CN115789404B - Electromechanical equipment mounting device and use method thereof - Google Patents

Abstract

The invention discloses an electromechanical device mounting device and a using method thereof, and belongs to the technical field of electromechanical devices. The utility model provides an electromechanical device installation device, including mount pad and equipment main part, the equipment main part sets up on the mount pad, the mount pad includes the base and places the board, the center department of placing the board has seted up the shrinkage pool, be provided with the grid board in the shrinkage pool, be provided with on the board of placing and be circumference evenly distributed and be used for the centre gripping subassembly of fixed equipment main part, every centre gripping subassembly all is including setting firmly the curb plate on placing the board, be provided with the elastic expansion link on the curb plate, the one end that the elastic expansion link kept away from the curb plate is connected with the heat conduction grip block, the heat conduction grip block offsets with the equipment main part activity, be provided with heat transfer cooling subassembly on the heat conduction grip block, be provided with damper between placing board and the base, be connected with radiator unit on the damper; the invention can realize the rapid installation and positioning of the equipment main body, and the installation seat has the effects of effectively cooling and damping the equipment main body, thereby ensuring the service life of the electromechanical equipment.

Description

Electromechanical equipment mounting device and use method thereof

Technical Field

The invention relates to the technical field of electromechanical equipment, in particular to an electromechanical equipment installation device and a use method thereof.

Background

It is well known that the electromechanical equipment not only can greatly improve the labor productivity, lighten the labor intensity, improve the production environment and complete the work which cannot be completed by manpower, but also is used as one of the national industrial bases, has direct and important influence on the development of the national economy and the improvement of science and technology and national defense strength, and is an important mark for measuring the national science and technology level and comprehensive national force.

In the using process of the electromechanical equipment, the electromechanical equipment is usually required to be fixedly installed, when the existing electromechanical equipment is installed, the electromechanical equipment is usually fixed by adopting screws, and in the screw fixing process, the installation and the disassembly are inconvenient, and when the electromechanical equipment is damaged and overhauled, the screws are easy to lose, so that inconvenience is caused to the installation process; simultaneously, the electromechanical equipment generates heat and vibration in the operation process, and the potential safety hazard can be caused to the electromechanical equipment due to the fact that the electromechanical equipment is subjected to too high temperature and severe shaking, the existing equipment mounting seat cannot be effectively cooled and damped, and the service life of the electromechanical equipment is influenced.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides an electromechanical equipment installation device and a use method thereof.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the utility model provides an electromechanical device installation device, includes mount pad and equipment body, the equipment body sets up on the mount pad, the mount pad includes the base and places the board, the center department of placing the board has seted up the shrinkage pool, be provided with the net board in the shrinkage pool, be provided with the centre gripping subassembly that is circumference evenly distributed and be used for the fixed equipment body on placing the board, every the centre gripping subassembly is all including setting firmly the curb plate on placing the board, be provided with the elastic expansion pole on the curb plate, the one end that the curb plate was kept away from to the elastic expansion pole is connected with the heat conduction grip block, the heat conduction grip block offsets with the equipment body activity, be provided with heat transfer cooling subassembly on the heat conduction grip block, be provided with damper between placing board and the base, be connected with radiator unit on the damper.

Preferably, the elastic telescopic rod comprises a sleeve fixedly connected with the side plate and an inner rod connected with the heat conduction clamping plate, the inner rod is arranged in the sleeve in a sliding mode, a first elastic element is arranged between the inner rod and the inner wall of the sleeve, and a limiting assembly used for limiting movement of the inner rod is arranged on the sleeve.

Preferably, the limiting component comprises a movable block arranged on the sleeve in a sliding manner, a sliding block is arranged on the movable block, a sliding groove matched with the sliding block is formed in the sleeve, a second elastic element is arranged between the sliding groove and the sliding block, a limiting plate is arranged on the movable block through a pin shaft, a torsion spring for resetting and rotating the limiting plate is sleeved on the pin shaft, the limiting component further comprises a flat groove formed in the inner rod, and ratchets which are uniformly distributed and are movably propped against the limiting plate are arranged in the flat groove.

Preferably, the damping component comprises a guide pipe fixedly arranged on the base, a piston block is arranged in the guide pipe in a sliding mode, the guide pipe is divided into an air cavity and a water cavity by the piston block, two one-way valve bodies are arranged in the air cavity and the water cavity, a third elastic element is arranged between the piston block and the inner wall of the guide pipe, a guide rod is arranged on one side, away from the third elastic element, of the piston block, and one end, away from the piston block, of the guide rod is fixedly connected with the placing plate.

Preferably, the radiating component comprises an air duct which is mutually communicated with the guide pipe air cavity, one end of the air duct, which is far away from the guide pipe, is provided with a connecting pipe seat, two openings are formed in the connecting pipe seat, the openings are respectively connected with a first air duct and a second air duct, one end, which is far away from the connecting pipe seat, of the first air duct is provided with an air outlet bucket, one end, which is far away from the connecting pipe seat, of the second air duct penetrates through the placing plate and is connected with an air outlet plate, the air outlet plate is connected with the heat conduction clamping plate, a first cavity which is mutually communicated with the second air duct is formed in the air outlet plate, and an air outlet which is mutually communicated with the cavity is formed in the air outlet plate.

Preferably, the support plate is arranged on the base, the rotating rod is arranged on the support plate, the moving gear and the main bevel gear are arranged on the rotating rod, the rack plate meshed with the moving gear is arranged on the guide rod, the telescopic pipe is arranged at the bottom of the placing plate, the auxiliary bevel gear meshed with the main bevel gear is arranged on the telescopic pipe, the connecting pipe seat is connected with the air duct through the bearing in a rotating mode, the fixing rod is arranged on the connecting pipe seat, the synchronizing wheels are arranged on the fixing rod and the telescopic pipe, and the synchronous belt is arranged between the synchronizing wheels.

Preferably, the heat exchange cooling component comprises a water outlet pipe which is mutually communicated with the water cavity of the guide pipe, one end of the water outlet pipe, far away from the guide pipe, penetrates through the placing plate and is connected with the heat conduction clamping plate, a second cavity which is mutually communicated with the water outlet pipe is formed in the heat conduction clamping plate, a water outlet which is mutually communicated with the second cavity is formed in the heat conduction clamping plate, the heat exchange cooling component further comprises a water tank which is fixedly arranged on the base, and a water inlet pipe is arranged between the water tank and the water cavity of the guide pipe.

Preferably, the heat conduction clamping plate is provided with a spray groove, the water outlet is arranged in the spray groove, the bottom of the spray groove is symmetrically provided with guide surfaces, a water inlet bucket is arranged at the junction of the two guide surfaces, and a water return pipe is arranged between the water inlet bucket and the water tank.

Preferably, a heat-conducting silica gel gasket is arranged on one side, away from the spraying groove, of the heat-conducting clamping plate, and the heat-conducting silica gel gasket is movably propped against the equipment main body.

The invention also discloses a using method of the electromechanical equipment installation device, which comprises the following steps:

s1: when the equipment main body is installed, the equipment main body is placed at the center of the placing plate, and then the heat conduction clamping plate is pushed to move towards the equipment main body and finally prop against the equipment main body, so that the equipment main body can be quickly installed and positioned, heat generated during the operation of the equipment main body can be transferred by the heat conduction clamping plate, and the stretched elastic telescopic rod can be limited by the limiting component on the elastic telescopic rod;

s2: when the equipment main body is in operation, vibration amplitude of the equipment main body is buffered through the damping component, and in the process, the damping component drives the heat dissipation component to work, so that the air outlet hopper at the end part of the first air pipe is opposite to the grid plate, the bottom of the equipment main body is dissipated, the air outlet plate arranged at the end part of the second air pipe dissipates heat of the heat conduction clamping plate, the heat conduction clamping plate with lower temperature is in contact with the equipment main body with higher temperature, and heat exchange and cooling are carried out between the heat conduction clamping plate and the equipment main body;

s3: and at damper during operation, heat transfer cooling module synchronous operation makes the heat conduction grip block dorsad contact with the lower clear water of temperature from one side of equipment main part, and clear water flows on the heat conduction grip block, cools down the heat conduction grip block, and the air outlet plate of second trachea tip blows the heat conduction grip block through the gas outlet simultaneously, makes the air in the heat conduction grip block outside flow fast for the evaporation rate of clear water on the heat conduction grip block, cools down the heat conduction grip block fast, and then makes heat transfer cooling between heat conduction grip block and the equipment main part, operating temperature when the reduction equipment main part is operated.

Compared with the prior art, the invention provides the electromechanical equipment installation device and the use method thereof, which have the following beneficial effects:

1. according to the electromechanical equipment installation device and the application method thereof, the heat conduction clamping plates are arranged through elasticity, so that the equipment main body can be installed and positioned rapidly, and when the equipment main body operates, the damping component works to drive the heat dissipation component and the heat exchange cooling component to act, so that the installation seat has the effects of effectively cooling and damping the equipment main body, and the service life of the electromechanical equipment is guaranteed.

2. According to the electromechanical equipment installation device and the application method thereof, vibration generated during operation of the equipment main body is used as an original driving force, so that the bottom and the side edges of the equipment main body are effectively cooled and radiated by the radiating component.

3. According to the electromechanical equipment installation device and the application method thereof, clear water is sprayed on the heat-conducting radiating plate through the vibration reduction assembly during operation, air blown by the heat radiation assembly can enable air outside the heat-conducting clamping plate to flow rapidly, so that the evaporation rate of the clear water on the heat-conducting clamping plate is accelerated, the heat-conducting clamping plate is cooled rapidly, heat exchange and cooling are carried out between the heat-conducting clamping plate and the equipment main body, the working temperature of the equipment main body during operation is reduced, and the service life of electromechanical equipment is guaranteed.

Drawings

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

FIG. 2 is a schematic diagram of a second embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of the present invention;

FIG. 4 is an enlarged schematic view of portion A of FIG. 3 in accordance with the present invention;

FIG. 5 is a schematic diagram of a cross-sectional structure of the present invention;

FIG. 6 is an enlarged schematic view of part B of FIG. 5 in accordance with the present invention;

FIG. 7 is a schematic cross-sectional view of an elastic telescopic rod according to the present invention;

FIG. 8 is a schematic diagram of a shock absorbing assembly and a heat dissipating assembly according to the present invention;

fig. 9 is a schematic cross-sectional view of a heat conductive clamping plate according to the present invention.

In the figure: 1. a base; 2. placing a plate; 201. concave holes; 202. a grid plate; 203. a side plate; 3. an apparatus main body; 4. an elastic telescopic rod; 401. a sleeve; 4011. a chute; 402. an inner rod; 4021. a ratchet; 403. a first elastic element; 5. a heat conductive clamping plate; 501. a spray tank; 502. a flow guiding surface; 6. a movable block; 601. a slide block; 602. a second elastic element; 603. a limiting plate; 7. a guide tube; 701. a piston block; 702. a third elastic element; 703. a guide rod; 7031. rack plate; 8. an air duct; 9. a connecting pipe seat; 901. a first air tube; 9011. an air outlet hopper; 902. a second air pipe; 9021. an air outlet plate; 9022. an air outlet; 903. a fixed rod; 10. a support plate; 11. a rotating lever; 111. a movable gear; 112. a main bevel gear; 12. a telescopic tube; 121. a secondary bevel gear; 13. a synchronizing wheel; 14. a water outlet pipe; 141. a water outlet; 15. a water tank; 151. a water inlet pipe; 16. a water inlet bucket; 161. a water return pipe; 17. a heat-conducting silica gel pad.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Examples:

referring to fig. 1, fig. 2, fig. 3, fig. 5 and fig. 6, an electromechanical device installation device comprises an installation seat and a device main body 3, the device main body 3 is arranged on the installation seat, the installation seat comprises a base 1 and a placing plate 2, a concave hole 201 is formed in the center of the placing plate 2, a grid plate 202 is arranged in the concave hole 201, clamping components which are uniformly distributed in the circumference and are used for fixing the device main body 3 are arranged on the placing plate 2, each clamping component comprises a side plate 203 fixedly arranged on the placing plate 2, an elastic telescopic rod 4 is arranged on the side plate 203, one end, far away from the side plate 203, of the elastic telescopic rod 4 is connected with a heat conduction clamping plate 5, the heat conduction clamping plate 5 is movably abutted against the device main body 3, a heat exchange cooling component is arranged on the heat conduction clamping plate 5, a damping component is arranged between the placing plate 2 and the base 1, and a heat dissipation component is connected on the damping component.

Specifically, when the equipment main body 3 is installed, the equipment main body 3 is placed at the center of the placement plate 2, and then the heat conduction clamping plate 5 is pushed, so that the heat conduction clamping plate 5 moves towards the equipment main body 3 and finally offsets against the equipment main body 3, the equipment main body 3 is quickly installed and positioned, heat generated during the operation of the equipment main body 3 can be transferred by the heat conduction clamping plate 5, the equipment main body 3 vibrates during the operation of the equipment main body 3, the vibration amplitude of the equipment main body 3 is buffered through the damping component, and in the process, the damping component drives the heat dissipation component and the heat exchange cooling component to work, the equipment main body 3 is effectively cooled and damped, and the service life of the electromechanical equipment is ensured.

Referring to fig. 1, 2 and 7, as a preferred technical solution of the present invention, the elastic telescopic rod 4 includes a sleeve 401 fixedly connected with the side plate 203 and an inner rod 402 connected with the heat conducting clamping plate 5, the inner rod 402 is slidably disposed in the sleeve 401, a first elastic element 403 is disposed between the inner rod 402 and the inner wall of the sleeve 401, and a limiting assembly for limiting movement of the inner rod 402 is disposed on the sleeve 401; specifically, by pushing the heat-conducting clamping plate 5, the heat-conducting clamping plate 5 drives the inner rod 402 to move relative to the sleeve 401, the inner rod 402 moves towards the outer side of the sleeve 401, the first elastic element 403 is stretched, in the process, the limiting assembly limits the back movement of the inner rod 402, and finally the heat-conducting clamping plate 5 is propped against the equipment main body 3, so that quick installation and positioning of electromechanical equipment are realized.

Referring to fig. 1 and 7, as a preferred technical scheme of the present invention, the limit component includes a movable block 6 slidably disposed on a sleeve 401, a sliding block 601 is disposed on the movable block 6, a sliding groove 4011 matched with the sliding block 601 is disposed on the sleeve 401, a second elastic element 602 is disposed between the sliding groove 4011 and the sliding block 601, a limit plate 603 is disposed on the movable block 6 through a pin shaft, a torsion spring for resetting and rotating the limit plate 603 is sleeved on the pin shaft, the limit component further includes a flat groove disposed on an inner rod 402, and ratchet 4021 uniformly distributed and movably propped against the limit plate 603 is disposed in the flat groove; specifically, when the inner rod 402 slides to the outside of the sleeve 401, the ratchet 4021 on the inner rod 402 applies force to the limiting plate 603 to enable the limiting plate 603 to turn over, but when the inner rod 402 slides to the inside of the sleeve 401, the ratchet 4021 is propped against the limiting plate 603, the limiting plate 603 cannot reversely turn over, so that the extending length of the inner rod 402 is limited, the clamping limit of the heat conduction clamping plate 5 on the equipment main body 3 is ensured, when the installation of the equipment main body 3 needs to be relieved, the movable block 6 is moved downwards, the movable block 6 drives the limiting plate 603 to move downwards, the limiting plate 603 does not prop against the ratchet 4021 any more, and the inner rod 402 is reset and contracted under the elastic action of the first elastic element 403.

Referring to fig. 8, as a preferred technical solution of the present invention, the shock absorbing assembly includes a guide tube 7 fixedly arranged on a base 1, a piston block 701 is slidably arranged in the guide tube 7, the piston block 701 divides the guide tube 7 into an air cavity and a water cavity, two unidirectional valve bodies are arranged in the air cavity and the water cavity, a third elastic element 702 is arranged between the piston block 701 and the inner wall of the guide tube 7, a guide rod 703 is arranged at one side of the piston block 701 facing away from the third elastic element 702, and one end of the guide rod 703 facing away from the piston block 701 is fixedly connected with a placing plate 2; specifically, in the running process of the device main body 3, the device main body 3 is combined with the placing plate 2 into a whole through the clamping assembly, and the shaking of the device main body 3 drives the placing plate 2 to shake, so that the guide rod 703 on the placing plate 2 slides in the guide tube 7 during vibration, the piston block 701 is stressed to squeeze the third elastic element 702, and the deformation of the third elastic element 702 plays a role of shock absorption and buffering.

Referring to fig. 1, fig. 2, fig. 3, fig. 5 and fig. 8, as a preferred technical solution of the present invention, the heat dissipation assembly includes an air duct 8 which is mutually communicated with the air cavity of the guide tube 7, one end of the air duct 8 far away from the guide tube 7 is provided with a connecting tube seat 9, two openings are provided on the connecting tube seat 9, the two openings are respectively connected with a first air duct 901 and a second air duct 902, one end of the first air duct 901 far away from the connecting tube seat 9 is provided with an air outlet hopper 9011, one end of the second air duct 902 far away from the connecting tube seat 9 passes through the placing plate 2 and is connected with an air outlet plate 9021, the air outlet plate 9021 is connected with the heat conduction clamping plate 5, a first cavity which is mutually communicated with the second air duct 902 is provided on the air outlet plate 9021, and an air outlet 9022 which is mutually communicated with the cavity is provided on the air outlet plate 9021; specifically, the inside of the guide pipe 7 is divided into an air cavity and a water cavity by the piston block 701, two one-way valves are respectively arranged in the two cavities, when the piston block 701 moves downwards in the guide pipe 7, the air cavity is smaller, air in the air cavity is discharged from the air guide pipe 8 through the one-way valve, then the piston block 701 moves upwards in the guide pipe 7 under the elastic action of the third elastic element 702, the air cavity extracts outside air through the other one-way valve, air discharged from the air guide pipe 8 flows into the first air pipe 901 and the second air pipe 902 respectively through the connecting pipe seat 9, the air outlet hopper 9011 at the end part of the first air pipe 901 is opposite to the grid plate 202, heat is dissipated to the bottom of the equipment main body 3, the air outlet plate 9021 arranged at the end part of the second air pipe 902 dissipates heat to the heat conducting clamping plate 5, the heat conducting clamping plate 5 with lower temperature is contacted with the equipment main body 3 with higher temperature, and the heat exchanging and cooling effects are achieved between the heat conducting clamping plate 5 and the equipment main body 3.

Referring to fig. 5, 6 and 8, as a preferred technical solution of the present invention, a support plate 10 is provided on a base 1, a rotating rod 11 is rotatably provided on the support plate 10, a moving gear 111 and a main bevel gear 112 are provided on the rotating rod 11, a rack plate 7031 engaged with the moving gear 111 is provided on a guide rod 703, a telescopic tube 12 is provided at the bottom of a placement plate 2, a secondary bevel gear 121 engaged with the main bevel gear 112 is provided on the telescopic tube 12, a connecting tube seat 9 is rotatably connected with an air duct 8 through a bearing, a fixing rod 903 is provided on the connecting tube seat 9, synchronizing wheels 13 are provided on both the fixing rod 903 and the telescopic tube 12, and a synchronizing belt is provided between the two synchronizing wheels 13; specifically, during operation of the shock assembly, the guide rod 703 moves up and down along with the placement plate 2, the guide rod 703 drives the rack plate 7031 to be meshed with the movable gear 111, so that the movable gear 111 drives the rotating rod 11 on the support plate 10 to rotate, further, the rotating rod 11 drives the main bevel gear 112 to rotate with the auxiliary bevel gear 121 on the telescopic tube 12, the telescopic tube 12 rotates and drives the fixing rod 903 to rotate through the synchronous wheel 13 and the synchronous belt, the fixing rod 903 drives the connecting tube seat 9 to rotate, further, the connecting tube seat 9 drives the first air tube 901 to rotate, the heat dissipation working range of the air outlet hopper 9011 at the end part of the first air tube 901 is improved, and the heat dissipation effect on the bottom of the equipment main body 3 is improved.

Referring to fig. 1, fig. 2, fig. 3, fig. 5, fig. 8 and fig. 9, as a preferred technical scheme of the present invention, the heat exchange cooling component includes a water outlet pipe 14 which is mutually communicated with the water cavity of the guide pipe 7, one end of the water outlet pipe 14, which is far away from the guide pipe 7, passes through the placing plate 2 and is connected with the heat conducting clamping plate 5, a second cavity which is mutually communicated with the water outlet pipe 14 is provided on the heat conducting clamping plate 5, a water outlet 141 which is mutually communicated with the second cavity is provided on the heat conducting clamping plate 5, the heat exchange cooling component further includes a water tank 15 which is fixedly arranged on the base 1, and a water inlet pipe 151 is arranged between the water tank 15 and the water cavity of the guide pipe 7; specifically, when the shock-absorbing assembly works, the piston block 701 reciprocates up and down in the guide pipe 7, when the piston block 701 moves up, the water cavity space becomes smaller, the piston block 701 discharges clear water with lower temperature in the water cavity to the heat-conducting clamping plate 5 through the water outlet pipe 14, when the piston block 701 moves down, the water cavity space becomes larger, clear water in the water tank 15 is extracted through the water inlet pipe 151 for subsequent use, clear water flows from the water outlet 141 to the outer wall of the heat-conducting clamping plate 5 to cool the heat-conducting clamping plate 5, meanwhile, the water drops adhere to the outer side of the clamping plate by the trace of clear water flowing, the air outlet plate 9021 at the end part of the second air pipe 902 blows the heat-conducting clamping plate 5 through the air outlet 9022, so that air outside the heat-conducting clamping plate 5 flows quickly, the evaporation rate of the clear water on the heat-conducting clamping plate 5 is quickened, the heat exchange cooling is performed between the heat-conducting clamping plate 5 and the equipment main body 3, and the working temperature of the equipment main body 3 is reduced, and the second air pipe 902 is set to be a hose to move conveniently along with the heat-conducting clamping plate 5.

Referring to fig. 3 and fig. 4, as a preferred technical solution of the present invention, a spraying groove 501 is formed on the heat conducting clamping plate 5, a water outlet 141 is arranged in the spraying groove 501, a diversion surface 502 is symmetrically arranged at the bottom of the spraying groove 501, a water inlet bucket 16 is arranged at the intersection of the two diversion surfaces 502, and a return pipe 161 is arranged between the water inlet bucket 16 and the water tank 15; specifically, the water outlet 141 is in the spraying tank 501, so that clear water flows in the spraying tank 501, the clear water is prevented from flowing to the outer side of the heat conduction clamping plate 5 to drop on the mounting seat or the equipment main body 3, the equipment main body 3 is wetted, and when water drops still remain unavaporated after flowing downwards from top to bottom, the water drops enter the water inlet bucket 16 along the flow guiding surface 502 at the bottom side of the spraying tank 501, and flow back into the water tank 15 through the water return pipe 161, so that water resources are saved, and reasonable use of the water resources is realized; the water return pipe 161 is a flexible pipe, so as to move along with the heat conductive clamping plate 5.

Referring to fig. 9, as a preferred technical solution of the present invention, a side of the heat conducting clamping plate 5 facing away from the spraying groove 501 is provided with a heat conducting silica gel pad 17, and the heat conducting silica gel pad 17 is movably abutted against the device main body 3; specifically, through setting up heat conduction silica gel gasket 17 on heat conduction grip block 5, the conduction of heat of being convenient for on the one hand protects equipment main part 3 on the other hand, avoids heat conduction grip block 5 to lead to the fact wearing and tearing to equipment main part 3 centre gripping installation in-process.

The invention also discloses a using method of the electromechanical equipment installation device, which comprises the following steps:

s1: when the equipment main body 3 is installed, the equipment main body 3 is placed at the center of the placing plate 2, and then the heat conduction clamping plate 5 is pushed, so that the heat conduction clamping plate 5 moves towards the equipment main body 3 and finally abuts against the equipment main body 3, the equipment main body 3 is quickly installed and positioned, the heat conduction clamping plate 5 can transfer heat generated by the equipment main body 3 during operation, and the limiting component on the elastic telescopic rod 4 can limit the stretched elastic telescopic rod 4;

s2: when the equipment main body 3 operates, vibration amplitude of the equipment main body 3 is buffered through the damping component, and in the process, the damping component drives the heat dissipation component to work, so that the air outlet hopper 9011 at the end part of the first air pipe 901 is opposite to the grid plate 202, the bottom of the equipment main body 3 is dissipated, the air outlet plate 9021 arranged at the end part of the second air pipe 902 dissipates heat of the heat conduction clamping plate 5, the heat conduction clamping plate 5 with lower temperature is contacted with the equipment main body 3 with higher temperature, and heat exchange and cooling are carried out between the heat conduction clamping plate 5 and the equipment main body 3;

s3: and at damper during operation, heat transfer cooling module synchronous operation makes heat conduction grip block 5 deviate from the lower clear water contact of temperature of one side of equipment main part 3, and the clear water flows on heat conduction grip block 5, cools down heat conduction grip block 5, and the air outlet plate 9021 of second trachea 902 tip blows heat conduction grip block 5 through gas outlet 9022 simultaneously, makes the air in heat conduction grip block 5 outside flow fast for the evaporation rate of clear water on heat conduction grip block 5, cools down heat conduction grip block 5 fast, and then makes heat transfer cooling down between heat conduction grip block 5 and the equipment main part 3, reduces the operating temperature when equipment main part 3 operates.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (6)

1. The utility model provides an electromechanical device installation device, includes mount pad and equipment main part (3), equipment main part (3) set up on the mount pad, its characterized in that, the mount pad includes base (1) and places board (2), the center department of placing board (2) sets up shrinkage pool (201), be provided with grid plate (202) in shrinkage pool (201), be provided with on placing board (2) and be circumference evenly distributed and be used for the clamping assembly of fixed equipment main part (3), every clamping assembly all includes curb plate (203) of setting on placing board (2), be provided with elastic telescopic link (4) on curb plate (203), one end that elastic telescopic link (4) kept away from curb plate (203) is connected with heat conduction grip block (5), heat conduction grip block (5) and equipment main part (3) activity offset, be provided with heat transfer cooling module on heat transfer grip block (5), be provided with damper between placing board (2) and base (1), damper is connected with radiator unit on the damper;

the damping component comprises a guide pipe (7) fixedly arranged on a base (1), a piston block (701) is arranged in the guide pipe (7) in a sliding manner, the guide pipe (7) is divided into an air cavity and a water cavity by the piston block (701), two one-way valve bodies are arranged in the air cavity and the water cavity, a third elastic element (702) is arranged between the piston block (701) and the inner wall of the guide pipe (7), a guide rod (703) is arranged on one side, away from the third elastic element (702), of the piston block (701), and one end, away from the piston block (701), of the guide rod (703) is fixedly connected with a placing plate (2);

the heat dissipation assembly comprises an air duct (8) which is mutually communicated with an air cavity of the guide tube (7), one end of the air duct (8) away from the guide tube (7) is provided with a connecting tube seat (9), two openings are formed in the connecting tube seat (9), the two openings are respectively connected with a first air duct (901) and a second air duct (902), one end of the first air duct (901) away from the connecting tube seat (9) is provided with an air outlet hopper (9011), one end of the second air duct (902) away from the connecting tube seat (9) penetrates through the placing plate (2) and is connected with an air outlet plate (9021), the air outlet plate (9021) is connected with the heat conduction clamping plate (5), a first cavity which is mutually communicated with the second air duct (902) is formed in the air outlet plate (9021), and an air outlet (9022) which is mutually communicated with the cavity is formed in the air outlet plate (9021);

the automatic lifting device is characterized in that a support plate (10) is arranged on the base (1), a rotating rod (11) is rotatably arranged on the support plate (10), a movable gear (111) and a main bevel gear (112) are arranged on the rotating rod (11), a rack plate (7031) meshed with the movable gear (111) is arranged on the guide rod (703), a telescopic tube (12) is arranged at the bottom of the placement plate (2), a secondary bevel gear (121) meshed with the main bevel gear (112) is arranged on the telescopic tube (12), the connecting tube seat (9) is rotatably connected with the air duct (8) through a bearing, a fixed rod (903) is arranged on the connecting tube seat (9), synchronous wheels (13) are arranged on the fixed rod (903) and the telescopic tube (12), and a synchronous belt is arranged between the two synchronous wheels (13);

the heat exchange cooling assembly comprises a water outlet pipe (14) which is mutually communicated with a water cavity of the guide pipe (7), one end of the water outlet pipe (14) far away from the guide pipe (7) penetrates through the placing plate (2) and is connected with the heat conduction clamping plate (5), a second cavity which is mutually communicated with the water outlet pipe (14) is formed in the heat conduction clamping plate (5), a water outlet (141) which is mutually communicated with the second cavity is formed in the heat conduction clamping plate (5), the heat exchange cooling assembly further comprises a water tank (15) which is fixedly arranged on the base (1), and a water inlet pipe (151) is arranged between the water tank (15) and the water cavity of the guide pipe (7).

2. The electromechanical device mounting arrangement according to claim 1, characterized in that the elastic telescopic rod (4) comprises a sleeve (401) fixedly connected with the side plate (203) and an inner rod (402) connected with the heat conducting clamping plate (5), the inner rod (402) is slidably arranged in the sleeve (401), a first elastic element (403) is arranged between the inner rod (402) and the inner wall of the sleeve (401), and a limiting assembly for limiting the movement of the inner rod (402) is arranged on the sleeve (401).

3. The electromechanical equipment installation device according to claim 2, characterized in that the limit component comprises a movable block (6) arranged on the sleeve (401) in a sliding manner, a sliding block (601) is arranged on the movable block (6), a sliding groove (4011) matched with the sliding block (601) is formed in the sleeve (401), a second elastic element (602) is arranged between the sliding groove (4011) and the sliding block (601), a limit plate (603) is arranged on the movable block (6) through a pin shaft, a torsion spring for resetting and rotating the limit plate (603) is sleeved on the pin shaft, the limit component further comprises a flat groove formed in the inner rod (402), and ratchet teeth (4021) which are uniformly distributed and are movably abutted against the limit plate (603) are arranged in the flat groove.

4. The electromechanical equipment installation device according to claim 1, characterized in that the heat conduction clamping plate (5) is provided with a spraying groove (501), the water outlet (141) is arranged in the spraying groove (501), the bottom of the spraying groove (501) is symmetrically provided with a diversion surface (502), the junction of the two diversion surfaces (502) is provided with a water inlet bucket (16), and a water return pipe (161) is arranged between the water inlet bucket (16) and the water tank (15).

5. The electromechanical equipment mounting device according to claim 4, characterized in that the side of the heat conducting clamping plate (5) facing away from the spraying groove (501) is provided with a heat conducting silica gel gasket (17), and the heat conducting silica gel gasket (17) is movably abutted against the equipment main body (3).

6. A method of using the electromechanical device mounting apparatus of any of claims 1-5, further comprising the steps of:

s1: when the equipment main body (3) is installed, the equipment main body (3) is placed at the center of the placing plate (2), then the heat conduction clamping plate (5) is pushed, the heat conduction clamping plate (5) moves towards the equipment main body (3) and finally abuts against the equipment main body (3), the equipment main body (3) is quickly installed and positioned, the heat generated during the operation of the equipment main body (3) can be transferred by the heat conduction clamping plate (5), and the stretched elastic telescopic rod (4) can be limited by the limiting component on the elastic telescopic rod (4);

s2: when the equipment main body (3) operates, vibration amplitude of the equipment main body (3) is buffered through the damping component, and in the process, the damping component drives the heat dissipation component to work, so that the air outlet hopper (9011) at the end part of the first air pipe (901) is opposite to the grid plate (202), heat dissipation is carried out on the bottom of the equipment main body (3), the air outlet plate (9021) arranged at the end part of the second air pipe (902) dissipates heat of the heat conduction clamping plate (5), the heat conduction clamping plate (5) with lower temperature is contacted with the equipment main body (3) with higher temperature, and heat exchange and cooling are carried out between the heat conduction clamping plate (5) and the equipment main body (3);

s3: at damper during operation, heat transfer cooling module synchronous operation makes one side that heat conduction grip block (5) deviate from equipment main part (3) and the lower clear water contact of temperature, and clear water flows on heat conduction grip block (5), cools down heat conduction grip block (5), and air outlet plate (9021) of second trachea (902) tip is blown heat conduction grip block (5) through gas outlet (9022) simultaneously, makes the air in heat conduction grip block (5) outside flow fast for the evaporation rate of clear water on heat conduction grip block (5), cools down heat conduction grip block (5) fast, and then makes heat transfer cooling between heat conduction grip block (5) and equipment main part (3), operating temperature when reducing equipment main part (3) operation.