CN210536122U

CN210536122U - Energy-saving cooling device for power equipment

Info

Publication number: CN210536122U
Application number: CN201921876502.5U
Authority: CN
Inventors: 黄会明; 应英
Original assignee: Nanchang Mingbo Automation Equipment Co Ltd
Current assignee: Nanchang Mingbo Automation Equipment Co Ltd
Priority date: 2019-11-01
Filing date: 2019-11-01
Publication date: 2020-05-15
Anticipated expiration: 2029-11-01

Abstract

The utility model relates to a power equipment cooling technical field discloses an energy-conserving heat sink for power equipment, the inside embedding of first cooler bin and second cooler bin is respectively installed first radiator unit and second radiator unit, the equal rigid coupling in lower surface center department of first cooler bin and second cooler bin has the delivery port, and the junction of first cooler bin and second cooler bin has from top to bottom set gradually adjusting part and flexible subassembly. The utility model discloses a combined use of first radiator unit and second radiator unit, can transmit the heat that the block terminal produced to first cooler bin and second cooler bin in through heat-conducting mode, the cooling is cooled down to the rethread cooling water, thereby the cooling effect of block terminal has been improved, this mode passes through the used together of cooling water and a plurality of heat conduction component simultaneously, thereby finally accomplish the cooling, this mode is compared with traditional flabellum heat dissipation, need not with the help of electric power heat dissipation, energy-saving more, the radiating effect is better.

Description

Energy-saving cooling device for power equipment

Technical Field

The utility model relates to a power equipment cooling technical field specifically is an energy-conserving heat sink for power equipment.

Background

The block terminal is according to electric wiring requirement with switchgear, measuring instrument, protection electrical apparatus and auxiliary assembly in closed or semi-closed metal cabinet or on the screen width, constitute low voltage distribution device, and the block terminal is common power equipment, and the block terminal can produce more heat in the use, just at this moment need cool down it through cooling device to ensure its normal use.

But current heat sink mostly need be through accomplishing the heat dissipation with the help of electric power apparatus, drive flabellum heat dissipation etc. like the motor, can the more electric energy of loss like this, current heat sink also is difficult to quick installation on the block terminal simultaneously to influence its normal use. Accordingly, one skilled in the art provides an energy-saving cooling device for electrical equipment to solve the problems set forth in the background art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an energy-conserving heat sink for power equipment to solve the problem that proposes among the above-mentioned background art.

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

the utility model provides an energy-conserving heat sink for power equipment, includes first cooler bin, one side of first cooler bin is provided with the second cooler bin, first radiator unit and second radiator unit are installed in the inside embedding respectively of first cooler bin and second cooler bin, and the upper surface center department of first cooler bin and second cooler bin has all seted up the water filling port, the equal rigid coupling in lower surface center department of first cooler bin and second cooler bin has the delivery port, and the junction of first cooler bin and second cooler bin has from top to bottom set gradually adjusting part and flexible subassembly.

As a further aspect of the present invention: first radiator unit includes mounting panel, heat pipe and fastening bolt, and first radiator unit and second radiator unit's internals is the same, first radiator unit and second radiator unit are relative setting, the one end rigid coupling of heat pipe has the mounting panel, and the other end of heat pipe runs through the inside of first cooler bin, the inside of mounting panel is still embedded and is installed the three fastening bolt that passes through threaded connection rather than self.

As a further aspect of the present invention: the inside rigid coupling that still has the barrel and the embedding of heat pipe installs the cooling tube, the one end and the barrel of cooling tube are fixed, and the cooling tube is the annular distribution on heat pipe and barrel, mounting panel, heat pipe, barrel and cooling tube are the component of copper alloy material.

As a further aspect of the present invention: the adjusting component comprises a first threaded rod, a sleeve, anti-skid protrusions and a second threaded rod, the first threaded rod and the second threaded rod which are connected with the inner side of the sleeve through threads are installed on the two sides of the inner side of the sleeve in an embedded mode, the anti-skid protrusions are fixedly bonded on the outer side of the sleeve, and the first threaded rod and the second threaded rod are equal in length.

As a further aspect of the present invention: the thread directions of the first threaded rod and the second threaded rod are opposite, one end of the first threaded rod is fixed to the inner side of the first cooling box, and one end of the second threaded rod is fixed to the inner side of the second cooling box.

As a further aspect of the present invention: the telescopic assembly comprises a first telescopic plate, a sleeve seat and a second telescopic plate, wherein the first telescopic plate and the second telescopic plate are respectively arranged on two sides of the inner portion of the sleeve seat in a sliding mode, one end of the first telescopic plate is fixed to the inner side of the first cooling box, and one end of the second telescopic plate is fixed to the inner side of the second cooling box.

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

1. the utility model discloses a combined use of first radiator unit and second radiator unit, can transmit the heat that the block terminal produced to first cooler bin and second cooler bin in through the mode of heat conduction, the cooling water of rethread cools off the temperature, thereby improved the cooling effect of block terminal, guaranteed the normal use of block terminal, this mode is through the common use of cooling water and a plurality of heat conduction component simultaneously, thereby finally accomplish the cooling, this mode is compared with traditional flabellum heat dissipation, need not to dispel the heat with the help of electric power, it is more energy-conserving, the radiating effect is better;

2. can adjust the interval between first cooler bin and the second cooler bin through adjusting part to the convenience is installed this heat sink on the block terminal, and flexible subassembly can improve the connection steadiness between first cooler bin and the second cooler bin, makes the difficult not hard up phenomenon that appears between the two.

Drawings

FIG. 1 is a schematic structural diagram of an energy-saving cooling device for electrical equipment;

FIG. 2 is a schematic view of an installation structure of a regulating assembly and a telescopic assembly in an energy-saving cooling device for electric equipment;

fig. 3 is a schematic view of an installation structure of a heat pipe in an energy saving and temperature reducing device for electric power equipment.

In the figure: 1. a water injection port; 2. a first cooling tank; 3. mounting a plate; 4. a heat conducting pipe; 5. fastening a bolt; 6. a first heat dissipation assembly; 7. a telescoping assembly; 8. a first threaded rod; 9. a sleeve; 10. anti-skid projections; 11. a second threaded rod; 12. an adjustment assembly; 13. a second cooling tank; 14. a second heat dissipation assembly; 15. a first expansion plate; 16. a sleeve seat; 17. a second expansion plate; 18. a barrel; 19. a heat radiation pipe.

Detailed Description

Referring to fig. 1 to 3, in an embodiment of the present invention, an energy saving and temperature reducing device for power equipment includes a first cooling box 2, a second cooling box 13 is disposed on one side of the first cooling box 2, a first heat dissipating assembly 6 and a second heat dissipating assembly 14 are respectively embedded in the first cooling box 2 and the second cooling box 13, a water filling port 1 is disposed at the center of the upper surface of each of the first cooling box 2 and the second cooling box 13, a water outlet is fixedly connected to the center of the lower surface of each of the first cooling box 2 and the second cooling box 13, the first heat dissipating assembly 6 includes a mounting plate 3, a heat conducting pipe 4 and a fastening bolt 5, the internal components of the first heat dissipating assembly 6 and the second heat dissipating assembly 14 are the same, the first heat dissipating assembly 6 and the second heat dissipating assembly 14 are disposed oppositely, the mounting plate 3 is fixedly connected to one end of the heat conducting pipe 4, and the other end of the heat conducting pipe 4 penetrates through the interior of the first cooling box 2, the mounting plate 3 is also embedded with three fastening bolts 5 which are connected with the mounting plate by threads, the heat conducting pipe 4 is also fixedly connected with a cylinder 18 and embedded with a heat radiating pipe 19, one end of the heat radiating pipe 19 is fixed with the cylinder 18, the heat radiating pipe 19 is annularly distributed on the heat conducting pipe 4 and the cylinder 18, the mounting plate 3, the heat conducting pipe 4, the cylinder 18 and the heat radiating pipe 19 are all components made of copper alloy materials, the heat generated by the distribution box can be transferred into the first cooling box 2 and the second cooling box 13 in a heat conduction mode by combining the first heat radiating component 6 and the second heat radiating component, and then cooling water is introduced for cooling, so that the cooling effect of the distribution box is improved, the normal use of the distribution box is ensured, meanwhile, the mode uses cooling water and a plurality of heat conducting components together, so as to finally finish cooling, compared with the traditional fan blade heat radiation, the heat dissipation is not needed by means of electric power, so that the energy is saved, and the heat dissipation effect is better.

In fig. 1 and 2: the adjusting component 12 and the telescopic component 7 are sequentially arranged at the joint of the first cooling box 2 and the second cooling box 13 from top to bottom, the adjusting component 12 comprises a first threaded rod 8, a sleeve 9, an anti-skid protrusion 10 and a second threaded rod 11, the first threaded rod 8 and the second threaded rod 11 which are in threaded connection with the sleeve 9 are respectively embedded into two sides of the sleeve 9, the anti-skid protrusion 10 is fixedly bonded on the outer portion of the sleeve 9, the lengths of the first threaded rod 8 and the second threaded rod 11 are equal, the thread directions of the first threaded rod 8 and the second threaded rod 11 are opposite, one end of the first threaded rod 8 is fixed with the inner side of the first cooling box 2, one end of the second threaded rod 11 is fixed with the inner side of the second cooling box 13, the telescopic component 7 comprises a first telescopic plate 15, a sleeve seat 16 and a second telescopic plate 17, the first telescopic plate 15 and the second telescopic plate 17 respectively slide on two sides of the sleeve seat 16, the one end of first expansion plate 15 is fixed with the inboard of first cooler bin 2, and the one end of second expansion plate 17 is fixed with the inboard of second cooler bin 13, can adjust the interval between first cooler bin 2 and the second cooler bin 13 through adjusting part 12 to conveniently install this heat sink on the block terminal, and telescopic part 7 can improve the connection steadiness between first cooler bin 2 and the second cooler bin 13, makes difficult appearance not hard up phenomenon between the two.

The utility model discloses a theory of operation is: the user puts the distribution box between the first heat dissipation assembly 6 and the second heat dissipation assembly 14, at the moment, the sleeve 9 is rotated clockwise, the first threaded rod 8 and the second threaded rod 11 can be driven to move relatively, and then the first cooling box 2 and the second cooling box 13 are driven to move relatively, after the mounting plates 3 positioned at two sides of the distribution box are respectively contacted with the sleeve, the user can mount the first cooling box 2 and the second cooling box 13 by screwing the fastening bolt 5, so that the distance between the first cooling box 2 and the second cooling box 13 can be adjusted by the adjusting assembly 12, the cooling device is conveniently mounted on the distribution box, the telescopic assembly 7 can improve the connection stability between the first cooling box 2 and the second cooling box 13, the loosening phenomenon between the first cooling box 2 and the second cooling box 13 is not easy to occur, and then the user injects cooling water into the first cooling box 2 and the second cooling box 13 through the water injection port 1, at this moment, the mounting plate 3 and the heat pipe 4 can transmit the heat generated by the distribution box to the first cooling box 2 and the second cooling box 13 in a heat conduction mode, at this moment, the heat can be dissipated through cooling water, finally, the cooling water is discharged through a water outlet at the lower part, a user can complete the cooling purpose by injecting circulating cooling water into the first cooling box 2 and the second cooling box 13, the radiating pipes 19 are annularly distributed on the heat pipe 4 and the barrel 18, so that the purpose of auxiliary radiating can be achieved through the radiating pipes 19, the heat generated by the distribution box can be transmitted to the first cooling box 2 and the second cooling box 13 in a heat conduction mode through the combined use of the first radiating assembly 6 and the second radiating assembly, the cooling effect of the distribution box is improved, and the normal use of the distribution box is guaranteed, simultaneously this mode is through the combined use of cooling water and a plurality of heat conduction component to the final cooling of accomplishing, this mode compares with traditional flabellum heat dissipation, need not to dispel the heat with the help of electric power, and is more energy-conserving, and the radiating effect is better.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. The utility model provides an energy-conserving heat sink for power equipment, includes first cooler bin (2), its characterized in that, one side of first cooler bin (2) is provided with second cooler bin (13), first radiator unit (6) and second radiator unit (14) are installed in the inside embedding respectively of first cooler bin (2) and second cooler bin (13), and the upper surface center department of first cooler bin (2) and second cooler bin (13) has all seted up water filling port (1), the equal rigid coupling in lower surface center department of first cooler bin (2) and second cooler bin (13) has the delivery port, and the junction of first cooler bin (2) and second cooler bin (13) has from top to bottom set gradually adjusting part (12) and flexible subassembly (7).

2. The energy-saving and temperature-reducing device for the power equipment is characterized in that the first heat dissipation assembly (6) comprises a mounting plate (3), a heat conduction pipe (4) and fastening bolts (5), the internal components of the first heat dissipation assembly (6) and the second heat dissipation assembly (14) are the same, the first heat dissipation assembly (6) and the second heat dissipation assembly (14) are oppositely arranged, the mounting plate (3) is fixedly connected to one end of the heat conduction pipe (4), the other end of the heat conduction pipe (4) penetrates through the inside of the first cooling box (2), and the three fastening bolts (5) which are in threaded connection with the mounting plate (3) are embedded in the mounting plate (3).

3. The energy-saving and temperature-reducing device for electric power equipment according to claim 2, wherein the heat conducting pipe (4) is further fixedly connected with a cylinder (18) and embedded with a heat radiating pipe (19), one end of the heat radiating pipe (19) is fixed with the cylinder (18), the heat radiating pipe (19) is annularly distributed on the heat conducting pipe (4) and the cylinder (18), and the mounting plate (3), the heat conducting pipe (4), the cylinder (18) and the heat radiating pipe (19) are all made of copper alloy materials.

4. The energy-saving and temperature-reducing device for the power equipment as claimed in claim 1, wherein the adjusting component (12) comprises a first threaded rod (8), a sleeve (9), anti-skid protrusions (10) and a second threaded rod (11), the first threaded rod (8) and the second threaded rod (11) which are connected with the sleeve (9) through threads are respectively embedded in two sides of the inner portion of the sleeve (9), the anti-skid protrusions (10) are fixedly bonded on the outer portion of the sleeve (9), and the first threaded rod (8) and the second threaded rod (11) are equal in length.

5. The energy-saving and temperature-reducing device for electric power equipment as claimed in claim 4, wherein the thread directions of the first threaded rod (8) and the second threaded rod (11) are opposite, one end of the first threaded rod (8) is fixed with the inner side of the first cooling box (2), and one end of the second threaded rod (11) is fixed with the inner side of the second cooling box (13).

6. The energy-saving and temperature-reducing device for the electric power equipment is characterized in that the telescopic assembly (7) comprises a first telescopic plate (15), a sleeve seat (16) and a second telescopic plate (17), the first telescopic plate (15) and the second telescopic plate (17) are respectively arranged on two sides of the inner portion of the sleeve seat (16) in a sliding mode, one end of the first telescopic plate (15) is fixed to the inner side of the first cooling box (2), and one end of the second telescopic plate (17) is fixed to the inner side of the second cooling box (13).