CN116209217A - Energy storage power supply capable of efficiently radiating and radiating method - Google Patents

Abstract

The invention discloses an energy storage power supply capable of efficiently radiating and a radiating method, and relates to the technical field of energy storage power supplies. When the cooling device is used, the motor is started firstly to drive the first impeller to rotate, and the second impeller is driven to rotate under the action of the transmission component, so that the rotating second impeller is utilized to enable air flow in the device to move upwards, and then the first impeller is utilized to form positive and negative pressure at the position of the air outlet pipe and the air outlet pipe of the air exhaust cylinder due to the eccentric design of the first impeller, so that heat in the device is further discharged into the air, and the heat cannot be gathered around the device to influence the integral heat dissipation effect, and the cooling circulation component is started in a matched mode, so that cooling liquid sequentially passes through the first fan frame and the cooling frame to be separated, and the cooling efficiency of the body is greatly improved.

Description

Energy storage power supply capable of efficiently radiating and radiating method

Technical Field

The invention relates to the technical field of energy storage power supplies, in particular to an energy storage power supply capable of efficiently radiating heat and a heat radiating method.

Background

The battery capacity of the energy storage power supply is large, in the use process, the battery and the circuit board of the energy storage power supply generate heat, so that the use safety of the energy storage power supply is guaranteed, heat is often dissipated in a mode of arranging a fan and the like in the energy storage power supply, and the heat dissipation effect of the energy storage power supply is poor in the mode.

The heat dissipation is carried out on a battery, a circuit board, a power device and the like in the energy storage power supply at present, wherein air cooling is utilized, and hot air is utilized to have high specific gravity, so that cold air sequentially passes through the battery, the circuit board and the power device along the bottom of the energy storage power supply and is discharged from the top of the energy storage power supply, and the heat dissipation is completed.

However, through the mechanism, when the battery works, the heat dissipation capacity is large, and the heat is dissipated upwards in sequence, so that the environment temperature of the components at the rear end is high, the normal work of the components is greatly influenced, the components with small heat resistance are damaged, and the overall maintenance cost is greatly improved.

Disclosure of Invention

Based on the above, the invention aims to provide an energy storage power supply with high-efficiency heat dissipation and a heat dissipation method, so as to solve the technical problems that in the prior art, as the heat dissipation capacity of a battery is large during operation, the heat dissipation is sequentially carried out upwards, the environment temperature of a rear-end component is high, the normal operation of the component is greatly influenced, and the component with low heat resistance is damaged, so that the whole maintenance cost is greatly improved.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a high-efficient radiating energy storage power supply, includes base, energy storage power supply frame, first fan frame, cooling frame, braced frame, components and parts installation frame, second fan frame and transmission frame, base, energy storage power supply frame, first fan frame, cooling frame, braced frame, components and parts installation frame, second fan frame are adjacent between through the block connection with the transmission frame, the outside of first fan frame is provided with first hollow seat and second hollow seat respectively symmetrically, communicate respectively between first hollow seat and the second hollow seat and be located the inside bottom cooling tube of first fan frame, the top intercommunication of first hollow seat has the conveyer pipe that runs through cooling frame to the opposite side, and the outside of cooling frame installs with conveyer pipe matched with water pump, the bottom intercommunication of second hollow seat has the outlet pipe, the outside symmetry of conveyer pipe is provided with the multiunit and the installation section of thick bamboo that is linked together with it, and the inside of installation section of thick bamboo is all rotated and is connected with the third impeller, the output is provided with along the fourth impeller to the inside of first fan frame;

the top of transmission frame is provided with the pump section of thick bamboo, and the motor is installed at the top of pump section of thick bamboo, the output of motor is provided with the first impeller that is located the pump section of thick bamboo inside, the inside of second fan frame evenly is provided with multiunit second impeller, and the inside of transmission frame be provided with respectively with second impeller, first impeller matched with drive assembly.

Through adopting above-mentioned technical scheme, the starter motor makes it drive first impeller and rotates, and under the effect of drive assembly, drive the rotation with the second impeller, consequently, utilize rotatory second impeller, make the inside air current of equipment upwards move, reuse first impeller's effect, because first impeller eccentric design, thereby make it form positive negative pressure in the outlet duct of section of thick bamboo of bleeding and exhaust tube department, further discharge the heat of equipment inside to in the air, and can not gather around equipment, and influence holistic radiating effect, secondly cooperate and start cooling circulation subassembly, make the coolant liquid pass through in first fan frame and the cooling frame in proper order, and at cooling circulation subassembly during operation, cooperate the mounted position of third impeller, make flowing coolant liquid drive the rotation with the fourth impeller, thereby utilize the effect of fourth impeller, the ascending of heat of being convenient for, and the in-process that rises, make it absorb heat, thereby pass through components and parts mount frame with cold wind, make it take away the heat in circuit board and the power device, therefore, the device is still carried away by the battery under the cooling circulation subassembly, but the cooling efficiency is greatly increased between the cooling plate and the cooling plate, thereby the cooling plate is greatly improved, and the cooling plate is cooled down by the cooling plate is set up.

The invention is further arranged that the base is connected with the energy storage power supply frame through the connecting bolts, and the energy storage power supply frame is connected with the first fan frame, the first fan frame is connected with the cooling frame, the cooling frame is connected with the component mounting frame, and the component mounting frame is connected with the transmission frame through the lock catches.

By adopting the technical scheme, equipment is convenient to install and disassemble, so that equipment maintenance efficiency is improved.

The invention is further arranged that the outer side of the air suction cylinder is communicated with an air suction pipe which is communicated with the inside of the transmission frame, and the outer side of the air suction cylinder is communicated with an air outlet pipe which is symmetrical to the air suction pipe.

Through adopting above-mentioned technical scheme, utilize exhaust tube and outlet duct to be convenient for take out the inside steam of transmission frame to make steam not gather around equipment.

The invention is further arranged that the outer sides of the second impeller and the fourth impeller are respectively matched with a first matching cylinder and a second matching cylinder, and the interiors of the first fan frame and the second fan frame are respectively provided with mounting grooves matched with the second matching cylinder and the first matching cylinder.

Through adopting above-mentioned technical scheme, utilize the effect of first cooperation section of thick bamboo and second cooperation section of thick bamboo, be convenient for install second impeller and fourth impeller, accomplish work.

The invention is further arranged that the outer sides of the energy storage power supply frames are provided with filter screens, and the four corners of the bottom of the base are provided with movable wheels.

Through adopting above-mentioned technical scheme, utilize the effect of filter screen, be convenient for make external gas get into in the equipment, accomplish the heat exchange.

The invention is further arranged that the transmission assembly comprises a first gear and a second gear, the bottom of the first impeller is provided with the first gear which is meshed with the first gear along the inner part of the transmission frame, and one end of the second impeller is provided with the second gear which is meshed with the first gear along the inner part of the transmission frame.

Through adopting above-mentioned technical scheme, utilize the effect of first gear, second gear, be convenient for will drive the second impeller and rotate to accomplish work.

The invention is further characterized in that the supporting frame is internally provided with the supporting hollowed-out plate, and four corners of the top of the supporting hollowed-out plate are respectively provided with a connecting plate.

Through adopting above-mentioned technical scheme, utilize the effect of supporting the fretwork board, be convenient for connect the connecting plate, the effect of reuse connecting plate is convenient for install circuit board and power supply device.

The invention is further arranged that the upper end and the lower end of the energy storage power supply frame are both provided with through holes.

Through adopting above-mentioned technical scheme, utilize the effect of through-hole, the heat dissipation of being convenient for.

The invention also provides a heat dissipation method of the energy storage power supply with high heat dissipation efficiency, which comprises the following steps:

step one: firstly, a cooling circulation assembly is started, so that cooling liquid passes through the upper part of an energy storage power supply, and when the cooling circulation assembly works, the third impeller 26 and the fourth impeller 28 are driven to rotate, so that heat emitted by the energy storage power supply can move upwards, and the filter screen 19 is combined, so that the energy storage power supply can rapidly dissipate heat;

step two: in the first step, cold air is led into the component mounting frame 5 through cold and heat exchange of the cooling liquid so as to radiate heat of the circuit board and the power supply device in the component mounting frame 5;

step three: simultaneously, the motor 10 is started to drive the first impeller 21 and drive the second impeller 24 to rotate under the action of the transmission component, so that the heat flow in the equipment is improved, and the heat dissipation efficiency is improved;

step four: the first impeller 21 rotating in the fourth step is utilized to form positive and negative pressure at the air outlet pipe 12 and the air outlet pipe 11 of the air suction barrel 9, so that heat in the equipment is rapidly sprayed out, accumulation is avoided around the equipment, and the whole heat dissipation effect is prevented from being influenced.

In summary, the invention has the following advantages: when the air pump is used, the motor is started firstly to drive the first impeller to rotate, and the second impeller is driven to rotate under the action of the transmission component, so that the air flow in the equipment moves upwards by utilizing the rotating second impeller, and positive and negative pressure is formed at the air outlet pipe and the air exhaust pipe of the air exhaust barrel by utilizing the action of the first impeller due to the eccentric design of the first impeller, so that heat in the equipment is further discharged into the air, and the heat is not accumulated around the equipment, so that the integral heat dissipation effect is influenced; secondly, the cooling circulation assembly is started in a matched mode, so that the cooling liquid sequentially passes through the first fan frame and the cooling frame, and in addition, when the cooling circulation assembly works, the cooling circulation assembly is matched with the mounting position of the third impeller, so that the flowing cooling liquid drives the third impeller to rotate, the fourth impeller is driven to rotate, the effect of the fourth impeller is utilized, the rising of heat is facilitated, in the rising process, the cooling circulation assembly is utilized to absorb and take away heat, cold air passes through the component mounting frame, the circuit board and the power supply device are enabled to take away heat, and therefore the device still dissipates heat from bottom to top, but the cooling circulation assembly is arranged between the battery and the circuit board, so that the cooling circulation assembly and the battery are separated, and the cooling efficiency of the body is greatly improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic view of the present invention in a cut-away configuration;

FIG. 3 is an enlarged view of the invention at A of FIG. 2;

FIG. 4 is a schematic view of an elevation cross-section of the present invention;

FIG. 5 is an enlarged view of the invention at B of FIG. 4;

fig. 6 is an enlarged view of fig. 4 at C in accordance with the present invention.

In the figure: 1. a base; 2. an energy storage power supply frame; 3. a first fan frame; 4. a cooling frame; 5. a support frame; 6. a component mounting frame; 7. a second fan frame; 8. a transmission frame; 9. a suction cylinder; 10. a motor; 11. an air outlet pipe; 12. an exhaust pipe; 13. locking; 14. a first hollow seat; 15. a second hollow seat; 16. a delivery tube; 17. a water pump; 18. a water outlet pipe; 19. a filter screen; 20. a moving wheel; 21. a first impeller; 22. a first gear; 23. a second gear; 24. a second impeller; 25. supporting the hollowed-out plate; 26. a third impeller; 27. a mounting cylinder; 28. a fourth impeller; 29. a cooling pipe; 30. a first mating cylinder; 31. a connecting plate; 32. a second mating cylinder; 33. and (5) connecting bolts.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

Hereinafter, an embodiment of the present invention will be described in accordance with its entire structure.

An energy storage power supply with high-efficiency heat dissipation, as shown in figures 1-6, comprises a base 1, an energy storage power supply frame 2, a first fan frame 3, a cooling frame 4, a supporting frame 5, a component mounting frame 6, a second fan frame 7 and a transmission frame 8, wherein the base 1, the energy storage power supply frame 2, the first fan frame 3, the cooling frame 4, the supporting frame 5, the component mounting frame 6, the second fan frame 7 and the transmission frame 8 are adjacently connected through clamping, the outer side of the first fan frame 3 is symmetrically provided with a first hollow seat 14 and a second hollow seat 15 respectively, the first hollow seat 14 and the second hollow seat 15 are respectively communicated with a cooling pipe 29 positioned at the inner bottom end of the first fan frame 3, a cooling circulation assembly is started in a matched mode, so that cooling liquid sequentially passes through the first fan frame 3 and the cooling frame 4, the top of the first hollow seat 14 is communicated with a conveying pipe 16 penetrating through the cooling frame 4 to the other side, the water pump 17 matched with the conveying pipe 16 is arranged on the outer side of the cooling frame 4, the water outlet pipe 18 is communicated with the bottom of the second hollow seat 15, a plurality of groups of mounting cylinders 27 communicated with the water outlet pipe are symmetrically arranged on the outer side of the conveying pipe 16, the inside of each mounting cylinder 27 is rotationally connected with a third impeller 26, the third impeller 26 is provided with a fourth impeller 28 along the inner part of the first fan frame 3 at the output end, when the cooling circulation assembly works, the cooling circulation assembly is matched with the mounting position of the third impeller 26, so that flowing cooling liquid drives the third impeller 26 to rotate, the fourth impeller 28 is driven to rotate, the heat is conveniently increased by utilizing the effect of the fourth impeller 28, in the rising process, the cooling circulation assembly absorbs and takes away the heat, cold air passes through the component mounting frame 6, and takes away the heat in the circuit board and the power supply device, therefore, although the device still radiates heat from bottom to top, the cooling circulation assembly is arranged between the battery and the circuit board, so that the battery and the circuit board are separated, and the cooling efficiency of the body increase is greatly improved; the top of transmission frame 8 is provided with pump bowl 9, and pump bowl 9 installs motor 10 at the top, start motor 10, make it drive first impeller 21 and rotate, the output of motor 10 is provided with the inside first impeller 21 that is located pump bowl 9, the inside of second fan frame 7 evenly is provided with multiunit second impeller 24, and transmission frame 8's inside is provided with respectively with second impeller 24, first impeller 21 matched with transmission assembly, under transmission assembly's effect, drive rotatory with second impeller 24, consequently, utilize rotatory second impeller 24, make the inside air current of equipment upwards move, utilize the effect of first impeller 21, because first impeller 21 eccentric design, thereby make it form positive negative pressure in the outlet duct 11 of pump bowl 9 and exhaust tube 12 department, further discharge the inside heat of equipment into the air, and can not gather around equipment, and influence holistic radiating effect.

Referring to fig. 4, the base 1 is connected with the energy storage power frame 2 through a connecting bolt 33, and the energy storage power frame 2 is connected with the first fan frame 3, the first fan frame 3 and the cooling frame 4, the cooling frame 4 and the component mounting frame 6, and the component mounting frame 6 and the transmission frame 8 through a lock catch 13, so that the equipment can be conveniently mounted and dismounted, and the equipment maintenance efficiency can be improved.

Referring to fig. 1, an exhaust pipe 12 is connected to the outside of the exhaust tube 9 and is connected to the inside of the transmission frame 8, an air outlet pipe 11 is connected to the outside of the exhaust tube 9 and is symmetrical to the exhaust pipe 12, and hot air in the transmission frame 8 is conveniently extracted by using the exhaust pipe 12 and the air outlet pipe 11, and is not accumulated around the equipment.

Referring to fig. 4, 5 and 6, the outer sides of the second impeller 24 and the fourth impeller 28 are respectively matched with a first matching cylinder 30 and a second matching cylinder 32, and the interiors of the first fan frame 3 and the second fan frame 7 are respectively provided with mounting grooves matched with the second matching cylinder 32 and the first matching cylinder 30, so that the second impeller 24 and the fourth impeller 28 can be conveniently mounted by utilizing the functions of the first matching cylinder 30 and the second matching cylinder 32 to finish the work.

Referring to fig. 1 and 3, the outside of the energy storage power frame 2 is provided with a filter screen 19, and four corners of the bottom of the base 1 are provided with moving wheels 20, so that external air can enter the device to complete heat exchange under the action of the filter screen 19.

Referring to fig. 4 and 5, the transmission assembly includes a first gear 22 and a second gear 23, the bottom of the first impeller 21 is provided with the first gear 22 along the inner portion of the transmission frame 8, one end of the second impeller 24 is provided with the second gear 23 meshed with the first gear 22 along the inner portion of the transmission frame 8, and the second impeller 24 is conveniently driven to rotate by the action of the first gear 22 and the second gear 23 so as to complete the work.

Referring to fig. 4 and 6, the supporting hollow plate 25 is disposed in the supporting frame 5, so that the connecting plate 31 is conveniently connected by using the supporting hollow plate 25, and the connecting plates 31 are disposed at four corners of the top of the supporting hollow plate 25, so that the circuit board and the power device are conveniently mounted by using the connecting plates 31.

Referring to fig. 4 and 6, through holes are formed at the upper and lower ends of the energy storage power frame 2, so that heat dissipation is facilitated by the effect of the through holes.

The invention also provides a heat dissipation method of the energy storage power supply with high heat dissipation efficiency, which comprises the following steps:

step one: firstly, a cooling circulation assembly is started, so that cooling liquid passes through the upper part of an energy storage power supply, and when the cooling circulation assembly works, the third impeller 26 and the fourth impeller 28 are driven to rotate, so that heat emitted by the energy storage power supply can move upwards, and the filter screen 19 is combined, so that the energy storage power supply can rapidly dissipate heat;

step two: in the first step, cold air is led into the component mounting frame 5 through cold and heat exchange of the cooling liquid so as to radiate heat of the circuit board and the power supply device in the component mounting frame 5;

step three: simultaneously, the motor 10 is started to drive the first impeller 21 and drive the second impeller 24 to rotate under the action of the transmission component, so that the heat flow in the equipment is improved, and the heat dissipation efficiency is improved;

step four: the first impeller 21 rotating in the fourth step is utilized to form positive and negative pressure at the air outlet pipe 12 and the air outlet pipe 11 of the air suction barrel 9, so that heat in the equipment is rapidly sprayed out, accumulation is avoided around the equipment, and the whole heat dissipation effect is prevented from being influenced.

The working principle of the invention is as follows: when the cooling device is used, the base 1, the energy storage power supply frame 2, the first fan frame 3, the cooling frame 4, the supporting frame 5, the component mounting frame 6, the second fan frame 7 and the transmission frame 8 are connected in a vertically clamping manner, and the base 1, the energy storage power supply frame 2, the first fan frame 3, the cooling frame 4, the supporting frame 5, the component mounting frame 6 and the second fan frame 7 are connected with the outer sides of the transmission frame 8 through lock catches 13;

then, the delivery pipe 16 and the water outlet pipe 18 are respectively connected with an external water tank, and then a cooling circulation assembly is started, wherein the cooling circulation assembly comprises a water pump 17, the delivery pipe 16, a first hollow seat 14, a cooling pipe 29, a second hollow pipe 15 and the water outlet pipe 18, namely, the water pump 17 is started to pump cooling liquid in the water tank into the delivery pipe 16, and the cooling liquid passes through the first hollow seat 14, the cooling pipe 29, the second hollow pipe 15 and the water outlet pipe 18 to finish circulation of the cooling liquid;

in the circulating process, the flowing cooling liquid drives the third impeller 26 to rotate, so that the fourth impeller 28 is driven to rotate, and after heat is dissipated by the energy storage power supply, the heat of the fourth impeller 28 moves upwards under the action of the fourth impeller 28 and is cooled by the cooling pipe 29, so that the output hot air is cold air, and a good environment is provided for heat dissipation of a subsequent circuit board and a power supply device;

next, the motor 10 is started to drive the first impeller 21 to rotate, and the second impeller 24 is driven to rotate under the action of the transmission component, so that the air flow in the equipment moves upwards by utilizing the rotating second impeller 24, so that the heat dissipation of the circuit board and the power supply device is finished, and the first impeller 21 is utilized, and due to the eccentric design of the first impeller 21, positive and negative pressure is formed at the air outlet pipe 11 and the air outlet pipe 12 of the air outlet barrel 9, so that heat in the equipment is further discharged into the air, and the heat is not accumulated around the equipment, so that the integral heat dissipation effect is affected.

Although embodiments of the invention have been shown and described, the detailed description is to be construed as exemplary only and is not limiting of the invention as the particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples, and modifications, substitutions, variations, etc. may be made in the embodiments as desired by those skilled in the art without departing from the principles and spirit of the invention, provided that such modifications are within the scope of the appended claims.

Claims (9)

1. The utility model provides a high-efficient radiating energy storage power, includes base (1), energy storage power frame (2), first fan frame (3), cooling frame (4), braced frame (5), components and parts installing frame (6), second fan frame (7) and transmission frame (8), base (1), energy storage power frame (2), first fan frame (3), cooling frame (4), braced frame (5), components and parts installing frame (6), second fan frame (7) are adjacent to be connected through the block between its characterized in that with transmission frame (8): the cooling device is characterized in that a first hollow seat (14) and a second hollow seat (15) are symmetrically arranged on the outer side of the first fan frame (3) respectively, a plurality of groups of installation cylinders (27) communicated with the first hollow seat (14) and the second hollow seat (15) are respectively communicated with a cooling pipe (29) positioned at the bottom end inside the first fan frame (3), a conveying pipe (16) penetrating through the cooling frame (4) to the other side is communicated with the top of the first hollow seat (14), a water pump (17) matched with the conveying pipe (16) is arranged on the outer side of the cooling frame (4), a water outlet pipe (18) is communicated with the bottom of the second hollow seat (15), a plurality of groups of installation cylinders (27) communicated with the conveying pipe are symmetrically arranged on the outer side of the conveying pipe (16), third impellers (26) are rotatably connected inside the installation cylinders (27), and the third impellers (26) are fourth impellers (28) arranged along the direction from the output ends to the inner side of the first fan frame (3);

the top of transmission frame (8) is provided with pump bowl (9), and motor (10) are installed at the top of pump bowl (9), the output of motor (10) is provided with first impeller (21) that are located pump bowl (9) inside, the inside of second fan frame (7) evenly is provided with multiunit second impeller (24), and the inside of transmission frame (8) is provided with respectively with second impeller (24), first impeller (21) matched with drive assembly.

2. The high efficiency heat dissipating energy storage power supply of claim 1, wherein: the base (1) is connected with the energy storage power supply frame (2) through connecting bolts (33), and the energy storage power supply frame (2) is connected with the first fan frame (3), the first fan frame (3) and the cooling frame (4), the cooling frame (4) and the component mounting frame (6) and the transmission frame (8) through lock catches (13).

3. The high efficiency heat dissipating energy storage power supply of claim 1, wherein: the outside intercommunication of section of thick bamboo (9) of bleeding has exhaust tube (12) that are linked together with transmission frame (8) inside, the outside intercommunication of section of thick bamboo (9) of bleeding has outlet duct (11) with exhaust tube (12) symmetry.

4. The high efficiency heat dissipating energy storage power supply of claim 1, wherein: the outer sides of the second impeller (24) and the fourth impeller (28) are respectively matched with a first matching cylinder (30) and a second matching cylinder (32), and mounting grooves matched with the second matching cylinder (32) and the first matching cylinder (30) are respectively formed in the first fan frame (3) and the second fan frame (7).

5. The high efficiency heat dissipating energy storage power supply of claim 1, wherein: the outer sides of the energy storage power supply frames (2) are provided with filter screens (19), and four corners of the bottom of the base (1) are provided with movable wheels (20).

6. The high efficiency heat dissipating energy storage power supply of claim 1, wherein: the transmission assembly comprises a first gear (22) and a second gear (23), the bottom of the first impeller (21) is provided with the first gear (22) which is arranged inside the transmission frame (8), and one end of the second impeller (24) is provided with the second gear (23) which is meshed with the first gear (22) inside the transmission frame (8).

7. The energy-storage power supply with high heat dissipation and the heat dissipation method according to claim 1, wherein: the inside of supporting frame (5) is provided with supports fretwork board (25), the top four corners department of supporting fretwork board (25) all is provided with connecting plate (31).

8. The high efficiency heat dissipating energy storage power supply of claim 1, wherein: the upper end and the lower end of the energy storage power supply frame (2) are provided with through holes.

9. The heat dissipation method of an energy storage power supply with high heat dissipation efficiency according to claim 1, comprising the following steps:

step one: firstly, starting a cooling circulation assembly to enable cooling liquid to pass through the upper part of an energy storage power supply, and driving a third impeller (26) and a fourth impeller (28) to rotate when the cooling circulation assembly works, so that heat emitted by the energy storage power supply can move upwards, and combining a filter screen (19) to enable the energy storage power supply to rapidly dissipate heat;

step two: cold air enters the component mounting frame (5) through cold and heat exchange of the cooling liquid in the first step so as to radiate heat of the circuit board and the power supply device in the component mounting frame (5);

step three: simultaneously, the motor (10) is started to drive the first impeller (21) and drive the second impeller (24) to rotate under the action of the transmission component, so that the heat flow in the equipment is improved, and the heat dissipation efficiency is improved;

step four: the first impeller (21) rotating in the fourth step is utilized to form positive and negative pressure at the air outlet pipe (12) and the air outlet pipe (11) of the air suction barrel (9), so that heat in the equipment is rapidly sprayed out, accumulation is avoided around the equipment, and the whole heat dissipation effect is prevented from being influenced.

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