CN221102192U - Multi-channel heat radiation structure for energy storage equipment - Google Patents

Abstract

The utility model belongs to the technical field of heat dissipation of energy storage equipment, and particularly relates to a multichannel heat dissipation structure for the energy storage equipment. The energy storage device comprises a bottom plate, an exhaust hole, a water tank, a water pump, a main drainage pipe, a branch drainage pipe, a spray head, a condensation pipe and a condensation component, wherein an air inlet is formed in the outer surface of the energy storage device, and an air outlet is formed in the outer surface of the energy storage device. This a multichannel heat radiation structure for energy storage equipment through installing a plurality of heat abstractor simultaneously in energy storage equipment's inside, dispels the heat simultaneously to reserve equipment, has improved radiating effect.

Description

Multi-channel heat radiation structure for energy storage equipment

Technical Field

The utility model relates to the technical field of heat dissipation of energy storage equipment, in particular to a multichannel heat dissipation structure for energy storage equipment.

Background

The energy storage is mainly the storage of electric energy, and the energy storage equipment can be colloquially understood as a large-scale treasured that charges, stores the electric energy that can not be used at ordinary times, releases when using.

Existing energy storage devices include: ① Pumping energy storage belonging to hydropower, flywheel energy storage belonging to wind power and the like; ② A power battery, a lead-acid battery, a lithium ion battery and the like which belong to the new energy industry; ③ Electromagnetic energy storage, such as super capacitor, superconductive energy storage, etc., belongs to the power equipment industry.

With the vigorous development of new energy industry, the lithium battery industry is also laid out from a power battery to the energy storage field, and the development of the electrochemical energy storage industry has a huge application prospect, but a certain risk exists, wherein the heat dissipation problem is the primary problem to be solved urgently.

In the patent document with the publication number of CN 219321446U, a multi-channel heat dissipation structure for energy storage equipment is disclosed, the device is divided into a plurality of air outlets arranged at the left side, the right side and the upper part of a sheet metal part at the rear side of the energy storage equipment, and the air outlets are matched with an air inlet arranged at the lower part of an opening and closing door of the energy storage system equipment, so that air in the energy storage equipment circulates in three directions, the contact area with the equipment inside the energy storage box is increased, and therefore, compared with an air flowing mode in a single direction, heat dissipation is easier, and good cooling is realized without increasing the burden of the energy storage equipment; the bent plate of the blade forms an upward convex angle, so that external dust, rain, snow and other pollutants can be blocked, and the dust, rain, snow and other pollutants can slide into an external environment through the straight plate, so that the blade has the functions of rain, snow, dust, leaf falling and the like.

But the heat dissipation effect of the device on the energy storage device needs to be improved.

Therefore, we propose a multi-channel heat dissipation structure for energy storage devices in order to solve the above-mentioned problems.

Disclosure of utility model

The present utility model is directed to a multi-channel heat dissipation structure for an energy storage device, so as to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the multi-channel heat dissipation structure for the energy storage equipment comprises the energy storage equipment, wherein a heat dissipation device is arranged in the energy storage equipment, the heat dissipation device comprises an air cooling unit and a water cooling unit, the air cooling unit is arranged at the top of the energy storage equipment, and the water cooling unit is arranged at the bottom of the energy storage equipment;

The air cooling unit comprises an exhaust fan, an air inlet pipe, an exhaust pipe, a cooling air box, an exhaust pipe orifice and an air inlet pipe orifice, wherein the exhaust fan is arranged at the top of the energy storage device, the air inlet pipe is arranged at the left side of the exhaust fan, the exhaust pipe is arranged at the right side of the exhaust fan, the cooling air box is arranged at the right side of the exhaust pipe, the exhaust pipe orifice is arranged in the exhaust pipe, and the air inlet pipe orifice is arranged in the air inlet pipe;

The water cooling unit comprises a bottom plate, an exhaust hole, a water tank, a water pump, a main drainage pipe, a branch drainage pipe, a spray head, a condensing pipe and a condensing assembly, wherein the bottom plate is arranged inside the energy storage device, the exhaust hole is formed in the bottom plate, the water tank is arranged on the inner bottom surface of the energy storage device, the water pump is arranged on the front surface of the water tank, the main drainage pipe is arranged on the front surface of the water pump, the branch drainage pipe is arranged on the front surface of the main drainage pipe, the spray head is arranged at the bottom of the branch drainage pipe, the condensing assembly is arranged at the bottom of the water tank, and the condensing pipe is arranged on the front surface of the condensing assembly.

Preferably, the air intake has been seted up to the surface of energy storage equipment, the internally mounted of air intake has air intake blade, the air outlet has been seted up to the surface of energy storage equipment, the inside of air outlet is held that has air outlet blade, makes the inside air of energy storage equipment can circulate through installation air intake and air outlet, can prevent through installation air intake blade and air outlet blade that impurity such as dust from getting into inside the energy storage device.

Preferably, the condensation assembly comprises a condensation water pump and a condensation water tank, so that the whole condensation assembly puts condensate into the condensation pipe through the condensation water pump, and the condensate is stored through the condensation water tank.

Preferably, radiator fan is installed to the surface mounting of energy storage equipment, damping base is installed to the bottom of energy storage equipment, further improves energy storage equipment's radiating effect through installing radiator fan, and the stability of energy storage equipment can be further strengthened to the rethread at energy storage equipment bottom installation damping base to improve the practicality of device.

Preferably, the condensing pipes are arranged in a plurality of surrounding mode, the water cooling effect is improved through the condensing pipes, and meanwhile, the placing space can be saved through the surrounding mode.

Preferably, the air outlet blade and the air inlet blade are provided with a plurality of blades, the angle can be changed, and the air inlet and outlet size inside the energy storage device can be changed by adjusting the air outlet blade and the air inlet blade.

Preferably, the damping base comprises damping spring and damping rubber pad, promotes whole energy storage equipment's shock attenuation effect through damping spring and damping rubber pad.

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

1. This a multichannel heat radiation structure for energy storage equipment through at the top installation exhaust fan of energy storage equipment, starts the air that drives whole energy storage equipment top when the exhaust fan and carries out cold and heat exchange, and rethread cooling bellows transmits inside the energy storage equipment to accomplish the radiating effect to energy storage equipment.

2. This a multichannel heat radiation structure for energy storage equipment, through the water-cooling unit of bottom installation at energy storage equipment, spray water on the condenser pipe through the water tank for condenser pipe surface adheres to water molecules, through the cooling, makes the water molecules take place to solidify, thereby makes the inside temperature of whole energy storage equipment reduce.

Drawings

FIG. 1 is an overall block diagram of the present utility model;

FIG. 2 is a back block diagram of the present utility model;

FIG. 3 is a block diagram of a water cooling unit according to the present utility model;

FIG. 4 is a block diagram of an air cooling unit according to the present utility model;

Fig. 5 is an air cooling air inlet and outlet structure diagram of the utility model.

In the figure: 101. an energy storage device; 102. a shock absorbing base; 103. a heat radiation fan; 104. an air outlet; 105. an air outlet blade; 106. an air inlet; 107. air inlet blades; 201. an exhaust fan; 202. an air inlet pipe; 203. an exhaust pipe; 204. cooling the bellows; 205. an exhaust pipe orifice; 206. an air inlet pipe orifice; 301. a bottom plate; 302. an exhaust hole; 303. a water tank; 304. a water pump; 305. a drainage main pipe; 306. a water discharge branch pipe; 307. a spray head; 308. a condensing tube; 309. and (3) a condensing assembly.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. 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.

Referring to fig. 1-5, the present utility model provides a technical solution: the multichannel heat dissipation structure for the energy storage equipment comprises the energy storage equipment 101, wherein a heat dissipation device is arranged in the energy storage equipment 101 and comprises an air cooling unit and a water cooling unit, the air cooling unit is arranged at the top of the energy storage equipment 101, and the water cooling unit is arranged at the bottom of the energy storage equipment 101;

the air cooling unit comprises an exhaust fan 201, an air inlet pipe 202, an exhaust pipe 203, a cooling bellows 204, an exhaust pipe orifice 205 and an air inlet pipe orifice 206, wherein the exhaust fan 201 is arranged at the top of the energy storage device 101, the air inlet pipe 202 is arranged at the left side of the exhaust fan 201, the exhaust pipe 203 is arranged at the right side of the exhaust fan 201, the cooling bellows 204 is arranged at the right side of the exhaust pipe 203, the exhaust pipe orifice 205 is arranged in the exhaust pipe 203, and the air inlet pipe orifice 206 is arranged in the air inlet pipe 202;

The water cooling unit comprises a bottom plate 301, an exhaust hole 302, a water tank 303, a water pump 304, a main drainage pipe 305, a branch drainage pipe 306, a spray head 307, a condensation pipe 308 and a condensation component 309, wherein the bottom plate 301 is installed inside the energy storage device 101, the exhaust hole 302 is formed in the bottom plate 301, the water tank 303 is installed on the bottom surface of the energy storage device 101, the water pump 304 is installed on the front surface of the water tank 303, the main drainage pipe 305 is installed on the front surface of the water pump 304, the branch drainage pipe 306 is installed on the front surface of the main drainage pipe 305, the spray head 307 is installed at the bottom of the branch drainage pipe 306, the condensation component 309 is installed at the bottom of the water tank 303, and the condensation pipe 308 is installed on the front surface of the condensation component 309.

An air inlet 106 is formed in the outer surface of the energy storage device 101, an air inlet blade 107 is arranged in the inner portion of the air inlet 106, an air outlet 104 is formed in the outer surface of the energy storage device, the air outlet blade 105 is pressed against the inner portion of the air outlet 104, air in the energy storage device 101 can circulate through the air inlet 106 and the air outlet 104, and impurities such as dust can be prevented from entering the energy storage device 101 through the air inlet blade 107 and the air outlet blade 105.

The condensing assembly 309 includes a condensate pump and a condensate tank, such that the entire condensing assembly 309 delivers condensate into the condenser tube 308 via the condensate pump therein, and stores the condensate via the condensate tank.

The radiator fan 103 is arranged on the outer surface of the energy storage device 101, the damping base 102 is arranged at the bottom of the energy storage device 101, the radiating effect of the energy storage device 101 is further improved by arranging the radiator fan 103, and the stability of the energy storage device 101 can be further enhanced by arranging the damping base 102 at the bottom of the energy storage device 101, so that the practicability of the device is improved.

The condensing pipes 308 are arranged in a plurality, and the circulating type discharge improves the water cooling effect through the condensing pipes 308, and meanwhile, the circulating type discharge can save the placing space.

The air outlet blades 105 and the air inlet blades 107 are several, and the angles can be changed, so that the air inlet and outlet size inside the energy storage device 101 can be changed by adjusting the air outlet blades 105 and the air inlet blades 107.

The damping base 102 is composed of a damping spring and a damping rubber pad, and the damping effect of the whole energy storage device 101 is improved through the damping spring and the damping rubber pad.

Working principle: after the energy storage equipment 101 is started, the water pump 304 at the bottom of the energy storage equipment 101 is started, water in the water tank 303 is transported from the water tank 304 to the inside of the drainage main pipe 305 through the water pump 304, the water is transferred to the inside of the drainage branch pipe 306 through the drainage main pipe 305, finally, the water in the water tank 303 is sprayed through the spray head 307 arranged at the bottom of the drainage branch pipe 306, condensate in the condensate box in the condensate assembly 309 is pumped through the condensate water pump in the condensate assembly 309, the water is transported to the inside of the condensate pipe 308, the temperature is reduced through the condensate pipe 308, the water mist sprayed out by the spray head 307 is solidified and reduced, the cold air at the bottom of the energy storage equipment 101 circulates upwards, the temperature of the inside of the energy storage equipment 101 is reduced, the exhaust fan 201 arranged at the top of the energy storage equipment 101 starts to work, the air passing through the air inlet 106 is absorbed, the air passing through the cooling bellows 204 is absorbed from the air inlet 106, the hot air absorbed is reduced, the temperature of the inside the energy storage equipment 101 is discharged through the exhaust pipe 203, the temperature of the inside the energy storage equipment 101 is reduced, and finally the air in the inside the energy storage equipment 101 is circulated through the cooling fan 103, and the practicability of the device is improved.

It is noted that relational terms such as first and second, and the like are 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. Moreover, 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. Without further limitation, an element defined by the phrase "comprising one does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises an element.

Claims (7)

1. A multi-channel heat dissipating structure for an energy storage device, comprising an energy storage device (101), characterized in that: a heat dissipation device is arranged in the energy storage equipment (101), the heat dissipation device comprises an air cooling unit and a water cooling unit, the air cooling unit is arranged at the top of the energy storage equipment (101), and the water cooling unit is arranged at the bottom of the energy storage equipment (101);

The air cooling unit comprises an exhaust fan (201), an air inlet pipe (202), an exhaust pipe (203), a cooling air box (204), an exhaust pipe orifice (205) and an air inlet pipe orifice (206), wherein the exhaust fan (201) is arranged at the top of the energy storage device (101), the air inlet pipe (202) is arranged at the left side of the exhaust fan (201), the exhaust pipe (203) is arranged at the right side of the exhaust fan (201), the cooling air box (204) is arranged at the right side of the exhaust pipe (203), the exhaust pipe orifice (205) is arranged in the exhaust pipe (203), and the air inlet pipe orifice (206) is arranged in the air inlet pipe (202);

The water cooling unit comprises a bottom plate (301), an exhaust hole (302), a water tank (303), a water pump (304), a main drainage pipe (305), a main drainage pipe (306), a spray head (307), a condensation pipe (308) and a condensation component (309), wherein the bottom plate (301) is installed inside the energy storage device (101), the exhaust hole (302) is formed in the bottom plate (301), the water tank (303) is installed on the inner bottom surface of the energy storage device (101), the water pump (304) is installed on the front surface of the water tank (303), the main drainage pipe (305) is installed on the front surface of the water pump (304), the main drainage pipe (306) is installed on the front surface of the main drainage pipe (305), the spray head (307) is installed at the bottom of the main drainage pipe (306), the condensation component (309) is installed at the bottom of the water tank (303), and the condensation pipe (308) is installed on the front surface of the condensation component (309).

2. A multi-channel heat sink structure for an energy storage device as defined in claim 1, wherein: an air inlet (106) is formed in the outer surface of the energy storage device (101), air inlet blades (107) are mounted in the air inlet (106), an air outlet (104) is formed in the outer surface of the energy storage device, and air outlet blades (105) are pressed in the air outlet (104).

3. A multi-channel heat sink structure for an energy storage device as defined in claim 1, wherein: the condensing assembly (309) includes a condensate pump, a condensate tank.

4. A multi-channel heat sink structure for an energy storage device as defined in claim 1, wherein: the energy storage device is characterized in that a cooling fan (103) is arranged on the outer surface of the energy storage device (101), and a damping base (102) is arranged at the bottom of the energy storage device (101).

5. A multi-channel heat sink structure for an energy storage device as defined in claim 1, wherein: the condensing tubes (308) are arranged in a plurality, and are arranged in a surrounding mode.

6. A multi-channel heat sink structure for an energy storage device as defined in claim 2, wherein: the number of the air outlet blades (105) and the air inlet blades (107) is several, and the angles can be changed.

7. The multi-channel heat sink structure for an energy storage device of claim 4, wherein: the damping base (102) is composed of a damping spring and a damping rubber pad.