation structure, also can prevent to scald the user.

In one embodiment of the present invention, the housing has a recess through which the heat transfer portion passes; the heat insulation material is heat insulation cotton.

In one embodiment of the invention, the furnace is internally provided with a fire grate, the side wall of the furnace is provided with an opening, and the opening is provided with a cover plate.

In one embodiment of the invention, a supporting frame is installed at the lower part of the hearth.

In an embodiment of the invention, the hollow columnar structure is an elliptical column, a circular column or a rectangular column.

In one embodiment of the invention, the upper end surface of the hearth is provided with a mounting groove, and the lower part of the hollow columnar structure is sleeved in the mounting groove and fixed with the hearth through screws. The mounting structure is simple and reliable.

In practical use, when the heat transfer part extends to the mounting groove, the mounting groove can be provided with an avoidance port for embedding the heat transfer part.

In practical use, the intelligent control system further comprises a storage battery electrically connected with the controller.

The application also discloses a thermoelectric power generation equipment's application method for at outdoor electricity generation and for the tent internal heat supply, specifically do: the main body of the thermoelectric power generation equipment is placed outside the tent, the water tank and the heat exchanger are only placed in the tent, fuel is added into the hearth, the water pump and the fan are turned on after the fuel is combusted for 1-2 min, heating operation is carried out, and the heat exchanger blows hot air after the fan works.

The beneficial effects of the invention are as follows: working principle of thermoelectric generation equipment: the furnace is used for supplying fuel to burn, flame produced by burning can heat the heated part of the heat transfer plate, the heated part transfers heat to the heat transfer part, the heat transfer part is attached to the hot end of the thermoelectric generation piece, the cooling element is attached to the cold end of the thermoelectric generation piece, thus the temperature difference can be produced at two sides of the thermoelectric generation piece, the voltage difference can be produced, and the controller electrically connected with the thermoelectric generation piece can provide electric energy to the outside.

The utility model provides a two clamp plates are used for compressing tightly cooling element, thermoelectric generation piece, heat transfer portion and fix, wherein can inject the position of heat transfer plate through first fastener, prevent to go up and down left and right sides drunkenness, can firmly fix two clamp plates through the second fastener, the second fastener does not contact with heat transfer plate and cooling element, can not influence the heat transfer of heat transfer portion, also can not influence cooling element's heat dissipation work, first fastener is through the form with through hole line contact, for the current face contact, can effectively reduce the heat of transmission, can reduce the influence to heat transfer portion and cooling element as far as possible.

Description of the drawings:

FIG. 1 is a schematic diagram of a thermoelectric generation device;

FIG. 2 is a schematic view of another angle of a thermoelectric generation device;

FIG. 3 is a schematic diagram of a thermoelectric generation device circulation waterway;

FIG. 4 is a schematic view of a heat exchanger;

FIG. 5 is a schematic illustration of a heat exchange circuit;

FIG. 6 is a schematic view of a furnace.

The reference numerals in the drawings are as follows:

1. a furnace; 2. a heat transfer plate; 3. a heat receiving unit; 4. a heat transfer section; 5. a heating group; 6. a hollow columnar structure; 7. a housing; 8. a notch; 9. a through hole; 10. a first fastener; 11. thermoelectric generation piece; 12. a cooling element; 13. a second fastener; 14. a pressing plate; 15. a support frame; 16. an opening; 17. a cover plate; 18. an installation space; 19. cooling the body; 20. a water inlet for cooling the body; 21. a water outlet of the cooling body; 22. a fire grate; 23. a water tank; 24. a water pump; 25. a heat exchanger; 26. a heat exchange pipeline; 27. a blower; 28. a water pipe; 29. a heat exchange fin; 30. a mounting groove; 31. and an avoidance port.

The specific embodiment is as follows:

the present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 1, a thermoelectric power generation device, including a furnace 1 and two heat transfer plates 2 installed on the upper portion of the furnace 1, the heat transfer plates 2 including a heat receiving portion 3 located in the middle and heat transfer portions 4 located at two ends of the heat receiving portion 3, the heat transfer portions 4 of the two heat transfer plates 2 being mutually attached, the two heat transfer portions 4 being mutually attached forming a heat generating group 5, the heat receiving portions 3 of the two heat transfer plates 2 forming a hollow columnar structure 6, the hollow columnar structure 6 being located directly above the furnace 1 for receiving heat transferred by flames, the thermoelectric power generation device further comprising:

the thermoelectric generation pieces 11 are arranged on two sides of the heating group 5, and one side of each thermoelectric generation piece 11 is abutted against the corresponding heat transfer part 4;

a cooling element 12 which is abutted against one side of the thermoelectric generation sheet 11 facing away from the heat transfer portion 4;

the pressing plates 14 are arranged on one side of the cooling element 12, which is opposite to the thermoelectric generation piece 11, and the two pressing plates 14 on two sides of the heating group 5 are mutually fixed; and

a controller (not shown) electrically connected to the thermoelectric generation sheet 11;

the heat generating set 5 has a through hole 9 penetrating the two heat transfer plates 2, and two pressing plates 14 on both sides of the heat generating set 5 are fixed by a first fastener 10 and a second fastener 13, the first fastener 10 penetrates the through hole 9, the first fastener 10 is in line contact with the through hole 9, and the second fastener 13 is located outside the heat transfer plates 2 and the cooling element 12 and is not in contact with the heat transfer plates 2 and the cooling element 12.

Working principle of thermoelectric generation equipment: the furnace 1 is used for supplying fuel to burn, flame generated by burning can heat the heated part 3 of the heat transfer plate 2, the heated part 3 transfers heat to the heat transfer part 4, the heat transfer part 4 is abutted against the hot end of the thermoelectric generation piece 11, the cooling element 12 is abutted against the cold end of the thermoelectric generation piece 11, thus, temperature difference can be generated at two sides of the thermoelectric generation piece 11, voltage difference can be generated, and a controller electrically connected with the thermoelectric generation piece 11 can provide electric energy to the outside.

The two pressing plates 14 are used for pressing and fixing the cooling element 12, the thermoelectric generation piece 11 and the heat transfer part 4, wherein the position of the heat transfer plate 2 can be limited through the first fastening piece 10, the upper, lower, left and right movement is prevented, the two pressing plates 14 can be firmly fixed through the second fastening piece 13, the second fastening piece 13 is not contacted with the heat transfer plate 2 and the cooling element 12, the heat transfer of the heat transfer part 4 is not influenced, the heat dissipation work of the cooling element 12 is not influenced, the first fastening piece 10 is in line contact with the through hole 9, compared with the existing surface contact, the heat transferred can be effectively reduced, and the influence on the heat transfer part 4 and the cooling element 12 can be reduced as far as possible.

In practice, it is preferred that there be only one first fastener 10, or only two first fasteners 10.

As shown in fig. 1, 2 and 3, in this embodiment, the cooling element 12 includes cooling bodies 19, the cooling bodies 19 have heat dissipation channels bent back and forth, two ends of each heat dissipation channel are respectively a water inlet 20 and a water outlet 21, the thermoelectric power generation device further includes a water tank 23, a heat exchanger 25 and a water pump 24, the water outlet of the water tank 23 is communicated with the water inlet of each cooling body 19 through a pipeline, the water outlet 20 of each cooling body 19 is communicated with the water inlet of the heat exchanger 25, the water outlet 21 of the heat exchanger 25 is communicated with the water inlet of the water tank 23, and the water pump 24 is used for driving the water tank 23, the cooling element 12 and the water in the heat exchanger 25 to circulate.

The water tank 23 can store more water, the water can circulate through the water pump 24, the water can dispel the heat and cool to the thermoelectric generation sheet 11 after entering the cooling element 12, the hot water that comes out from the cooling element 12 enters the heat exchanger 25, can carry out heating operation through the heat exchanger 25, and finally the water that comes out from the heat exchanger 25 enters the water tank 23. With the use of the thermoelectric power generation device, the water in the water tank 23 is slowly heated, and the user can use warm water or hot water in the water tank 23.

In this embodiment, the water pump 24 is electrically connected to the controller.

As shown in fig. 3, 4 and 5, in the present embodiment, the heat exchanger 25 includes a heat exchange pipeline 26 and a fan 27 disposed at one side of the heat exchange pipeline 26 for blowing air to the heat exchange pipeline 26, the heat exchange pipeline 26 includes a flat water pipe 28 which is reciprocally bent, and the outer side wall of the water pipe 28 has heat exchange fins 29; the blower 27 is electrically connected to the controller.

The flat water pipe 28 of buckling reciprocally, and set up heat transfer fin 29 on the lateral wall of water pipe 28, this kind of structure can improve heat exchange efficiency, and fan 27 during operation, the wind through heat transfer pipeline 26 can be reliably and rapidly heated to the wind that heat exchanger 25 blown out is hot-blast. The heating mode is safe and reliable, and the problem of harmful gas is avoided.

As shown in fig. 1 and 2, in the present embodiment, the thermoelectric generation device further includes a housing 7 that is sleeved outside the hollow columnar structure 6, and an installation space 18 is formed between an inner side wall of the housing 7 and an outer side wall of the hollow columnar structure 6, and a heat insulating material (not shown in the drawings) is installed in the installation space 18.

The installation space 18 can be formed by arranging the housing 7 to install the heat insulating material, so that the hollow columnar structure 6 can be prevented from affecting the efficient operation of the thermoelectric generation structure, and the user can be prevented from being scalded.

As shown in fig. 1, in the present embodiment, the housing 7 has a recess 8 through which the heat transfer portion 4 passes; the heat insulating material is heat insulating cotton.

In the present embodiment, as shown in fig. 1, the furnace 1 is provided with a grate 22, the side wall of the furnace 1 is provided with an opening 16, and a cover plate 17 is arranged at the opening 16.

As shown in fig. 1, 2 and 6, in the present embodiment, a supporting frame 15 is installed at the lower portion of the furnace 1.

In this embodiment, the hollow columnar structure 6 is an elliptical column, a circular column or a rectangular column.

As shown in fig. 6, in the present embodiment, the upper end surface of the furnace 1 has a mounting groove 30, and the lower portion of the hollow columnar structure 6 is sleeved in the mounting groove 30 and fixed to the furnace 1 by screws. The mounting structure is simple and reliable. In this embodiment, the mounting groove 30 is provided with a relief port 31, and the relief port 31 is used for fitting the heat transfer portion 4.

In practical use, the intelligent control system further comprises a storage battery electrically connected with the controller.

The application also discloses a thermoelectric power generation equipment's application method for at outdoor electricity generation and for the tent internal heat supply, specifically do: the main body of the thermoelectric power generation equipment is placed outside the tent, only the water tank 23 and the heat exchanger 25 are placed in the tent, fuel is added into the hearth 1, the water pump 24 and the fan 27 are turned on after the main body is combusted for 1-2 min, heating operation is performed, and the heat exchanger 25 blows hot air after the fan 27 works.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover all equivalent structures as modifications within the scope of the invention, either directly or indirectly, as may be contemplated by the present invention.

Claims (7)

1. The utility model provides a thermoelectric power generation equipment, its characterized in that includes furnace and installs two heat transfer plates in furnace upper portion, the heat transfer plate is including being located the heat portion in the middle and being located the heat transfer portion at heat portion both ends, and the heat transfer portion of two heat transfer plates is mutually leaned on, and two heat transfer portions that mutually lean on form the group that generates heat, and the heat portion of two heat transfer plates forms hollow columnar structure, and hollow columnar structure is located the furnace directly over for receive the heat of flame transmission, thermoelectric power generation equipment still includes:

the thermoelectric generation pieces are arranged on two sides of the heating group, and one side of each thermoelectric generation piece is abutted against the corresponding heat transfer part;

the cooling element is abutted against one side of the thermoelectric generation piece, which is opposite to the heat transfer part;

the pressing plate is arranged on one side of the cooling element, which is opposite to the thermoelectric generation sheet, and the two pressing plates on the two sides of the heating group are mutually fixed; and

the controller is electrically connected with the thermoelectric generation sheet;

the heating group is provided with a through hole penetrating through the two heat transfer plates, the two pressing plates on the two sides of the heating group are fixed through a first fastening piece and a second fastening piece, the first fastening piece penetrates through the through hole, the first fastening piece is in line contact with the through hole, and the second fastening piece is positioned on the outer sides of the heat transfer plates and the cooling elements and is not in contact with the heat transfer plates and the cooling elements;

the cooling element comprises cooling bodies, wherein the cooling bodies are internally provided with heat dissipation channels which are bent in a reciprocating manner, two ends of each heat dissipation channel are respectively provided with a water inlet and a water outlet, the thermoelectric power generation equipment further comprises a water tank, a heat exchanger and a water pump, the water outlets of the water tank are communicated with the water inlets of the cooling bodies through pipelines, the water outlets of the cooling bodies are communicated with the water inlets of the heat exchanger, the water outlets of the heat exchanger are communicated with the water inlets of the water tank, and the water pump is used for driving the water tank, the cooling elements and the water in the heat exchanger to circularly flow;

the water pump is electrically connected with the controller;

the heat exchanger comprises a heat exchange pipeline and a fan arranged at one side of the heat exchange pipeline and used for blowing air to the heat exchange pipeline, the heat exchange pipeline comprises a flat water pipe which is bent back and forth, and the outer side wall of the water pipe is provided with heat exchange fins; the fan is electrically connected with the controller.

2. The thermoelectric generation device of claim 1 further comprising a housing that is externally sleeved outside the hollow columnar structure, wherein an installation space is formed between an inner side wall of the housing and an outer side wall of the hollow columnar structure, and wherein a thermal insulation material is installed in the installation space.

3. The thermoelectric generation device according to claim 2, wherein the housing has a recess through which the heat transfer portion passes; the heat insulation material is heat insulation cotton.

4. The thermoelectric generation device of claim 1 wherein the furnace has a grate therein, the side wall of the furnace has an opening, and the opening is provided with a cover plate.

5. The thermoelectric generation device of claim 4 wherein a support frame is mounted to the lower portion of the furnace.

6. The thermoelectric generation apparatus of claim 1 wherein the hollow columnar structure is an oval column, a circular column, or a rectangular column.

7. The thermoelectric generation equipment of claim 1, wherein the upper end face of the hearth is provided with a mounting groove, and the lower part of the hollow columnar structure is sleeved in the mounting groove and fixed with the hearth through screws.