CN219643403U - Heat dissipation base for SVG reactive power compensator - Google Patents

Abstract

The utility model relates to the technical field of heat dissipation bases, and discloses a heat dissipation base for an SVG reactive power compensation device, which solves the problem of poor heat dissipation effect of the heat dissipation base for the existing SVG reactive power compensation device, and comprises a heat dissipation base body, wherein the heat dissipation base body is fixedly connected to the bottom end of the SVG reactive power compensation device, the heat dissipation base body is composed of a bottom frame type supporting seat, a detachable plate body and a heat conduction supporting vertical plate, mounting plates are arranged on both sides of the front surface and the back surface of the heat conduction supporting vertical plate, a liquid cooling heat dissipation combined type through groove is formed in the heat conduction supporting vertical plate, a cooling liquid diversion component communicated with the liquid cooling heat dissipation combined type through groove is arranged at the bottom end of the heat conduction supporting vertical plate, and a liquid inlet interface and a liquid outlet interface are arranged at one end of the bottom frame type supporting seat; through this heat dissipation base can realize supporting SVG reactive power compensator, simultaneously through liquid cooling and forced air cooling combination formula radiating mode, can effectively improve the radiating effect.

Description

Heat dissipation base for SVG reactive power compensator

Technical Field

The utility model belongs to the technical field of heat dissipation bases, and particularly relates to a heat dissipation base for an SVG reactive power compensation device.

Background

The SVG reactive compensation device is a technology for improving the power factor of a power grid, reducing the loss of a power supply transformer and a transmission line, improving the power supply efficiency and improving the power supply environment in a power supply system.

The base is SVG reactive power compensator's support base for to SVG reactive power compensator's support, also some bases have the heat dissipation function, because SVG reactive power compensator during operation can produce a large amount of heat, consequently can improve the radiating effect to SVG reactive power compensator through the base that has the heat dissipation function, but current SVG reactive power compensator is with the radiating base generally only through the radiating mode realization heat dissipation function of air-cooled, its whole radiating effect is not ideal, influences SVG reactive power compensator's life.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the utility model provides the heat dissipation base for the SVG reactive power compensation device, which effectively solves the problem that the heat dissipation effect of the heat dissipation base for the SVG reactive power compensation device is poor.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a SVG is heat dissipation base for reactive power compensator, including the heat dissipation base body, heat dissipation base body fixed connection is in SVG reactive power compensator's bottom, the heat dissipation base body comprises bottom frame type supporting seat, can dismantle plate body and heat conduction support riser, can dismantle plate body fixed connection in the intermediate position on bottom frame type supporting seat top, heat conduction support riser fixed connection is in the top of dismantling the plate body and alternates in SVG reactive power compensator's inside, heat conduction support riser openly and the both sides of back are all fixed and are provided with the mounting panel with SVG reactive power compensator assorted, the liquid cooling heat dissipation combination formula logical groove has been seted up to the inside of heat conduction support riser, the bottom of heat conduction support riser is provided with the coolant liquid water conservancy diversion subassembly with the liquid cooling heat dissipation combination formula logical groove intercommunication, the four corners on bottom frame type supporting seat top all is fixed and is provided with the anchor bolt with SVG reactive power compensator assorted, the one end of bottom frame type supporting seat is provided with feed liquor interface and the drain interface with coolant liquid water conservancy diversion subassembly.

Preferably, the air intake has been seted up in the front of bottom frame type supporting seat, and the air exit has been seted up at the back of bottom frame type supporting seat, and the inside of air intake and air exit is all fixed to be provided with the protection network, and the inside of bottom frame type supporting seat is provided with a plurality of radiator fan and a plurality of radiating fin with heat conduction support riser fixed connection, and heat conduction support riser and radiating fin are the aluminum alloy material.

Preferably, the liquid cooling heat dissipation combined type through groove is composed of an S-shaped heat dissipation through groove I, an S-shaped heat dissipation through groove II and an S-shaped heat dissipation through groove III, and the S-shaped heat dissipation through groove II is located between the S-shaped heat dissipation through groove I and the S-shaped heat dissipation through groove III.

Preferably, the cooling liquid flow guiding component is composed of a liquid inlet pipe, a plurality of liquid inlet shunt pipes, a liquid discharge pipe and a plurality of liquid discharge branch pipes, one end of the liquid inlet pipe is fixedly connected with the liquid inlet interface, the liquid inlet shunt pipes are fixedly connected between the liquid inlet pipe and the liquid inlet of the liquid cooling heat dissipation combined type through groove, one end of the liquid discharge pipe is fixedly connected with the liquid discharge interface, the liquid discharge branch pipes are fixedly connected between the liquid discharge pipes and the liquid discharge ports of the liquid cooling heat dissipation combined type through groove, and electromagnetic valves are arranged on the liquid inlet shunt pipes.

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

(1) In operation, through arranging the liquid cooling radiating combined type through groove formed by the S-shaped radiating through groove I, the S-shaped radiating through groove II and the S-shaped radiating through groove III and the cooling liquid diversion component formed by the liquid inlet pipe, the liquid inlet shunt pipes, the liquid outlet pipes and the liquid outlet branch pipes, the liquid cooling radiation of the SVG reactive power compensation device can be realized, the radiating efficiency is effectively improved, and meanwhile, the quantity of the opened S-shaped radiating through grooves can be selected according to different working temperatures of the SVG reactive power compensation device, so that the energy saving effect is achieved;

(2) The SVG reactive power compensation device is provided with the air inlet, the air outlet, the protective net, the cooling fan and the cooling fins, so that the SVG reactive power compensation device can be subjected to air cooling to assist in heat dissipation, and the heat dissipation effect of the SVG reactive power compensation device is further improved.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

In the drawings:

FIG. 1 is a schematic diagram of a connection structure between a heat dissipation base body and an SVG reactive power compensation device according to the present utility model;

FIG. 2 is a schematic view of a heat dissipation base body according to the present utility model;

FIG. 3 is a schematic view of the inner structure of the bottom frame-type support base of the present utility model;

FIG. 4 is a cross-sectional view of a thermally conductive support riser of the present utility model;

FIG. 5 is an enlarged view of a portion of FIG. 4 in accordance with the present utility model;

in the figure: 1. a heat dissipation base body; 2. SVG reactive power compensation device; 3. a bottom frame type supporting seat; 4. a detachable plate body; 5. a heat conduction supporting vertical plate; 6. a mounting plate; 7. liquid cooling and heat radiation combined through groove; 8. a coolant flow directing assembly; 9. reinforcing bolts; 10. a liquid inlet port; 11. a liquid discharge interface; 12. an air inlet; 13. an air outlet; 14. a protective net; 15. a heat radiation fan; 16. a heat radiation fin; 17. s-shaped heat dissipation through groove I; 18. s-shaped radiating through grooves II; 19. s-shaped heat dissipation through grooves III; 20. a liquid inlet pipe; 21. a liquid inlet shunt tube; 22. a liquid discharge pipe; 23. a liquid discharge branch pipe; 24. a solenoid valve.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model; all other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 5, a heat dissipation base for an SVG reactive power compensation device according to the present utility model includes a heat dissipation base body 1, the heat dissipation base body 1 is fixedly connected to the bottom end of an SVG reactive power compensation device 2, the heat dissipation base body 1 is composed of a bottom frame-type supporting seat 3, a detachable plate body 4 and a heat conduction supporting riser 5, the detachable plate body 4 is fixedly connected to the middle position of the top end of the bottom frame-type supporting seat 3, the heat conduction supporting riser 5 is fixedly connected to the top end of the detachable plate body 4 and is inserted into the interior of the SVG reactive power compensation device 2, both sides of the front and back surfaces of the heat conduction supporting riser 5 are fixedly provided with mounting plates 6 matched with the SVG reactive power compensation device 2, the interior of the heat conduction supporting riser 5 is provided with a liquid cooling heat dissipation combined through groove 7, the bottom end of the heat conduction supporting riser 5 is provided with a cooling liquid guide component 8 communicated with the liquid cooling combined through groove 7, four corners at the top end of the bottom frame-type supporting seat 3 are fixedly provided with reinforcing bolts 9 matched with the SVG reactive power compensation device 2, one end of the bottom frame-type supporting seat 3 is provided with liquid inlet ports 10 matched with the cooling liquid guide component 8;

as shown in fig. 2 to 5, the front surface of the bottom frame-type supporting seat 3 is provided with an air inlet 12, the back surface of the bottom frame-type supporting seat 3 is provided with an air outlet 13, the interiors of the air inlet 12 and the air outlet 13 are fixedly provided with a protection net 14, the interiors of the bottom frame-type supporting seat 3 are provided with a plurality of cooling fans 15 and a plurality of cooling fins 16 fixedly connected with the heat conduction supporting vertical plates 5, the SVG reactive compensation device 2 can be subjected to air cooling and heat radiation, the heat conduction supporting vertical plates 5 and the cooling fins 16 are all made of aluminum alloy materials, the heat radiation efficiency can be improved, the liquid cooling and heat radiation combined type through groove 7 is formed by an S-type heat radiation through groove one 17, an S-type heat radiation through groove two 18 and an S-type heat radiation through groove three 19, the S-type heat radiation through groove two 18 is positioned between the S-type heat radiation through groove one 17 and the S-type heat radiation through groove three 19, the cooling liquid diversion component 8 is formed by a plurality of liquid inlet pipes 20, a plurality of liquid diversion pipes 21, a liquid drainage pipe 22 and a plurality of liquid drainage 23 fixedly connected with the liquid drainage pipe 20, one end of the liquid inlet pipe 20 is fixedly connected with the liquid diversion pipe 10 and the liquid drainage pipe 21, and one end of the liquid drainage pipe is fixedly connected with the liquid drainage pipe 21 and the liquid drainage pipe 7 is fixedly connected with the liquid drainage port 7, and the liquid drainage port is fixedly connected with the liquid drainage port 7 through the liquid diversion pipe through the liquid pipe 21;

when the SVG reactive power compensation device is used, the liquid inlet interface 10 and the liquid outlet interface 11 are connected with a liquid cooling circulation system, the working temperature of the SVG reactive power compensation device 2 is monitored in real time through a temperature sensor in the SVG reactive power compensation device 2, according to the opening quantity of the S-shaped heat dissipation through groove I17, the S-shaped heat dissipation through groove II 18 and the S-shaped heat dissipation through groove III 19, if the temperature is lower, one channel or two channels can be selectively opened, if the temperature is higher, synchronous heat dissipation is realized by opening the three channels, the on-off of the electromagnetic valve 24 can realize the on-off of the S-shaped heat dissipation through groove I17, the S-shaped heat dissipation through groove II 18 and the S-shaped heat dissipation through groove III 19, heat generated by the SVG reactive power compensation device 2 is transferred to the heat conduction support vertical plate 5 and the radiating fin 16, and cooling liquid discharged by the liquid cooling circulation system is discharged to the inside of the liquid cooling combined through the liquid inlet interface 10, the liquid inlet pipe 20 and the liquid distribution pipe 21, thereby the temperature on the heat conduction support vertical plate 5 is taken away, then the cooling liquid is discharged back to the liquid cooling circulation system through the liquid outlet pipe 22 and the liquid discharge branch pipe 23 to realize circulation, and meanwhile, the cooling effect can be realized through the electromagnetic valve 24, and the cooling effect can be improved by combining the heat dissipation effect and the cooling effect of the SVG and the cooling device through the cooling effect.

In operation, through arranging the liquid cooling radiating combined type through groove formed by the S-shaped radiating through groove I, the S-shaped radiating through groove II and the S-shaped radiating through groove III and the cooling liquid diversion component formed by the liquid inlet pipe, the liquid inlet shunt pipes, the liquid outlet pipes and the liquid outlet branch pipes, the liquid cooling radiation of the SVG reactive power compensation device can be realized, the radiating efficiency is effectively improved, and meanwhile, the quantity of the opened S-shaped radiating through grooves can be selected according to different working temperatures of the SVG reactive power compensation device, so that the energy saving effect is achieved; through being provided with air intake, air exit, protection network, radiator fan and fin, can carry out forced air cooling auxiliary heat dissipation to SVG reactive power compensator, further improve the radiating effect to SVG reactive power compensator.

Claims (4)

1. The utility model provides a SVG reactive power compensator is with heat dissipation base, includes heat dissipation base body (1), its characterized in that: the heat dissipation base body (1) fixed connection is in the bottom of SVG reactive power compensator (2), heat dissipation base body (1) comprises bottom frame type supporting seat (3), can dismantle plate body (4) and heat conduction support riser (5), can dismantle intermediate position on bottom frame type supporting seat (3) top of plate body (4) fixed connection, heat conduction support riser (5) fixed connection is in the top of dismantling plate body (4) and alternates in the inside of SVG reactive power compensator (2), heat conduction support riser (5) openly and the both sides of back are all fixed be provided with SVG reactive power compensator (2) assorted mounting panel (6), liquid cooling heat dissipation combination formula logical groove (7) have been seted up to the inside of heat conduction support riser (5), the bottom of heat conduction support riser (5) is provided with coolant liquid water conservancy diversion subassembly (8) with liquid cooling heat dissipation combination formula logical groove (7) intercommunication, four corners on bottom frame type supporting seat (3) top all is fixed to be provided with SVG reactive power compensator (2) assorted reinforcement bolt (9), bottom frame type supporting seat (3) openly and the one end of back all is provided with liquid cooling liquid diversion subassembly (11) and liquid drainage interface (11).

2. The heat dissipation base for an SVG reactive power compensation device of claim 1, wherein: air intake (12) have been seted up in the front of bottom frame type supporting seat (3), air exit (13) have been seted up at the back of bottom frame type supporting seat (3), the inside of air intake (12) and air exit (13) is all fixed to be provided with protection network (14), the inside of bottom frame type supporting seat (3) is provided with a plurality of radiator fan (15) and a plurality of radiating fin (16) with heat conduction support riser (5) fixed connection, heat conduction support riser (5) and radiating fin (16) are the aluminum alloy material.

3. The heat dissipation base for an SVG reactive power compensation device of claim 1, wherein: the liquid cooling heat dissipation combined type through groove (7) is composed of an S-shaped heat dissipation through groove I (17), an S-shaped heat dissipation through groove II (18) and an S-shaped heat dissipation through groove III (19), and the S-shaped heat dissipation through groove II (18) is located between the S-shaped heat dissipation through groove I (17) and the S-shaped heat dissipation through groove III (19).

4. A heat dissipation base for SVG reactive compensation device according to claim 3, characterized in that: the cooling liquid flow guide assembly (8) comprises a liquid inlet pipe (20), a plurality of liquid inlet shunt pipes (21), a liquid discharge pipe (22) and a plurality of liquid discharge branch pipes (23), one end of the liquid inlet pipe (20) is fixedly connected with the liquid inlet interface (10), the liquid inlet shunt pipes (21) are fixedly connected between the liquid inlet of the liquid inlet pipe (20) and the liquid cooling heat dissipation combined type through groove (7), one end of the liquid discharge pipe (22) is fixedly connected with the liquid discharge interface (11), the liquid discharge branch pipes (23) are fixedly connected between the liquid discharge pipes (22) and the liquid discharge ports of the liquid cooling heat dissipation combined type through groove (7), and electromagnetic valves (24) are arranged on the liquid inlet shunt pipes (21).