CN214371023U - Solid heat exchange device - Google Patents

Abstract

The utility model discloses a solid heat transfer device, including solar panel, solar panel's bottom surface is equipped with solid heat-retaining main part, the inside staggered distribution of solid heat-retaining main part has first runner and second runner, the both ends of first runner and second runner communicate with the support piece that is fixed in solid heat-retaining main part both ends respectively. The utility model discloses in, combine solar panel and solid heat-retaining main part, utilize solar panel to carry out effective utilization to solar energy, later on the rethread heat-conducting layer transmits heat energy to solid heat-retaining main part, solid heat-retaining main part overlaps and places, can effectively utilize the cubical space, improve space utilization, solid heat-retaining main part is after absorbing heat energy, the medium that flows through first runner and second runner carries out the heat exchange, because first runner and the crisscross setting of second runner, and the flow direction of internal medium is opposite, thereby make each partial heat exchange in the solid heat-retaining main part all comparatively balanced, and then improve exchange efficiency.

Description

Solid heat exchange device

Technical Field

The utility model relates to a heat exchange device field, concretely relates to solid heat transfer device.

Background

Conventional energy is limited, and under the premise that the requirement on the environment is higher and higher, the shortage of energy is more and more obvious, and renewable energy, especially relatively unlimited solar energy, is more and more valued and favored by people.

However, the maximum utilization of the heat energy carried by the solar energy has the defects that the energy supply is unstable, and the conversion efficiency of the heat energy is to be improved, thereby limiting the wide utilization of the solar heat energy.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a solid heat transfer device to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

solid heat transfer device, including solar panel, solar panel's bottom surface is equipped with solid heat-retaining main part, the inside staggered distribution of solid heat-retaining main part has first runner and second runner, the both ends of first runner and second runner respectively with be fixed in the support piece intercommunication at solid heat-retaining main part both ends, be equipped with the first inlet tube and the first outlet pipe that correspond first runner both ends and correspond second inlet tube and the second outlet pipe of second runner on the support piece, support piece's top extends to the top of solid heat-retaining main part to with the detachable fixed connection in solar panel's both ends, be equipped with the heat-conducting layer between solid heat-retaining main part and the solar panel.

Furthermore, the first flow channel and the second flow channel are both L-shaped structures, one end of the first flow channel penetrates through the end part of the solid heat storage main body, and the other end of the first flow channel penetrates through the bottom surface of the solid heat storage main body.

Furthermore, the cross section of the support piece is of an L-shaped structure, cavity channels are arranged inside the vertical part and inside the horizontal part of the support piece and are respectively communicated with the corresponding first flow channel and the corresponding second flow channel, and the cavity channels are communicated with the corresponding first water inlet pipe, the corresponding first water outlet pipe, the corresponding second water inlet pipe and the corresponding second water outlet pipe.

Furthermore, the ports of the first flow channel and the second flow channel, which are positioned on the bottom surface of the solid heat storage main body, are respectively communicated with the cavities at the two ends and positioned inside the horizontal part of the support member.

Furthermore, the cavity channels in the vertical part of the supporting piece are respectively communicated with the corresponding first water outlet pipe and the second water outlet pipe, and the cavity channels in the horizontal part of the supporting piece are respectively communicated with the corresponding first water inlet pipe and the second water inlet pipe.

Further, the length and width dimensions of the solar panel are not less than the length and width dimensions of the solid heat storage body.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses in, combine solar panel and solid heat-retaining main part, utilize solar panel to carry out effective utilization to solar energy, later on the rethread heat-conducting layer with heat energy transfer to solid heat-retaining main part, can effectively avoid solar panel overheated influence photoelectric conversion efficiency on the one hand, on the other hand solar panel and solid heat-retaining main part overlap and place, can effectively utilize the cubical space, improve space utilization, solid heat-retaining main part is after absorbing heat energy, the medium that flows through first runner and second runner carries out the heat exchange, because first runner and the crisscross setting of second runner, and inside medium flow opposite direction, thereby make each partial heat exchange in the solid heat-retaining main part all comparatively balanced, and then improve exchange efficiency.

Drawings

FIG. 1 is a front view of a solid heat exchange device;

FIG. 2 is a sectional view taken along line A-A.

In the figure: 1. a solar panel; 2. a solid heat storage body; 3. a first flow passage; 4. a second flow passage; 5. a support member; 6. a first water inlet pipe; 7. a first water outlet pipe; 8. a second water inlet pipe; 9. a second water outlet pipe; 10. a heat conductive layer; 11. a cavity channel.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by the skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides a technical solution:

solid heat transfer device, including solar panel 1, solar panel 1's bottom surface is equipped with solid heat-retaining main part 2, the inside staggered distribution of solid heat-retaining main part 2 has first flow channel 3 and second flow channel 4, the both ends of first flow channel 3 and second flow channel 4 respectively with be fixed in the 5 intercommunications of support piece at 2 both ends of solid heat-retaining main part, be equipped with first inlet tube 6 and the first outlet pipe 7 that correspond 3 both ends of first flow channel on support piece 5 and correspond second inlet tube 8 and the second outlet pipe 9 of second flow channel 4, support piece 5's top extends to the top of solid heat-retaining main part 2, and with the detachable fixed connection in solar panel 1 both ends, be equipped with heat-conducting layer 10 between solid heat-retaining main part 2 and the solar panel 1.

In this scheme, combine solar panel 1 and solid heat-retaining main part 2, utilize solar panel 1 to carry out effective utilization to solar light ability, later on through heat-conducting layer 10 with heat energy transfer to solid heat-retaining main part 2 on, on the one hand, can effectively avoid solar panel 1 overheated influence photoelectric conversion efficiency, on the other hand solar panel 1 and solid heat-retaining main part 2 overlap and place, can effectively utilize the cubical space, improve space utilization, solid heat-retaining main part 2 is after absorbing heat energy, the medium that flows through first runner 3 and second runner 4 carries out the heat exchange, because first runner 3 and 4 crisscross settings of second runner, and the inside medium flow opposite direction, thereby make each partial heat exchange on the solid heat-retaining main part 2 all comparatively balanced, and then improve exchange efficiency.

In addition, the solid heat storage body 2 can be combined with other heat dissipation devices or systems, such as industrial waste heat, so that the solid heat storage body 2 can operate more efficiently.

The first flow channel 3 and the second flow channel 4 are both in an L-shaped structure, one end of the first flow channel penetrates through the end of the solid heat storage main body 2, and the other end of the first flow channel penetrates through the bottom surface of the solid heat storage main body 2, so that the ports of the first flow channel 3 and the second flow channel 4 are staggered, and the pipelines are connected conveniently.

The cross section of the support piece 5 is of an L-shaped structure, cavity channels 11 are arranged in the vertical part and the horizontal part of the support piece 5, the cavity channels 11 are respectively communicated with the corresponding first flow channel 3 and the corresponding second flow channel 4, the cavity channels 11 are communicated with the L-shaped support piece 5 through the corresponding first water inlet pipe 6, the corresponding first water outlet pipe 7, the corresponding second water inlet pipe 8 and the corresponding second water outlet pipe 9, and the support piece 2 has a better supporting effect and can better distribute the positions of the cavity channels 11.

The ports of the first flow channel 3 and the second flow channel 4 on the bottom surface of the solid heat storage body 2 are respectively communicated with the cavity channels 11 at the two ends and inside the horizontal part of the support 5, so that the positions of the first flow channel 3 and the second flow channel 4 are oppositely arranged, and the flow directions of the media inside are opposite.

The cavity 11 in the vertical part of the support member 5 is respectively communicated with the corresponding first water outlet pipe 7 and the second water outlet pipe 9, the cavity 11 in the horizontal part of the support member 5 is respectively communicated with the corresponding first water inlet pipe 6 and the second water inlet pipe 8, so that the media in the first flow channel 3 and the second flow channel 4 are opposite in flow direction, and the purpose of relatively balanced heat exchange of all parts on the solid heat storage main body 2 is achieved.

The length and width dimensions of the solar panel 1 are not less than those of the solid heat storage body 2, so that the solar panel 1 can better cover the top surface of the solid heat storage body 2, and the same length and width dimensions are preferred.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which includes the appended claims and their equivalents.

Claims (6)

1. Solid heat transfer device, including solar panel (1), its characterized in that: the bottom surface of solar panel (1) is equipped with solid heat-retaining main part (2), the inside staggered distribution of solid heat-retaining main part (2) has first runner (3) and second runner (4), the both ends of first runner (3) and second runner (4) communicate with support piece (5) that are fixed in solid heat-retaining main part (2) both ends respectively, be equipped with first inlet tube (6) and first outlet pipe (7) that correspond first runner (3) both ends on support piece (5) and correspond second inlet tube (8) and second outlet pipe (9) of second runner (4), the top of support piece (5) extends to the top of solid heat-retaining main part (2) to with the detachable fixed connection in both ends of solar panel (1), be equipped with heat-conducting layer (10) between solid heat-retaining main part (2) and solar panel (1).

2. The solid heat exchange device of claim 1, wherein: the first flow channel (3) and the second flow channel (4) are both L-shaped structures, one end of each flow channel penetrates through the end portion of the solid heat storage main body (2), and the other end of each flow channel penetrates through the bottom face of the solid heat storage main body (2).

3. The solid heat exchange device of claim 2, wherein: the cross section of support piece (5) is L shape structure, the inside of the vertical portion of support piece (5) and the inside of horizontal part all are equipped with chamber way (11), and chamber way (11) communicate with corresponding first runner (3) and second runner (4) respectively, chamber way (11) and corresponding first inlet tube (6), first outlet pipe (7), second inlet tube (8) and second outlet pipe (9) intercommunication.

4. The solid heat exchange device of claim 3, wherein: the first flow channel (3) and the second flow channel (4) are positioned at the ports on the bottom surface of the solid heat storage main body (2) and are respectively communicated with the cavity channels (11) which are positioned at the two ends and are positioned inside the horizontal part of the supporting piece (5).

5. The solid heat exchange device of claim 2, wherein: the water inlet pipe is characterized in that a cavity (11) in the vertical part of the support piece (5) is communicated with the corresponding first water outlet pipe (7) and the second water outlet pipe (9) respectively, and a cavity (11) in the horizontal part of the support piece (5) is communicated with the corresponding first water inlet pipe (6) and the second water inlet pipe (8) respectively.

6. The solid heat exchange device of claim 1, wherein: the length and width dimensions of the solar panel (1) are not less than those of the solid heat storage main body (2).

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