CN219971372U - Copper-clad plate stacking device - Google Patents

Abstract

The utility model discloses a copper-clad plate stacking device which comprises two supporting frames, a receiving plate, an intermittent conveying belt, a clamping mechanism and a correcting mechanism, wherein the two supporting frames are horizontally spaced and arranged in parallel; the bearing plate is placed on the supporting frame and is used for supporting a plurality of copper-clad plates stacked from bottom to top; one end of the intermittent conveyor belt is connected with the cutting mechanism and used for conveying the single copper-clad plate cut by the cutting mechanism to the direction of the connection plate; the clamping mechanism is arranged on the supporting frame and is used for stacking a single copper-clad plate on the intermittent conveyor belt on the bearing plate when the intermittent conveyor belt pauses; the correction mechanism is arranged on the supporting frame and is used for correcting the plurality of stacked copper-clad plates on the bearing plate in order. The copper-clad plate stacking device can improve the stacking efficiency of the copper-clad plate, and simultaneously prevent the surface of the copper-clad plate from being folded in the stacking process, thereby causing quality problems.

Description

Copper-clad plate stacking device

Technical Field

The utility model relates to the field of copper-clad foil production equipment, in particular to a copper-clad plate stacking device.

Background

The copper clad laminate (Copper Clad Laminate, CCL) is simply called copper clad laminate, which is a plate-like material made by impregnating electronic glass fiber cloth or other reinforcing materials with resin, coating copper foil on one or both sides, and hot-pressing.

In the production process of the copper-clad plate, the stacking procedure is a procedure for stacking one or more copper-clad plates according to the requirement of an order. The conventional stacking procedure is as follows: after the copper-clad plate from the impregnation coil-unloading section is cut by a cutting mechanism, cloth distribution and stacking are performed manually according to the arrangement period requirement. This approach has the following drawbacks:

1. the efficiency is low;

2. the surface of the copper-clad plate is easy to be broken, and the quality problem is caused.

Disclosure of Invention

Aiming at the defects existing in the prior art, the technical problem to be solved by the utility model is to provide the copper-clad plate stacking device which can improve the stacking efficiency of the copper-clad plate and prevent the surface of the copper-clad plate from being broken in the stacking process to cause quality problems.

In order to achieve the above object, the present utility model is realized by the following technical scheme: a copper-clad plate stacking device, comprising:

the two support frames are horizontally spaced and arranged in parallel;

the bearing plate is placed on the supporting frame and used for supporting a plurality of copper-clad plates stacked from bottom to top;

one end of the intermittent conveying belt is connected with the cutting mechanism and is used for conveying the single copper-clad plate cut by the cutting mechanism to the direction of the connecting plate;

the clamping mechanism is arranged on the supporting frame and used for stacking a single copper-clad plate on the intermittent conveyor belt on the bearing plate when the intermittent conveyor belt pauses; a kind of electronic device with high-pressure air-conditioning system

And the correction mechanism is arranged on the support frame and is used for correcting the plurality of stacked copper-clad plates on the bearing plate in order.

Further, the clamping mechanism comprises a horizontal motion driving source, a mounting plate, a clamping driving source and a clamping plate; the top of support frame is provided with the cantilever frame, the horizontal movement actuating source sets up on the cantilever frame, the mounting panel is located directly over the support frame, and with the power output shaft of horizontal movement actuating source, the horizontal movement actuating source can drive the mounting panel with the syntropy motion of intermittent type formula conveyer belt, the centre gripping actuating source sets up on the mounting panel, splint have two, two splint relative setting, two splint the top with the centre gripping actuating source is connected, the centre gripping actuating source can drive two splint horizontal phase is moved, in order to with copper-clad plate on the discharge end of intermittent type formula conveyer belt carries out the centre gripping.

Further, the splint include connecting plate and hook plate, the setting that the connecting plate is upright, the top of connecting plate with the centre gripping actuating source is connected, the hook plate sets up the inside wall that the connection is close to the bottom, the centre gripping actuating source to the connecting plate is towards when the copper-clad plate is close to, the hook plate can hook the tip at the copper-clad plate.

Further, the clamping plate further comprises a guide plate, the guide plate is arranged at the end part of the hook plate and is inclined downwards from the hook plate to the center direction of the copper-clad plate in an opposite direction, the bottom end of the guide plate is lower than the end part of the copper-clad plate, and the hook plate is higher than the end part of the copper-clad plate.

Further, the clamping driving source comprises a rotary power source, a bidirectional screw and a guide rod, the rotary power source is arranged on the cantilever plate, the bidirectional screw is arranged on a power output shaft of the rotary power source and is horizontally orthogonal to the conveying direction of the intermittent conveying belt, the two connecting plates are respectively in threaded connection with two ends of the bidirectional screw, and the guide rod is arranged on the mounting plate in parallel with the bidirectional screw and can be in sliding connection with the two connecting plates.

Further, the correction mechanism comprises a fixing plate and a pushing assembly, the bearing plate can be fixed on the supporting frame, the fixing plate is vertically arranged on the bearing plate and is located at one side far away from the conveying belt, and the pushing assembly is arranged on the mounting plate and can stretch up and down.

Further, the pushing assembly comprises a telescopic power source and a pushing plate, the telescopic power source is arranged on the power output shaft of the mounting plate, the pushing plate is arranged at the end part of the telescopic power source, and the telescopic power source can drive the pushing plate to vertically lift up and down.

The utility model has the beneficial effects that:

when the copper-clad plate stacking device is used, after the cutting mechanism cuts down a single copper-clad plate, the copper-clad plate falls on the intermittent conveyor belt, the intermittent conveyor belt conveys the copper-clad plate towards the direction of the bearing plate, the copper-clad plate is stopped after the copper-clad plate is about to reach the bearing plate, and then the clamping mechanism is started to clamp the single copper-clad plate to the bearing plate. And after stacking a plurality of copper-clad plates on the bearing plate, starting the correction mechanism, and correcting the copper-clad plates with the position offset in the stacked bearing plate in order, so that the copper-clad plates can be stacked and carried away, and the copper-clad plates of the next week can be stacked.

By adopting the device, the device is adopted to automatically stack in the stacking process, so that the efficiency can be improved; meanwhile, according to production, the stacking quantity of copper-clad plates at each time is consistent by connecting with an external control mechanism, so that the stacking quantity of the copper-clad plates is prevented from being wrong; in addition, the copper-clad plate can be prevented from falling in a manual operation mode, so that quality problems are caused.

Drawings

Fig. 1 is a schematic structural view of a copper-clad plate stacking device according to the present utility model;

FIG. 2 is a schematic view of another angle of a copper-clad laminate stacking device according to the present utility model;

FIG. 3 is a side view of a copper clad laminate stacking apparatus according to the present utility model;

FIG. 4 is a schematic view of a copper-clad laminate stacking device according to the present utility model after changing angles;

reference numerals: 1. copper-clad plate; 100. a support frame; 110. cantilever mount; 200. a receiving plate; 300. an intermittent conveyor belt; 400. a clamping mechanism; 410. a horizontal movement driving source; 420. a mounting plate; 430. clamping a driving source; 431. a rotary power source; 432. a bidirectional screw; 433. a guide rod; 440. a clamping plate; 441. a connecting plate; 442. a hook plate; 443. a guide plate; 500. a correction mechanism; 510. a fixing plate; 520. a pushing assembly; 521. a telescopic power source; 522. a push plate.

Detailed Description

Embodiments of the technical scheme of the present utility model will be described in detail below with reference to the accompanying drawings. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and thus are merely examples, and are not intended to limit the scope of the present utility model.

As shown in fig. 1 to 4, the present embodiment provides a copper-clad plate stacking device. Comprises a supporting frame 100, a bearing plate 200, an intermittent conveyor belt 300, a clamping mechanism 400 and a correction mechanism 500.

Specifically, there are two supporting frames 100, and the two supporting frames 100 are horizontally spaced and arranged in parallel. The bearing plate 200 is placed on the supporting frame 100 and is used for supporting a plurality of copper clad laminates 1 stacked from bottom to top. One end of the intermittent conveyor belt 300 is connected with the cutting mechanism and used for conveying the single copper-clad plate 1 cut by the cutting mechanism to the direction of the connection plate 200. The clamping mechanism 400 is disposed on the supporting frame 100, and is used for stacking a single copper-clad plate on the intermittent conveyor 300 on the receiving plate 200 when the intermittent conveyor 300 pauses. The correction mechanism 500 is disposed on the support frame 100, and is used for correcting the plurality of stacked copper clad laminates 1 on the receiving board 200. The intermittent conveyor 300 is a commercially available intermittent conveyor mechanism.

When the copper-clad plate 1 cutting machine is used, after a cutting mechanism cuts a single copper-clad plate 1, the copper-clad plate 1 falls on the intermittent conveyor 300, the intermittent conveyor 300 conveys the copper-clad plate 1 towards the bearing plate 200, and when the copper-clad plate 1 is about to reach the bearing plate 200, the copper-clad plate 1 stops, and then the clamping mechanism 400 is started to clamp the single copper-clad plate 1 to the bearing plate 200. After stacking a plurality of copper clad laminates on the bearing plate 200, the correction mechanism 500 is started to correct the offset copper clad laminate 1 in the stacked bearing plate 200, so that the copper clad laminate stack can be carried away, and the copper clad laminate 1 in the next week can be stacked.

By adopting the device, the device is adopted to automatically stack in the stacking process, so that the efficiency can be improved; meanwhile, according to production, the stacking quantity of copper-clad plates at each time is consistent by connecting with an external control mechanism, so that the stacking quantity of the copper-clad plates is prevented from being wrong; in addition, the copper-clad plate 1 can be prevented from falling off in a manual operation mode, so that quality problems are caused.

In the present embodiment, the clamping mechanism 400 includes a horizontal movement drive source 410, a mounting plate 420, a clamping drive source 430, and a clamping plate 440. The top of the support 100 is provided with a cantilever mount 110, a horizontal movement driving source 410 is provided on the cantilever mount 110, and a mounting plate 420 is positioned right above the support 100 and connected with a power output shaft of the horizontal movement driving source 410. The horizontal movement driving source 410 can drive the mounting plate 420 and the intermittent conveyor 300 to move in the same direction, and the clamping driving source 430 is provided on the mounting plate 420. The two clamping plates 440 are oppositely arranged, the top ends of the two clamping plates 440 are connected with the clamping driving source 430, and the clamping driving source 430 can drive the two clamping plates 440 to horizontally move in opposite directions so as to clamp the copper-clad plate 1 on the discharge end of the intermittent conveyor belt 300.

When in use, when the copper-clad plate 1 needs to be clamped, the mounting plate 420 is positioned right above the copper-clad plate 1 through the horizontal movement driving source 410, then the clamping driving source 430 drives the two clamping plates 440 to move oppositely to clamp the two ends of the copper-clad plate 1, then the horizontal movement driving source 410 drives the mounting plate 420 to move right above the bearing plate 200, the clamping driving source 430 drives the two clamping plates 440 to move oppositely to loosen the copper-clad plate 1, and the copper-clad plate 1 falls on the bearing plate 200.

In this embodiment, the clamping plate 440 includes a connection plate 441 and a hook plate 442. The connection plate 441 is vertically arranged, the top end of the connection plate 441 is connected with the clamping driving source 430, the hook plate 442 is arranged on the inner side wall near the bottom end, and when the clamping driving source 430 approaches the connection plate 441 to the copper-clad plate 1, the hook plate 442 can be hooked at the end part of the copper-clad plate 1.

The clamping plate 440 also includes, as a preferred embodiment, a hook plate guide 443. The guide plate 443 is disposed at an end of the hook plate 442 and is inclined downward from the hook plate 442 to the center of the copper-clad plate 1 in opposite directions, and the bottom end of the guide plate 443 is lower than the end of the copper-clad plate 1 and the hook plate 442 is higher than the end of the copper-clad plate 1.

Through the direction of deflector 443, splint 440 makes copper-clad plate 1 slide to the couple after rising through deflector 443 in the in-process of centre gripping copper-clad plate 1 to upwards improve certain height with copper-clad plate 1, prevent that copper-clad plate 1 from dragging at intermittent type formula conveyer belt 300 in the transfer process.

In the present embodiment, the grip driving source 430 includes a rotary power source 431, a bidirectional screw 432, and a guide lever 433. The rotary power source 431 is mounted on the cantilever mount 110, the bidirectional screw 432 is disposed on a power output shaft of the rotary power source 431, and the horizontal orthogonal intermittent conveyor belt 300 is disposed in a conveying direction, and the two connection plates 441 are respectively in threaded connection with two ends of the bidirectional screw 432. The guide rods 433 are disposed on the mounting plate 420 in parallel with the bi-directional screw 432 and slidably connected to the two connection plates 420.

When the rotary power source 431 drives the bidirectional screw 432 to rotate clockwise or anticlockwise, the two connecting plates 441 can be driven to move relatively or reversely to perform clamping operation. In particular embodiments, the rotary power source 431 may be a bi-directional rotary motor commonly used in the art.

In this embodiment, the correction mechanism 500 includes a fixed plate 510 and a push assembly 520. The receiving plate 200 can be fixed on the supporting frame 100, the fixing plate 510 is vertically arranged on the receiving plate 200 and is positioned at one side far away from the conveying belt, and the pushing assembly 520 is arranged on the mounting plate 420 and can stretch up and down.

Specifically, the pushing assembly 520 includes a telescoping power source 521 and a push plate 522. The telescopic power source 521 is disposed on the power output shaft of the mounting plate 420, and the push plate 522 is disposed at an end of the telescopic power source 521, and the telescopic power source 521 can drive the push plate 522 to vertically up and down.

When the copper clad laminate 1 in the stacking state needs to be corrected, the push plate 522 is driven to descend through the telescopic power source 521, the push plate 522 is positioned between the intermittent conveyor belt 300 and the copper clad laminate stack through the movement of the horizontal movement driving source 410 mounting plate 420 after the push plate 522 is equal to the copper clad laminate stack, and then the push plate 522 pushes the copper clad laminate 1 to approach towards the fixed plate 510 again through the movement of the horizontal movement driving source 410 mounting plate 420, so that the misplaced copper clad laminate stack is corrected under the common clamping action of the fixed plate 510 and the push plate 522.

The using mode of the copper-clad plate stacking device is as follows:

when in use, when the copper-clad plate 1 needs to be clamped, the mounting plate 420 is positioned right above the copper-clad plate 1 through the horizontal movement driving source 410, then the clamping driving source 430 drives the two clamping plates 440 to move oppositely to clamp the two ends of the copper-clad plate 1, then the horizontal movement driving source 410 drives the mounting plate 420 to move right above the bearing plate 200, the clamping driving source 430 drives the two clamping plates 440 to move oppositely to loosen the copper-clad plate 1, and the copper-clad plate 1 falls on the bearing plate 200. When the copper clad laminate 1 in the stacking state needs to be corrected, the push plate 522 is driven to descend through the telescopic power source 521, the push plate 522 is positioned between the intermittent conveyor belt 300 and the copper clad laminate stack through the movement of the horizontal movement driving source 410 mounting plate 420 after the push plate 522 is equal to the copper clad laminate stack, and then the push plate 522 pushes the copper clad laminate 1 to approach towards the fixed plate 510 again through the movement of the horizontal movement driving source 410 mounting plate 420, so that the misplaced copper clad laminate stack is corrected under the common clamping action of the fixed plate 510 and the push plate 522.

By adopting the device, the device is adopted to automatically stack in the stacking process, so that the efficiency can be improved; meanwhile, according to production, the stacking quantity of copper-clad plates at each time is consistent by being connected with an external control mechanism, so that the stacking quantity of the copper-clad plates is prevented from being wrong. In addition, the copper-clad plate 1 can be prevented from falling off in a manual operation mode, so that quality problems are caused.

Finally, it should be noted that: while the fundamental and principal features of the utility model and advantages of the utility model have been shown and described, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (7)

1. The utility model provides a copper-clad plate piles up device which characterized in that includes:

the two support frames are horizontally spaced and arranged in parallel;

the bearing plate is placed on the supporting frame and used for supporting a plurality of copper-clad plates stacked from bottom to top;

one end of the intermittent conveying belt is connected with the cutting mechanism and is used for conveying the single copper-clad plate cut by the cutting mechanism to the direction of the connecting plate;

the clamping mechanism is arranged on the supporting frame and used for stacking a single copper-clad plate on the intermittent conveyor belt on the bearing plate when the intermittent conveyor belt pauses; a kind of electronic device with high-pressure air-conditioning system

And the correction mechanism is arranged on the support frame and is used for correcting the plurality of stacked copper-clad plates on the bearing plate in order.

2. The copper-clad laminate stacking device according to claim 1, wherein the clamping mechanism comprises a horizontal movement driving source, a mounting plate, a clamping driving source and a clamping plate; the top of support frame is provided with the cantilever frame, the horizontal movement actuating source sets up on the cantilever frame, the mounting panel is located directly over the support frame, and with the power output shaft of horizontal movement actuating source, the horizontal movement actuating source can drive the mounting panel with the syntropy motion of intermittent type formula conveyer belt, the centre gripping actuating source sets up on the mounting panel, splint have two, two splint relative setting, two splint the top with the centre gripping actuating source is connected, the centre gripping actuating source can drive two splint horizontal phase is moved, in order to with copper-clad plate on the discharge end of intermittent type formula conveyer belt carries out the centre gripping.

3. The copper-clad plate stacking device according to claim 2, wherein the clamping plate comprises a connecting plate and a hook plate, the connecting plate is arranged vertically, the top end of the connecting plate is connected with the clamping driving source, the hook plate is arranged on the inner side wall of the connecting part, which is close to the bottom end, of the connecting plate, and the hook plate can be hooked at the end part of the copper-clad plate when the clamping driving source approaches the copper-clad plate towards the connecting plate.

4. The copper-clad plate stacking device according to claim 3, wherein the clamping plate further comprises a guide plate, the guide plate is arranged at the end part of the hook plate and is inclined downwards in the opposite direction from the hook plate to the center of the copper-clad plate, the bottom end of the guide plate is lower than the end part of the copper-clad plate, and the hook plate is higher than the end part of the copper-clad plate.

5. The copper-clad plate stacking device according to claim 2 or 4, wherein the clamping driving source comprises a rotary power source, a bidirectional screw rod and a guide rod, the rotary power source is mounted on a cantilever plate, the bidirectional screw rod is arranged on a power output shaft of the rotary power source and is horizontally orthogonal to the conveying direction of the intermittent conveyor belt, two connecting plates are respectively in threaded connection with two ends of the bidirectional screw rod, and the guide rod is arranged on the mounting plate in parallel with the bidirectional screw rod and can be in sliding connection with the two connecting plates.

6. The copper-clad plate stacking device according to claim 2, wherein the correction mechanism comprises a fixing plate and a pushing assembly, the receiving plate can be fixed on the supporting frame, the fixing plate is vertically arranged on the receiving plate and is positioned on one side far away from the conveying belt, and the pushing assembly is arranged on the mounting plate and can stretch up and down.

7. The copper-clad plate stacking device according to claim 6, wherein the pushing assembly comprises a telescopic power source and a pushing plate, the telescopic power source is arranged on the power output shaft of the mounting plate, the pushing plate is arranged at the end part of the telescopic power source, and the telescopic power source can drive the pushing plate to vertically lift up and down.