CN211181770U - Fluidization dip-coating device for special-shaped connection copper bar - Google Patents

Abstract

The utility model relates to a fluidization dip-coating device for special-shaped connecting copper bars, which belongs to the technical field of connecting copper bar processing, and comprises a frame, a guide rail, a hanger trolley, a preheating furnace, a powder fluidized bed and a curing furnace, wherein the guide rail is arranged along the length direction of the frame; when the connecting copper bar heated by the preheating furnace moves to the upper part of the powder fluidized bed along with the hanging rack trolley, the pneumatic lifting assembly is utilized to immerse the connecting copper bar in the powder fluidized bed, after the hanging rack trolley is dipped and coated, the vibration assembly is utilized to shake off redundant powder on the corner of the connecting copper bar in the rising process of the hanging rack trolley, so that the powder on the connecting copper bar is uniformly distributed, and the quality of the processed connecting copper bar is higher.

Description

Fluidization dip-coating device for special-shaped connection copper bar

Technical Field

The utility model belongs to the technical field of the technique of connecting copper bar insulating layer processing and specifically relates to a dysmorphism is connected copper bar and is dip-coated device with fluidization.

Background

The connecting copper bar is made of copper materials, the long conductor with the rectangular or round-corner rectangular cross section plays a role in conveying current and connecting electrical equipment in a circuit, and the connecting copper bar is widely applied to electrical equipment, particularly complete sets of power distribution devices, and is widely applied to the electrical equipment of new energy automobiles at present.

In the prior art, when the connecting copper bar insulating layer is processed, epoxy resin powder is usually placed in a powder fluidized bed, the connecting copper bar is preheated in a heating furnace in advance, the preheated connecting copper is discharged in the powder fluidized bed to be dip-coated, a worker takes out the connecting copper bar by using a clamp, the connecting copper bar is placed in a curing furnace to be cured, and the processing process of the connecting copper bar insulating layer is completed.

The prior art scheme in the foregoing has drawbacks: the workman adds man-hour to connecting the copper bar insulating layer, belongs to pure manual operation, and from the connecting copper bar that takes out in the powder fluidized bed, the insulating layer of dip-coating probably has inhomogeneous condition to make the quality inconsistent of connecting the copper bar.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art existence, the utility model aims at providing a dysmorphism is connected copper bar and is used fluidization dip-coating device can save some manual operation steps, makes workman labour saving and time saving in operation process, has solved the inhomogeneous problem of insulating layer of connecting the copper bar dip-coating.

The utility model discloses a can realize through following technical scheme:

the utility model provides a dysmorphism is connected copper bar and is dip-coated device with fluidization, includes frame, guide rail, stores pylon dolly, preheater, powder fluidized bed, curing oven, the guide rail sets up along frame length direction, the stores pylon dolly slides and connects on the guide rail, preheater, powder fluidized bed and curing oven are located the guide rail below and arrange along frame length direction in order, it is equipped with pneumatic lifting unit to lie in powder fluidized bed top in the frame, be equipped with the locating part that is used for fixed stores pylon dolly on the pneumatic lifting unit, be equipped with on the pneumatic lifting unit and be used for shaking off the vibration subassembly of connecting unnecessary powder on the copper bar turning.

By adopting the technical scheme, when the connecting copper bar insulating layer is processed, the connecting copper bar is hung on the hanging rack trolley, the hanging rack trolley moves along the guide rail in the length direction of the rack, and the guide rail plays a role in guiding the hanging rack trolley; after the hanger trolley enters the preheating furnace, the connecting copper bar is uniformly heated; when the hanger trolley moves above the powder fluidized bed, the hanger trolley moves downwards by using the pneumatic lifting assembly, so that the connecting copper bar is immersed in the powder fluidized bed, and the hanger trolley is prevented from shaking due to vibration when moving downwards by using the limiting part; after dip-coating, utilize the vibration subassembly, at the stores pylon dolly in-process that rises, shake off and connect unnecessary powder on the copper bar corner, and make the powder evenly distributed on the connection copper bar, and then make the quality of the connection copper bar after the processing higher.

The utility model discloses can further configure into: the pneumatic lifting assembly comprises an air cylinder and a bearing bracket, and the bearing bracket is connected with a piston rod of the air cylinder.

Through adopting above-mentioned technical scheme, the cylinder drive holds the bracket up-and-down motion to realize the up-and-down motion of stores pylon dolly, through the common cooperation of cylinder and support bracket, make the motion of stores pylon dolly more steady.

The utility model discloses can further set up to: the supporting bracket comprises two supporting angle irons oppositely arranged along the length direction of the rack and two door-shaped frames oppositely arranged, and the door-shaped frames are vertically welded on the two supporting angle irons.

By adopting the technical scheme, the supporting angle iron is utilized, so that the hanging rack trolley moving to the upper part of the fluidized bed can be supported; the door-shaped frame can be used for supporting the vibration assembly.

The utility model discloses can further set up to: the vibration component comprises a vibration motor, an upper top plate, a lower bottom plate and damping springs, the vibration motor is fixed on the lower bottom plate, the upper top plate is connected with the lower bottom plate through the damping springs, the upper top plate is connected with a piston rod of the air cylinder, and the lower bottom plate is fixed on the portal frame.

By adopting the technical scheme, in the rising process of the dip-coated connecting copper bar, the vibration motor is utilized to shake off the redundant powder on the corner of the connecting copper bar, the frequency of the vibration motor is stable, and the powder on the connecting copper bar can be uniformly distributed, so that the processed connecting copper bar has higher quality; the upper top plate is connected with the lower bottom plate through a plurality of damping springs, so that the stability of the vibration assembly during working is improved; the lower bottom plate is fixed on the door-shaped frame and plays a role in supporting the vibration assembly.

The utility model discloses can further set up to: the vibration subassembly includes chassis, U-shaped frame, striker bar and drive assembly, the chassis is fixed on holding the bracket, the U-shaped frame sets up on the chassis top, the striker bar slides and connects in the U-shaped frame.

Through adopting above-mentioned technical scheme, having accomplished the powder when connecting the copper bar dip-coating, utilize drive assembly, the drive impact pole strikes the support bracket with reciprocating to shake off unnecessary powder on connecting the copper bar turning, and make the powder evenly distributed of dip-coating on connecting the copper bar, and then make the connection copper bar quality of processing out higher.

The utility model discloses can further set up to: the drive assembly includes driving motor, rotor arm, driven arm and driven rod, the chassis includes montant and horizontal pole, driving motor is located the horizontal pole, driving motor's motor shaft level is passed the horizontal pole and is connected with the one end of rotor arm, be equipped with the U-shaped hole on the driven arm, the one end that the motor shaft was kept away from to the rotor arm is slided and is connected downtheholely in the U-shaped, the one end of driven arm is rotated and is connected on the horizontal pole, the other end and the drive rod of driven arm are articulated mutually, the one end that the driven arm was kept away from to the driven rod is articulated mutually with the striker.

By adopting the technical scheme, under the action of the driving motor, the rotating arm rotates in the U-shaped hole, the rotating arm drives the driven arm to do reciprocating motion, the driven arm drives the driving rod to do reciprocating motion, the driving rod drives the impact rod to do reciprocating motion in the U-shaped frame, and the frequency of the impact rod stably impacts the bearing bracket, so that redundant powder on the corner of the connecting copper bar can be shaken off, and the powder on the surface of the connecting copper bar can be uniformly distributed.

The utility model discloses can further set up to: the locating part includes dead lever, connecting rod and clamping jaw, the bottom of dead lever is connected on the lateral wall of support bracket, the top of dead lever is articulated mutually with the one end of connecting rod, the clamping jaw is vertical to be connected the one end of keeping away from the dead lever at the connecting rod, the clamping jaw extends to on the stores pylon dolly and holds and hold on the lateral wall of stores pylon dolly.

Through adopting above-mentioned technical scheme, when the stores pylon dolly moves to holding the bracket on, under the combined action of pneumatic lifting unit and vibration subassembly, the slope is rocked easily to the stores pylon dolly, and at this moment, the clamping jaw receives the vibration, holds under the action of gravity and holds and hold on the stores pylon dolly, or the workman utilizes handheld pole to beat the connecting rod, makes the clamping jaw hold and holds on the stores pylon dolly, can promote the stability of stores pylon dolly when the fluidized bed top moves along vertical direction.

The utility model discloses can further set up to: the hanger trolley comprises a sliding frame, a plurality of idler wheels, a plurality of hanging rods and a top plate, wherein the idler wheels are uniformly distributed at four corners of the bottom of the sliding frame, the hanging rods are equidistantly distributed on the sliding frame along the width direction of the sliding frame, and the top plate is welded on the hanging rods.

Through adopting above-mentioned technical scheme, the stores pylon dolly moves along frame length direction on the guide rail to the copper bar motion is connected in the drive, makes the material loading process of connecting the copper bar need not artifical too much intervention, and is labour saving and time saving relatively.

The utility model discloses can further set up to: copper bar transmission direction's both sides are connected to preheater and curing oven perpendicular to all are equipped with the overhead door, the overhead door includes the closing plate, holds pole, fixed pulley, steel wire and balancing weight, the one end of holding the pole articulates in the frame, the other end of holding the pole upwards extends, the fixed pulley sets up the top in the frame, steel wire one end is connected on the roof of closing plate, the other end of steel wire is walked around the fixed pulley and is linked to each other with the balancing weight, the balancing weight is kept away from the one end of pulley and is passed through wire rope and hold the pole and link to each other.

By adopting the technical scheme, the energy consumption of the preheating furnace and the curing furnace can be saved by arranging the lifting door; when a worker presses one end of the holding rod, which is far away from the rack, the steel wire pulls the sealing plate upwards, and when the worker lifts the end, which extends upwards, of the holding rod, the steel wire drives the sealing plate to move downwards, so that the sealing plate on the preheating furnace is closed with the side wall of the preheating furnace, and the sealing plate on the curing furnace is closed with the side wall of the curing furnace, and therefore the function of lifting the sealing plate is achieved; utilize the balancing weight cooperation to hold the pole, can make the workman control the in-process labour saving and time saving that the closing plate goes up and down.

The utility model discloses can further set up to: the powder fluidized bed comprises a container and a conical ventilation cover which are connected up and down, vent holes communicated with the conical ventilation cover are uniformly distributed in the bottom wall of the container, an air inlet is formed in the bottom wall of the conical ventilation cover, and a compression air pump is connected to one side, far away from the bottom wall of the container, of the air inlet.

Through adopting above-mentioned technical scheme, when utilizing the compression air pump to blow in the cover is ventilated to the toper, the toper is ventilated the speed of flow that the cover can strengthen the air current to make the powder in the powder fluidized bed roll, and then make and connect the copper row and can fully dip-coat the powder in the powder fluidized bed.

By adopting the technical scheme, to sum up, the utility model discloses a following at least one useful technological effect:

1. time and labor are saved: the hanger trolley moves on the guide rail along the length direction of the rack, sequentially passes through the preheating furnace, the fluidized bed and the curing furnace, and moves along the vertical direction above the fluidized bed by utilizing the pneumatic lifting group price to complete dip-coating, so that excessive manual intervention is not needed in the whole processing process, and time and labor are saved;

2. the quality of the processed connecting copper bar is higher: when the bearing bracket moves upwards to a certain height, the vibration component is utilized to shake off redundant powder on the corner of the connecting copper bar, and the vibration motor with stable vibration frequency is utilized to uniformly distribute the powder on the surface of the connecting copper bar, so that the processed connecting copper bar has higher quality;

3. the vibration process is stable: the limiting piece and the bearing angle iron are arranged on the bearing bracket, when the hanging rack trolley moves downwards, the bearing angle iron plays a role in supporting the hanging rack trolley, and the limiting piece can prevent the hanging rack trolley from shaking left and right and even falling off the bearing bracket; utilize damping spring, make the vibration subassembly relatively stable at the during operation to whole vibration process's stability has been promoted.

Drawings

Fig. 1 is a schematic structural diagram of the first embodiment.

Fig. 2 is a schematic structural diagram of the connection relationship between the hanger trolley and the connecting copper bar.

FIG. 3 is a schematic structural diagram of the connection relationship between the cylinder, the vibration assembly, the support bracket, the limiting member and the hanger trolley.

FIG. 4 is a schematic view of the connection between the support bracket, the limiting member and the hanger trolley.

Fig. 5 is a schematic structural view of the vibration assembly.

FIG. 6 is a schematic structural view showing the connection relationship between the fluidized powder bed and the compressed air pump.

FIG. 7 is a schematic structural view showing the connection relationship between the elevating door and the preheating furnace.

FIG. 8 is a schematic structural diagram of the connection relationship between the vibration assembly, the support bracket and the hanging rack trolley.

Fig. 9 is a schematic structural diagram for showing the connection relationship between the driving unit, the lower base plate, and the upper plate in the second embodiment.

In the figure, 1, a frame; 11. a guide rail; 12. a pneumatic lifting assembly; 121. a limiting member; 1211. fixing the rod; 1212. a connecting rod; 1213. a clamping jaw; 123. fixing a top plate; 124. a cylinder; 1241. a piston rod; 125. a support bracket; 1251. supporting angle iron; 1252. a door-shaped frame; 126. a support; 1261. a support bar; 1262. a cross beam; 13. a vibrating assembly; 131. a vibration motor; 132. an upper top plate; 133. a lower base plate; 134. a damping spring; 135. a chassis; 1351. a vertical rod; 1352. a cross bar; 136. a U-shaped frame; 137. a striker bar; 138. a drive assembly; 1381. a drive motor; 1382. a rotating arm; 1383. a driven arm; 1384. driving the rod; 1385. a U-shaped hole; 14. a pillar; 15. an iron rod; 2. a hanger trolley; 21. a sliding frame; 22. a roller; 23. a hanging rod; 231. iron wires; 2311. connecting the copper bars; 24. a top plate; 3. preheating a furnace; 31. a lift gate; 311. a sealing plate; 312. a holding rod; 313. a fixed pulley; 314. a steel wire; 315. a balancing weight; 316. a wire rope; 32. a support pillar; 321. a slide rail; 33. a support beam; 4. a powder fluidized bed; 41. a container; 411. a vent hole; 42. a conical ventilation hood; 421. compressing the air pump; 422. an air inlet; 4211. an air outlet pipe; 5. and (4) a curing oven.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

referring to fig. 1, the utility model discloses a fluidization dip-coating device for special-shaped connecting copper bars, which solves the problem of uneven dip-coating when connecting copper bar insulating layers are processed; the device comprises a frame 1, a guide rail 11, a hanging rack trolley 2 and a preheating furnace 3, powder fluidized bed 4, curing oven 5, frame 1 includes four pillars 14 and two iron poles 15 that two liang of relative settings set up, two iron poles 15 are connected on the top of pillar 14 perpendicular to connection copper bar 2311 direction of transmission, guide rail 11 sets up along frame 1 length direction, the both ends of guide rail 11 are connected with iron pole 15, guide rail 11 constitutes a rectangle frame with iron pole 15, hanger trolley 2 slides and connects on guide rail 11, preheater 3, the fluidized bed, curing oven 5 arranges along frame 1 length direction in order in the below of guide rail 11, it is equipped with pneumatic lifting unit 12 to lie in powder fluidized bed 4 top on the frame 1, be equipped with the locating part 121 that is used for fixed hanger trolley 2 on the pneumatic lifting unit 12, be equipped with the vibrating component 13 that is used for shaking off the unnecessary powder on the connection copper bar 2311 on the pneumatic lifting unit 12.

Referring to fig. 1, when the insulating layer of the connecting copper bar 2311 is processed, the connecting copper bar 231 is firstly hung on the hanging rack trolley 2, the hanging rack trolley 2 slides into the preheating furnace 3 along the guide rail 11, the connecting copper bar 2311 is heated in the preheating furnace 3, the heated connecting copper bar 2311 moves downwards into the powder fluidized bed 4 under the action of the pneumatic lifting assembly 12, the hanging rack trolley 2 is limited by the limiting piece 121, the hanging rack trolley 2 is prevented from shaking leftwards and rightwards when moving towards the powder fluidized bed 4, after the powder is dip-coated, the hanging rack trolley 2 moves upwards under the action of the pneumatic lifting assembly 12, meanwhile, the powder on the connecting copper bar 2311 is shaken off by the vibrating assembly 13 and is uniformly distributed on the surface of the connecting copper bar 2311, the connecting copper bar 2311 moves into the curing furnace 5 along with the hanging rack trolley 2 to be cured, and the processing process of the insulating layer of the connecting copper bar.

Referring to fig. 2, the hanger trolley 2 includes a sliding frame 21, rollers 22, hanging rods 23 and a top plate 24, the sliding frame 21 is a rectangular frame, the rollers 22 are preferably four, the hanging rods 23 are preferably one, the four rollers 22 are uniformly distributed at four corners of the bottom of the sliding frame 21, the hanging rods 23 are uniformly distributed on the sliding frame 21 along the width direction of the sliding frame 21, the bottom wall of the top plate 24 is welded with the hanging rods 23, two ends of the top plate 24 are connected with two inner side walls of the sliding frame 21, two iron wires 231 are vertically connected to the hanging rods 23 relatively, and one ends of the iron wires 231, which are far away from the hanging rods 23, are connected with a connecting copper; the hanging rack trolley 2 is used for driving the connecting copper bar 2311 to move, excessive manual intervention is not needed, and time and labor are saved.

Referring to fig. 3, the pneumatic lifting assembly 12 (fig. 1) includes an air cylinder 124 and a support bracket 125, a support 126 for supporting the air cylinder 124 extends upward from the frame 1, the support 126 includes four support rods 1261 and two cross beams 1262 arranged opposite to each other two by two, the two cross beams 1262 are connected to the top ends of the support rods 1261 perpendicular to the length direction of the frame 1, the two cross beams 1262 are connected to a fixed top plate 123, the air cylinder 124 is fixed on the fixed top plate 123, and a piston rod 1241 of the air cylinder 124 extends out of the fixed top plate 123 to be connected to the support bracket 125; when the preheated connecting copper bar 2311 is dip-coated, the cylinder 124 drives the piston rod 1241 to drive the support bracket 125 to move downwards, so that the connecting copper bar 2311 is fully dip-coated with powder; after the connecting copper bar 2311 is dipped and coated with the powder, the cylinder 124 drives the piston rod 1241 to drive the support bracket 125 to move upwards, and excessive manual intervention is not needed in the whole dipping and coating process, so that the time and labor are saved when workers dip and coat the connecting copper bar 2311.

Referring to fig. 4, the support bracket 125 includes two supporting angle irons 1251 oppositely disposed along the length direction of the rack 1 and two door-shaped frames 1252 oppositely disposed, the longitudinal section of the two supporting angle irons 1251 is L-shaped, the two door-shaped frames 1252 are welded on the two supporting angle irons 1251, the two limiting members 121 are preferably two, the two limiting members 121 are oppositely welded on the side wall of one supporting angle iron 1251, the limiting member 121 includes a fixing rod 1211, a connecting rod 1212 and clamping jaws 1213, the fixing rod 1211 is welded on the side wall of the supporting angle iron 1251, one end of the connecting rod 1212 is hinged with the fixing rod 1211, the other end of the connecting rod 1212 is vertically connected with the clamping jaws 1213, and the clamping jaws 1213 are grasped on the side wall of the rack cart.

Referring to fig. 4, when the support bracket 125 carries the hanger trolley 2 to move downwards, the support bracket 125 supports the hanger trolley 2, at this time, the hanger trolley 2 is easy to shake due to the vibration of the vibration component 13 (fig. 3), because the connecting rod 1212 is hinged to the fixing rod 1211, the connecting rod 1212 is vibrated or knocked manually by a worker, and the connecting rod 1212 falls downwards under the action of gravity, thereby driving the clamping jaw 1213 to move downwards, and further the clamping jaw 1213 is grabbed on the side wall of the hanger trolley 2, the clamping jaw 1213 plays a limiting role for the hanger trolley 2, and the clamping jaw 1213 is matched with the support bracket 125, so that the hanger trolley 2 is more stable when moving downwards.

Referring to fig. 5, the vibration assembly 13 includes a vibration motor 131, an upper top plate 132, a lower bottom plate 133 and damping springs 134, the vibration motor 131 is fixed on the lower bottom plate 133, the lower bottom plate 133 is fixed on a door-shaped frame 1252 (fig. 3), the upper top plate 132 is connected with a piston rod 1241 (fig. 3), and four corners of the bottom wall of the upper top plate 132 are connected with four corners of the lower bottom plate 133 through four damping springs 134; when the vibration motor 131 works, the four damping springs 134 can support the upper top plate 132 and reduce the vibration of the vibration motor 131 to the support bracket 125, so that the rack trolley 2 (fig. 3) can move downwards more stably.

Referring to fig. 6, the powder fluidized bed 4 includes a container 41 and a conical ventilation hood 42 connected up and down, the container 41 is rectangular, vent holes 411 communicated with the conical ventilation hood 42 are uniformly distributed on the bottom wall of the container 41, an air inlet 422 is arranged on the bottom wall of the conical ventilation hood 42, and a compressed air pump 421 is connected to one side of the air inlet 422 away from the bottom wall of the container 41; after the air is compressed by the compressed air pump 421, the air is blown into the air inlet 422 through the air outlet pipe 4211, and the air flow blown out by the air pump can be enhanced by utilizing the conical ventilation hood 42, so that the powder in the container 41 can be rolled, and the connecting copper bar 2311 (shown in fig. 3) can be fully dip-coated with the powder in the powder fluidized bed 4.

Referring to fig. 7, four support columns 32 of the preheating furnace 3 and the curing furnace 5 (fig. 1) extend from the ground to the upper side of the preheating furnace 3 and the curing furnace 5, the top ends of the four support columns 32 are connected through support beams 33, slide rails 321 are arranged on the four support columns 32 along the height direction thereof, two sides of the preheating furnace 3 and the curing furnace 5 perpendicular to the transmission direction of the connecting copper bar 2311 (fig. 1) are respectively provided with a lifting door 31, each lifting door 31 comprises a sealing plate 311, a holding rod 312, a fixed pulley 313, a steel wire 314 and a counterweight 315, the sealing plate 311 is connected on the support columns 32 in a sliding manner, one end of the holding rod 312 is hinged on the side wall of the rack 1, the other end of the holding rod 312 extends upwards, the holding rod 312 is connected with a steel wire 314 rope, one end of the steel wire 314 rope far away from the holding rod 312 is connected with the counterweight 315, the fixed pulley 313 is, the other two fixed pulleys 313 are connected to the other end of the support beam 33, the two steel wires 314 are preferably selected, the first fixed pulley 313 is fixed at one end of the support beam 33, the second fixed pulley 313 and the third fixed pulley 313 are fixed at the other end of the support beam 33, the two steel wires 314 are respectively connected to two ends of the top wall of the sealing plate 311, one steel wire 314 sequentially rounds the first fixed pulley 313, the second fixed pulley 313 and the third fixed pulley 313 to be connected with the top end of the balancing weight 315, and the other steel wire 314 sequentially rounds the second fixed pulley 313 and the third fixed pulley 313 to be connected with the top end of the balancing weight 315.

Referring to fig. 7, when the rack cart 2 (fig. 4) moves to the preheating furnace 3, a worker presses one end of the holding rod 312 extending upward, and at this time, the steel wire 314 of the sealing plate 311 pulls the sealing plate 311 to slide upward, thereby performing a lifting function of the sealing plate 311; after the hanger trolley 2 comes out of the preheating furnace 3, the worker loosens the holding rod 312, and the steel wire 314 on the sealing plate 311 moves downwards under the action of the gravity of the sealing plate 311, so that the function of descending the sealing plate 311 is realized; by using the weight 315, the worker can save time and labor when controlling the lifting of the sealing plate 311.

The working process of the embodiment is as follows: when the insulating layer of the connecting copper bar 2311 is processed, the hanging rack trolley 2 carries the connecting copper bar 2311 to slide towards the preheating furnace 3, a worker presses the holding rod 312 to control the sealing plate 311 to ascend and descend, and after the connecting copper bar 2311 is preheated by the preheating furnace 3, the hanging rack trolley 2 moves to the bearing bracket 125; at this time, the air cylinder 124 drives the support bracket 125 to move downwards, so that the connecting copper bar 2311 is fully dipped and coated with powder in the powder fluidized bed 4, when the connecting copper bar 2311 comes out of the powder, the vibration motor 131 vibrates to shake off the redundant powder on the corner of the connecting copper bar 2311, the powder dipped and coated on the surface of the connecting copper bar 2311 is uniformly distributed, and meanwhile, the support bracket 125 moves upwards; the hanging rack trolley 2 moves along the guide rail 11 to the curing oven 5 for curing, and the processing process of the insulating layer of the connecting copper bar 2311 is completed.

Example two:

referring to fig. 8 and 9, the difference from the first embodiment is that the vibrating assembly 13 has a different structure, the vibrating assembly 13 includes a chassis 135, a U-shaped frame 136, a striker 137, and a driving assembly 138, the chassis 135 includes a stem 1351 and a crossbar 1352, a bottom wall of the stem 1351 is vertically connected to the bottom plate 133, one end of the crossbar 1352 is vertically connected to a side wall of the stem 1351, the other end of the crossbar 1352 is vertically connected to a side wall of the U-shaped frame 136, an opening of the U-shaped frame 136 faces downward, the striker 137 is slidably connected in the U-shaped frame 136 in a vertical direction, the driving assembly 138 includes a driving motor 1381, a rotating arm 1382, a driven arm 1383, and a driving rod 1384, the driving motor 1381 is located on an outer side wall of the crossbar 1352, a motor shaft of the driving motor 1381 horizontally passes through the crossbar 1352 and is connected to one end of the rotating arm 1382, the rotating arm 1382 is attached to the crossbar 1382, the driven arm 1383 is attached to the driven arm 1383, the driven arm, one end of the driven arm 1383 is rotatably connected with the cross bar 1352, the other end of the driven arm 1383 is hinged with the driving rod 1384, and one end of the driving rod 1384 far away from the driven arm 1383 is hinged with the impact rod 137.

Referring to fig. 8 and 9, after the connecting copper bar 2311 is dip-coated, the support bracket 125 carries the hanger trolley 2 to move upward until the connecting copper bar 2311 comes out of the powder, the vibration motor 131 drives the rotating arm 1382 to rotate, the rotating arm 1382 slides in the U-shaped hole 1385, so as to drive the driven arm 1383 to swing, the driven arm 1383 drives the driving rod 1384 to reciprocate, the driving rod 1384 drives the impact rod 137 to slide up and down in the U-shaped frame 136 in a reciprocating manner, the impact rod 137 impacts the top plate 24 on the hanger trolley 2 in a reciprocating manner, and therefore the redundant powder on the corner of the connecting copper bar 2311 is shaken off, and the powder on the surface of the connecting copper bar 2311 can be uniformly distributed.

The working process of the embodiment is as follows: after the connecting copper bar 2311 is dipped and coated with powder, the driving motor 1381 drives the impact rod 137 to impact the top plate 24 of the hanging rack trolley 2 up and down in a reciprocating manner, so that redundant powder on the corner of the connecting copper bar 2311 is shaken off, and the powder dipped and coated on the connecting copper bar 2311 can be uniformly distributed.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (10)

1. The utility model provides a dysmorphism is connected copper bar and is used fluidization dip-coating device which characterized in that: including frame (1), guide rail (11), stores pylon dolly (2), preheater (3), powder fluidized bed (4), curing oven (5), frame (1) length direction setting is followed in guide rail (11), slide to connect on guide rail (11) in stores pylon dolly (2), preheater (3), powder fluidized bed (4) and curing oven (5) are located guide rail (11) below and arrange along frame (1) length direction in order, it is equipped with pneumatic lifting unit (12) to lie in powder fluidized bed (4) top in frame (1), be equipped with locating part (121) that are used for fixed stores pylon dolly (2) on pneumatic lifting unit (12), be equipped with on pneumatic lifting unit (12) and be used for shaking off vibration subassembly (13) of connecting unnecessary powder on copper bar (2311) turning.

2. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: the pneumatic lifting assembly (12) comprises a cylinder (124) and a support bracket (125), wherein the support bracket (125) is connected with a piston rod (1241) of the cylinder (124).

3. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: the supporting bracket (125) comprises two supporting angle irons (1251) which are oppositely arranged along the length direction of the rack (1) and two door-shaped frames (1252) which are oppositely arranged, and the door-shaped frames (1252) are vertically welded on the two supporting angle irons (1251).

4. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: the vibration component (13) comprises a vibration motor (131), an upper top plate (132), a lower bottom plate (133) and damping springs (134), the vibration motor (131) is fixed on the lower bottom plate (133), the upper top plate (132) is connected with the lower bottom plate (133) through the damping springs (134), the upper top plate (132) is connected with a piston rod (1241) of the air cylinder (124), and the lower bottom plate (133) is fixed on the door-shaped frame (1252).

5. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: the vibration component (13) comprises an underframe (135), a U-shaped frame (136), a striking rod (137) and a driving component (138), wherein the underframe (135) is fixed on a support bracket (125), the U-shaped frame (136) is arranged at the top end of the underframe (135), and the striking rod (137) is connected in the U-shaped frame (136) in a sliding manner.

6. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: drive assembly (138) are including driving motor (1381), rotor arm (1382), driven arm (1383) and driving pole (1384), chassis (135) are including montant (1351) and horizontal pole (1352), driving motor (1381) are located on horizontal pole (1352), the motor shaft level of driving motor (1381) is passed horizontal pole (1352) and is connected with the one end of rotor arm (1382), be equipped with U-shaped hole (1385) on driven arm (1383), the one end that the motor shaft was kept away from in rotor arm (1382) slides and connects in U-shaped hole (1385), the one end rotation of driven arm (1383) is connected on horizontal pole (1352), the other end of driven arm (1383) is articulated mutually with driving pole (1384), the one end that driven arm (1383) was kept away from to driving pole (1384) is articulated mutually with impact bar (137).

7. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: the limiting part (121) comprises a fixing rod (1211), a connecting rod (1212) and a clamping jaw (1213), the bottom of the fixing rod (1211) is connected to the outer side wall of the support bracket (125), the top end of the fixing rod (1211) is hinged to one end of the connecting rod (1212), the clamping jaw (1213) is vertically connected to one end, away from the fixing rod (1211), of the connecting rod (1212), and the clamping jaw (1213) extends to the hanger trolley (2) and is clamped on the side wall of the hanger trolley (2).

8. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: the hanger trolley (2) comprises a sliding frame (21), a plurality of idler wheels (22), a plurality of hanging rods (23) and a top plate (24), wherein the idler wheels (22) are uniformly distributed at four corners of the bottom of the sliding frame (21), the hanging rods (23) are arranged on the sliding frame (21) along the width direction of the sliding frame (21) at equal intervals, and the top plate (24) is welded on the hanging rods (23).

9. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: preheating furnace (3) and curing oven (5) perpendicular to connect copper bar (2311) transmission direction's both sides all are equipped with overhead door (31), overhead door (31) include closing plate (311), hold pole (312), fixed pulley (313), steel wire (314) and balancing weight (315), the one end of holding pole (312) articulates in frame (1), the other end of holding pole (312) upwards extends, fixed pulley (313) set up the top in frame (1), steel wire (314) one end is connected on the roof of closing plate (311), the other end of steel wire (314) is walked around fixed pulley (313) and is linked to each other with balancing weight (315), balancing weight (315) keep away from the one end of pulley and link to each other with holding pole (312) through steel wire (314) rope.

10. The fluidization dip-coating device for the special-shaped connection copper bar is characterized in that: powder fluidized bed (4) including container (41) and the toper of connecting from top to bottom ventilate cover (42), the diapire equipartition of container (41) has vent hole (411) that are linked together with toper cover (42) of ventilating, toper cover (42) diapire of ventilating is equipped with air inlet (422), one side that container (41) diapire was kept away from in air inlet (422) is connected with compressed air pump (421).

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