CN111642120A

CN111642120A - Electromechanical device heat dissipation protection device

Info

Publication number: CN111642120A
Application number: CN202010641775.2A
Authority: CN
Inventors: 浦绍情
Original assignee: Guangzhou Yangping Electromechanical Technology Co ltd
Current assignee: Guangzhou Yangping Electromechanical Technology Co ltd
Priority date: 2020-07-06
Filing date: 2020-07-06
Publication date: 2020-09-08

Abstract

The invention discloses a heat dissipation protection device for electromechanical equipment, which comprises a base, wherein an inner cavity is arranged in the base, a circulating pipeline is fixedly arranged in the left end of the base, the left end surface of the circulating pipeline is attached to the surface of the electromechanical equipment needing heat dissipation, a circulating channel is arranged in the circulating pipeline in a through manner, a slide block cavity is arranged in the circulating pipeline, the left wall of the slide block cavity is communicated with the circulating channel, and the right wall of the slide block cavity is communicated with the inner cavity. The service life of the electromechanical device is prolonged.

Description

Electromechanical device heat dissipation protection device

Technical Field

The invention relates to the field of electromechanical equipment, in particular to a heat dissipation protection device for electromechanical equipment.

Background

Electromechanical device generally refers to machinery, electrical apparatus and electric automation equipment, and no matter processing of mill or daily life all need electromechanical device more and more, but electromechanical device often can produce a lot of heats in the course of the work to influence electromechanical device's life, therefore it is indispensable that electromechanical device is equipped with heat abstractor time, and heat abstractor's radiating effect is poor, be difficult to remove, the noise that produces in the heat dissipation process is big and electromechanical device during operation's vibrations influence heat abstractor's life now on the market.

The electromechanical equipment heat dissipation protection device can solve the problems, can fully dissipate heat of electromechanical equipment, and prolongs the service life of the device.

Disclosure of Invention

In order to solve the above problems, the present invention provides a heat dissipation protection device for electromechanical equipment, comprising a base, wherein an inner cavity is arranged in the base, a circulation pipeline is fixedly arranged in the left end of the base, the left end surface of the circulation pipeline is attached to the surface of the electromechanical equipment needing heat dissipation, a circulation channel is arranged in the circulation pipeline in a through manner, a slider cavity is arranged in the circulation pipeline, the left wall of the slider cavity is communicated with the circulation channel, the right wall of the slider cavity is communicated with the inner cavity, a fin cooling box is fixedly arranged in the lower wall of the slider cavity, a cooling water inlet is fixedly arranged at the rear end of the fin cooling box, the cooling water inlet is communicated with the circulation channel, a cooling water outlet is fixedly arranged at the left end of the fin cooling box, the left end of the cooling water outlet is communicated with a cooling pipeline, and a cooling channel is arranged in the cooling pipeline in a left, the left end of the cooling pipeline is fixedly connected with a water pump, the lower end of the water pump is fixedly connected with a water pumping pipeline, a water pumping channel is vertically communicated in the water pumping pipeline, the upper end of the water pumping channel is communicated with the water pump, the upper end of the water pump is fixedly connected with a water inlet pipeline, a water inlet channel is arranged in the water inlet pipeline, the lower end of the water inlet channel is communicated with the water pump, the upper end of the water inlet channel is communicated with the slide block cavity, a motor is fixedly arranged in the rear wall of the inner cavity, the front end of the motor is dynamically connected with a cam shaft, the front end of the cam shaft is fixedly connected with a cam, one side of the front end of the cam, which is far away from the cam shaft, is fixedly provided with a cam fixing pin, the front end of the cam fixing pin is rotatably connected with a, the water pump is started, external water flow is pumped into the water pump through the water pumping channel and then enters the water inlet channel and then enters the slider cavity, the motor is started to drive the cam shaft to rotate and further drive the cam to rotate and further drive the connecting rod to move left and right and further drive the slider to move left and right, and then the water flow in the slider cavity is extruded to flow along the inner wall of the circulating pipeline and flow in the circulating channel in a circulating mode, and then heat exchange is carried out between water flowing in the circulating channel and electromechanical equipment needing heat dissipation.

The threaded shaft cavity is arranged in the base in a front-back through mode, the threaded shaft is arranged in the threaded shaft cavity in a rotating mode, the threaded shaft cavity is communicated with the inner cavity, a shaft support is fixedly arranged on the upper wall of the inner cavity, the threaded shaft is connected with the shaft support in a front-back through mode and in a rotating mode, a transmission belt wheel is fixedly connected to the middle of the threaded shaft, the transmission belt wheel is connected to the camshaft through a transmission belt, two internal gears are in threaded connection with the threaded shaft and are located on the front side and the rear side of the transmission belt wheel respectively, a connecting rod is fixedly connected to the left end of each internal gear, two guide grooves with openings towards the left are formed in the left wall of the threaded shaft cavity in a communicating mode, the left ends of the two connecting rods penetrate through the two guide grooves respectively and extend out of the base and are fixedly connected with a sliding pipeline, a sliding, the slide bar is kept away from the one end of connecting rod has linked firmly splint, splint with be connected with damping spring between the slip pipeline, start the motor drives the camshaft rotates, and then drives the screw spindle rotates, and then drives inner gear reciprocating motion back and forth, and then drives the connecting rod with slip pipeline reciprocating motion back and forth, and then drive splint reciprocating motion back and forth, splint fixed clamp electromechanical device carries out the shock attenuation.

Profitable, seted up steam inner chamber and air conditioning inner chamber in the inner chamber lower wall, steam inner chamber left side intercommunication in the fin cooling box to its right side is linked together has the steam passageway, steam passageway right side intercommunication has electrically conductive hot chamber, air conditioning inner chamber opening right, and its left side is linked together has the air conditioning passageway, air conditioning passageway left side intercommunication has electrically conductive cold chamber, electrically conductive hot chamber with the electrically conductive cold chamber between set firmly the current conducting plate, the electrically conductive plate right side lower extreme electric connection has the battery, the steam that fin cooling box gave out inhales the steam inner chamber at this moment, gets into through the steam passageway in the electrically conductive hot chamber, the air conditioning inner chamber is inhaled to external air at this moment, gets into in the electrically conductive cold chamber through the air conditioning passageway, there is the temperature difference at this moment the current conducting plate left and right sides the electrically conductive hot chamber with the air in the, the heat energy can be converted into electric energy by means of the conductive plate, and the generated electricity is stored in the storage battery.

The heat-absorbing fan is characterized in that a belt groove is communicated between the rear side walls of the hot air cavity and the cold air cavity, linkage belt wheels are respectively arranged in the belt groove in a left-right rotating mode, a linkage belt is connected between the two linkage belt wheels, a worm is fixedly connected at the front end of the linkage belt wheel at the left side, a worm wheel is connected at the upper end of the worm in a meshed mode, a heat-absorbing fan shaft is fixedly connected at the left end of the worm wheel, heat-absorbing fan blades are fixedly connected on the outer peripheral surface of the heat-absorbing fan shaft, a transmission shaft is fixedly connected at the front end of the linkage belt wheel at the right side, a driving bevel gear is fixedly connected at the front end of the transmission shaft, a driven bevel gear is rotatably connected at the left end of the driving bevel gear, a cold air fan shaft is fixedly connected at the right end of the driven bevel gear, a cold air fan, and a transmission chain is connected between the cam shaft and the worm, the motor is started to drive the cam shaft to rotate, further drive the worm to rotate, further drive the transmission shaft to synchronously rotate, and at the moment, the heat absorption fan shaft and the air conditioning fan shaft are driven to rotate.

The left wall of the cavity of the sliding block is internally provided with a cavity, the left wall of the cavity is internally communicated with a movable channel, the left wall of the movable channel is internally provided with a backing plate cavity with a leftward opening, the left end of the movable channel is communicated with the backing plate cavity, the rear wall of the cavity is internally and fixedly provided with a fixed support, the front end of the fixed support is rotatably connected with a clamping wheel shaft, the middle of the clamping wheel shaft is fixedly connected with an outer ratchet clamping wheel, the outer side of the outer ratchet clamping wheel is engaged and connected with an inner ratchet wheel, the outer side of the inner ratchet wheel is fixedly connected with a rotating gear, a cylindrical clamping pin is fixedly connected between two teeth at the upper end of the rotating gear, the upper end of the cylindrical clamping pin is rotatably connected with a linkage rod, the upper end of the linkage rod is rotatably connected with a double-head linkage rod, the left end of the double-head linkage rod is rotatably connected with a movable, promote the integrated device and move left and be close to and contact electromechanical device surface, the backing plate receives pressure and slides right this moment and gets into the backing plate chamber, and then promotes movable rod and double-end gangbar and move right, and then drives the gangbar and move right, and then drives running gear and interior ratchet clockwise rotation, and then drives outer ratchet card wheel and card wheel axle clockwise rotation, and expanding spring receives the extrusion this moment and takes place compression deformation, alleviates the vibrations that electromechanical device produced in the course of the work and the injury to the device.

Beneficially, a gear shaft support is fixedly arranged on the inner side of the front wall of the cavity, a gear shaft is rotatably connected to the rear end of the gear shaft support, a transmission belt wheel is fixedly connected to the front end of the clamping wheel shaft and the rear end of the gear shaft respectively, a transmission chain is connected between the two transmission belt wheels, a rolling gear is fixedly connected to the gear shaft and located on the front side of the transmission belt wheel on the lower side of the clamping wheel shaft, two rotating wheel supports are fixedly connected to the left side and the right side of the inner side of the lower wall of the cavity respectively, fixed rotating wheels are rotatably connected to the upper ends of the two rotating wheel supports respectively, a transmission rack is connected between the upper ends of the left fixed rotating wheel and the upper end of the right fixed rotating wheel in a meshing manner, the.

Beneficially, the upper end of the transmission rack is fixedly connected with a clamping block, the right end of the clamping block is fixedly connected with a sliding rod, the right end of the sliding rod is fixedly connected with a linkage spring, the right end of the linkage spring is fixedly connected with a baffle, the baffle is arranged in the water inlet channel in a sliding mode, the right end of the linkage spring is tightly attached to the inner wall of the right end of the water inlet pipeline, the transmission rack slides leftwards at the moment and then drives the clamping block and the sliding rod to move leftwards, the baffle slides leftwards at the moment and is opened in the water inlet channel, and at the moment, water flows pass through.

The invention has the beneficial effects that: the cooling water circulation type electromechanical equipment cooling device can perform cooling protection treatment on electromechanical equipment through cooling water circulation, the damage of vibration generated when the electromechanical equipment works to the device is reduced through spring damping, heat dissipated by the electromechanical equipment is converted into electric energy through temperature difference to be stored, energy regeneration is performed, meanwhile, a large amount of manpower and material resources are saved, the working efficiency is improved, the input cost is reduced, the cooling device is improved, the damping treatment is performed on the electromechanical equipment, and the service life of the electromechanical equipment is prolonged.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic view of the overall structure of a heat dissipation protection device for an electromechanical device according to the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 1;

FIG. 6 is an enlarged schematic view of "E" of FIG. 1;

FIG. 7 is a schematic view of the structure in the direction "F-F" of FIG. 6;

FIG. 8 is a schematic view of the structure in the direction "G-G" of FIG. 7;

fig. 9 is a schematic view of the structure in the direction "H-H" of fig. 8.

Detailed Description

The invention will now be described in detail with reference to fig. 1-9, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a heat dissipation protection device for electromechanical equipment, which comprises a base 11, wherein an inner cavity 12 is arranged in the base 11, a circulating pipeline 14 is fixedly arranged in the left end of the base 11, the left end surface of the circulating pipeline 14 is attached to the surface of the electromechanical equipment needing heat dissipation, a circulating channel 15 is arranged in the circulating pipeline 14 in a penetrating manner, a slider cavity 13 is arranged in the circulating pipeline 14, the left wall of the slider cavity 13 is communicated with the circulating channel 15, the right wall of the slider cavity 13 is communicated with the inner cavity 12, a fin cooling box 32 is fixedly arranged in the lower wall of the slider cavity 13, a cooling water inlet 34 is fixedly arranged at the rear end of the fin cooling box 32, the cooling water inlet 34 is communicated with the circulating channel 15, a cooling water outlet 33 is fixedly arranged at the left end of the fin cooling box 32, a cooling pipeline 17 is communicated with the left end of the cooling water outlet 33, a cooling channel 76 is arranged, the left end of the cooling pipeline 17 is fixedly connected with a water pump 19, the lower end of the water pump 19 is fixedly connected with a water pumping pipeline 18, a water pumping channel 77 is vertically communicated in the water pumping pipeline 18, the upper end of the water pumping channel 77 is communicated with the water pump 19, the upper end of the water pump 19 is fixedly connected with a water inlet pipeline 16, a water inlet channel 75 is arranged in the water inlet pipeline 16, the lower end of the water inlet channel 75 is communicated with the water pump 19, the upper end of the water inlet channel 75 is communicated with the slider cavity 13, a motor 48 is fixedly arranged in the rear wall of the inner cavity 12, the front end of the motor 48 is dynamically connected with a cam shaft 22, the front end of the cam shaft 22 is fixedly connected with a cam 21, one side of the front end of the cam 21, which is far away from the cam shaft 22, is fixedly provided with a cam fixing pin 23, the front end of the cam fixing pin 23 is, and the upper and lower both ends of slider 20 hug closely in circulating line 14 inner wall, start water pump 19, external rivers pass through pumping channel 77 and take out in water pump 19, and then get into in intake passage 75, and then get into in the slider chamber 13, start motor 48, drive camshaft 22 rotates, and then drive cam 21 rotates, and then drive connecting rod 24 side-to-side movement, and then drive slider 20 side-to-side movement, and then the extrusion rivers follow in the slider chamber 13 circulating line 14 inner wall and circulating line 15 internal circulation flows, and then through the water that flows in circulating line 15 carries out the heat transfer with the electromechanical device that needs the heat dissipation.

Beneficially, a threaded shaft cavity 80 is formed in the base 11 in a front-back through manner, a threaded shaft 45 is rotatably arranged in the threaded shaft cavity 80, the threaded shaft cavity 80 is communicated with the inner cavity 12, a shaft support 47 is fixedly arranged on the upper wall of the inner cavity 12, the threaded shaft 45 is connected to the shaft support 47 in a front-back through manner and in a rotating manner, a transmission belt wheel 44 is fixedly connected to the middle portion of the threaded shaft 45, the transmission belt wheel 44 is connected to the camshaft 22 through a transmission belt 43, two internal gears 46 are connected to the threaded shaft 45 in a threaded manner, the two internal gears 46 are respectively arranged on the front side and the rear side of the transmission belt wheel 44, a connecting rod 57 is fixedly connected to the left end of the internal gear 46, two guide grooves 100 with openings facing left are formed in the left wall of the threaded shaft cavity 80, the left ends of the two connecting rods 57 respectively penetrate through the two guide grooves 100, be equipped with slide channel 56 in the slip pipeline 55, the gliding slide bar 54 that is equipped with from top to bottom in the slide channel 56, slide bar 54 keeps away from the one end of connecting rod 57 has linked firmly splint 52, splint 52 with be connected with damping spring 53 between the slip pipeline 55, start motor 48 drives camshaft 22 rotates, and then drives threaded shaft 45 rotates, and then drives internal gear 46 reciprocating motion, and then drives connecting rod 57 with slip pipeline 55 reciprocating motion, and then drive splint 52 reciprocating motion, splint 52 fixes the clamp electromechanical device and carries out the shock attenuation.

Beneficially, seted up steam inner chamber 35 and air conditioning inner chamber 38 in the 12 lower walls of inner chamber, steam inner chamber 35 left side intercommunication in fin cooling box 32 to its right side is linked together there is hot gas passage 78, hot gas passage 78 right side intercommunication has electrically conductive hot chamber 101, air conditioning inner chamber 38 opening right side, and its left side is linked together air conditioning passage 79, air conditioning passage 79 left side intercommunication has electrically conductive cold chamber 102, electrically conductive hot chamber 101 with electrically conductive cold chamber 102 between set firmly current conducting plate 41, current conducting plate 41 right side lower extreme electric connection has battery 42, the steam that fin cooling box 32 gave out this moment inhales steam inner chamber 35, through hot gas passage 78 gets into in the electrically conductive hot chamber 101, external air conditioning inhales this moment air conditioning inner chamber 38, through air conditioning passage 79 gets into in the electrically conductive cold chamber 102, at this moment the current conducting plate 41 left and right sides electrically conductive hot chamber 101 with there is the temperature difference in the air in the electrically conductive cold chamber 102 And thus thermal energy can be converted into electric energy by means of the conductive plates, and the generated electricity can be stored in the storage battery 42.

Beneficially, a belt groove 105 is communicated between the rear side walls of the hot air cavity 35 and the cold air cavity 38, a linkage belt wheel 61 is respectively rotatably arranged at the left and the right in the belt groove 105, a linkage belt 60 is connected between the two linkage belt wheels 61, a worm 50 is fixedly connected to the front end of the linkage belt wheel 61 at the left side, a worm wheel 51 is connected to the upper end of the worm 50 in a meshing manner, a heat absorption fan shaft 37 is fixedly connected to the left end of the worm wheel 51, a heat absorption fan blade 36 is fixedly connected to the outer peripheral surface of the heat absorption fan shaft 37, the left end of the heat absorption fan shaft 37 is rotatably arranged on the left wall of the hot air cavity 35, a transmission shaft 59 is fixedly connected to the front end of the linkage belt wheel 61 at the right side, a drive bevel gear 58 is fixedly connected to the front end of the transmission shaft 59, a driven bevel gear 103 is rotatably connected to the left end of the drive bevel gear 58, a cold, the right end of the cold air fan shaft 40 is rotatably arranged on the right wall of the cold air cavity 38, a transmission chain 49 is connected between the cam shaft 22 and the worm 50, the motor 48 is started to drive the cam shaft 22 to rotate, further drive the worm 50 to rotate, further drive the transmission shaft 59 to synchronously rotate, and at the moment, the heat absorption fan shaft 37 and the cold air fan shaft 40 are driven to rotate.

Beneficially, a cavity 104 is arranged in the left wall of the slider cavity 13, a movable channel 30 is arranged in the left wall of the cavity 104 in a communicating manner, a backing plate cavity 31 with a leftward opening is arranged in the left wall of the movable channel 30, the left end of the movable channel 30 is communicated with the backing plate cavity 31, a fixed support 82 is fixedly arranged in the rear wall of the cavity 104, the front end of the fixed support 82 is rotatably connected with a clamping wheel shaft 66, an outer ratchet wheel 65 is fixedly connected in the middle of the clamping wheel shaft 66, an inner ratchet wheel 64 is connected to the outer side of the outer ratchet wheel 65 in a meshing manner, a rotating gear 63 is fixedly connected to the outer side of the inner ratchet wheel 64, a cylindrical clamping pin 62 is fixedly connected between two teeth at the upper end of the rotating gear 63, a linkage rod 29 is rotatably connected to the upper end of the cylindrical clamping pin 62, a double-head linkage rod 28 is rotatably connected to the upper end of the linkage rod 29, and its left end fixedly connected with backing plate 25, backing plate chamber 31 right wall with be connected with expanding spring 26 between the backing plate 25, promote whole device to move left and be close to and contact electromechanical device surface, backing plate 25 receives pressure right slip entering backing plate chamber 31 this moment, and then promote movable rod 27 and double-end gangbar 28 and move right, and then drive gangbar 29 and move right, and then drive rotating gear 63 and interior ratchet 64 clockwise rotation, and then drive outer ratchet card wheel 65 and card wheel shaft 66 clockwise rotation, expanding spring 26 receives the extrusion and takes place compression deformation this moment, alleviate the vibrations that electromechanical device produced in the course of the work and the injury to the device.

Advantageously, a gear shaft support 84 is fixedly arranged on the inner side of the front wall of the cavity 104, a gear shaft 68 is rotatably connected to the rear end of the gear shaft support 84, the front end of the clamping wheel shaft 66 and the rear end of the gear shaft 68 are respectively fixedly connected with a driving belt wheel 83, a driving chain 74 is connected between the two driving belt wheels 83, a rolling gear 67 is fixedly connected to the gear shaft 68, the rolling gear 67 is positioned at the front side of the transmission belt wheel 83 at the lower side, the inner side of the lower wall of the cavity 104 is fixedly connected with two rotating wheel supporting seats 85 at the left and the right respectively, the upper ends of the two rotating wheel supporting seats 85 are respectively and rotatably connected with a fixed rotating wheel 81, a transmission rack 69 is engaged and connected between the upper ends of the left and the right fixed rotating wheels 81, the lower end of the rolling gear 67 is meshed with the transmission rack 69, the clamping wheel shaft 66 rotates, thereby driving the gear shaft 68 to rotate and further driving the transmission rack 69 to slide leftwards.

Beneficially, the upper end of the transmission rack 69 is fixedly connected with a fixture block 70, the right end of the fixture block 70 is fixedly connected with a sliding rod 71, the right end of the sliding rod 71 is fixedly connected with a linkage spring 72, the right end of the linkage spring 72 is fixedly connected with a baffle 73, the baffle 73 is arranged in the water inlet channel 75 in a left-right sliding mode, the right end of the baffle is tightly attached to the inner wall of the right end of the water inlet pipeline 16, at the moment, the transmission rack 69 slides leftwards to further drive the fixture block 70 and the sliding rod 71 to move leftwards, at the moment, the baffle 73 is further driven to slide leftwards to open the water inlet channel 75, and at the moment, water flows into.

The following describes in detail the use steps of the electromechanical device heat dissipation protection device in this document with reference to fig. 1 to 9: initially, the slider 20 is at the right limit position, the two internal gears 46 are respectively located at the left and right sides of the threaded shaft 45, the baffle 73 is at the right limit position, and the backing plate 25 is at the left limit position.

Placing the device on the surface of a heating part of the electromechanical device, pushing the whole device to move leftwards to be close to and contact the surface of the electromechanical device, at this time, the backing plate 25 slides rightwards under pressure to enter the backing plate cavity 31, further pushing the movable rod 27 and the double-head linkage rod 28 to move rightwards, further driving the linkage rod 29 to move rightwards, further driving the rotating gear 63 and the inner ratchet wheel 64 to rotate clockwise, further driving the outer ratchet wheel 65 and the wheel clamping shaft 66 to rotate clockwise, further driving the gear shaft 68 and the rolling gear 67 to rotate, further driving the transmission rack 69 to slide leftwards, further driving the clamping block 70 and the sliding rod 71 to move leftwards, at this time, driving the baffle 73 to move leftwards, when the device is completely attached to and fixed on the surface of the electromechanical device, the backing plate 25 stops moving, at this time, the clamping block 70 just moves to the position of the rolling gear 67 and, the water inlet channel 75 is opened, the backing plate 25 is tightly attached to the surface of the electromechanical device at the moment, the expansion spring 26 is extruded to generate compression deformation, vibration and damage to the device generated in the working process of the electromechanical device are reduced, the clamping plates 52 are positioned on the front side and the rear side of the device at the moment, the motor 48 is started to drive the cam shaft 22 to rotate and further drive the threaded shaft 45 to rotate, further drive the two inner gears 46 to move towards one side close to the transmission belt 43, and drive the connecting rod 57 and the sliding pipeline 55 to move towards one side close to the transmission belt 43, further drive the two clamping plates 52 to move oppositely, fix and clamp the electromechanical device, at the moment, the two sliding rods 54 slide reversely, and meanwhile, the damping spring 53 is in a compression; at this time, the water pump 19 is started, the external water flow is pumped into the water pump 19 through the water pumping channel 77, and then pumped into the water inlet channel 75 from the water pump 19, and then enters the slider cavity 13, the motor 48 is started, the cam shaft 22 is driven to rotate, the cam 21 is driven to rotate, the connecting rod 24 is driven to move left and right, and then the slider 20 is driven to reciprocate left and right along the inner wall of the circulating pipeline 14, so that the water flow in the slider cavity 13 is extruded to flow circularly along the inner wall of the circulating pipeline 14 and inside the circulating pipeline 15, and then the water flowing in the circulating pipeline 15 exchanges heat with the electromechanical equipment needing heat dissipation, the water flow enters the inside of the fin cooling box 32 through the cooling water inlet 34 after circulating for one circle to be cooled, at this time, the water pump 19 pumps the water cooled in the fin cooling box 32 through the cooling channel 76 and the cooling water outlet 33, and then drive the drive shaft 59 to rotate synchronously, drive the heat absorption fan shaft 37 and the cold air fan shaft 40 to rotate at this moment, the hot gas that the fin cooling box 32 gives out is inhaled into the hot gas inner chamber 35, and enter the electrically conductive hot cavity 101 through the hot gas channel 78, the external cold air sucks the cold air inner chamber 38 at this moment, enter the electrically conductive cold cavity 102 through the cold air channel 79, there is temperature difference in the electrically conductive hot cavity 101 of the left and right sides of the conductive plate 41 and air in the electrically conductive cold cavity 102 at this moment, and then can turn the heat energy into the electric energy with the help of the conductive plate, and then store the electricity produced into the storage.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. The utility model provides an electromechanical device heat dissipation protection device, includes the base, its characterized in that: the cooling device is characterized in that an inner cavity is arranged in the base, a circulating pipeline is fixedly arranged in the left end of the base, the left end face of the circulating pipeline is attached to the surface of electromechanical equipment needing heat dissipation, a circulating channel is arranged in the circulating pipeline in a communicated manner, a slider cavity is arranged in the circulating pipeline, the left end of the slider cavity is communicated with the circulating channel, the right end of the slider cavity is communicated with the inner cavity, a fin cooling box is fixedly arranged in the lower wall of the slider cavity, a cooling water inlet is fixedly arranged at the rear end of the fin cooling box, the cooling water inlet is communicated with the circulating channel, a cooling water outlet is fixedly arranged at the left end of the fin cooling box, the left end of the cooling water outlet is communicated with a cooling pipeline, a cooling channel is arranged in the cooling pipeline in a communicated manner from left to right, a water pump is fixedly connected with the left end of, the utility model discloses a slide block, including draw water channel, intake channel, water pump, inner chamber, cam, connecting rod, slider, inner chamber, cam fixed pin, connecting rod left end, slider, inner chamber.

2. The electromechanical device heat dissipation protection apparatus of claim 1, wherein: the base is internally provided with a threaded shaft cavity which is communicated with the inner cavity in a front-back way, a threaded shaft is arranged in the threaded shaft cavity in a rotating way, the threaded shaft cavity is communicated with the inner cavity, the upper wall of the inner cavity is fixedly provided with a shaft support, the threaded shaft is communicated with the shaft support in a front-back way and is rotatably connected with the shaft support, the middle part of the threaded shaft is fixedly connected with a transmission belt wheel, the transmission belt wheel is connected with the camshaft through a transmission belt, the threaded shaft is connected with two internal gears in a threaded way, the two internal gears are respectively positioned at the front side and the rear side of the transmission belt wheel, the left end of the internal gear is fixedly connected with a connecting rod, the left wall of the threaded shaft cavity is communicated with two guide grooves with a left opening, the left ends of the two connecting rods respectively penetrate through the two guide grooves and extend to the, the one end that the connecting rod was kept away from to the slide bar has linked firmly splint, splint with be connected with damping spring between the slip pipeline.

3. The electromechanical device heat dissipation protection apparatus of claim 1, wherein: seted up steam inner chamber and air conditioning inner chamber in the inner chamber lower wall, steam inner chamber left side communicate in the fin cooler bin to its right side is linked together has hot gas passage, hot gas passage right side intercommunication has electrically conductive hot chamber, air conditioning inner chamber opening right, and its left side is linked together has the air conditioning passageway, air conditioning passageway left side intercommunication has electrically conductive cold chamber, electrically conductive hot chamber with the electrically conductive current conducting plate has set firmly between the cold chamber, current conducting plate right side lower extreme electric connection has the battery.

4. The electromechanical device heat dissipation protection apparatus of claim 1, wherein: a belt groove is communicated between the hot air inner cavity and the rear side wall of the cold air inner cavity, linkage belt wheels are respectively arranged in the belt groove in a left-right rotating mode, a linkage belt is connected between the two linkage belt wheels, a worm is fixedly connected to the front end of the linkage belt wheel on the left side, a worm wheel is connected to the upper end of the worm in a meshed mode, a heat absorption fan shaft is fixedly connected to the left end of the worm wheel, heat absorption fan blades are fixedly connected to the outer peripheral surface of the heat absorption fan shaft, the left end of the heat absorption fan shaft is rotatably arranged on the left wall of the hot air inner cavity, a transmission shaft is fixedly connected to the front end of the linkage belt wheel on the right side, a driving bevel gear is fixedly connected to the front end of the transmission shaft, a driven bevel gear is rotatably connected to the left end of the driving bevel gear, a cold air fan shaft is fixedly, and a transmission chain is connected between the camshaft and the worm.

5. The electromechanical device heat dissipation protection apparatus of claim 1, wherein: a cavity is arranged in the left wall of the slide block cavity, a movable channel is communicated in the left wall of the cavity, a backing plate cavity with a leftward opening is arranged in the left wall of the movable channel, the left end of the movable channel is communicated with the backing plate cavity, a fixed support is fixedly arranged in the rear wall of the cavity, the front end of the fixed support is rotatably connected with a clamping wheel shaft, the middle of the clamping wheel shaft is fixedly connected with an outer ratchet clamping wheel, the outer side of the outer ratchet clamping wheel is engaged and connected with an inner ratchet wheel, a rotating gear is fixedly connected with the outer side of the inner ratchet wheel, a cylindrical bayonet lock is fixedly connected between two teeth at the upper end of the rotating gear, the upper end of the cylindrical bayonet lock is rotationally connected with a linkage rod, the upper end of the linkage rod is rotationally connected with a double-end linkage rod, the left end of the double-end linkage rod is rotationally connected with a movable rod which passes through the interior of the movable channel, and the left end of the base plate is fixedly connected with a base plate, and an expansion spring is connected between the right wall of the cavity of the base plate and the base plate.

6. The electromechanical device heat dissipation protection apparatus of claim 1, wherein: the inner side of the front wall of the cavity is fixedly provided with a gear shaft support, the rear end of the gear shaft support is rotatably connected with a gear shaft, the front end of the clamping wheel shaft and the rear end of the gear shaft are fixedly connected with a transmission belt wheel respectively, a transmission chain is connected between the two transmission belt wheels, a rolling gear is fixedly connected to the gear shaft and is positioned on the front side of the transmission belt wheel on the lower side, the left side and the right side of the inner side of the lower wall of the cavity are fixedly connected with two rotating wheel supports respectively, the upper ends of the two rotating wheel supports are rotatably connected with fixed rotating wheels respectively, a transmission rack is meshed between the upper ends of the left fixed rotating wheel and.

7. The electromechanical device heat dissipation protection apparatus of claim 1, wherein: the upper end of the transmission rack is fixedly connected with a clamping block, the right end of the clamping block is fixedly connected with a sliding rod, the right end of the sliding rod is fixedly connected with a linkage spring, the right end of the linkage spring is fixedly connected with a baffle, the baffle is arranged in the water inlet channel in a left-right sliding mode, and the right end of the baffle is tightly attached to the inner wall of the right end of the water inlet pipeline.