CN219761716U - Small SVG water-air heat exchange device - Google Patents

Abstract

The utility model discloses a small SVG water-air heat exchange device, which comprises a pump inlet pipeline module, a main circulating water pump, a pump outlet pipeline module, an electric three-way valve module, a main filter pipeline module and a cooled device inlet pipeline module, wherein the main filter pipeline module is connected with the main circulating water pump; the pump inlet pipeline module, the main circulating water pump, the pump outlet pipeline module, the electric three-way valve module, the main filter pipeline module and the cooled device inlet pipeline module are sequentially connected through pipelines to form a main circulating loop. The small SVG water-air heat exchange device provided by the utility model utilizes modularized and generalized designs, integrates parts and systems with different functions into each module, changes the complex into simple, increases the space utilization rate in equipment, and simplifies the mechanical structure to the greatest extent under the condition of realizing the system functions, thereby realizing the cost reduction and the optimal design of the whole system.

Description

Small SVG water-air heat exchange device

Technical Field

The utility model relates to a cooling system, in particular to a small SVG water-air heat exchange device.

Background

The static var generator (Static Var Generator, SVG for short) is flexible alternating current power transmission and distribution system equipment which is gradually popularized and mature in the domestic power system at present, solves the problems of stability, voltage fluctuation and the like in the system by controlling reactive power, and improves the safe operation level and the electric energy quality of a power grid. SVG will generate a lot of heat during operation, and its cooling problems seriously affect the performance and reliability of the device. Therefore, an efficient heat dissipation method must be employed. The pure water circulating cooling system provides good heat dissipation conditions for the operation of SVG, simplifies the cooling system structure through the modularized design, improves the cooling efficiency, and enables the SVG device to safely and normally operate.

Disclosure of Invention

In order to solve the defects in the prior art, the utility model provides the small SVG water-air heat exchange device which is used for cooling the valve group and provides a reliable foundation for the platform and the universalization of a pure water cooling system by using a modularized design.

The utility model adopts the following technical scheme.

The main machine comprises a pump inlet pipeline module, a main circulating water pump, a pump outlet pipeline module, an electric three-way valve module, a main filter pipeline module and a cooled device inlet pipeline module; the pump inlet pipeline module, the main circulating water pump, the pump outlet pipeline module, the electric three-way valve module, the main filter pipeline module and the cooled device inlet pipeline module are sequentially connected through pipelines to form a main circulating loop.

Further, the small SVG water-air heat exchange device also comprises an ion tank module and a water supplementing system, wherein the water supplementing system comprises a water supplementing pipeline module, a buckling hose module and a non-electric quantity instrument module which are connected in sequence;

the first inlet of the ion tank module is connected with the bottom outlet of the inlet pipeline module of the cooled device through the buckling hose module, and the outlet of the ion tank module is connected with the pump inlet pipeline module through the buckling hose module.

Further, the outlet of the water supplementing pipeline module is connected with the inlet of the buckling hose module, the outlet of the buckling hose module is connected with the inlet of the non-electric quantity instrument module, and the outlet of the non-electric quantity instrument module is connected with the second inlet of the ion tank module.

Further, the small SVG water-wind heat exchange device also comprises an air bag expansion module and a frame system, wherein the frame system comprises a self-made frame module; the air bag expansion module is connected with the pump inlet pipeline module through a rubber hose, is connected with the pump inlet pipeline module and the main circulating water pump in series, and is fixed on a self-made frame module beam through bolts.

Further, the air bag expansion module is connected with the pump inlet pipeline module through a rubber hose.

Further, the frame system further comprises a frame side plate, wherein the frame side plate is fixed on the bottom plate, the upright posts and the cross beam of the self-made frame module through countersunk bolts, and the main filter pipeline module and the cooled device inlet pipeline module are fixed on the self-made frame module bottom plate through bolts.

Further, the small SVG water-air heat exchange device also comprises a bracket system, wherein the bracket system comprises a pump pipeline bracket, a three-way valve bracket and an ion tank body fixing beam module, the pump pipeline bracket is used for respectively connecting and fixing the pump inlet pipeline module and the pump outlet pipeline module with a self-made frame module bottom plate through bolts, the three-way valve bracket is used for connecting and fixing the electric three-way valve module with the self-made frame module bottom plate through bolts, the ion tank module is fixed on the ion tank body fixing beam module through bolts, and the ion tank body fixing beam module is fixed on a stand column of the self-made frame module through bolts; because the weight and the volume of the ion tank are smaller, the ion tank can be fixed in a mode of being hung on a beam, and an exhaust valve is arranged below the ion tank.

Further, the bottom of the main circulating water pump is fixed on the pump adapter plate module through bolts, and the pump adapter plate module is fixed with the bottom plate of the self-made frame module through bolts.

Further, the cooled device inlet pipeline module is connected with an electric quantity instrument module.

Further, the main line diameter of the main circulation loop was 1.5 inches.

Compared with the prior art, the small SVG water-air heat exchange device provided by the utility model has the beneficial effects that the modularized and generalized design is adopted, parts and systems with different functions are integrated into each module, the complex is simplified, the space utilization rate in the equipment is increased, and the mechanical structure is simplified to the greatest extent under the condition of realizing the system function, so that the cost reduction and the optimization design of the whole system are realized. The small SVG water-air heat exchange device has the advantages of simple and compact structure, increased space utilization rate, simple production process, convenient installation, effective improvement of production efficiency and reliable foundation for the platformization and universalization of the pure water cooling system.

Drawings

FIG. 1 is a schematic diagram of a front view of a small SVG water-wind heat exchange device;

FIG. 2 is a schematic diagram of the back of a small SVG water-wind heat exchange device;

FIG. 3 is a schematic diagram of the interior of a small SVG water-wind heat exchanger frame system.

1-a main circulating water pump; 2-a pump adapter module; 3-self-made frame module; 4-a pump inlet line module; 5-pump outlet line module; 6-an electric three-way valve module; 7-a main filter line module; 8-a cooled device inlet piping module; 9-an airbag inflation module; 10-an ion tank module; 11-a water replenishment line module; 12-crimping the hose module; 13-frame side panels; 14-a pump line bracket; 15-a three-way valve holder; 16-ion tank support; 17-an electric quantity meter module; 18-non-electrical meter module.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. The described embodiments of the utility model are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art without making any inventive effort, are within the scope of the present utility model.

As shown in fig. 1, 2 and 3, a small SVG water-air heat exchange device comprises a pump inlet pipeline module 4, a main circulating water pump 1, a pump outlet pipeline module 5, an electric three-way valve module 6, a main filter pipeline module 7 and a cooled device inlet pipeline module 8; the pump inlet pipeline module 4, the main circulating water pump 1, the pump outlet pipeline module 5, the electric three-way valve module 6, the main filter pipeline module 7 and the cooled device inlet pipeline module 8 are sequentially connected through pipelines to form a main circulating loop. Preferably, the main line diameter is 1.5 inches.

The small SVG water-air heat exchange device further comprises a water treatment loop, the water treatment loop comprises an ion tank module 10, an inlet of the ion tank module 10 is connected with an outlet at the bottom of the cooled device inlet pipeline module 8 through a buckling hose module 12, and an outlet of the ion tank module 10 is connected with the pump inlet pipeline module 4 through the buckling hose module 12. In order to meet the use requirement of high-power electronic equipment under the high-voltage condition and prevent leakage current from generating under the high-voltage environment, the cooling medium must have extremely low conductivity. Therefore, the deionized water treatment loop is connected in parallel with the main circulation cooling loop. A part of the cooling medium with preset flow rate flows through the ion tank module, so that ions possibly precipitated in the pipeline are continuously purified, and the ions are combined with the cooling medium of the main circulation loop before the main circulation pump after being filtered.

The small SVG water-air heat exchange device further comprises a water supplementing system, wherein the water supplementing system comprises a water supplementing pipeline module 11, a buckling hose module 12 and a non-electric quantity instrument module 18 which are sequentially connected, an outlet of the water supplementing pipeline module 11 is connected with an inlet of the buckling hose module 12, an outlet of the buckling hose module 12 is connected with one end of the non-electric quantity instrument module 18, and the other end of the non-electric quantity instrument module 18 is connected with a second inlet of the ion tank module 10.

The small SVG water-air heat exchange device further comprises a nitrogen pressure stabilizing system, the nitrogen pressure stabilizing system comprises an air bag expansion module 9, the air bag expansion module 9 is connected with the pump inlet pipeline module 4 through a rubber hose, the air bag expansion module 9 is sequentially connected with the pump inlet pipeline module 4 and the main circulating water pump 1 in series, and the air bag expansion module 9 is fixed on a beam of the self-made frame module 3 through bolts. The nitrogen pressure stabilizing system keeps the system pipeline full of cooling medium and isolates air. The expansion tank can buffer the capacity change of the cooling water caused by the temperature change. The top of the expansion tank is filled with high-purity nitrogen with stable pressure, and when the cooling medium is lost due to a small amount of extravasation or electrolysis, the nitrogen automatically expands to press the cooling medium into the circulating pipeline system so as to keep the pressure of the pipeline constant and fill the cooling medium.

The small SVG water-air heat exchange device further comprises a frame system, the frame system comprises a self-made frame module 3 and a frame side plate 13, the frame side plate 13 is fixed on a bottom plate, an upright post and a cross beam of the self-made frame module 3 through countersunk bolts, and the main filter pipeline module 7 and the cooled device inlet pipeline module 8 are fixed on the bottom plate of the self-made frame module 3 through bolts.

The small SVG water-air heat exchange device further comprises a support system, the support system comprises a pump pipeline support 14, a three-way valve support 15 and an ion tank body fixing beam module 16, the pump pipeline support 14 is used for connecting and fixing the pump inlet pipeline module and the pump outlet pipeline module 5 with the bottom plate of the self-made frame module 3 respectively through bolts, the three-way valve support 15 is used for connecting and fixing the electric three-way valve module 6 with the bottom plate of the self-made frame module 3 through bolts, and the ion tank body fixing beam module 16 is used for connecting and fixing the ion tank module 10 with the bottom plate of the self-made frame module 3 through bolts. Because the ion tank has smaller weight and volume, the ion tank can be fixed by hanging on a beam. An exhaust valve is arranged below the ion tank for emptying.

The bottom of the main circulating water pump 1 is fixed on the pump adapter plate module 2 through bolts, and the pump adapter plate module 2 is fixed with the bottom plate of the self-made frame module 3 through bolts.

The two main circulating water pumps 1 are connected in parallel. The two main circulating water pumps 1 can be used for one time, and the standby of one pump is prevented when the fault occurs.

The cooled device inlet pipeline module 8 is connected with the electric quantity instrument module 17, and the electric quantity instrument module 17 is connected with the cooled device inlet pipeline module 8.

The pump inlet pipeline module 4 and the pump outlet pipeline module 5 are manufactured by square pipes.

Compared with the prior art, the small SVG water-air heat exchange device provided by the utility model has the beneficial effects that the modularized and generalized design is adopted, parts and systems with different functions are integrated into each module, the complex is simplified, the space utilization rate in the equipment is increased, and the mechanical structure is simplified to the greatest extent under the condition of realizing the system function, so that the cost reduction and the optimization design of the whole system are realized. The small SVG water-air heat exchange device has the advantages of simple and compact structure, increased space utilization rate, simple production process, convenient installation, effective improvement of production efficiency and reliable foundation for the platformization and universalization of the pure water cooling system.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the above embodiments, it should be understood by those skilled in the art that: modifications and equivalents may be made to the specific embodiments of the utility model without departing from the spirit and scope of the utility model, which is intended to be covered by the claims.

Claims (10)

1. A small SVG water-wind heat exchange device is characterized in that: the small SVG water-air heat exchange device comprises a pump inlet pipeline module (4), a main circulating water pump (1), a pump outlet pipeline module (5), an electric three-way valve module (6), a main filter pipeline module (7) and a cooled device inlet pipeline module (8);

the device comprises a pump inlet pipeline module (4), a main circulating water pump (1), a pump outlet pipeline module (5), an electric three-way valve module (6), a main filter pipeline module (7) and a cooled device inlet pipeline module (8), which are sequentially connected through pipelines to form a main circulating loop.

2. The small SVG water-wind heat exchange device according to claim 1, wherein:

the small SVG water-air heat exchange device also comprises an ion tank module (10) and a water supplementing system, wherein the water supplementing system comprises a water supplementing pipeline module (11), a buckling hose module (12) and a non-electric quantity instrument module (18) which are connected in sequence;

the first inlet of the ion tank module (10) is connected with the outlet of the bottom of the cooled device inlet pipeline module (8) through the buckling hose module (12), and the outlet of the ion tank module (10) is connected with the pump inlet pipeline module (4) through the buckling hose module (12).

3. A compact SVG water-wind heat exchange device according to claim 2, characterized in that:

the outlet of the water supplementing pipeline module (11) is connected with the inlet of the buckling hose module (12), the outlet of the buckling hose module (12) is connected with the inlet of the non-electric quantity instrument module (18), and the outlet of the non-electric quantity instrument module (18) is connected with the second inlet of the ion tank module (10).

4. The small SVG water-wind heat exchange device according to claim 1, wherein:

the small SVG water-air heat exchange device also comprises an air bag expansion module (9) and a frame system, wherein the frame system comprises a self-made frame module (3);

the air bag expansion module (9) is sequentially connected with the pump inlet pipeline module (4) and the main circulating water pump (1) in series, and the air bag expansion module (9) is fixed on a beam of the self-made frame module (3) through bolts.

5. The small SVG water-wind heat exchange device according to claim 4, wherein:

the air bag expansion module (9) is connected with the pump inlet pipeline module (4) through a rubber hose.

6. The small SVG water-wind heat exchange device according to claim 4, wherein:

the frame system further comprises a frame side plate (13), the frame side plate (13) is fixed on the bottom plate, the upright posts and the cross beam of the self-made frame module (3) through countersunk bolts, and the main filter pipeline module (7) and the cooled device inlet pipeline module (8) are fixed on the bottom plate of the self-made frame module (3) through bolts.

7. The small SVG water-wind heat exchange device according to claim 4, wherein:

the small SVG water-air heat exchange device further comprises a bracket system, the bracket system comprises a pump pipeline bracket (14), a three-way valve bracket (15) and an ion tank body fixing beam module (16), the pump pipeline bracket (14) is used for connecting and fixing a pump inlet pipeline module and a pump outlet pipeline module (5) with a bottom plate of a self-made frame module (3) respectively through bolts, the three-way valve bracket (15) is used for connecting and fixing an electric three-way valve module (6) with the bottom plate of the self-made frame module (3) through bolts, the ion tank module (10) is fixed on the ion tank body fixing beam module (16) through bolts, and the ion tank body fixing beam module (16) is fixed on a stand column of the self-made frame module (3) through bolts; the ion tank is fixed in a mode of being hung on the cross beam, and an exhaust valve is arranged below the ion tank.

8. The small SVG water-wind heat exchange device according to claim 4, wherein:

the bottom of the main circulating water pump (1) is fixed on the pump adapter plate module (2) through bolts, and the pump adapter plate module (2) is fixed with the bottom plate of the self-made frame module (3) through bolts.

9. The small SVG water-wind heat exchange device according to claim 1, wherein:

the inlet pipeline module (8) of the cooled device is connected with the electric quantity instrument module (17).

10. The small SVG water-wind heat exchange device according to claim 1, wherein:

the main pipeline diameter of the main circulation loop is 1.5 inches.