CN117000545B - Be used for magnetic ring production to use automatic transport formula application equipment - Google Patents

Abstract

The utility model discloses automatic conveying type coating equipment for magnetic ring production, which comprises a base, a material rack assembly, a material moving assembly and a conveying chamber, wherein the material rack assembly and the conveying chamber are oppositely arranged at two ends of the upper side of the base, the material rack assembly comprises a plurality of material storage rods and a rotating main shaft, the rotating main shaft drives the material storage rods to rotate, a plurality of magnetic ring bodies are sleeved on the material storage rods, and the magnetic ring bodies are arranged in a like-pole repulsion sequence; the conveying chamber is disc-shaped and comprises an annular side plate, a material passing opening is formed in one end of the annular side plate, which faces the material rack assembly, and a powder soaking cavity and a drying chamber are arranged in the conveying chamber; the rotary assembly comprises a plurality of material rotating rods, the number of the material rotating rods is equal to that of the material storage rods, the material rotating rods are oppositely arranged, and a plurality of magnetic ring bodies are sleeved on the outer sides of the material rotating rods.

Description

Be used for magnetic ring production to use automatic transport formula application equipment

Technical Field

The utility model relates to the technical field of magnetic ring production, in particular to automatic conveying type coating equipment for magnetic ring production.

Background

The magnetic ring is a common anti-interference element in an electronic circuit, has a good effect of inhibiting high-frequency noise, is generally made of ferrite materials (Mn-Zn), is an important application material in the current scientific and technological production, and needs to be coated on the surface in the production process.

The utility model discloses energy-saving magnetic ring coating equipment in the China patent publication No. CN211160522U, which comprises a coating equipment body, an electric telescopic rod and a drying mechanism, wherein the electric telescopic rod is installed on the upper end face of the inner wall of the coating equipment body, the lower end of the electric telescopic rod is connected with a movable plate, both sides of a mounting seat are hinged with an A inclined rod, the A inclined rod is connected with a clamping block through a B inclined rod, both sides of the movable plate are connected with a fixed block through a traction wire, the fixed block is connected with a connecting block through a vortex spring, the drying mechanism is installed on the inner wall of the coating equipment body, and a powder soaking cavity is formed below the inside of the coating equipment body. In the technical scheme, a worker is required to manually sleeve the magnetic ring on the mounting seat, only a single magnetic ring can be installed in each sleeve joint, the automation degree is low, the production efficiency is low, and the upper end face is difficult to be fully immersed with powder when the axis of the magnetic ring is vertical to the ground, so that the coating is uneven.

Therefore, it is necessary to provide an automatic conveying type coating device for magnetic ring production, which can achieve the effect of transportation coating.

Disclosure of Invention

The utility model aims to provide automatic conveying type coating equipment for magnetic ring production, so as to solve the problems in the background technology.

In order to solve the technical problems, the utility model provides the following technical scheme: an automatic conveying type coating device for magnetic ring production comprises a base, a material rack component, a material moving component and a conveying chamber,

the material rack assembly and the conveying chamber are oppositely arranged at two ends of the upper side of the base, the material rack assembly comprises a plurality of material storage rods and a rotating main shaft, the rotating main shaft drives the material storage rods to rotate, a plurality of magnetic ring bodies are sleeved on the material storage rods, and the magnetic ring bodies are arranged in a like-pole repulsion sequence;

the conveying chamber is disc-shaped and comprises an annular side plate, a material passing opening is formed in one end of the annular side plate, which faces the material rack assembly, and a powder soaking cavity and a drying chamber are arranged in the conveying chamber;

the rotary assembly comprises a plurality of material rotating rods, the number of the material rotating rods is equal to that of the material storage rods, the material rotating rods are oppositely arranged, a plurality of magnetic ring bodies are sleeved on the outer sides of the material rotating rods, and the material rotating rods are used for driving the magnetic ring bodies to sequentially pass through the powder soaking cavity and the drying chamber;

the material moving assembly is used for driving the magnetic ring bodies to move back and forth between the material storage rod and the material rotating rod.

In one embodiment, the hollow groove is formed in the material transferring rod, the hollow groove is communicated with one end of the material transferring rod, square through holes are formed in the upper end and the lower end of the hollow groove, supporting blocks are slidably matched in the square through holes, spring telescopic rods are arranged at the two ends of the supporting blocks, partition plates are fixedly connected to the middle sides of the two ends of the hollow groove, the spring telescopic rods are connected with the partition plates, and when the square through holes extend out of the supporting blocks, the magnetic ring bodies are supported and fixed.

In one embodiment, a connecting block is fixedly connected to the inner side of the supporting block, a semi-conical part is fixedly connected to one end of the connecting block, which faces to the opening of the material rotating rod, a push rod is slidably matched with one end of the opening of the material rotating rod, a conical groove is formed in one end of the push rod, the conical groove is matched with the semi-conical part, the push rod extends to the outer end of the material rotating rod and is fixedly connected with a push block, a cross-shaped groove is formed in the inner side of the push rod, a baffle plate and a spring telescopic rod on one side slide in the cross-shaped groove, and a spring part is arranged between the push block and the material rotating rod;

an annular groove is formed in the inner side of the annular side plate, and the pushing block moves along the annular groove.

In one embodiment, the upper end fixedly connected with top cap of annular curb plate, the lower extreme fixedly connected with backup pad of annular curb plate, backup pad and magnetic ring body clearance fit, the up end in soaking powder chamber flushes the setting with the backup pad, including a plurality of heating strips in the drying chamber, the heating strip is fixed in the backup pad.

In one embodiment, the rotary assembly further comprises a first motor, the first motor is fixed at the lower end of the base, a rotating shaft is driven at the upper end of the first motor, the outer end of the rotating shaft is fixedly connected with a rotating sleeve, a sliding block is slidingly matched with the outer side of the rotating sleeve, and the material rotating rod is connected with the sliding block;

the center lower extreme fixedly connected with spacing lid of top cap, the lower extreme and the axis of rotation of spacing lid rotate to be connected, one side fixedly connected with dysmorphism piece that is close to the powder soaking cavity of spacing lid, one side of dysmorphism piece sets up to the inclined plane, and the opposite side sets up to vertical face, the powder soaking cavity is immersed under the restriction of dysmorphism piece changes the material pole.

In one embodiment, the middle side fixedly connected with arc spacing of backup pad, one side that the arc spacing is close to the powder soaking cavity is provided with oblique angle breach groove, the outside fixedly connected with elastic wheel of changeing the material pole, the elastic wheel rolls along arc spacing and oblique angle breach groove, the sliding block rotates with changeing the material pole to be connected.

In one embodiment, the elastic wheel comprises a center sleeve, the center sleeve is fixedly connected with the material rotating rod, a plurality of spring telescopic short rods are arranged on the outer side of the center sleeve, and rubber pressing sheets are arranged at the outer ends of the spring telescopic short rods.

In one embodiment, the lower extreme of rotating the main shaft is provided with motor assembly, the upper end fixedly connected with rolling disc of rotating the main shaft, the outside fixedly connected with dead lever of rolling disc, the through-hole has been seted up to one side of storage pole, through-hole and dead lever sliding fit, the through-hole inboard is provided with spring one, the outside rotation of rotating the main shaft is connected with the fixed cover, the fixed cover is fixed in on the base, the outside fixedly connected with spacing dish of fixed cover, the mouth has been seted up to one side that the spacing dish is close to the mouth of passing through, mouth department sets up to oblique chamfer, the lower extreme of storage pole is provided with the runner, the runner rolls along spacing dish inner wall, the terminal surface and the ejector pad of storage pole correspond the setting.

In one embodiment, the material moving assembly comprises a pair of clamping jaws, the clamping jaws are used for clamping a plurality of magnetic ring bodies simultaneously, a plurality of separation blocks are fixedly connected in the clamping jaws, a concave frame is hinged at the upper end of the clamping jaws, a driving seat is fixedly connected at the upper end of the concave frame, an electric telescopic cylinder is fixedly connected at the inner side of the driving seat, a pull plate is arranged at the driving end of the electric telescopic cylinder, pull ropes are arranged at the two ends of the pull plate, and the pull ropes are connected with the clamping jaws.

In one embodiment, the upper end fixedly connected with of base removes the support, the both ends fixedly connected with slider of drive seat, the upside of removing the support is provided with the slide rail groove, the slider slides along the slide rail groove, the drive seat is by sharp drive assembly drive removal.

Compared with the prior art, the utility model has the following beneficial effects: according to the utility model, a plurality of magnetic ring bodies are stored by utilizing the material rack assembly, a corresponding number of material transferring rods are arranged in the conveying chamber, and are used for receiving the magnetic ring bodies on the material storing rods, specifically, when the material storing rods and the material transferring rods are respectively rotated to the positions where the axes of the material storing rods and the material transferring rods are coincident, the rod end surfaces of the material storing rods and the material transferring rods are attached, the material transferring assembly can push the plurality of magnetic ring bodies from the material storing rods to the material transferring rods, so that feeding can be completed, and the plurality of magnetic ring bodies can be installed at one time, so that the efficiency is improved, then the material transferring rods enter the conveying chamber, are transported in a ring shape, sequentially pass through the powder soaking cavity to perform powder soaking work, and then the magnetic ring bodies subjected to powder soaking are dried through the drying chamber, so that coating can be completed, the plurality of magnetic ring bodies can be coated at one time, the work efficiency is greatly improved, the overall powder soaking quality and uniformity of coating are ensured because the magnetic ring bodies roll through the powder soaking cavity in a vertical state; finally, the magnetic ring body for finishing coating is similarly moved into the storage rod again from the material transferring rod under the action of the material transferring assembly, automatic discharging is finished, the degree of automation is high, labor is saved, and the storage rod and the material transferring rod are provided with a plurality of groups, so that the effect is realized: the magnetic ring bodies on each storage rod can be matched with the material rotating rod to sequentially finish feeding, then the coated magnetic ring bodies are sequentially discharged, a worker can synchronously take off the coated magnetic ring bodies on the storage rods and then the uncoated magnetic ring bodies are mounted, and the continuous coating operation can be realized, so that the coating machine is suitable for mass coating production work.

Drawings

The technical solution and other advantageous effects of the present utility model will be made apparent by the following detailed description of the specific embodiments of the present utility model with reference to the accompanying drawings.

In the drawings:

FIG. 1 is a schematic view of the overall structure of the present utility model;

FIG. 2 is a schematic side cross-sectional view of the rack assembly of the present utility model;

FIG. 3 is a schematic cross-sectional view of a swing assembly of the present utility model;

FIG. 4 is a schematic perspective view of a swivel assembly of the present utility model;

FIG. 5 is a schematic view of the inside cross-section of the transfer bar of the present utility model;

FIG. 6 is an enlarged partial schematic view of area A of FIG. 3;

FIG. 7 is a schematic perspective view of a support block and pushrod of the present utility model;

FIG. 8 is a partial perspective view of the swivel assembly of the present utility model;

FIG. 9 is a partially enlarged schematic illustration of region B of FIG. 8;

FIG. 10 is a schematic perspective view of a retaining cap of the present utility model;

FIG. 11 is a schematic perspective view of a rack assembly of the present utility model;

FIG. 12 is a partial perspective view of a pipetting assembly of the utility model;

in the figure: 1. a transport chamber; 101. a powder soaking cavity; 102. a drying chamber; 103. a material passing opening; 104. a first motor; 105. a rotating shaft; 106. a rotating sleeve; 107. a sliding block; 108. a limit cover; 109. a special-shaped block; 110. arc-shaped limit strips; 111. bevel notch groove; 112. a center sleeve; 113. tabletting rubber;

2. a swivel assembly; 201. a material transferring rod; 202. a support block; 203. a spring telescoping rod; 204. a partition plate; 205. a semi-conical member; 206. a push rod; 207. a conical groove; 208. a pushing block; 209. a spring member;

3. a work or material rest assembly; 301. a storage rod; 302. rotating the main shaft; 303. a fixed rod; 304. a first spring; 305. a rotating wheel; 306. a fixed sleeve; 307. a limiting disc;

4. a material moving assembly; 401. a clamping jaw; 402. separating the blocks; 403. a driving seat; 404. an electric telescopic cylinder; 405. pulling a plate; 406. a pull rope; 407. a slide block;

6. a magnetic ring body;

7. a base; 701. a movable support; 702. a slide rail groove;

8. an annular side plate; 801. an annular groove; 802. a top cover; 803. a support plate; 804. and heating the strip.

Detailed Description

The following disclosure provides many different embodiments, or examples, for implementing different features of the utility model. In order to simplify the present disclosure, components and arrangements of specific examples are described below. They are, of course, merely examples and are not intended to limit the utility model. Furthermore, the present utility model may repeat reference numerals and/or letters in the various examples, which are for the purpose of brevity and clarity, and which do not themselves indicate the relationship between the various embodiments and/or arrangements discussed. In addition, the present utility model provides examples of various specific processes and materials, but one of ordinary skill in the art will recognize the application of other processes and/or the use of other materials.

Referring to fig. 1-12, the present utility model provides the following technical solutions: an automatic conveying type coating device for magnetic ring production comprises a base 7, a material rack assembly 3, a material moving assembly 4 and a conveying chamber 1,

the material rack assembly 3 and the conveying chamber 1 are oppositely arranged at two ends of the upper side of the base 7, the material rack assembly 3 comprises a plurality of material storage rods 301 and a rotating main shaft 302, the rotating main shaft 302 drives the material storage rods 301 to rotate, a plurality of magnetic ring bodies 6 are sleeved on the material storage rods 301, and the magnetic ring bodies 6 are arranged in a like-pole repulsion sequence;

the whole conveying chamber 1 is disc-shaped and comprises an annular side plate 8, a material passing opening 103 is formed in one end of the annular side plate 8, which faces the material rack component 3, and a powder soaking cavity 101 and a drying chamber 102 are arranged in the conveying chamber 1;

the rotary assembly 2 is arranged in the center of the interior of the conveying chamber 1, the rotary assembly 2 comprises a plurality of material rotating rods 201, the material rotating rods 201 and the material storing rods 301 are equal in number and are oppositely arranged, a plurality of magnetic ring bodies 6 are sleeved on the outer sides of the material rotating rods 201, and the material rotating rods 201 are used for driving the plurality of magnetic ring bodies 6 to sequentially pass through the powder soaking cavity 101 and the drying chamber 102;

the material moving assembly 4 is used for driving the magnetic ring bodies 6 to move back and forth between the material storage rod 301 and the material rotating rod 201.

Firstly, a plurality of magnetic ring bodies 6 are stored by using a material rack assembly 3, a worker can place a row of magnetic ring bodies 6 on a material storage rod 301 by using a mechanical arm or manually, and the magnetic ring bodies 6 are tightly matched with the material storage rod 301, so that the magnetic ring bodies 6 are prevented from falling off when a rotating main shaft 302 rotates; the magnetic ring bodies 6 are arranged in the same polarity and opposite sequence, so that the distance between each magnetic ring body 6 is automatically controlled, a corresponding number of material rotating rods 201 are also arranged in the conveying chamber 1 and used for receiving the magnetic ring bodies 6 on the material storing rods 301, specifically, when the material storing rods 301 and the material rotating rods 201 rotate to the positions where the axes of the material storing rods 301 and the material rotating rods are coincident (namely, when the material rotating rods 201 rotate to the material passing openings 103), the rod end surfaces of the material rotating rods and the material rotating rods are attached, a plurality of magnetic ring bodies 6 can be pushed onto the material rotating rods 201 from the material storing rods 301 through the material moving assembly 4, feeding can be completed, a plurality of magnetic ring bodies 6 can be installed at one time, the efficiency is improved, then the material rotating rods 201 enter the conveying chamber 1, are sequentially conveyed in a ring mode along the conveying chamber, are sequentially subjected to powder soaking work in the powder soaking cavity 101, and then the magnetic ring bodies 6 subjected to powder soaking work are dried through the drying chamber 102, so that coating can be carried out on the magnetic ring bodies 6 at one time, the working efficiency is greatly improved, and the magnetic ring bodies 6 can be rolled from the powder soaking cavity 101 in a vertical state, the overall quality and the powder soaking uniformity are guaranteed; finally, the coated magnetic ring body 6 is also moved into the storage rod 301 again from the material transferring rod 201 under the action of the material transferring assembly 4, so that automatic discharging is finished, the degree of automation is high, labor is saved, and the storage rod 301 and the material transferring rod 201 are provided with a plurality of groups, so that the effect is realized: the magnetic ring bodies 6 on each storage rod 301 can be matched with the material transferring rods 201, feeding is completed sequentially, then the coated magnetic ring bodies 6 are discharged sequentially, workers can synchronously take off the coated magnetic ring bodies 6 on the storage rods 301, and uncoated magnetic ring bodies 6 are mounted, so that continuous coating operation can be realized, and the coating machine is suitable for mass coating production.

The hollow groove is formed in the material rotating rod 201, the hollow groove is communicated with one end of the material rotating rod 201, square through holes are formed in the upper end and the lower end of the hollow groove, supporting blocks 202 are slidably matched in the square through holes, spring telescopic rods 203 are arranged at the two ends of the supporting blocks 202, partition plates 204 are fixedly connected to the middle sides of the two ends of the hollow groove, the spring telescopic rods 203 are connected with the partition plates 204, and when the square through holes extend out of the supporting blocks 202, the magnetic ring bodies 6 are supported and fixed.

In order to facilitate loading and unloading and improve the coating stability of the bearing magnetic ring bodies 6, a supporting block 202 is arranged, specifically, when a plurality of magnetic ring bodies 6 are sleeved on the material rotating rod 201, clearance fit is formed between the two, so that loading and unloading are facilitated, square through holes are formed in the surface of the material rotating rod 201, a spring telescopic rod 203 is arranged to prop against the supporting block 202, the supporting block 202 extends out of the surface of the material rotating rod 201, and therefore the magnetic ring bodies 6 are supported (as shown in fig. 5), and the stability during transportation coating is improved.

The inner side of the supporting block 202 is fixedly connected with a connecting block, one end of the connecting block, which faces the opening of the material rotating rod 201, is fixedly connected with a semi-conical part 205, a push rod 206 is slidably matched in one end of the opening of the material rotating rod 201, one end of the push rod 206 is provided with a conical groove 207, the conical groove 207 is matched with the semi-conical part 205, the push rod 206 extends to the outer end of the material rotating rod 201 and is fixedly connected with a push block 208, the inner side of the push rod 206 is provided with a cross-shaped groove, a baffle 204 and a spring telescopic rod 203 on one side slide in the cross-shaped groove, and a spring part 209 is arranged between the push block 208 and the material rotating rod 201;

an annular groove 801 is formed in the inner side of the annular side plate 8, and the pushing block 208 moves along the annular groove 801.

In order to facilitate loading and unloading, the supporting block 202 needs to be collected and rotated into the material rotating rod 201 when loading and unloading is performed, specifically, a movable push rod 206 is arranged in the material rotating rod 201, when loading and unloading is performed, the push rod 206 is pushed by the material storing rod 301 to prop against the push block 208, one end of the push rod 206 is provided with a conical groove 207, the conical groove 207 limits the movement of the semi-conical piece 205, the semi-conical piece 205 drives the connecting block and the supporting block 202 to retract into the material rotating rod 201, the limitation on the magnetic ring body 6 is removed, and at the moment, the magnetic ring body 6 can be easily detached from the material rotating rod 201, so that the material moving assembly 4 is convenient to move by only abutting the material storing rod 301 and the material rotating rod 201, and the supporting block 202 is synchronously controlled to retract into the material rotating rod 201, so that the process steps of the utility model are more reasonable;

the cross-shaped groove is formed in the inner side of the push rod 206, the baffle 204 and the spring telescopic rod 203 slide in the cross-shaped groove conveniently, the annular groove 801 is formed in the annular side plate 8, the magnetic ring body 6 after the feeding is completed is driven by the material rotating rod 201 to move along the inner side of the annular side plate 8, the pushing block 208 can be clamped in the annular groove 801 to move, the whole material rotating rod 201 and the magnetic ring bodies 6 are supported, the transportation stability is further improved, the axial displacement sinking of the material rotating rod 201 caused by long-time use is avoided, and the practicability is high.

The upper end fixedly connected with top cap 802 of annular curb plate 8, the lower extreme fixedly connected with backup pad 803 of annular curb plate 8, backup pad 803 and magnetic ring body 6 clearance fit, the up end of soaking powder chamber 101 flushes the setting with backup pad 803, including a plurality of heating strips 804 in the drying chamber 102, heating strips 804 are fixed in on backup pad 803.

Specifically, when the powder dipping work is needed, the material transferring rod 201 drives the magnetic ring bodies 6 to sink into the powder dipping cavity 101 and roll along the powder dipping cavity, so that the powder is uniformly coated, and then the powder is dried in the drying chamber 102 through the heating strips 804, so that the functions of transporting and coating the magnetic ring bodies 6 are realized, and the working efficiency is greatly improved.

The rotary assembly 2 further comprises a first motor 104, the first motor 104 is fixed at the lower end of the base 7, a rotating shaft 105 is driven at the upper end of the first motor 104, a rotating sleeve 106 is fixedly connected to the outer end of the rotating shaft 105, a sliding block 107 is slidingly matched with the outer side of the rotating sleeve 106, and a material rotating rod 201 is connected with the sliding block 107;

the center lower extreme fixedly connected with spacing lid 108 of top cap 802, the lower extreme of spacing lid 108 rotates with axis of rotation 105 to be connected, and the one side that is close to the powder soaking cavity 101 of spacing lid 108 fixedly connected with dysmorphism piece 109, dysmorphism piece 109 one side set up to the inclined plane, and the opposite side sets up to the vertical face, and the immersion powder soaking cavity 101 under the restriction of dysmorphism piece 109 changes material pole 201.

The first motor 104 drives the rotating shaft 105 and the rotating sleeve 106 to rotate, namely, a plurality of rotating rods 201 and magnetic ring bodies 6 can be driven to transport in the conveying chamber 1, the rotating sleeve 106 is provided with a movable sliding block 107, namely, the rotating rods 201 can move up and down along with the sliding block 107, so that the rotating rods 201 and the magnetic ring bodies 6 conveniently sink into the powder soaking cavity 101 and then rise into the drying chamber 102 from the powder soaking cavity 101, and a spring assembly can be arranged at the lower end of the sliding block 107, so that the spring assembly is convenient to reset;

specifically, a limit cover 108 is fixed at the lower end of the top cover 802, that is, the limit cover 108 is fixed, as shown in fig. 10, the lower end of the limit cover 108 is provided with a special-shaped block 109, and the limit cover 108 is in contact with the material transferring rod 201, when the material transferring rod 201 moves to the special-shaped block 109 and is in contact with the special-shaped block, the material transferring rod 201 moves along the inclined plane thereof first, so that the whole material transferring rod 201 is limited to move downwards, at the moment, the material transferring rod 201 just corresponds to the powder soaking cavity 101, so that a plurality of magnetic ring bodies 6 sink into the cavity to fully soak powder, when the powder soaking cavity 101 is quickly moved out, the material transferring rod 201 moves to the vertical surface of the special-shaped block 109 and rises again to be in contact with the limit cover 108, then enters the drying chamber 102 to be dried, and a groove type which moves synchronously with the material transferring rod 201 is also arranged in the corresponding annular groove 801;

that is, the whole process only uses the sliding block 107 capable of sliding up and down and the fixed limit cover 108, and only uses the first motor 104 to drive the material transferring rod 201 to transport, so that the material transferring rod 201 can automatically sink and rise, the powder soaking work is completed, and the cost is saved.

The middle side of backup pad 803 fixedly connected with arc spacing 110, the side that arc spacing 110 is close to the powder soaking cavity 101 is provided with oblique angle breach groove 111, and the outside fixedly connected with elastic wheel of material turning rod 201, elastic wheel roll along arc spacing 110 and oblique angle breach groove 111, and slider 107 rotates with material turning rod 201 to be connected.

The elastic wheel can be fixedly connected to the outer side of the material rotating rod 201 so as to replace the spring assembly, the reset effect of the material rotating rod 201 is achieved, specifically, the elastic wheel is fixed with the material rotating rod 201, when the elastic wheel rolls along the arc-shaped limiting strip 110 and the bevel notch groove 111, the elastic wheel props up the material rotating rod 201 through a reaction force, the elastic wheel is tightly attached to the limiting cover 108 and the special-shaped block 109, the material rotating rod 201 is convenient to reset when moving up and down, the bevel notch groove 111 corresponds to the powder soaking cavity 101, the elastic wheel synchronously moves downwards when the material rotating rod 201 is limited to move downwards by the special-shaped block 109, and the material rotating rod 201 is rotationally connected with the sliding block 107 due to the fact that the elastic wheel rolls all the time, the elastic wheel drives the material rotating rod 201 to synchronously rotate when the elastic wheel rolls, and therefore the magnetic ring body 6 can improve coating uniformity and coating quality when the powder soaking and drying work.

The elastic wheel comprises a center sleeve 112, the center sleeve 112 is fixedly connected with a material rotating rod 201, a plurality of spring telescopic short rods are arranged on the outer side of the center sleeve 112, and rubber pressing sheets 113 are arranged at the outer ends of the spring telescopic short rods.

Specifically, the rubber pressing sheet 113 is propped against by the spring telescopic short rod, so that the rubber pressing sheet 113 synchronously drives the material rotating rod 201 to rotate when rolling, and the material rotating rod 201 is limited to always ensure contact with the limit cover 108.

The lower extreme of rotating main shaft 302 is provided with motor element, rotating main shaft 302's upper end fixedly connected with rolling disc, rolling disc's outside fixedly connected with dead lever 303, the through-hole has been seted up to one side of storage pole 301, through-hole and dead lever 303 sliding fit, the through-hole inboard is provided with spring one 304, rotating main shaft 302's outside rotation is connected with fixed cover 306, fixed cover 306 is fixed in on the base 7, fixed cover 306's outside fixedly connected with spacing dish 307, the one side that spacing dish 307 is close to the feed gap 103 has been seted up and has been crossed the mouth, it sets up to oblique chamfer to cross mouth department, storage pole 301's lower extreme is provided with runner 305, runner 305 rolls along spacing dish 307 inner wall, storage pole 301's terminal surface corresponds the setting with ejector pad 208.

The rotating main shaft 302 and the rotating disc are driven to rotate through the motor component, a plurality of storage rods 301 can be driven to rotate, a plurality of fixing rods 303 are fixed on the outer side of the rotating disc, the fixing rods 303 are clamped into through holes in the storage rods 301 and are in sliding fit with the through holes, a fixing sleeve 306 is arranged on the outer side of the rotating main shaft 302, a limit disc 307 is fixed on the fixing sleeve 306, a rotating wheel 305 is arranged at one end of the storage rods 301, the rotating wheel 305 is limited to roll in the limit disc 307, the storage rods 301 are pushed through an inner spring 304, the rotating wheel 305 always ensures to roll on the inner side of the limit disc 307, when the storage rods 301 rotate to the joint with the rotating rod 201, the rotating wheel 305 moves to the passing opening of the limit disc 307, so that the limit disc 307 is lost, the storage rods 301 are propped against a pushing block 208 under the elastic force of the spring 304, the effect of the technical scheme can be achieved, the support block 202 is retracted into the inside the rotating rod 201, the upper and lower parts are completed, the effect can be achieved without any driving piece, cost is saved, the chamfer is arranged at the passing opening, and the rotating wheel 305 is convenient to be repeatedly abutted into the limit disc 307.

The material moving assembly 4 comprises a pair of clamping jaws 401, wherein the clamping jaws 401 are used for clamping a plurality of magnetic ring bodies 6 at the same time, a plurality of separation blocks 402 are fixedly connected in the clamping jaws 401, a concave frame is hinged to the upper end of the clamping jaws 401, a driving seat 403 is fixedly connected to the upper end of the concave frame, an electric telescopic cylinder 404 is fixedly connected to the inner side of the driving seat 403, a pull plate 405 is arranged at the driving end of the electric telescopic cylinder 404, pull ropes 406 are arranged at the two ends of the pull plate 405, and the pull ropes 406 are connected with the clamping jaws 401.

The hinge of the clamping jaw 401 is provided with the torsion spring, so that the clamping jaw 401 is convenient to clamp a plurality of magnetic ring bodies 6 in a natural state, when the clamping jaw 401 needs to be controlled to be unfolded, the pulling plate 405 is pushed by the electric telescopic cylinder 404, the pulling rope 406 can be pulled to be lifted up so as to be unfolded, the clamping jaw 401 is convenient to clamp a plurality of magnetic ring bodies 6, and particularly, the separating block 402 is arranged in the clamping jaw 401, so that the magnetic ring bodies 6 are convenient to uniformly spaced when the material is moved, and the displacement of the lower magnetic ring bodies 6 can be not hindered only by controlling the opening of the clamping jaw 401 due to the unchanged height of the clamping jaw 401.

The upper end fixedly connected with of base 7 removes support 701, and the both ends fixedly connected with slider 407 of drive seat 403, the upside of removing support 701 is provided with slide rail groove 702, and slider 407 slides along slide rail groove 702, and drive seat 403 is by the drive of sharp drive assembly removal.

Specifically, a linear driving component, such as an air cylinder, a hydraulic cylinder or a screw rod mechanism, is used to drive the driving seat 403 to move, and the sliding block 407 moves along the sliding rail groove 702 to guide, so as to drive the clamping jaw 401 to repeatedly reciprocate between the storage rod 301 and the material rotating rod 201 to perform displacement of the magnetic ring body 6.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically connected, electrically connected or can be communicated with each other; may be directly connected, may be in communication with the interior of two elements or may be in interaction with two elements. The meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The automatic conveying type coating equipment for magnetic ring production provided by the embodiment of the utility model is described in detail, and specific examples are applied to explain the principle and the implementation mode of the utility model, and the description of the above examples is only used for helping to understand the technical scheme and the core idea of the utility model; those of ordinary skill in the art will appreciate that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (6)

1. Be used for magnetic ring production to use automatic transport formula coating equipment, include base (7), work or material rest subassembly (3), move material subassembly (4) and transfer chamber (1), its characterized in that:

the material rack assembly (3) and the conveying chamber (1) are oppositely arranged at two ends of the upper side of the base (7), the material rack assembly (3) comprises a plurality of material storage rods (301) and a rotating main shaft (302), the rotating main shaft (302) drives the material storage rods (301) to rotate, a plurality of magnetic ring bodies (6) are sleeved on the material storage rods (301), and the magnetic ring bodies (6) are arranged in a like-pole repulsion sequence;

the conveying chamber (1) is integrally disc-shaped and comprises an annular side plate (8), a material passing opening (103) is formed in one end, facing the material rack assembly (3), of the annular side plate (8), and a powder soaking cavity (101) and a drying chamber (102) are arranged in the conveying chamber (1);

the automatic powder soaking device is characterized in that a rotatable rotating assembly (2) is arranged in the center of the inside of the conveying chamber (1), the rotating assembly (2) comprises a plurality of rotating rods (201), the rotating rods (201) and the storage rods (301) are equal in number and are oppositely arranged, a plurality of magnetic ring bodies (6) are sleeved on the outer sides of the rotating rods (201), and the rotating rods (201) are used for driving the magnetic ring bodies (6) to sequentially pass through the powder soaking cavity (101) and the drying chamber (102);

the material moving assembly (4) is used for driving the magnetic ring bodies (6) to move back and forth between the material storage rod (301) and the material rotating rod (201);

the rotary assembly comprises a base (7), and is characterized in that a top cover (802) is fixedly connected to the upper end of the annular side plate (8), a supporting plate (803) is fixedly connected to the lower end of the annular side plate (8), a first motor (104) is further arranged on the rotary assembly (2), the first motor (104) is fixed to the lower end of the base (7), a rotating shaft (105) is driven by the upper end of the first motor (104), a rotating sleeve (106) is fixedly connected to the outer end of the rotating shaft (105), a sliding block (107) is slidingly matched with the outer side of the rotating sleeve (106), and a material rotating rod (201) is connected with the sliding block (107);

the powder soaking device is characterized in that a limiting cover (108) is fixedly connected to the lower end of the center of the top cover (802), the lower end of the limiting cover (108) is rotationally connected with the rotating shaft (105), a special-shaped block (109) is fixedly connected to one side, close to the powder soaking cavity (101), of the limiting cover (108), one side of the special-shaped block (109) is set to be an inclined plane, the other side of the special-shaped block is set to be a vertical plane, and the special-shaped block (109) limits the rotary rod (201) to be immersed into the powder soaking cavity (101) downwards;

the middle side of the supporting plate (803) is fixedly connected with an arc-shaped limit bar (110), one side of the arc-shaped limit bar (110) close to the powder soaking cavity (101) is provided with an oblique angle notch groove (111), the outer side of the material rotating rod (201) is fixedly connected with an elastic wheel, the elastic wheel rolls along the arc-shaped limit bar (110) and the oblique angle notch groove (111), and the sliding block (107) is rotationally connected with the material rotating rod (201);

the material moving assembly (4) comprises a pair of clamping jaws (401), wherein the clamping jaws (401) are used for clamping a plurality of magnetic ring bodies (6) at the same time, a plurality of separation blocks (402) are fixedly connected in the clamping jaws (401), a concave frame is hinged at the upper end of the clamping jaws (401), a driving seat (403) is fixedly connected at the upper end of the concave frame, an electric telescopic cylinder (404) is fixedly connected at the inner side of the driving seat (403), a pulling plate (405) is arranged at the driving end of the electric telescopic cylinder (404), pull ropes (406) are arranged at two ends of the pulling plate (405), and the pull ropes (406) are connected with the clamping jaws (401);

the upper end fixedly connected with of base (7) removes support (701), the both ends fixedly connected with slider (407) of drive seat (403), the upside of removing support (701) is provided with slide rail groove (702), slider (407) slide along slide rail groove (702), drive seat (403) are removed by the drive of sharp drive assembly.

2. An automatic conveyor type coating apparatus for magnetic ring production as claimed in claim 1, wherein: the inside of changeing material pole (201) has seted up the hollow tank, the hollow tank communicates with each other with the one end that changes material pole (201), square through-hole has been seted up at the upper and lower both ends in hollow tank, sliding fit has supporting shoe (202) in the square through-hole, the both ends of supporting shoe (202) are provided with spring telescopic link (203), side fixedly connected with baffle (204) in the both ends of hollow tank, spring telescopic link (203) are connected with baffle (204), when extending square through-hole supporting shoe (202), support fixedly to a plurality of magnetic ring bodies (6).

3. An automatic conveyor type coating apparatus for magnetic ring production as claimed in claim 2, wherein: the inner side of the supporting block (202) is fixedly connected with a connecting block, one end of the connecting block, which faces the opening of the material rotating rod (201), is fixedly connected with a semi-conical part (205), a push rod (206) is slidably matched in one end of the opening of the material rotating rod (201), a conical groove (207) is formed in one end of the push rod (206), the conical groove (207) is matched with the semi-conical part (205), the push rod (206) extends to the outer end of the material rotating rod (201) and is fixedly connected with a push block (208), a cross-shaped groove is formed in the inner side of the push rod (206), a baffle plate (204) and a spring telescopic rod (203) on one side slide in the cross-shaped groove, and a spring part (209) is arranged between the push block (208) and the material rotating rod (201);

an annular groove (801) is formed in the inner side of the annular side plate (8), and the pushing block (208) moves along the annular groove (801).

4. An automatic conveyor type coating apparatus for magnetic ring production as claimed in claim 1, wherein: the powder soaking device is characterized in that the supporting plate (803) is in clearance fit with the magnetic ring body (6), the upper end face of the powder soaking cavity (101) is arranged flush with the supporting plate (803), the drying chamber (102) is internally provided with a plurality of heating strips (804), and the heating strips (804) are fixed on the supporting plate (803).

5. An automatic conveyor type coating apparatus for magnetic ring production as claimed in claim 1, wherein: the elastic wheel comprises a center sleeve (112), the center sleeve (112) is fixedly connected with a material rotating rod (201), a plurality of spring telescopic short rods are arranged on the outer side of the center sleeve (112), and rubber pressing sheets (113) are arranged at the outer ends of the spring telescopic short rods.

6. An automatic conveyor type coating apparatus for magnetic ring production as claimed in claim 3, wherein: the lower extreme of rotating main shaft (302) is provided with motor element, the upper end fixedly connected with rotating disc of rotating main shaft (302), the outside fixedly connected with dead lever (303) of rotating disc, through-hole has been seted up to one side of storage pole (301), through-hole and dead lever (303) sliding fit, the through-hole inboard is provided with first spring (304), the outside rotation of rotating main shaft (302) is connected with fixed cover (306), fixed cover (306) are fixed in on base (7), the outside fixedly connected with limiting disc (307) of fixed cover (306), crossing mouth has been seted up to one side that limiting disc (307) is close to crossing material mouth (103), crossing mouth department sets up to oblique chamfer, the lower extreme of storage pole (301) is provided with runner (305), runner (305) roll along limiting disc (307) inner wall, the terminal surface of storage pole (301) corresponds setting with ejector pad (208).