CN113675803A - Resistance to compression heat dissipation bus duct - Google Patents

Abstract

The invention discloses a compression-resistant heat dissipation bus duct, which comprises an upper shell and a lower shell, wherein waterproof parts are arranged between two ends of the upper shell and the lower shell, copper bars are arranged in the upper shell and the lower shell, two ends of each copper bar respectively penetrate through the corresponding waterproof parts, a heat dissipation box is fixedly connected to the top of the upper shell, a heat dissipation fan is arranged at the inner top of the heat dissipation box, fixing mechanisms are symmetrically arranged at two inner ends of the upper shell and the lower shell, and a wire arrangement plate is arranged between the two fixing mechanisms. The problem of slow heat dissipation is faced with a large amount of heat.

Description

Resistance to compression heat dissipation bus duct

Technical Field

The invention relates to the technical field of bus ducts, in particular to a compression-resistant heat dissipation bus duct.

Background

The bus duct is a closed metal device formed from copper and aluminium bus posts, and is used for distributing large power for all elements of decentralized system, and in the indoor low-voltage power transmission main line engineering project the wire and cable can be increasingly substituted.

The current resistance to compression heat absorption bus duct that application number is 201520868635.3 discloses sets up last closing plate into the arc, and lower closing plate embeds the strengthening rib, has strengthened the compressive capacity, and JRF aluminium oxide ceramic layer has the heat absorption function, can transmit the heat to the heat absorption cotton, dispels the heat fast through the good heat dissipation function of aluminium base board, and aluminium base board still is equipped with the recess, has strengthened the radiating effect. In addition, the heat generated between the conductors can be buffered, noise is prevented from being generated, and stable current transmission is guaranteed.

Disclosure of Invention

The invention aims to solve the problems and provides a compression-resistant heat dissipation bus duct.

In order to achieve the purpose, the invention adopts the following technical scheme:

a compression-resistant heat dissipation bus duct comprises an upper shell and a lower shell, wherein waterproof parts are arranged between two ends of the upper shell and the lower shell, side panels are connected to two sides of the two waterproof parts, copper bars are arranged in the upper shell and the lower shell, two ends of each copper bar penetrate through the corresponding waterproof parts respectively, a heat dissipation box is fixedly connected to the top of the upper shell, a heat dissipation fan is arranged at the inner top of the heat dissipation box, fixing mechanisms are symmetrically arranged at the upper end and the lower end of the inner parts of the upper shell and the lower shell, a wire arrangement plate is arranged between the two fixing mechanisms, a plurality of heat collection tubes are fixedly connected to the two fixing mechanisms, a plurality of air suction nozzles are connected to one side, close to the wire arrangement plate, of each heat collection tube at equal intervals, a heat absorption tube is connected to the bottom end of the heat dissipation box, one end, after penetrating through the upper shell, of each heat absorption tube is connected with the corresponding heat collection tube at the top, a plurality of first wire arrangement grooves and a plurality of second wire arrangement grooves are formed in the surfaces of the upper end and the upper end of the wire arrangement plate at equal intervals respectively, a plurality of first winding displacement groove and second winding displacement groove are crisscross distribution.

Preferably, the upper and lower both ends of winding displacement board all are equipped with a plurality of bunched line areas, every the both ends in bunched line area all are connected with the connecting piece, every the connecting piece all with winding displacement board fixed connection, every the bunched line area all sets up the top that corresponds first winding displacement groove and the bottom of second winding displacement groove.

Preferably, the fixing mechanism comprises a plurality of U-shaped frames, every two adjacent U-shaped frames are fixedly connected with connecting columns and positioning plates, the positioning plates are fixedly connected with the inner walls of the two sides of each U-shaped frame, a plurality of through holes are formed in one side of each positioning plate in a penetrating mode, and each through hole is connected with the corresponding heat collecting tube.

Preferably, gas pipes are hermetically connected between two ends of each heat collecting pipe, and a communicating pipe is connected between every two adjacent gas pipes.

Preferably, one side of heat dissipation box is equipped with dry box the heat dissipation window has been seted up on the top of dry box, top one side of dry box is connected with the heat dissipation section of thick bamboo through the air duct, the bottom of heat dissipation section of thick bamboo is connected with the water storage box, bottom one side of water storage box is connected with the condenser through the air duct, the one end of condenser is connected with the heat dissipation box through the air duct.

Preferably, the interior bottom that the one end of condenser runs through to extend to the water storage box through the air duct is connected with the cooling tube, a plurality of heat transfer holes have been seted up to the equidistant on the outer wall of cooling tube, fixedly connected with mounting between the both ends of cooling tube and the water storage box inner wall.

Preferably, the inside of a heat dissipation section of thick bamboo is equipped with the heating panel, the top of a heat dissipation section of thick bamboo is run through the air duct and is extended to be connected with S type drying tube in the drying box, the one end of S type drying tube is equipped with water absorption cotton net and super absorbent resin net in proper order.

Preferably, one side that the absorbent cotton net was kept away from to super absorbent resin net is equipped with two U type electromagnetic heating pipe, and two U type electromagnetic heating pipe are opposite setting, two the equal fixedly connected with installed part of one end of U type electromagnetic heating pipe, two the installed part respectively with dry box upper and lower both ends inner wall fixed connection.

Compared with the prior art, the invention has the following advantages:

1. according to the invention, the heat dissipation box, the heat dissipation wind, the fixing mechanism, the wire arrangement plate, the heat collection pipe, the suction nozzle, the heat absorption pipe, the first wire arrangement groove and the second wire arrangement groove are arranged, so that the bus can be uniformly distributed, the local high-temperature phenomenon is avoided, the heat collection pipe, the suction nozzle and the heat absorption pipe are matched to dissipate heat of the corresponding bus, the heat dissipation effect is improved, and the problems that the existing aluminum substrate and the bus groove are too small in contact area, the heat dissipation is slow in the face of a large amount of heat, and the aluminum substrate is not high in strength and is easy to deform and damage are effectively solved.

2. According to the invention, through the action of the water storage box, the radiating pipe and the plurality of heat exchange holes, the heat absorption and cooling of the water bath on the heat in the air can be effectively improved, the radiating effect is further improved, and through the design that the water absorption cotton net and the super absorbent resin net have higher water absorption, the water absorption on the gas after the water bath radiating can be effectively realized, and the influence of direct emission on the humidity of the surrounding environment is avoided.

Drawings

FIG. 1 is a schematic structural view of the present invention as a whole;

fig. 2 is a schematic diagram of an internal structure of a bus duct of the pressure-resistant heat dissipation bus duct provided by the invention;

fig. 3 is a schematic structural view of a line board of a pressure-resistant heat dissipation bus duct provided by the invention;

fig. 4 is a schematic structural view of a fixing mechanism of a pressure-resistant heat dissipation bus duct provided by the invention;

fig. 5 is a schematic view of internal structures of a water storage box and a heat dissipation cylinder of the pressure-resistant heat dissipation bus duct provided by the invention;

fig. 6 is a schematic view of an internal structure of a drying box of the pressure-resistant heat dissipation bus duct provided by the invention;

fig. 7 is a schematic view of an internal structure of a heat box of the pressure-resistant heat dissipation bus duct provided in the present invention.

In the figure: 1. an upper housing; 2. a lower housing; 3. a waterproof member; 4. a side panel; 5. copper bars; 6. a heat dissipation box; 7. a heat radiation fan; 8. a fixing mechanism; 9. a wire arranging plate; 10. a heat absorbing tube; 11. a heat collecting pipe; 12. a suction nozzle; 13. a gas delivery pipe; 14. a first wire arrangement groove; 15. a second wire arrangement groove; 16. a cable tie; 17. a connecting member; 18. a U-shaped frame; 19. connecting columns; 20. positioning a plate; 21. perforating; 22. drying the box; 23. a condenser; 24. a water storage box; 25. a heat dissipation window; 26. a heat dissipation plate; 27. an S-shaped drying tube; 28. a water absorbent cotton net; 29. a superabsorbent resin network; 30. a mounting member; 31. a U-shaped electromagnetic heating pipe; 32. a radiating pipe; 33. heat exchange holes; 34. a fixing member; 35. a heat dissipation cylinder.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

The first embodiment is as follows:

referring to fig. 1 to 7, a resistance to compression heat dissipation bus duct, includes casing 1 and casing 2 down, all be equipped with waterproof piece 3 between the both ends of casing 1 and casing 2 down, the both sides of two waterproof pieces 3 are connected with side board 4, be equipped with copper bar 5 in casing 1 and the casing 2 down, corresponding waterproof piece 3 is run through respectively at the both ends of copper bar 5, the top fixedly connected with heat dissipation box 6 of casing 1 goes up, the interior top of heat dissipation box 6 is equipped with cooling fan 7, the inside upper and lower bilateral symmetry of casing 1 and casing 2 down is equipped with fixing mechanism 8, two be equipped with calandria 9 between the fixing mechanism 8, two a plurality of thermal-collecting tubes 11 of equal fixedly connected with in the fixing mechanism 8.

Fixing mechanism 8 is including a plurality of U type frame 18, every adjacent two equal fixedly connected with spliced pole 19, every between U type frame 18 equal fixedly connected with locating plate 20, every between the both sides inner wall of U type frame 18 one side of locating plate 20 all runs through and has seted up a plurality of perforation 21, every perforation 21 all is connected with corresponding thermal-collecting tube 11, through the effect of mutually supporting between U type frame 18, spliced pole 19, locating plate 20 and a plurality of perforation 21 to can effectual realization to the fixed mounting of a plurality of thermal-collecting tubes 11, thereby not only can improve thermal-collecting tube 11's stability, but also can be more even heat absorption heat dissipation, improve the radiating efficiency.

Every the solar collector tube 11 is close to the equant interval in one side of winding displacement board 9 and is connected with a plurality of suction nozzles 12, the bottom of heat dissipation box 6 is connected with heat-absorbing pipe 10, heat-absorbing pipe 10 runs through the one end behind the casing 1 and is connected with top solar collector tube 11, a plurality of first winding displacement grooves 14 and second winding displacement groove 15 have been seted up to the upper and lower both ends surface of winding displacement board 9 equidistant respectively, and is a plurality of first winding displacement groove 14 is the staggered distribution with second winding displacement groove 15.

Further, in above-mentioned technical scheme, the upper and lower both ends of winding displacement board 9 all are equipped with a plurality of bunched line areas 16, through bunched line area 16's effect to can effectually play the effect of fixed generating line, avoid the generating phenomenon that drops when arranging of generating line, every bunched line area 16's both ends all are connected with connecting piece 17, every connecting piece 17 all with winding displacement board 9 fixed connection, every bunched line area 16 all sets up at the top that corresponds first winding displacement groove 14 and the bottom of second winding displacement groove 15, through connecting piece 17's effect, thereby can effectually play the effect of fixed bunched line area 16.

Further, in the above technical scheme, each gas pipe 13 is hermetically connected between two ends of the heat collecting pipe 11, and every two adjacent gas pipes 13 are connected with a communicating pipe, so that the heat collecting of the plurality of heat collecting pipes 11 can be effectively realized through the design of the gas pipes 13 and the communicating pipe, and the uniform emission and heat dissipation are facilitated.

Example two:

referring to fig. 1, 5, 6 and 7, one side of heat dissipation box 6 is equipped with dry box 22 the top of dry box 22 has been seted up heat dissipation window 25, top one side of dry box 22 is connected with heat dissipation tube 35 through the air duct, the bottom of heat dissipation tube 35 is connected with water storage box 24, bottom one side of water storage box 24 is connected with condenser 23 through the air duct, one end of condenser 23 is connected with heat dissipation box 6 through the air duct, the one end of condenser 23 runs through the interior bottom that extends to water storage box 24 through the air duct and is connected with cooling tube 32, a plurality of heat transfer holes 33 have been seted up at equidistant on the outer wall of cooling tube 32, fixedly connected with mounting 34 between the both ends of cooling tube 32 and the 24 inner walls of water storage box, through the effect of water storage box 24, cooling tube 32 and a plurality of heat transfer holes 33 to can effectually improve the water bath and carry out the heat absorption cooling to the heat in the air, further improving the heat dissipation effect.

Further, in the above technical solution, the heat dissipating plate 26 is arranged inside the heat dissipating cylinder 35, the top of the heat dissipating cylinder 35 is connected with the S-shaped drying pipe 27 through the air duct, the water absorbing cotton net 28 and the super absorbent resin net 29 are sequentially arranged at one end of the S-shaped drying pipe 27, the water absorbing cotton net 28 and the super absorbent resin net 29 have high water absorption performance, so that the water absorption of the gas after the water bath heat dissipation can be effectively realized, the direct discharge and the influence on the humidity of the surrounding environment can be avoided, two U-shaped electromagnetic heating pipes 31 are arranged on one side of the super absorbent resin net 29 away from the water absorbing cotton net 28, the two U-shaped electromagnetic heating pipes 31 are oppositely arranged, one end of each of the two U-shaped electromagnetic heating pipes 31 is fixedly connected with the mounting part 30, and the two mounting parts 30 are respectively fixedly connected with the inner walls of the upper end and the lower end of the drying box 22, through the effect of U type electromagnetic heating pipe 31 to can be effectual through further heating evaporation steam, avoid direct emission to influence the surrounding environment humidity.

The working principle is as follows: firstly, arranging each bus in each first wire arranging groove 14 and each second wire arranging groove 15 in sequence, then fixedly installing a wire binding belt 16 and a connecting piece 17 on the upper end surface and the lower end surface of each wire arranging groove 9, starting a condenser 23, a heat radiation fan 7 and a U-shaped electromagnetic heating pipe 31 to work after heat is generated in each bus groove, firstly, the heat radiation fan 7 works to absorb hot air into heat collecting pipes 11 through a plurality of air suction nozzles 12, the hot air in the heat collecting pipes 11 is intensively conveyed to heat absorbing pipes 10 through communicating pipes and air conveying pipes 13 and then reaches a heat radiation box 6, then, the hot air is conveyed into the condenser 23 through air guide pipes to be subjected to primary cooling treatment, then, the hot air is conveyed into heat radiation pipes 32 of an inner bottom plate of a water storage box 24, is subjected to water bath heat radiation through a plurality of heat exchanging holes 33, then, the air is conveyed into a heat radiation cylinder 35 to be further radiated through a heat radiation plate 26, then conveyed into a drying box 22, and finally, the hot air is firstly, and finally, the hot air is conveyed into an S-shaped drying pipe 27, The water absorption cotton net 28 and the super absorbent resin net 29 realize that the moisture absorption is carried out to the gas after the water bath heat dissipation, avoid directly discharging and influence the surrounding environment humidity, then through the effect of U type electromagnetic heating pipe 31 to can be effectual through further heating evaporation steam, it can to discharge air at last.

The previous description is provided to enable any person skilled in the art to practice the various aspects described herein. Various modifications to these aspects will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other aspects. Thus, the claims are not intended to be limited to the aspects shown herein, but is to be accorded the full scope consistent with the language claims, wherein reference to an element in the singular is not intended to mean "one and only one" unless specifically so stated, but rather "one or more.

Claims (8)

1. The compression-resistant heat dissipation bus duct comprises an upper casing (1) and a lower casing (2), and is characterized in that waterproof parts (3) are arranged between two ends of the upper casing (1) and the lower casing (2), side panels (4) are connected to two sides of the two waterproof parts (3), copper bars (5) are arranged in the upper casing (1) and the lower casing (2), two ends of each copper bar (5) penetrate through the corresponding waterproof parts (3) respectively, a heat dissipation box (6) is fixedly connected to the top of the upper casing (1), a heat dissipation fan (7) is arranged at the inner top of the heat dissipation box (6), fixing mechanisms (8) are symmetrically arranged at the upper end and the lower end of the inner parts of the upper casing (1) and the lower casing (2), a wire arrangement plate (9) is arranged between the two fixing mechanisms (8), and a plurality of heat collection tubes (11) are fixedly connected to the inner parts of the fixing mechanisms (8), every the equipartition interval in one side that thermal-collecting tube (11) are close to winding displacement board (9) is connected with a plurality of suction nozzles (12), the bottom of heat dissipation box (6) is connected with heat-absorbing pipe (10), one end after heat-absorbing pipe (10) run through casing (1) is connected with top thermal-collecting tube (11), a plurality of first winding displacement grooves (14) and second winding displacement groove (15), a plurality of are seted up to the upper and lower both ends surface of winding displacement board (9) equidistant respectively, and are a plurality of first winding displacement groove (14) are crisscross distribution with second winding displacement groove (15).

2. The compression-resistant heat dissipation bus duct according to claim 1, wherein a plurality of wiring harnesses (16) are arranged at the upper end and the lower end of the wiring board (9), connecting pieces (17) are connected to the two ends of each wiring harness (16), each connecting piece (17) is fixedly connected with the wiring board (9), and each wiring harness (16) is arranged at the top of the corresponding first wiring groove (14) and the bottom of the corresponding second wiring groove (15).

3. The pressure-resistant heat dissipation bus duct according to claim 1, wherein the fixing mechanism (8) comprises a plurality of U-shaped frames (18), a connecting column (19) is fixedly connected between every two adjacent U-shaped frames (18), a positioning plate (20) is fixedly connected between the inner walls of two sides of each U-shaped frame (18), a plurality of through holes (21) are formed in one side of each positioning plate (20) in a penetrating manner, and each through hole (21) is connected with a corresponding heat collection tube (11).

4. The compression-resistant heat dissipation bus duct according to claim 1, wherein gas pipes (13) are hermetically connected between two ends of each heat collection pipe (11), and a communicating pipe is connected between every two adjacent gas pipes (13).

5. The compression-resistant heat dissipation bus duct according to claim 1, wherein a drying box (22) is arranged on one side of the heat dissipation box (6), a heat dissipation window (25) is formed in the top end of the drying box (22), a heat dissipation cylinder (35) is connected to one side of the top of the drying box (22) through an air duct, a water storage box (24) is connected to the bottom end of the heat dissipation cylinder (35), a condenser (23) is connected to one side of the bottom of the water storage box (24) through an air duct, and one end of the condenser (23) is connected with the heat dissipation box (6) through an air duct.

6. The pressure-resistant heat dissipation bus duct of claim 5, wherein one end of the condenser (23) penetrates through and extends to the inner bottom of the water storage box (24) through an air duct to be connected with a heat dissipation pipe (32), a plurality of heat exchange holes (33) are formed in the outer wall of the heat dissipation pipe (32) at equal intervals, and fixing pieces (34) are fixedly connected between the two ends of the heat dissipation pipe (32) and the inner wall of the water storage box (24).

7. The pressure-resistant heat dissipation bus duct according to claim 5, wherein a heat dissipation plate (26) is arranged inside the heat dissipation cylinder (35), the top of the heat dissipation cylinder (35) penetrates through the air duct and extends into the drying box (22) to be connected with an S-shaped drying pipe (27), and a water absorption cotton net (28) and a super absorbent resin net (29) are sequentially arranged at one end of the S-shaped drying pipe (27).

8. The compression-resistant heat-dissipation bus duct according to claim 7, wherein two U-shaped electromagnetic heating pipes (31) are arranged on one side, away from the water-absorbing cotton net (28), of the high water-absorbing resin net (29), the two U-shaped electromagnetic heating pipes (31) are oppositely arranged, one ends of the two U-shaped electromagnetic heating pipes (31) are fixedly connected with mounting pieces (30), and the two mounting pieces (30) are fixedly connected with inner walls of the upper end and the lower end of the drying box (22) respectively.

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