CN114433417A

CN114433417A - New energy battery heat conduction silica gel smearing device

Info

Publication number: CN114433417A
Application number: CN202210052793.6A
Authority: CN
Inventors: 段天肆
Original assignee: Individual
Current assignee: Hunan Qiaolian Intelligent Equipment Manufacturing Co ltd
Priority date: 2022-01-18
Filing date: 2022-01-18
Publication date: 2022-05-06
Anticipated expiration: 2042-01-18
Also published as: CN114433417B

Abstract

The invention relates to a smearing device, in particular to a new energy battery heat-conducting silica gel smearing device which comprises a bottom plate, placing blocks, first springs and the like, wherein the first springs are symmetrically connected to the left and right sides of the front side of the top of the bottom plate, and the placing blocks used for placing new energy batteries are fixedly connected between the tail ends of the two first springs. According to the novel energy battery, the novel energy battery is placed on the placing block, the novel energy battery is in contact with the material guide plate, the rotating mechanism can be pulled to rotate reversely, the rotating mechanism rotates reversely to drive the glue injection mechanism to operate, the glue injection mechanism operates to coat a proper amount of heat-conducting silica gel on the novel energy battery, the glue injection mechanism further drives the material guide plate to rotate forward, the material guide plate rotates forward to uniformly coat the heat-conducting silica gel on the novel energy battery, and therefore an operator can coat the heat-conducting silica gel on the novel energy battery only by pulling the rotating mechanism to rotate reversely, and the novel energy battery is convenient to use.

Description

New energy battery heat conduction silica gel smearing device

Technical Field

The invention relates to a smearing device, in particular to a new energy battery heat-conducting silica gel smearing device.

Background

The new energy battery is generally applied to a new energy automobile, but in the manufacturing process of the new energy battery, a proper amount of heat-conducting silica gel generally needs to be coated on the new energy battery, so that the new energy battery has cold and heat alternation resistance, aging resistance and electrical insulation performance, and at present, the following problems exist when the heat-conducting silica gel is coated on the new energy battery by a coating machine: people need to operate the machine earlier and adjust exhaust heat conduction silica gel, spout heat conduction silica gel on new energy battery again, and when heat conduction silica gel spouted on new energy battery, the machine operation of operating again smears heat conduction silica gel on new energy battery, and so operating procedure is more, and is more loaded down with trivial details, leads to follow-up work efficiency to hang down.

The invention aims to solve the problems in the patent, and provides the new energy battery heat-conducting silica gel smearing device which can evenly smear heat-conducting silica gel on a new energy battery, is convenient to operate and has high working efficiency.

Disclosure of Invention

In order to overcome the defects that the heat-conducting silica gel needs to be continuously coated on the new energy battery by a machine, the operation steps are more, the operation is more complicated, and the subsequent working efficiency is low, the invention provides the heat-conducting silica gel coating device for the new energy battery, which can uniformly coat the heat-conducting silica gel on the new energy battery, is convenient to operate and has high working efficiency.

The invention is realized by the following technical approaches:

a new energy battery heat-conducting silica gel smearing device comprises a bottom plate, a placing block, first springs, a guide plate, a fixing frame, a limiting frame, a supporting frame, a shell, a glue injection mechanism and a rotating mechanism, wherein the front side of the top of the bottom plate is bilaterally and symmetrically connected with the first springs, the placing block for placing a new energy battery is fixedly connected between the tail ends of the two first springs, the front part of the left side of the top of the bottom plate is fixedly connected with the fixing frame, the rear part of the left side of the top of the bottom plate is fixedly connected with the supporting frame, the rear part of the right side of the top of the bottom plate is fixedly connected with the limiting frame, the left side of the outer left side of the limiting frame is fixedly connected with the right side of the upper part of the outer rear side of the fixing frame through two rods, the front part of the limiting frame is fixedly connected with the shell, the glue injection mechanism for discharging the heat-conducting silica gel is installed between the fixing frame and the limiting frame, the guide plate for evenly smearing the heat-conducting silica gel on the new energy battery is installed on the glue injection mechanism, a rotating mechanism used for driving the glue injection mechanism to operate is installed between the shell and the bottom plate, and the rotating mechanism is further connected with the glue injection mechanism.

Further, the glue injection mechanism comprises a storage cylinder, a one-way feeding pipe, a one-way discharging pipe, a rotating disc, a piston rod, a second spring and a piston cylinder, the storage cylinder is fixedly connected to the left side of the upper portion of the limiting frame in a penetrating manner, the one-way feeding pipe is communicated with the middle of the bottom of the storage cylinder, the piston cylinder is fixedly connected to the right side of the upper portion of the fixing frame in a penetrating manner, the middle of the lower portion of the rear side of the piston cylinder is fixedly connected to the tail end of the one-way feeding pipe, the one-way feeding pipe is communicated with the interior of the piston cylinder, the piston rod is slidably arranged in the piston cylinder, the second spring is fixedly connected between the outer top of the piston rod and the inner top of the shell, the rotating mechanism rotates reversely to contact with the piston rod, the one-way discharging pipe for discharging heat-conducting silica gel is communicated with the middle of the bottom of the piston cylinder, the rotating disc is rotatably connected to the rotating disc in an embedded manner for driving the material guide plate to rotate forwardly, the rotating disc is sleeved on the one-way discharging pipe, and the outer bottom of the rotating disc is fixedly connected to the bottom of the material guide plate, the outer lower part of the rotating disc is connected with the rotating mechanism, and the rotating disc penetrates through the right side of the middle part of the fixed frame.

Furthermore, the rotating mechanism comprises a conical fluted disc, a rotating rod, a fixed plate, an accelerating component, a rotating shaft, a bevel gear, a rotating rod, a driving disk and a handle, wherein the rotating rod is rotatably connected in the middle of the front side surface of the shell in a penetrating way, the driving disk for driving the piston rod to move downwards is fixedly connected in the front side of the rotating rod along the circumferential direction, the driving disk is positioned outside the shell, the handle is fixedly connected in the middle of the upper part of the front side surface of the driving disk, the rotating shaft is rotatably connected in the middle of the right side of the shell in a penetrating way, the bevel gears are fixedly sleeved in the left side of the rotating shaft and the front side of the rotating rod along the circumferential direction, the two bevel gears are meshed, the fixed plate is fixedly connected in the right part of the front side of the top of the bottom plate, the rotating rod is rotatably connected in the upper part of the fixed plate, the accelerating component is connected between the right end of the rotating rod and the right side of the rotating shaft, the accelerating component penetrates through the limiting frame, the accelerating component comprises two belt pulleys and a flat belt, one of the belt is fixedly sleeved on the right side of the rotating shaft, the other belt pulley is fixedly sleeved at the right end of the rotating rod, the flat belt is wound between the two belt pulleys, conical fluted discs are fixedly connected to the bottom in the rotating disc and the left end of the rotating rod, and the two conical fluted discs are meshed.

Further, the novel energy battery clamping device comprises a material guiding mechanism for clamping and limiting the novel energy battery, the material guiding mechanism comprises support rods, material guiding frames, sliding blocks, sliding plates, third springs, guide rods, fourth springs, sliding blocks, fifth springs and trigger blocks, the support rods are fixedly connected to the front side of the top of the bottom plate in a bilateral symmetry mode, the material guiding frames are fixedly connected between the top ends of the two support rods, the bottom end of each material guiding frame is fixedly connected with the rear side of the top of the bottom plate, the sliding plates are connected to the left side and the right side of the upper portion in the material guiding frame in a sliding mode, the sliding blocks used for clamping the novel energy battery are connected to the middle of the sliding plates in a sliding mode in a penetrating mode, the sliding blocks are made of iron and are connected with the material guiding frames in a sliding mode, the third springs are connected between the inner side faces of the sliding plates in an up-down symmetry mode, the sliding blocks are connected to the rear side in the upper portion of the material guiding frames in an embedded mode, the guide rods are fixedly connected to the inner sides of the front sides of the sliding blocks, the front end of the guide rod penetrates through the sliding block, a fourth spring is connected between the inner side of the rear side face of the sliding block and the inner side of the front side face of the sliding block, the fourth spring is sleeved on the guide rod, three fifth springs are uniformly connected between the outer side face of the sliding block and the inner side of the material guide frame at intervals, and the rear sides of the left side face and the right side face outside the material guide frame are fixedly connected with a trigger block used for driving the sliding block to move outwards.

Further, still including being used for driving the mechanism that pushes down of placing the piece downstream, it is including triggering the dish to push down the mechanism, the stock, the dead lever, the guide post, sixth spring and contact block, bottom plate top rear side bilateral symmetry rigid coupling has the dead lever, the cover of slidingtype is equipped with the stock between the left and right sides dead lever upper portion front side, the rigid coupling has the guide post in the stock, the guide post runs through the dead lever, the stock leading flank lower part all rigid coupling has and is used for driving the contact block of placing the piece downstream, contact block and the contact of placing a top, the outer top front side of left and right sides dead lever respectively with be connected with the sixth spring in the stock between the left and right sides top, sixth spring housing is on the guide post, the dwang rear side has along circumference rigid coupling to be used for driving the trigger dish of stock downstream.

Further, still including the pulling mechanism who is used for driving the slider rearward movement, pulling mechanism is including the rack, the connecting axle, the rotating gear, the reel, act as go-between and the magnetic path, the outer left and right sides face upper portion front side of guide frame all is connected with the magnetic path that is used for driving the slider rearward movement, the outer left and right sides face rear side of guide frame all rotary type be connected with the connecting axle, the circumference rigid coupling has the rotating gear in the left and right sides connecting axle outside, the fixed cover in circumference is equipped with the reel in the left and right sides connecting axle outside all, around having the line of acting as go-between that is used for driving the magnetic path rearward movement on the reel, act as go-between the tail end and magnetic path trailing flank lower part fixed connection, left and right sides face lower part all rigid coupling has the rack that is used for driving the rotating gear reversal in the stock.

Furthermore, the heat conducting silica gel stopper further comprises a limiting mechanism used for stopping thrown heat conducting silica gel, the limiting mechanism comprises a mounting ring and a limiting ring, the mounting ring is fixedly connected to the outer lower portion of the rotating disc along the circumferential direction, and the limiting ring used for stopping the thrown heat conducting silica gel is fixedly connected to the bottom of the mounting ring along the circumferential direction.

Furthermore, a convex strip is fixedly connected to the handle along the circumferential direction.

Further, the slider (73) is iron.

The invention has the remarkable advantages that:

1. put the new forms of energy battery on placing the piece, the new forms of energy battery and stock guide contact, can stimulate the slewing mechanism reversal, the slewing mechanism reversal drives the injecting glue mechanism and operates, injecting glue mechanism operates and scribbles proper amount heat conduction silica gel on the new forms of energy battery, and injecting glue mechanism still drives stock guide corotation, stock guide corotation is with even scribbling on the new forms of energy battery of heat conduction silica gel, so, operating personnel only need stimulate the slewing mechanism reversal and just can realize scribbling heat conduction silica gel on the new forms of energy battery, it is more convenient.

2. An operator can move the new energy battery to the material guide mechanism, the material guide mechanism tightly clamps the new energy battery to be limited, and the new energy battery is guided through the material guide mechanism, so that the new energy battery is in contact with the material guide plate, and therefore the new energy battery can be prevented from moving to influence the uniform smearing of the heat conduction silica gel.

3. When heat conduction silica gel is smeared to the new energy battery, pulling mechanism function drives the slider rearward movement, just also makes the slider outwards remove and loosen the new energy battery, so, when heat conduction silica gel was smeared to the new energy battery, need not operating personnel and continue to promote the new energy battery rearward movement and be loosened and drop to the bottom plate on, labour saving and time saving.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a first partial sectional structural view of the present invention.

Fig. 5 is a perspective view of a third embodiment of the present invention.

FIG. 6 is a second partial sectional structural view of the present invention.

Fig. 7 is a third partial sectional structural schematic of the present invention.

Fig. 8 is an enlarged schematic view of part a of the present invention.

Fig. 9 is an enlarged view of part B of the present invention.

Fig. 10 is a perspective view of a fourth embodiment of the present invention.

Fig. 11 is a fourth partial sectional structural view of the present invention.

Fig. 12 is an enlarged schematic view of part C of the present invention.

FIG. 13 is a schematic view of a fifth partial cross-sectional structure of the present invention.

Fig. 14 is an enlarged view of the portion D of the present invention.

Fig. 15 is a schematic structural view of a fifth partial body according to the present invention.

Wherein the figures include the following reference numerals: 1. a bottom plate, 2, a placing block, 21, a first spring, 22, a material guide plate, 3, a fixed frame, 31, a limiting frame, 32, a supporting frame, 4, a shell, 5, a glue injection mechanism, 51, a material storage cylinder, 52, a one-way feeding pipe, 53, a one-way discharging pipe, 54, a rotating disc, 55, a piston rod, 56, a second spring, 57, a piston cylinder, 6, a rotating mechanism, 61, a bevel gear disc, 62, a rotating rod, 63, a fixed plate, 64, an accelerating component, 65, a rotating shaft, 66, a bevel gear, 67, a rotating rod, 68, a driving disc, 69, a handle, 7, a material guide mechanism, 71, a supporting rod, 72, a material guide frame, 73, a sliding block, 74, a sliding plate, 75, a third spring, 76, a guide rod, 77, a fourth spring, 78, a sliding block, 79, a fifth spring, 710, a triggering block, 8, a pressing mechanism, 81, a triggering disc, 82, a long rod, a fixed rod, 84, a guide column, 85. the device comprises a sixth spring, 86, a contact block, 9, a pulling mechanism, 91, a rack, 92, a connecting shaft, 93, a rotating gear, 94, a reel, 95, a pull wire, 96, a magnetic block, 10, a limiting mechanism, 101, a mounting ring, 102 and a limiting ring.

Detailed Description

The invention is further explained by combining the drawings in the specification and the embodiments of the invention are given by combining the drawings in the specification.

Example 1

A new energy battery heat-conducting silica gel smearing device comprises a bottom plate 1, a placing block 2, first springs 21, a material guide plate 22, a fixing frame 3, a limiting frame 31, a supporting frame 32, a shell 4, a glue injection mechanism 5 and a rotating mechanism 6, please refer to fig. 1-6, wherein the first springs 21 are symmetrically arranged on the left and right sides of the front side of the top of the bottom plate 1 in a welding connection mode, the placing block 2 is fixedly connected between the tail ends of the two first springs 21, an operator can place a new energy battery on the placing block 2, the fixing frame 3 is arranged on the front portion of the left side of the top of the bottom plate 1 in a welding connection mode, the supporting frame 32 is fixedly connected on the rear portion of the left side of the top of the bottom plate 1, the limiting frame 31 is arranged on the rear portion of the right side of the top of the bottom plate 1 in a welding connection mode, the left side of the outer front side of the limiting frame 31 is fixedly connected with the right side of the upper portion of the outer rear side of the fixing frame 3 through two rods, spacing 31 anterior rigid coupling has casing 4, install injecting glue mechanism 5 between mount 3 and the spacing 31, when injecting glue mechanism 5 functions, injecting glue mechanism 5 can realize discharging heat conduction silica gel, install stock guide 22 on injecting glue mechanism 5, when stock guide 22 corotation, stock guide 22 can realize smearing heat conduction silica gel on new forms of energy battery, install slewing mechanism 6 between casing 4 and the bottom plate 1, slewing mechanism 6 still is connected with injecting glue mechanism 5, when operating personnel pulling slewing mechanism 6 reversal, slewing mechanism 6 can realize driving injecting glue mechanism 5 and function.

The glue injection mechanism 5 comprises a storage tank 51, a one-way feeding pipe 52, a one-way discharging pipe 53, a rotary disc 54, a piston rod 55, a second spring 56 and a piston cylinder 57, please refer to fig. 1, fig. 2 and fig. 4, the storage tank 51 is connected to the left side of the upper part of the limiting frame 31 in a penetrating manner by welding, the one-way feeding pipe 52 is communicated with the middle of the bottom of the storage tank 51, the piston cylinder 57 is fixedly connected to the right side of the upper part of the fixing frame 3 in a penetrating manner, the middle of the lower part of the rear side of the piston cylinder 57 is fixedly connected to the tail end of the one-way feeding pipe 52, the one-way feeding pipe 52 is communicated with the piston cylinder 57, the piston rod 55 is placed in an inward sliding manner in the piston cylinder 57, the second spring 56 is installed between the outer top of the piston rod 55 and the inner top of the housing 4 in a welding manner, when the rotating mechanism 6 rotates reversely, the rotating mechanism 6 can drive the piston rod 55 to move downwards, the one-way discharging pipe 53 is communicated with the middle of the bottom of the piston cylinder 57, when the heat-conducting silica gel is discharged into the one-way discharging pipe 53, the one-way discharging pipe 53 can discharge the heat-conducting silica gel, the embedded rotation of the outer bottom of the piston cylinder 57 is connected with the rotating disc 54, the rotating disc 54 is sleeved on the one-way discharging pipe 53, the outer bottom of the rotating disc 54 is fixedly connected with the bottom of the material guide plate 22, when the rotating disc 54 rotates forwards, the rotating disc 54 can drive the material guide plate 22 to rotate forwards, the outer lower part of the rotating disc 54 is connected with the rotating mechanism 6, the rotating disc 54 penetrates through the right side of the middle part of the fixing frame 3, and the one-way feeding pipe 52 and the one-way discharging pipe 53 are both provided with one-way valves.

The rotating mechanism 6 includes a bevel gear plate 61, a rotating rod 62, a fixing plate 63, an accelerating assembly 64, a rotating shaft 65, a bevel gear 66, a rotating rod 67, a driving plate 68 and a handle 69, as shown in fig. 1, fig. 2 and fig. 6, the rotating rod 67 is rotatably connected to the middle of the front side of the housing 4 in a penetrating manner, the driving plate 68 is installed on the front side of the rotating rod 67 in a circumferential direction in a welded connection manner, the driving plate 68 is located outside the housing 4, when the driving plate 68 rotates reversely, the driving plate 68 can drive the piston rod 55 to move downwards, the handle 69 is installed in the middle of the upper portion of the front side of the driving plate 68 in a welded connection manner, an operator can pull the handle 69 to drive the driving plate 68 to rotate reversely, the handle 69 is fixedly connected with a convex strip along the circumferential direction, the rotating shaft 65 is rotatably connected to the middle of the right side of the housing 4, the bevel gear 66 is fixedly installed on the left side of the rotating shaft 65 and the front side of the rotating rod 67 in a circumferential direction, and the two bevel gears 66 are engaged, fixed plate 63 is installed through welded connection's mode to bottom plate 1 top front side right part, the cross-under of fixed plate 63 upper portion rotary type has bull stick 62, be connected with between bull stick 62 right-hand member and the pivot 65 right side with higher speed subassembly 64, subassembly 64 runs through spacing 31 with higher speed, subassembly 64 comprises two belt pulleys and flat belt with higher speed, one of them belt pulley is fixed to be adorned in pivot 65 right side, the fixed suit of another belt pulley is in the bull stick 62 right-hand member, the flat belt is around between two belt pulleys, conical tooth dish 61 is all installed through welded connection's mode to bottom and bull stick 62 left end in the rolling disc 54, two conical tooth dish 61 mesh mutually.

Firstly, an operator pulls the placing block 2 to move downwards for a certain distance, the first spring 21 is compressed, then a new energy battery is placed on the placing block 2, the placing block 2 is loosened, the placing block 2 moves upwards to drive the new energy battery to move upwards under the action of the first spring 21, the new energy battery moves upwards to be in contact with the material guide plate 22, the rotating mechanism 6 is pulled to rotate reversely, the rotating mechanism 6 rotates reversely to drive the glue injection mechanism 5 to operate, the glue injection mechanism 5 operates to discharge the heat-conducting silica gel, the heat-conducting silica gel is in contact with the material guide plate 22 and the new energy battery, the rotating mechanism 6 is continuously pulled to rotate reversely, the rotating mechanism 6 drives the glue injection mechanism 5 to rotate forwards, the glue injection mechanism 5 rotates forwards to drive the material guide plate 22 to rotate forwards, the material guide plate 22 rotates forwards to drive the heat-conducting silica gel to uniformly coat on the new energy battery, when the rotating mechanism 6 rotates reversely and resets, the rotating mechanism 6 stops pulling the rotating mechanism 6 to rotate forwards and stops driving the glue injection mechanism 5, the glue injection mechanism 5 stops driving the material guide plate 22 to rotate forwards, then pulls the placing block 2 to move downwards to a proper position, the first spring 21 is compressed, the placing block 2 moves downwards to drive the new energy battery to move downwards, the new energy battery moves downwards to be separated from the material guide plate 22, the new energy battery coated with the heat-conducting silica gel is taken down, and the steps are repeated, so that the heat-conducting silica gel can be continuously and uniformly coated on the new energy battery.

Initially, a proper amount of heat-conducting silica gel is filled in both the storage cylinder 51 and the piston cylinder 57, when the new energy battery contacts the material guide plate 22, the rotating mechanism 6 is pulled to rotate reversely, the rotating mechanism 6 rotates reversely to drive the piston rod 55 to move downwards, the second spring 56 is stretched, the piston rod 55 moves downwards to push the heat-conducting silica gel in the piston cylinder 57 into the one-way discharge pipe 53, the heat-conducting silica gel in the one-way discharge pipe 53 is discharged to contact the material guide plate 22, the heat-conducting silica gel also contacts the new energy battery, when the rotating mechanism 6 rotates reversely to be separated from the piston rod 55, the piston rod 55 moves upwards to reset through the one-way feed pipe 52, the proper amount of heat-conducting silica gel in the storage cylinder 51 is sucked into the piston cylinder 57, meanwhile, the rotating mechanism 6 rotates reversely to drive the rotating disc 54 to rotate forwardly, the rotating disc 54 rotates forwardly to drive the material guide plate 22, the rotating disc 22 drives the heat-conducting silica gel to rotate forwardly, the guide plate 22 evenly paints the heat-conducting silica gel on the new energy battery, when the rotating mechanism 6 rotates reversely and resets, the rotating mechanism 6 stops being pulled, the rotating mechanism 6 stops driving the rotating disc 54 to rotate forwardly, the rotating disc 54 stops driving the guide plate 22 to rotate forwardly, the new energy battery coated with the heat-conducting silica gel can be taken down from the placing block 2, and the steps are repeated so as to evenly paint the heat-conducting silica gel on the new energy battery. When there is no heat conductive silica gel in the accumulator 51, an appropriate amount of heat conductive silica gel may be poured into the accumulator 51.

When the new energy battery contacts the material guide plate 22, the handle 69 can be pulled to rotate reversely, since the raised strips are fixedly connected to the handle 69 along the circumferential direction, the operator can hold the handle 69 more stably, the handle 69 rotates reversely to drive the driving disc 68 to rotate reversely, the driving disc 68 rotates reversely to drive the piston rod 55 to move downwards, so that the one-way discharging pipe 53 discharges the heat-conducting silica gel, when the driving disc 68 rotates reversely to be separated from the piston rod 55, the piston rod 55 moves upwards to reset due to the action of the second spring 56, the heat-conducting silica gel stops discharging, the driving disc 68 rotates reversely to drive the rotating rod 67 to rotate reversely, the rotating rod 67 rotates reversely to drive the front-side bevel gear 66 to rotate reversely, the front-side bevel gear 66 rotates reversely to drive the rear-side bevel gear 66 to rotate forwardly, the rotating shaft 65 rotates forwardly to drive the accelerating assembly 64 to rotate forwardly, the accelerating assembly 64 rotates forwardly to drive the rotating rod 62 to rotate forwardly, the rotating rod 62 drives the upper bevel gear disc 61, the upper conical fluted disc 61 rotates forward to drive the lower conical fluted disc 61 to rotate forward, the lower conical fluted disc 61 rotates forward to drive the rotating disc 54 to rotate forward, the rotating disc 54 rotates forward to drive the material guide plate 22 to rotate forward, the material guide plate 22 rotates forward to uniformly coat the heat-conducting silica gel on the new energy battery, when the driving disc 68 is reversely rotated and reset, the handle 69 is stopped to drive the driving disc 68 to reversely rotate, the driving disc 68 stops driving the rotating rod 67 to reversely rotate, the rotating rod 67 stops driving the front bevel gear 66 to reversely rotate, the rotating rod 62 stops driving the upper bevel gear 61 to forwardly rotate, the upper bevel gear 61 stops driving the lower bevel gear 61 to forwardly rotate, the lower bevel gear 61 stops driving the rotating disc 54 to forwardly rotate, the rotating disc 54 stops driving the material guide plate 22 to forwardly rotate, and thus, when new energy batteries are placed on the placing block 2 and contact with the material guide plate 22, the grip 69 can be pulled to drive the driving disc 68 to rotate reversely by three hundred and sixty degrees, so that the material guide plate 22 can uniformly coat the heat-conducting silica gel on the new energy battery.

Example 2

On the basis of embodiment 1, the energy-saving device further comprises a material guiding mechanism 7, wherein the material guiding mechanism 7 comprises a support rod 71, a material guiding frame 72, a sliding block 73, a sliding plate 74, a third spring 75, a guide rod 76, a fourth spring 77, a sliding block 78, a fifth spring 79 and a trigger block 710, as shown in fig. 1, 2, 7, 8, 9 and 10, the support rod 71 is symmetrically installed on the front side of the top of the bottom plate 1 in a left-right mode through a welded connection mode, the material guiding frame 72 is fixedly connected to the top ends of the two support rods 71, the bottom end of the material guiding frame 72 is installed on the rear side of the top of the bottom plate 1 through a welded connection mode, the sliding plates 74 are connected to the left side and the right side of the upper portion in the material guiding frame 72 in a sliding mode, the sliding block 73 is connected to the middle portion of the sliding plate 74 in a sliding mode in a penetrating manner, the sliding block 73 is iron, the sliding block 73 is connected to the material guiding frame 72 in a sliding mode, when an operator places a new energy battery between the two sliding blocks 73, the novel energy battery can be clamped by the sliding block 73, the third springs 75 are symmetrically connected between the inner side face of the sliding block 73 and the inner side face of the sliding plate 74 from top to bottom, the sliding block 78 is connected to the inner side face of the upper portion of the material guide frame 72 in an embedded mode on the inner side face of the rear side face, the guide rods 76 are installed on the inner side face of the front side face of the sliding block 78 in a welded connection mode, the front ends of the guide rods 76 penetrate through the sliding block 73, the fourth springs 77 are connected between the inner side face of the rear side face of the sliding block 73 and the inner side face of the front side face of the sliding block 78, the fourth springs 77 are sleeved on the guide rods 76, three fifth springs 79 are evenly connected between the outer side face of the sliding block 78 and the inner side face of the material guide frame 72 at intervals, the trigger blocks 710 are installed on the rear sides of the left side face and the right side face of the outer side face of the material guide frame 72 in a bolted connection mode, and when the sliding block 73 moves backwards and contacts with the trigger blocks 710, the trigger blocks can drive the sliding block 73 to move outwards.

The device also comprises a pressing mechanism 8, the pressing mechanism 8 comprises a triggering plate 81, a long rod 82, a fixed rod 83, a guide post 84, a sixth spring 85 and a contact block 86, please refer to fig. 1, 2, 11 and 12, the fixed rod 83 is symmetrically arranged at the left and right sides of the rear side of the top of the bottom plate 1 by welding connection, the long rod 82 is sleeved between the front sides of the upper parts of the fixed rods 83 at the left and right sides in a sliding manner, the guide post 84 is fixedly connected in the long rod 82, the guide post 84 penetrates through the fixed rod 83, the contact block 86 is arranged at the lower part of the front side of the long rod 82 by welding connection, the contact block 86 is contacted with the top of the placing block 2, when the contact block 86 moves downwards, the contact block 86 can drive the placing block 2 to move downwards, the sixth spring 85 is connected between the front side of the top of the fixed rod 83 and the inner top of the long rod 82, the sixth spring 85 is sleeved on the guide post 84, the triggering plate 81 is arranged at the rear side of the 67 by welding connection along the circumferential direction, when the trigger plate 81 is reversed to contact the long rod 82, the trigger plate 81 can drive the long rod 82 to move downwards.

Firstly, an operator moves a new energy battery between two sliding blocks 73, and the new energy battery is in contact with a placing block 2, the two sliding blocks 73 clamp the new energy battery, then the new energy battery is pushed to move backwards, the new energy battery moves backwards to drive the sliding block 73 to move backwards, a fourth spring 77 is compressed, when the new energy battery moves backwards to be under a material guide plate 22, the new energy battery stops pushing the new energy battery to move backwards, the new energy battery stops driving the sliding block 73 to move backwards, namely, heat-conducting silica gel can be uniformly coated on the new energy battery, when the new energy battery is coated with the heat-conducting silica gel, the placing block 2 is pushed to move downwards for a certain distance, a first spring 21 is compressed, the placing block 2 drives the new energy battery to move downwards to be separated from the material guide plate 22, then the new energy battery is pushed to move backwards to drive the sliding block 73 to move backwards, and the fourth spring 77 is compressed, when the sliding block 73 moves backwards to be in contact with the triggering block 710, the triggering block 710 enables the sliding block 73 moving backwards to move outwards, the third spring 75 is compressed, the sliding block 73 moves outwards to drive the guide rod 76 to move outwards, the guide rod 76 moves outwards to drive the sliding block 78 to move outwards, the fifth spring 79 is compressed, the sliding block 73 moves outwards to release the new energy battery, the new energy battery falls onto the material guide frame 72, the new energy battery on the material guide frame 72 slides onto the bottom plate 1, the sliding block 73 moves forwards to reset and is separated from the contact with the triggering block 710 under the action of the fourth spring 77, the sliding block 78 moves inwards to drive the guide rod 76 to move inwards to reset under the action of the fifth spring 79, meanwhile, the sliding block 73 moves inwards to reset under the action of the third spring 75, and then releases the placing block 2 to move upwards to reset. Therefore, the phenomenon that the new energy battery moves to influence the uniform smearing of the heat-conducting silica gel can be avoided.

When an operator pulls the handle 69 to drive the driving disc 68 to rotate reversely, the rotating rod 67 rotates reversely to drive the trigger disc 81 to rotate reversely, when the new energy battery is coated with the heat-conducting silica gel, the trigger disc 81 rotates reversely to contact with the long rod 82, the trigger disc 81 drives the long rod 82 to move downwards, the sixth spring 85 is compressed, the long rod 82 moves downwards to drive the contact block 86 to move downwards, the contact block 86 moves downwards to drive the placing block 2 to move downwards, the first spring 21 is compressed, due to the weight of the new energy battery, the placing block 2 moves downwards to drive the new energy battery to move downwards to be separated from the contact with the material guide plate 22, the handle 69 is stopped to be pulled to drive the driving disc 68 to rotate reversely, the trigger disc 81 stops rotating reversely, the contact block 86 also stops driving the placing block 2 to move downwards to push the new energy battery to move backwards to a proper position to fall onto the bottom plate 1, and then the handle 69 is pulled to drive the driving disc 68 to rotate reversely to reset, driving-disc 68 resets and drives trigger plate 81 reversal through dwang 67 and resets, triggers plate 81 reversal and resets and break away from the contact with stock 82, because of sixth spring 85's effect, stock 82 rebound resets and drives contact piece 86 rebound and resets, and contact piece 86 resets and does not carry out spacingly to placing piece 2, because of first spring 21's effect, places piece 2 rebound and resets. So, need not operating personnel and push with the hand and place piece 2 downstream and drive new forms of energy lithium cell downstream, convenient and fast.

Example 3

On the basis of the embodiment 1 and the embodiment 2, the pulling mechanism 9 is further included, the pulling mechanism 9 includes a rack 91, a connecting shaft 92, a rotating gear 93, a reel 94, a pull wire 95 and a magnet 96, please refer to fig. 1, 2, 13 and 14, the magnet 96 is connected to the front sides of the upper portions of the left and right side surfaces of the guide frame 72 in a sliding manner, when the slider 73 contacts with the magnet 96, the magnet 96 can drive the slider 73 to move backwards, the connecting shaft 92 is connected to the rear sides of the left and right side surfaces of the guide frame 72 in a rotating manner, the rotating gear 93 is installed on the outer sides of the left and right side connecting shafts 92 in a welding connection manner along the circumferential direction, the reel 94 is fixedly installed on the outer sides of the left and right side connecting shafts 92 along the circumferential direction, the rotating gear 93 is on the outer sides of the reel 94, the pull wire 95 is wound on the reel 94, the tail end of the pull wire 95 is fixedly connected to the lower portion of the rear side surface of the magnet 96, when the pull wire 95 is wound, the pull wire 95 can drive the magnetic block 96 to move backwards, the racks 91 are fixedly connected to the lower portions of the left side surface and the right side surface in the long rod 82, and when the racks 91 move downwards to be meshed with the rotating gear 93, the racks 91 can drive the rotating gear 93 to rotate reversely.

The novel energy battery is characterized by further comprising a limiting mechanism 10, wherein the limiting mechanism 10 comprises a mounting ring 101 and a limiting ring 102, as shown in fig. 1 and fig. 15, the mounting ring 101 is mounted on the outer lower portion of the rotating disc 54 in a circumferential direction in a bolt connection mode, the limiting ring 102 is mounted at the bottom of the mounting ring 101 in a circumferential direction in a welding connection mode, and when the material guide plate 22 rotates forwards to coat the heat-conducting silica gel on the new energy battery, the limiting ring 102 can block the thrown heat-conducting silica gel.

When an operator moves a new energy battery between the two sliding blocks 73, pushes the new energy battery to move backwards to drive the sliding block 73 to move backwards, the sliding block 73 moves backwards to be in contact with the magnetic block 96, the magnetic block 96 attracts the sliding block 73 through magnetic force, the new energy battery stops being pushed, the new energy battery is in contact with the material guide plate 22, and further, heat conducting silica gel is coated on the new energy battery, the long rod 82 moves downwards to also drive the rack 91 to move downwards, when the rack 91 moves downwards to be meshed with the rotating gear 93, the rack 91 drives the rotating gear 93 to rotate backwards, the rotating gear 93 rotates backwards to drive the connecting shaft 92 to rotate backwards, the connecting shaft 92 rotates backwards to drive the reel 94 to rotate backwards, the reel 94 rotates backwards to roll the pull wire 95, the pull wire 95 is rolled to drive the magnetic block 96 to move backwards to drive the sliding block 73 to move backwards, the magnetic block 73 moves backwards to drive the new energy battery to move backwards, and the sliding block 73 moves backwards to be in contact with the trigger block 710, the trigger block 710 drives the sliding block 73 to move outwards, the sliding block 73 moves outwards to release a new energy battery, the new energy battery slides from the material guide plate 22 to the bottom plate 1, at the moment, the long rod 82 moves upwards to drive the rack 91 to move upwards for resetting, the rack 91 moves upwards to drive the rotating gear 93 to rotate forwards for resetting, the rotating gear 93 rotates forwards for resetting to drive the connecting shaft 92 to rotate forwards for resetting, the connecting shaft 92 rotates forwards for resetting to drive the winding wheel 94 to rotate forwards for resetting, the winding wheel 94 rotates forwards for resetting to release the stay wire 95, the sliding block 73 moves forwards for resetting to drive the magnetic block 96 to move forwards for resetting due to the action of the fourth spring 77, the magnetic block 96 moves forwards to drive the stay wire 95 to move forwards for resetting, and after the magnetic block 96 resets, the sliding block 73 continues to move forwards for resetting to be separated from the magnetic block 96. Therefore, when the new energy battery is coated with the heat-conducting silica gel, the new energy battery is not required to be continuously pushed by an operator to move backwards and is loosened to fall onto the bottom plate 1, and time and labor are saved.

When the rotating disc 54 rotates forward to drive the material guide plate 22 to rotate forward to uniformly coat the heat-conducting silica gel on the new energy battery, the rotating disc 54 rotates forward to drive the mounting ring 101 to rotate forward, the mounting ring 101 rotates forward to drive the limiting ring 102 to rotate forward, and the limiting ring 102 rotates forward to block the thrown-out heat-conducting silica gel. When the rotating disc 54 stops the forward rotation, the rotating disc 54 stops the forward rotation of the stopper ring 102 by the mount ring 101. Therefore, the heat-conducting silica gel can be prevented from being thrown out to influence the surrounding environment.

Finally, it is necessary to state that: the above-mentioned contents are only used to help understanding the technical solution of the present invention, and should not be interpreted as limiting the scope of the present invention; insubstantial modifications and adaptations of the invention as described above will occur to those skilled in the art and are intended to be within the scope of the invention as claimed.

Claims

1. A new energy battery heat-conducting silica gel smearing device comprises a bottom plate (1), a placing block (2), first springs (21), a material guide plate (22), a fixing frame (3), a limiting frame (31), a supporting frame (32) and a shell (4), wherein the first springs (21) are symmetrically connected to the left and right of the front side of the top of the bottom plate (1), the placing block (2) for placing a new energy battery is fixedly connected between the tail ends of the two first springs (21), the fixing frame (3) is fixedly connected to the front portion of the left side of the top of the bottom plate (1), the supporting frame (32) is fixedly connected to the rear portion of the left side of the top of the bottom plate (1), the limiting frame (31) is fixedly connected to the right end of the supporting frame (32), the left side of the upper portion of the front side of the outside of the limiting frame (31) is fixedly connected to the right side of the upper portion of the rear side of the outside of the fixing frame (3) through two rods, spacing (31) front portion rigid coupling has casing (4), stock guide (22) are used for evenly smearing heat conduction silica gel on new energy battery, characterized by, still including injecting glue mechanism (5) and slewing mechanism (6), install between mount (3) and spacing (31) and be used for injecting glue mechanism (5) with heat conduction silica gel exhaust, injecting glue mechanism (5) are connected with stock guide (22), install slewing mechanism (6) that are used for driving injecting glue mechanism (5) function between casing (4) and bottom plate (1), slewing mechanism (6) still are connected with injecting glue mechanism (5).

2. The new energy battery heat-conducting silica gel smearing device as claimed in claim 1, wherein the glue injection mechanism (5) comprises a storage vat (51), a one-way feeding pipe (52), a one-way discharging pipe (53), a rotating disc (54), a piston rod (55), a second spring (56) and a piston cylinder (57), the storage vat (51) is fixedly connected to the left side of the upper portion of the limiting frame (31) in a penetrating manner, the one-way feeding pipe (52) is communicated with the middle of the bottom of the storage vat (51), the piston cylinder (57) is fixedly connected to the right side of the upper portion of the fixing frame (3) in a penetrating manner, the middle of the lower portion of the rear side of the piston cylinder (57) is fixedly connected with the tail end of the one-way feeding pipe (52), the one-way feeding pipe (52) is communicated with the piston cylinder (57), the piston rod (55) is placed in an inward sliding manner in the piston cylinder (57), the second spring (56) is fixedly connected between the outer top of the piston rod (55) and the inner top of the shell (4), the rotating mechanism (6) is in contact with the piston rod (55) in a reverse rotation mode, a one-way discharging pipe (53) used for discharging heat-conducting silica gel is communicated with the middle of the bottom of the piston cylinder (57), a rotating disc (54) used for driving the material guide plate (22) to rotate forward is connected to the embedded rotation of the outer bottom of the piston cylinder (57), the rotating disc (54) is sleeved on the one-way discharging pipe (53), the outer bottom of the rotating disc (54) is fixedly connected with the bottom of the material guide plate (22), the outer lower portion of the rotating disc (54) is connected with the rotating mechanism (6), and the rotating disc (54) penetrates through the right side of the middle of the fixing frame (3).

3. The new energy battery heat-conducting silica gel smearing device as claimed in claim 2, wherein the rotating mechanism (6) comprises a conical fluted disc (61), a rotating rod (62), a fixing plate (63), an accelerating assembly (64), a rotating shaft (65), a bevel gear (66), a rotating rod (67), a driving disc (68) and a handle (69), the rotating rod (67) is rotatably connected in the middle of the front side of the housing (4) in a penetrating manner, the driving disc (68) for driving the piston rod (55) to move downwards is fixedly connected in the front side of the rotating rod (67) along the circumferential direction, the driving disc (68) is positioned outside the housing (4), the handle (69) is fixedly connected in the middle of the upper portion of the front side of the driving disc (68), the rotating shaft (65) is rotatably connected in the middle of the right side of the housing (4), the bevel gear (66) is fixedly sleeved in the circumferential direction on both the left side of the rotating shaft (65) and the front side of the rotating rod (67), and the two bevel gears (66) are meshed, bottom plate (1) top front side right part rigid coupling has fixed plate (63), the cross-under of fixed plate (63) upper portion rotary type has bull stick (62), be connected with between bull stick (62) right-hand member and pivot (65) right side with higher speed subassembly (64), running through spacing (31) with higher speed subassembly (64), with higher speed subassembly (64) comprise two belt pulleys and flat belt, the fixed suit of one of them belt pulley is in pivot (65) right side, the fixed suit of another belt pulley is in bull stick (62) right-hand member, the flat belt is around between two belt pulleys, bottom and bull stick (62) left end all rigid couplings have awl fluted disc (61) in rolling disc (54), two awl fluted disc (61) mesh mutually.

4. The new energy battery heat-conducting silica gel smearing device as claimed in claim 3, characterized by further comprising a material guiding mechanism (7) for clamping and limiting the new energy battery, wherein the material guiding mechanism (7) comprises supporting rods (71), a material guiding frame (72), sliding blocks (73), sliding plates (74), third springs (75), guide rods (76), fourth springs (77), sliding blocks (78), fifth springs (79) and trigger blocks (710), the supporting rods (71) are fixedly connected to the front side of the top of the bottom plate (1) in a bilateral symmetry manner, the material guiding frame (72) is fixedly connected between the top ends of the two supporting rods (71), the bottom end of the material guiding frame (72) is fixedly connected to the rear side of the top of the bottom plate (1), the sliding plates (74) are connected to the left and right sides of the upper portion in the material guiding frame (72) in a sliding manner, and the sliding blocks (73) for clamping the new energy battery are slidably connected to the middle of the sliding plates (74) in a penetrating manner, slider (73) and guide frame (72) sliding connection, the vertical symmetry is connected with third spring (75) between slider (73) medial surface and sliding plate (74) medial surface, the embedded sliding connection of trailing flank has slider (78) in guide frame (72) upper portion, slider (78) leading flank inboard rigid coupling has guide bar (76), guide bar (76) front end runs through slider (73), be connected with fourth spring (77) between slider (73) trailing flank inboard and slider (78) leading flank inboard, fourth spring (77) cover is on guide bar (76), evenly spaced is connected with three fifth spring (79) between slider (78) lateral surface and guide frame (72) inboard, guide frame (72) outer left and right sides lateral surface rear side all rigid coupling has trigger block (710) that is used for driving slider (73) outwards to move.

5. The new energy battery heat-conducting silica gel smearing device as claimed in claim 4, characterized by further comprising a pressing mechanism (8) for driving the placement block (2) to move downwards, wherein the pressing mechanism (8) comprises a trigger plate (81), a long rod (82), a fixing rod (83), a guide post (84), a sixth spring (85) and a contact block (86), the fixing rods (83) are fixedly connected to the rear side of the top of the bottom plate (1) in a bilateral symmetry manner, the long rod (82) is slidably sleeved between the front sides of the upper portions of the left and right fixing rods (83), the guide post (84) is fixedly connected to the inside of the long rod (82), the guide post (84) penetrates through the fixing rod (83), the contact blocks (86) for driving the placement block (2) to move downwards are fixedly connected to the left and right sides of the lower portion of the front side of the long rod (82), the contact block (86) is in contact with the top of the placement block (2), and the front sides of the outer tops of the left and right fixing rods (83) are respectively connected to the top of the left and right sides of the long rod (82) in a sixth spring Spring (85), sixth spring (85) cover is on guide post (84), and dwang (67) rear side is along circumference rigid coupling have and be used for driving trigger dish (81) that stock (82) moved down.

6. The new energy battery heat-conducting silica gel smearing device as claimed in claim 5, further comprising a pulling mechanism (9) for driving the sliding block (73) to move backwards, wherein the pulling mechanism (9) comprises a rack (91), a connecting shaft (92), a rotating gear (93), a winding wheel (94), a pulling wire (95) and magnetic blocks (96), the magnetic blocks (96) for driving the sliding block (73) to move backwards are connected to the front sides of the upper portions of the left and right outer side surfaces of the material guide frame (72) in a sliding manner, the connecting shaft (92) is rotatably connected to the rear sides of the left and right outer side surfaces of the material guide frame (72), the rotating gear (93) is fixedly connected to the outer sides of the connecting shaft (92) at the left and right sides along the circumferential direction, the winding wheel (94) is fixedly sleeved on the outer sides of the connecting shaft (92) at the left and right sides along the circumferential direction, the pulling wire (95) for driving the magnetic blocks (96) to move backwards is wound on the winding wheel (94), the tail end of the pull wire (95) is fixedly connected with the lower part of the rear side of the magnetic block (96), and racks (91) for driving the rotary gear (93) to rotate reversely are fixedly connected with the lower parts of the left side and the right side in the long rod (82).

7. The new energy battery heat-conducting silica gel smearing device as claimed in claim 6, further comprising a limiting mechanism (10) for blocking the thrown heat-conducting silica gel, wherein the limiting mechanism (10) comprises a mounting ring (101) and a limiting ring (102), the mounting ring (101) is fixedly connected to the outer lower portion of the rotating disc (54) along the circumferential direction, and the limiting ring (102) for blocking the thrown heat-conducting silica gel is fixedly connected to the bottom of the mounting ring (101) along the circumferential direction.

8. The new energy battery heat-conducting silica gel smearing device as claimed in claim 7, wherein raised strips are fixedly connected to the handle (69) along a circumferential direction.

9. The new energy battery heat-conducting silica gel smearing device as claimed in claim 4, wherein the sliding block (73) is iron.