A power device cooling device that is easy to install

By integrating the discharge components, sliding conveyor devices, and melted water cooling bonding components, the problems of inconvenient ice block transportation and insufficient utilization of ice water in power equipment cooling devices have been solved. This has enabled efficient insulation of ice blocks and secondary utilization of ice water, reducing consumption and costs while improving cooling effect.

CN117479490BActive Publication Date: 2026-07-10STATE GRID JIANGSU ELECTRIC POWER CO LTD NANJING POWER SUPPLY COMPANY

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
STATE GRID JIANGSU ELECTRIC POWER CO LTD NANJING POWER SUPPLY COMPANY
Filing Date
2023-10-17
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing power equipment cooling devices are not convenient for achieving labor-saving cooling, ice block refrigeration is not convenient for heat preservation and utilization, consumption is large and cost is high, and the melted ice water is not convenient for reuse. Overall consumption is large and the cooling effect is not practical and economical.

Method used

By employing a propulsion and discharge component and a sliding conveyor device, combined with a self-closing auxiliary component and a melt water cooling and bonding component, the ice blocks are automatically propelled and sealed for heat preservation. Melted ice water is used for auxiliary cooling, and a drive displacement adjustment device enables labor-saving and efficient movement. The ice water is reused, and a rapid exhaust and diffusion device is used for localized cooling.

Benefits of technology

It improves the utilization rate and cooling effect of ice blocks, reduces overall consumption, realizes the secondary use of ice water, reduces water waste, has a simple and reasonable structure, has a significant cooling effect, and lower cost.

✦ Generated by Eureka AI based on patent content.

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    Figure CN117479490B_ABST
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Abstract

The application provides a power equipment cooling device convenient to install, relates to the technical field of power equipment cooling, and comprises an installation guide part, a cooling collection device is fixedly welded on the installation guide part; a propelling and discharging piece is slidably connected to the cooling collection device, and the propelling and discharging piece is connected to a propelling and discharging driving device installed on the installation guide part; a sliding conveying device is installed on the installation guide part; a self-closing auxiliary piece is slidably connected to the cooling collection device; a driving displacement adjusting device is welded on the sliding conveying device; the self-closing auxiliary piece is arranged, can automatically open by using ice blocks, can be quickly closed and heat-insulated after the ice blocks are pushed out, effectively improves the utilization rate of the ice blocks, balances the cost of the ice blocks while guaranteeing the cooling effect, and solves the problems that the ice blocks of the current power equipment cooling device are inconvenient to heat-insulate and utilize, and the melted ice water is inconvenient to utilize for secondary utilization.
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Description

Technical Field

[0001] This invention relates to the field of power equipment cooling technology, and in particular to a power equipment cooling device that is easy to install. Background Technology

[0002] In the daily maintenance of electrical equipment, especially in machine rooms, a large number of electrical cabinets emit a lot of heat. Natural ventilation and other energy-saving methods are usually used to cool them down. When the temperature is high, air conditioning and other equipment are also used for cooling. However, it is not convenient to take care of some equipment that generates a lot of heat. Therefore, the industry often sees the use of ice to quickly absorb heat and cool down. This cooling method is more direct in installation, but it is not flexible or labor-saving to transport. Current power equipment cooling devices are not convenient for labor-saving cooling. At the same time, ice refrigeration is not convenient for heat preservation and utilization, and the consumption is large. It is also not convenient to use melted ice water for auxiliary secondary utilization. It is not practical and economical, and the overall consumption is large and the cost is high. Summary of the Invention

[0003] In view of this, the present invention provides an easy-to-install power equipment cooling device, which has a propulsion and discharge component that can realize hydraulic propulsion, effectively ensuring the heat preservation effect of the ice blocks to be used, and utilizing them one by one, reducing overall consumption and making it more economical.

[0004] This invention provides an easy-to-install power equipment cooling device, specifically including an installation guide, one end of which is fixed with a cooling collection device; a propulsion and discharge component is slidably connected to the cooling collection device, and the propulsion and discharge component is connected to a propulsion and discharge drive device mounted on the installation guide. The propulsion and discharge drive device drives the propulsion and discharge component to slide relative to the cooling collection device, for discharging ice blocks placed inside the cooling collection device in use; a sliding conveyor device is slidably mounted on the installation guide, for receiving and conveying the ice blocks discharging from the cooling collection device; a self-closing auxiliary component is slidably connected to the cooling collection device, for opening the cooling collection device when discharging ice blocks and closing the cooling collection device after discharging ice blocks; a rapid exhaust diffusion device is provided on the sliding conveyor device; the sliding conveyor device is provided with... A drive displacement adjustment device is provided, which drives the sliding conveyor to slide on the installation guide. A pumping and discharging device is installed on the installation guide, connected to a melting water cooling fitting. The melting water cooling fitting is used to adhere to the electrical cabinet in use, and the pumping and discharging device pumps water from the melted ice on the installation guide into the melting water cooling fitting to cool the electrical cabinet. The installation guide includes a mounting support guide slider and a guide mounting groove. The top of the mounting support guide slider has a groove, and the guide mounting groove is located at the bottom of the groove to receive water from the melted ice. The bottom end of the push-discharge component is installed in the groove and driven to slide within the groove by the drive displacement adjustment device. The push-discharge drive device is installed on the mounting support guide slider.

[0005] Furthermore, the installation guide also includes: four foot mounting blocks, which are respectively fixed on the installation support guide slider.

[0006] Furthermore, the cooling collection device includes: a double-layer ice storage and insulation shell and a snap-on cover plate. The double-layer ice storage and insulation shell is fixed on the mounting support guide slider. An ice outlet is opened on the front side of the bottom of the double-layer ice storage and insulation shell. The push-out discharge component extends into the double-layer ice storage and insulation shell from the rear side. The snap-on cover plate is snapped onto the double-layer ice storage and insulation shell. A self-closing auxiliary component is installed on the front side of the double-layer ice storage and insulation shell for opening and closing the ice outlet.

[0007] Furthermore, the propulsion and emission component includes: a propulsion and emission mounting block and a propulsion connection auxiliary plate. The propulsion and emission mounting block slides into the double-layer ice storage insulation shell from the rear side. The propulsion connection auxiliary plate is fixed to the rear side of the propulsion and emission mounting block and is connected to the propulsion and emission drive device.

[0008] Furthermore, the self-closing auxiliary component includes: a closing mounting slide shaft, a reset connecting spring, and a compression up-and-down movement control insulation plate. Two mounting plates are fixed to the front side of the double-layer ice storage insulation shell. Two closing mounting slide shafts are provided, each slidably connected to one of the two mounting plates. Each of the two closing mounting slide shafts is fitted with a reset connecting spring. The two reset connecting springs are respectively connected between the mounting plates and the top ends of the closing mounting slide shafts. The compression up-and-down movement control insulation plate is fixed to the bottom of the two closing mounting slide shafts. The bottom of the compression up-and-down movement control insulation plate near the ice outlet has a sloping structure. The compression up-and-down movement control insulation plate is slidably connected to the double-layer ice storage insulation shell.

[0009] Furthermore, the sliding conveying device includes: a sliding conveying plate, a diffusion installation and discharge hood, a one-way closed control door, and a control door switch limiting plate. The sliding conveying plate is slidably connected to a groove opened at the top of the mounting support guide slider. The diffusion installation and discharge hood is fixedly welded to the sliding conveying plate, and a row of diffusion slots is opened on both sides of the diffusion installation and discharge hood. The top of the one-way closed control door is rotatably connected to the diffusion installation and discharge hood. There are two control door switch limiting plates, which are respectively welded to the diffusion installation and discharge hood. The bottom of the diffusion installation and discharge hood has two through holes for drainage, so that the water generated by the melting ice is discharged into the guide installation groove.

[0010] Furthermore, the rapid exhaust diffusion device includes: a diffusion mounting cylinder, a diffusion mounting fan, and a diffusion auxiliary impeller. The diffusion mounting cylinder is fixedly welded to the diffusion mounting exhaust hood and communicates with the diffusion mounting exhaust hood. The diffusion mounting fan is mounted inside the diffusion mounting cylinder via a bracket. The diffusion auxiliary impeller is fixedly mounted on the output shaft of the diffusion mounting fan. The diffusion auxiliary impeller is located inside the diffusion mounting cylinder.

[0011] Furthermore, the drive displacement adjustment device includes: a drive motor frame, a drive transfer motor, and a drive gear. The drive motor frame is fixedly welded to the side of the diffuser installation emission hood; the drive transfer motor is fixed on the drive motor frame; the drive gear is fixed on the output shaft of the drive transfer motor; a drive rack is provided on the side where the support guide slider is installed, and the drive gear meshes with the drive rack.

[0012] Furthermore, the pumping and discharging device includes: a pumping and discharging pump and a connecting auxiliary pipe, the connecting auxiliary pipe being connected to the pumping and discharging pump; the pumping and discharging pump is fixedly installed on the side of the mounting support guide slider; the pumping and discharging pump is connected to the guide mounting groove.

[0013] Furthermore, the melting water cooling fitting includes: a cooling connecting water bag, connecting adhesive tape, a wastewater diversion and drainage pipe, and a wastewater drainage valve. The cooling connecting water bag is connected to the connecting auxiliary pipe. At least one side of the cooling connecting water bag is fixedly equipped with two connecting adhesive tapes. The wastewater diversion and drainage pipe is connected to the side of the cooling connecting water bag. A wastewater drainage valve is installed on the wastewater diversion and drainage pipe.

[0014] Compared with the prior art, the present invention has the following beneficial effects:

[0015] By employing a self-closing auxiliary component and utilizing an inclined structure, the ice block can be pushed in to automatically open, and then quickly close and retain heat after the ice block is pushed out, effectively improving the utilization rate of the ice block. Combined with the cooling collection device, a large number of ice blocks can be collected at once for unified allocation and use. The structure is simpler and more reasonable, which can effectively ensure the cooling effect while balancing the cost of ice blocks.

[0016] In addition, by using melted water cooling bonding components in conjunction with a pump discharge device, the ice water from melting ice can be fully utilized for auxiliary cooling work, ensuring the cooling effect of the structure, enabling secondary utilization of wastewater, improving energy conservation and environmental protection, and effectively reducing water waste.

[0017] In addition, the set drive displacement adjustment device can be used in conjunction with the sliding conveyor to achieve more labor-saving and efficient mobile conveying work, preventing the time-consuming and labor-intensive manual handling of ice blocks and the need to install ice blocks. This structure directly covers the ice blocks and uses air pressure to achieve assisted diffusion cooling, which can not only cool the overall environment, but also control the local heat generation. Attached Figure Description

[0018] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings of the embodiments will be briefly described below.

[0019] The accompanying drawings described below are only related to some embodiments of the invention and are not intended to limit the invention.

[0020] In the attached diagram:

[0021] Figure 1 This is a schematic diagram of the overall structure of the cooling device of the present invention.

[0022] Figure 2 This is a schematic diagram of the rear structure of the cooling device of the present invention.

[0023] Figure 3 This is a schematic diagram of the bottom structure of the cooling device of the present invention.

[0024] Figure 4 This is a cross-sectional view of the internal structure of the cooling device of the present invention.

[0025] Figure 5 This is a schematic diagram of the installation guide section of the present invention.

[0026] Figure 6 This is a schematic diagram of the cooling collection device of the present invention.

[0027] Figure 7 This is a cross-sectional view reflecting the structure of the cooling collection device, the sliding conveying device, and the propulsion and discharge component in this invention.

[0028] Figure 8 This is a schematic diagram of the self-closing auxiliary component structure of the present invention.

[0029] Figure 9 This is a schematic diagram of the sliding conveyor device of the present invention.

[0030] Figure 10 yes Figure 7 A magnified view of a section at point E in the middle.

[0031] Figure 11 yes Figure 2 A magnified view of a section at point D.

[0032] Figure 12 This is a schematic diagram of the pumping and discharging device and the melting water cooling and bonding component of the present invention.

[0033] Figure 13 yes Figure 12 A magnified view of a section at point F.

[0034] List of reference numerals

[0035] 1. Installation guide; 101. Installation support guide slider; 1011. Guide mounting groove; 102. Drive rack; 103. Drive propulsion hydraulic cylinder; 104. Foot mounting block; 2. Cooling collection device; 201. Double-layer ice storage insulation shell; 202. Mounting plate; 203. Embedded auxiliary window; 204. Snap-on cover plate; 3. Propulsion and discharge component; 301. Propulsion and discharge mounting block; 302. Propulsion connection auxiliary plate; 4. Self-closing auxiliary component; 401. Closing mounting slide shaft; 402. Reset connection tension spring; 403. Extrusion up and down movement control insulation plate; 5. Sliding conveyor device; 501. Sliding conveyor 502. Diffusion installation exhaust hood; 503. One-way closed control door; 5031. Control door switch limit plate; 6. Rapid exhaust diffusion device; 601. Diffusion installation cylinder; 602. Diffusion installation fan; 603. Diffusion auxiliary impeller; 7. Drive displacement adjustment device; 701. Drive motor frame; 702. Drive transfer motor; 703. Drive gear; 8. Pump-out discharge device; 801. Pump-out discharge pump; 802. Connecting auxiliary pipe; 9. Melting water cooling bonding piece; 901. Cooling connecting water bag; 902. Connecting adhesive tape; 903. Wastewater diversion and drainage pipe; 904. Wastewater drainage valve. Detailed Implementation

[0036] To make the objectives, solutions, and advantages of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Unless otherwise stated, the terms used herein have their ordinary meanings in the art. The same reference numerals in the drawings represent the same parts.

[0037] Example 1: Please refer to Figures 1 to 13 As shown:

[0038] This invention provides an easy-to-install power equipment cooling device, including an installation guide 1, with a cooling collection device 2 fixedly welded to one end of the installation guide 1; a pushing and discharging component 3 is slidably connected to the cooling collection device 2, and the pushing and discharging component 3 is connected to a pushing and discharging drive device installed on the installation guide 1, the pushing and discharging drive device driving the pushing and discharging component 3 to slide relative to the cooling collection device 2, for discharging ice blocks placed in the cooling collection device 2 in use; a sliding conveying device 5 is slidably installed on the installation guide 1, the sliding conveying device 5 is used to receive and convey the ice blocks discharging from the cooling collection device 2; a self-closing auxiliary component 4 is slidably connected to the cooling collection device 2, for opening the cooling collection device 2 when discharging ice blocks and closing the cooling collection device 2 after discharging ice blocks; a rapid exhaust diffusion device 6 is welded to the sliding conveying device 5; a drive displacement adjustment device 7 is welded to the sliding conveying device 5; the drive displacement adjustment device 7 is used to drive the sliding conveying device 5 to slide on the installation guide 1; the installation guide 1... The installation guide 1 is equipped with a pumping and discharging device 8; a melting water cooling fitting 9 is connected to the pumping and discharging device 8, which is used to fit onto the electrical cabinet in use. The pumping and discharging device 8 is used to pump the water after the ice on the installation guide 1 has melted into the melting water cooling fitting 9 to cool the electrical cabinet. The installation guide 1 includes: an installation support guide slider 101, a guide installation groove 1011, a drive rack 102, and a drive propulsion hydraulic cylinder 103, which is used for propulsion and discharge. The drive device has a sliding groove on the top of the mounting support guide slider 101, and a guide mounting groove 1011 is formed on the mounting support guide slider 101; the drive rack 102 is embedded in the edge of the mounting support guide slider 101 for engaging the drive displacement adjustment device 7; the drive propulsion hydraulic cylinder 103 is fixedly mounted on the mounting support guide slider 101, and the propulsion discharge component 3 is connected to the piston rod of the drive propulsion hydraulic cylinder 103. The extension and retraction of the piston rod of the drive propulsion hydraulic cylinder 103 is used to drive the movement of the propulsion discharge component 3.

[0039] The installation guide unit 1 further includes: four mounting blocks 104, which are fixedly welded to both ends of the mounting support guide slider 101. Two mounting blocks 104 are welded to each end of the mounting support guide slider 101. The cooling collection device 2 includes: a double-layer ice storage insulation shell 201, a mounting plate 202, an embedded auxiliary viewing window 203, and a snap-on cover plate 204. The double-layer ice storage insulation shell 201 is fixedly welded to the mounting support guide slider 101 and is used to hold ice blocks in use. An ice outlet is opened on the front side of the bottom of the double-layer ice storage insulation shell 201. Two mounting plates 204 are fixedly installed on the double-layer ice storage insulation shell 201. 02; An auxiliary viewing window 203 is embedded in the side of the double-layer ice storage insulation shell 201 and is made of transparent material, making it easy to observe the amount of ice inside the double-layer ice storage insulation shell 201; A snap-on cover 204 is snapped onto the double-layer ice storage insulation shell 201. Opening the snap-on cover 204 allows for adding ice to the double-layer ice storage insulation shell 201, and closing the snap-on cover 204 facilitates the insulation of the ice; A handle is provided on the top of the snap-on cover 204; The double-layer ice storage insulation shell 201 has a double-layer insulation structure, which provides better insulation and can effectively delay the melting of the ice stored inside the double-layer ice storage insulation shell 201; The propulsion and discharge component 3 includes: a propulsion and discharge mounting block 301 and a propulsion connecting auxiliary component. The auxiliary plate 302 has a movable through hole on the rear side of the bottom of the double-layer ice storage insulation shell 201, which is adapted to the shape of the push-out mounting block 301. The push-out mounting block 301 is disposed in the movable through hole and can move within the movable through hole. A push-connecting auxiliary plate 302 is fixedly welded to the rear side of the push-out mounting block 301, and the push-connecting auxiliary plate 302 is connected to the tail of the drive push hydraulic cylinder 103. The piston rod of the drive push hydraulic cylinder 103 extends and retracts, and the push-connecting auxiliary plate 302 pushes the push-out mounting block 301 to move horizontally within the movable through hole, pushing the ice block out of the ice outlet from the double-layer ice storage insulation shell 201. The self-closing auxiliary component 4 includes: a closing mounting slide 401, a reset... The insulation plate 403 for controlling the up-and-down movement of the compression spring 402 is connected to the compression spring 402. Two closed mounting shafts 401 are provided, each slidably connected to one of the two mounting plates 202 and capable of moving up and down relative to the mounting plates 202. Each of the two closed mounting shafts 401 is fitted with a reset connecting spring 402. The two reset connecting springs 402 are connected between the mounting plate 202 and the top of the closed mounting shaft 401. The insulation plate 403 for controlling the up-and-down movement of the compression spring 403 is fixedly welded to the bottom of the two closed mounting shafts 401. The rear side of the bottom of the insulation plate 403 is a sloping structure. The insulation plate 403 for controlling the up-and-down movement of the compression spring 403 is slidably connected to the double-layer ice storage insulation shell 201.The compression-driven up-and-down movement control insulation plate 403 is a double-layer insulation structure. Using a self-closing auxiliary component 4 and an inclined structure, it automatically opens when the ice block is pushed towards the compression-driven up-and-down movement control insulation plate 403 by the pushing and discharging installation block 301. Simultaneously, it quickly closes the ice outlet after discharging the ice block, effectively improving ice utilization. Combined with the cooling collection device 2, a large quantity of ice blocks can be collected at once for unified distribution. The pushing and discharging component 3 has a simple, convenient, labor-saving, and efficient propulsion method, enabling hydraulic propulsion and effectively ensuring the insulation effect of the ice blocks. Simultaneously, individual use reduces overall consumption and saves resources. The installation method is simple and convenient. When the inclined surface of the compression-driven up-and-down movement control insulation plate 403 is pressed, it moves upward, discharging the ice block. Pulled by the reset connecting spring 402, the compression-driven up-and-down movement control insulation plate 403 can reset and close. This cycle repeats, with the ice blocks moving downward one by one, achieving both discharge and insulation. ;

[0040] The sliding conveyor device 5 includes: a sliding conveyor plate 501, a diffusion installation and emission hood 502, a one-way closed control door 503, and a control door switch limiting plate 5031. The sliding conveyor plate 501 is slidably connected to a groove opened at the top of the mounting support guide slider 101. The diffusion installation and emission hood 502 is fixedly welded to the sliding conveyor plate 501, and a row of diffusion slots is opened on both sides of the diffusion installation and emission hood 502. The top end of the one-way closed control door 503 is rotatably connected to the diffusion installation and emission hood 502. Two control door switch limiting plates 5031 are provided. The diffuser is welded to the lower part of the left and right sides of the diffuser installation exhaust hood 502 respectively; the bottom of the diffuser installation exhaust hood 502 has two through holes for drainage, and the water from the melting ice inside the diffuser installation exhaust hood 502 is discharged into the guide installation groove 1011 through the through holes; the rapid exhaust diffusion device 6 includes: a diffuser installation cylinder 601, a diffuser installation fan 602 and a diffuser auxiliary impeller 603. The diffuser installation cylinder 601 is fixedly welded to the diffuser installation exhaust hood 502 and communicates with the diffuser installation exhaust hood 502; the diffuser installation fan 602 is installed inside the diffuser installation cylinder 601 by a bracket; the diffuser auxiliary impeller 603 is fixedly welded to the diffuser installation exhaust hood 502. The diffuser is fixedly installed on the output shaft of the diffuser fan 602; the diffuser auxiliary impeller 603 is located inside the diffuser cylinder 601, specifically on the side of the diffuser cylinder 601 near the diffuser exhaust hood 502; the drive displacement adjustment device 7 includes: a drive motor frame 701, a drive transfer motor 702, and a drive gear 703. The drive motor frame 701 is fixedly welded to the side of the diffuser exhaust hood 502; the drive transfer motor 702 is fixedly installed on the drive motor frame 701; the drive gear 703 is welded and fixed to the output shaft of the drive transfer motor 702; the drive gear 703 meshes with the drive rack 102. The drive displacement adjustment device 7 can work in conjunction with the sliding conveyor device 5 to achieve more labor-saving and efficient mobile conveying. When ice blocks need to be installed, this structure directly covers the ice blocks and uses air pressure to achieve assisted diffusion cooling. The mobile cooling method effectively ensures the flexibility of cooling, especially for local high temperatures, and can ensure the quality of cooling. The ice blocks slide on the sliding conveyor plate 501 to open the one-way closed control door 503. Then, under its own weight, the one-way closed control door 503 flips down and closes. The control door switch limit plate 5031 can prevent the one-way closed control door 503 from opening in the opposite direction.

[0041] Example 2: Based on Example 1, the pumping and discharging device 8 includes: a pumping and discharging pump 801 and a connecting auxiliary pipe 802, the connecting auxiliary pipe 802 being connected to the pumping and discharging pump 801; the pumping and discharging pump 801 is fixedly installed on the side of the mounting support guide slider 101; the pumping and discharging pump 801 is connected to the guide mounting groove 1011, and pumps water from the melting ice from the guide mounting groove 1011; the melting water cooling and bonding component 9 includes: a cooling connecting water bag 901, a connecting adhesive patch 902, a wastewater guide drain pipe 903, and a wastewater drain valve 904, the cooling connecting water bag 901 being connected to the connecting auxiliary pipe 802; two connecting adhesive patches are fixedly installed on the inner side of the cooling connecting water bag 901. 902 is attached; the wastewater diversion and drainage pipe 903 is connected to the side of the cooling connection water bag 901; a wastewater drainage valve 904 is installed on the wastewater diversion and drainage pipe 903. By using the melted water cooling adhesive 9 in conjunction with the pump discharge device 8, the ice water from the melting ice can be fully utilized for cooling assistance, ensuring the cooling effect of the structure and enabling secondary utilization of wastewater. At the same time, the structure is simple and convenient to install. The cooling connection water bag 901 is attached to the electrical cabinet using the connecting adhesive 902, which can be used for cooling at the bottom of the cabinet, making it more practical. Opening the wastewater drainage valve 904 can discharge the used ice water, forming a circulation, making the cooling efficient and reasonable, and lower in cost.

[0042] The specific usage and function of this embodiment are as follows: First, ice blocks are stored inside the double-layer ice storage insulation shell 201. The equipment is installed in the machine room corridor by bolts passing through the mounting blocks 104. Driven by the hydraulic cylinder 103, the discharge mounting block 301 is moved, pushing the ice blocks and pushing out the bottom layer of ice blocks. This compresses the insulation plate 403, causing its inclined surface to be pressed and moving upwards, thus discharging the ice blocks. The resetting connecting spring 402 extends, and after the ice blocks are expelled, the resetting connecting spring 402 pulls the insulation plate 403 back to its original position. This cycle repeats, with the ice blocks moving downwards one by one, achieving discharge and insulation. The drive gear 703 is driven by the drive motor 702 to rotate, meshing with the drive rack 102. The sliding conveyor plate 501 is driven to slide. The one-way closed control door 503 and the control door switch limit plate 5031 enable one-way ice entry and prevent leakage. When ice blocks are pushed on the sliding conveyor plate 501, the ice blocks slide on the sliding conveyor plate 501, which opens the one-way closed control door 503. Then, under its own weight, it flips down and closes. The control door switch limit plate 5031 prevents the one-way closed control door 503 from opening in the opposite direction. The diffuser fan 602 drives the diffuser auxiliary impeller 603 to rotate, which enables rapid exhaust ventilation. The cooling water bag 901 is attached to the electrical cabinet with the connecting adhesive 902. The ice water is drawn into the cooling water bag 901 by the pump 801 to cool the electrical equipment. The used ice water can be discharged by opening the wastewater drain valve 904.

[0043] The above description is merely an exemplary embodiment of the present invention and is not intended to limit the scope of protection of the present invention, which is determined by the appended claims.

Claims

1. A power equipment cooling device that is easy to install, comprising an installation guide (1), wherein a cooling collection device (2) is fixed to one end of the installation guide (1); characterized in that, The cooling collection device (2) is slidably connected to a propulsion and discharge component (3), and the propulsion and discharge component (3) is connected to a propulsion and discharge drive device installed on the installation guide (1). The propulsion and discharge drive device drives the propulsion and discharge component (3) to slide relative to the cooling collection device (2) to push out ice blocks placed in the cooling collection device (2) in the use state. A sliding conveyor device (5) is slidably installed on the installation guide (1). The sliding conveyor device (5) is used to receive and transport ice blocks pushed out from the cooling collection device (2). A self-closing auxiliary component (4) is slidably connected to the cooling collection device (2) to open the cooling collection device (2) when pushing out ice blocks and to close the cooling collection device (2) after pushing out ice blocks. A rapid exhaust diffusion device (6) is provided on the sliding conveyor device (5). A drive displacement adjustment device (7) is provided on the sliding conveyor device (5). The drive displacement adjustment device (7) is used to drive the sliding conveyor device (5) to slide relative to the cooling collection device (2) in the use state. The installation guide (1) slides on the installation guide (1); a pumping and discharging device (8) is installed on the installation guide (1), and the pumping and discharging device (8) is connected to a melting water cooling fitting (9). The melting water cooling fitting (9) is used to fit onto the electrical cabinet in the use state. The pumping and discharging device (8) is used to pump the water after the ice on the installation guide (1) melts into the melting water cooling fitting (9) to cool the electrical cabinet. The installation guide (1) includes: an installation support guide slider (101) The mounting support guide slider (101) and the guide mounting groove (1011) are provided with a groove on the top of the mounting support guide slider (101). The guide mounting groove (1011) is located on the bottom of the groove and is used to receive water after the ice melts. The bottom end of the push discharge component (3) is installed in the groove and is driven to slide in the groove by the drive displacement adjustment device (7). The push discharge drive device is installed on the mounting support guide slider (101).

2. The power equipment cooling device that is easy to install according to claim 1, characterized in that: The installation guide (1) further includes: four foot mounting blocks (104), which are respectively fixed on the installation support guide slider (101).

3. The power equipment cooling device that is easy to install according to claim 1, characterized in that: The cooling collection device (2) includes: a double-layer ice storage insulation shell (201) and a snap-on cover plate (204). The double-layer ice storage insulation shell (201) is fixed on the mounting support guide slider (101). An ice outlet is opened on the front side of the bottom of the double-layer ice storage insulation shell (201). The push-out discharge component (3) extends into the double-layer ice storage insulation shell (201) from the rear side. The snap-on cover plate (204) is snapped onto the double-layer ice storage insulation shell (201). The self-closing auxiliary component (4) is installed on the front side of the double-layer ice storage insulation shell (201) for opening and closing the ice outlet.

4. The power equipment cooling device that is easy to install according to claim 3, characterized in that: The propulsion and emission component (3) includes a propulsion and emission mounting block (301) and a propulsion connection auxiliary plate (302). The propulsion and emission mounting block (301) slides into the double-layer ice storage insulation shell (201) on the rear side. The propulsion connection auxiliary plate (302) is fixed on the rear side of the propulsion and emission mounting block (301) and is connected to the propulsion and emission drive device.

5. A power equipment cooling device that is easy to install according to claim 3, characterized in that: The self-closing auxiliary component (4) includes: a closing mounting slide (401), a reset connecting spring (402), and a compression up-and-down movement control insulation plate (403). Two mounting plates (202) are fixed on the front side of the double-layer ice storage insulation shell (201). There are two closing mounting slides (401), and the two closing mounting slides (401) are slidably connected to the two mounting plates (202) respectively. Each of the two closing mounting slides (401) is fitted with a reset connecting spring (402). The two reset connecting springs (402) are respectively connected between the mounting plate (202) and the top of the closing mounting slide (401). The compression up-and-down movement control insulation plate (403) is fixed to the bottom of the two closing mounting slides (401). The bottom of the compression up-and-down movement control insulation plate (403) near the ice outlet has a sloping structure. The compression up-and-down movement control insulation plate (403) is slidably connected to the double-layer ice storage insulation shell (201).

6. The power equipment cooling device that is easy to install according to claim 1, characterized in that: The sliding conveying device (5) includes: a sliding conveying plate (501), a diffusion installation and discharge hood (502), a one-way closed control door (503), and a control door switch limit plate (5031). The sliding conveying plate (501) is slidably connected to the groove opened at the top of the mounting support guide slider (101). The diffusion installation and discharge hood (502) is fixedly welded on the sliding conveying plate (501), and a row of diffusion slots are opened on both sides of the diffusion installation and discharge hood (502). The top of the one-way closed control door (503) is rotatably connected to the diffusion installation and discharge hood (502). There are two control door switch limit plates (5031), and the two control door switch limit plates (5031) are respectively welded to the diffusion installation and discharge hood (502). The bottom of the diffusion installation and discharge hood (502) has two through holes for drainage, so that the water generated by the melting of ice is discharged into the guide installation groove (1011).

7. A power equipment cooling device that is easy to install according to claim 6, characterized in that: The rapid exhaust diffusion device (6) includes: a diffusion mounting cylinder (601), a diffusion mounting fan (602), and a diffusion auxiliary impeller (603). The diffusion mounting cylinder (601) is fixedly welded to the diffusion mounting exhaust hood (502) and communicates with the diffusion mounting exhaust hood (502). The diffusion mounting fan (602) is installed inside the diffusion mounting cylinder (601) by a bracket. The diffusion auxiliary impeller (603) is fixedly installed on the output shaft of the diffusion mounting fan (602). The diffusion auxiliary impeller (603) is located inside the diffusion mounting cylinder (601).

8. A power equipment cooling device that is easy to install according to claim 6, characterized in that: The drive displacement adjustment device (7) includes: a drive motor frame (701), a drive transfer motor (702), and a drive gear (703). The drive motor frame (701) is fixedly welded to the side of the diffuser installation exhaust cover (502). The drive transfer motor (702) is fixed on the drive motor frame (701). The drive gear (703) is fixed on the output shaft of the drive transfer motor (702). A drive rack (102) is provided on one side of the mounting support guide slider (101), and the drive gear (703) meshes with the drive rack (102).

9. A power equipment cooling device that is easy to install according to claim 1, characterized in that: The pumping and discharging device (8) includes: a pumping and discharging pump (801) and a connecting auxiliary pipe (802), the connecting auxiliary pipe (802) being connected to the pumping and discharging pump (801); the pumping and discharging pump (801) is fixedly installed on the side of the mounting support guide slider (101); the pumping and discharging pump (801) is connected to the guide mounting groove (1011).

10. A power equipment cooling device that is easy to install according to claim 9, characterized in that: The melting water cooling bonding component (9) includes: a cooling connecting water bag (901), a connecting adhesive tape (902), a wastewater diversion drain pipe (903), and a wastewater drain valve (904). The cooling connecting water bag (901) is connected to the connecting auxiliary pipe (802). Two connecting adhesive tapes (902) are fixedly installed on at least one side of the cooling connecting water bag (901). The wastewater diversion drain pipe (903) is connected to the side of the cooling connecting water bag (901). A wastewater drain valve (904) is installed on the wastewater diversion drain pipe (903).