CN218560037U - Plate turnover mechanism for bidirectional operation - Google Patents

Abstract

The utility model aims at providing a panel turnover mechanism of two-way operation, it includes conveyer belt and upset subassembly, the upset subassembly includes the universal driving shaft, decide the clamp splice, move the clamp splice, centre gripping driving piece and upset driving piece, decide the clamp splice and move the clamp splice and rotate respectively and set up in the conveyer belt, and move the clamp splice and decide the clamp splice and align the setting each other, the centre gripping driving piece sets up in the conveyer belt, and the centre gripping driving piece with move the clamp splice and be connected, the centre gripping driving piece is used for driving and moves the clamp splice and be close to or keep away from and decide the clamp splice, the universal driving shaft rotates and sets up in the conveyer belt, and the universal driving shaft respectively with decide the clamp splice and move the clamp splice and be connected, the upset driving piece sets up in the conveyer belt, and the upset driving piece is connected with moving the clamp splice, the upset driving piece is used for driving to move the clamp splice and decide the clamp splice and rotate in step. Through set up the upset subassembly in the conveyer belt, can transfer the plate-like material to carry out the upset operation on the conveyer belt. The utility model discloses can be applied to the conveyer belt field.

Description

Plate turnover mechanism for bidirectional operation

Technical Field

The utility model relates to a technical field of conveyer belt especially relates to a panel turnover mechanism of two-way operation.

Background

The conveying belt is a conveying device which is driven by a motor and is matched with a plurality of rollers through an annular belt. Conveyor belts are capable of moving materials in different areas within a plant, and therefore conveyor belts have been greatly developed today with increasing demands for automated production.

However, the current conveyor belt has the following problems in practical use: the current conveyor belt can not turn over conveyed materials, for example, for materials with plate-shaped structures such as circuit boards, the front and the back of the conveyor belt need to be processed in production, but due to the lack of an effective turning device, workers are required to turn over the circuit boards on a specified station, so that the circuit boards flow into the next process, the conveyor belt lacking the turning device needs to be additionally added with manual operation stations, the labor cost of production is increased, the automatic production level can be reduced, and the production efficiency is reduced. Therefore, in order to solve the technical problem, the utility model discloses a two-way operation's panel turnover mechanism has been proposed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the not enough among the prior art, providing a two-way operation's that can overturn the plate material of carrying board-like material board turnover mechanism.

The utility model adopts the technical proposal that:

a bi-directional work panel turnover mechanism comprising:

a conveyor belt; and

the upset subassembly, the upset subassembly includes the universal driving shaft, decides the clamp splice, moves clamp splice, centre gripping driving piece and upset driving piece, decide the clamp splice with move the clamp splice rotate respectively set up in the conveyer belt, just move the clamp splice with decide the clamp splice and align the setting each other, the centre gripping driving piece set up in the conveyer belt, just the centre gripping driving piece with it connects to move the clamp splice, the centre gripping driving piece is used for driving it is close to or keeps away from to move the clamp splice decide the clamp splice, the universal driving shaft rotate set up in the conveyer belt, just the universal driving shaft respectively with decide the clamp splice and move the clamp splice and connect, the upset driving piece set up in the conveyer belt, just the upset driving piece with it connects to move the clamp splice, the upset driving piece is used for driving it rotates with to move the clamp splice with decide the clamp splice in step.

Preferably, the turnover assembly comprises a linkage piece, and the linkage piece is respectively connected with the linkage shaft and the fixed clamping block.

Preferably, the linkage piece includes belt and two belt pulleys, and one of them belt pulley fixed set up in on the universal driving shaft, another belt pulley fixed set up in on deciding the clamp splice, the belt overlaps respectively and locates two on the belt pulley.

Preferably, the linkage further comprises a tensioning wheel, the tensioning wheel is rotatably disposed on the conveying belt, and the tensioning wheel abuts against the belt.

Preferably, clamping grooves are formed in the side faces, opposite to the movable clamping block, of the fixed clamping block.

Preferably, the movable clamping block is sleeved with a return spring, and the return spring is used for pushing the movable clamping block to slide in the direction away from the fixed clamping block.

Preferably, the upset subassembly still includes the screens piece, the screens piece fixed set up in on the output shaft of upset driving piece, move and seted up the screens groove on the clamp splice, screens piece sliding fit ground set up in the screens inslot.

Preferably, the tumble drive is an electric motor.

Preferably, the turnover assembly further comprises a pressing pushing block, the pressing pushing block is fixedly arranged on the output shaft of the clamping driving piece, and the pressing pushing block is abutted to the movable clamping block.

Preferably, the top pressing block is provided with a position avoiding groove, and the clamping block is positioned in the position avoiding groove.

The utility model has the advantages that:

the utility model discloses a panel turnover mechanism of two-way operation, including conveyer belt and upset subassembly, the upset subassembly includes the universal driving shaft, decide the clamp splice, move the clamp splice, centre gripping driving piece and upset driving piece, decide the clamp splice and move the clamp splice and rotate respectively and set up in the conveyer belt, and move the clamp splice and decide the clamp splice and align the setting each other, the centre gripping driving piece sets up in the conveyer belt, and the centre gripping driving piece with move the clamp splice and be connected, the centre gripping driving piece is used for driving and moves the clamp splice and be close to or keep away from and decide the clamp splice, the universal driving shaft rotates and sets up in the conveyer belt, and the universal driving shaft respectively with decide the clamp splice and move the clamp splice and be connected, the upset driving piece sets up in the conveyer belt, and the upset driving piece is connected with moving the clamp splice, the upset driving piece is used for driving and moves the clamp splice and decides the clamp splice and rotate in step. Through set up the upset subassembly in the conveyer belt, can transfer the plate-like material to carry out the upset operation on the conveyer belt.

Drawings

Fig. 1 is a schematic structural view of a two-way operation panel turnover mechanism according to an embodiment of the present invention;

fig. 2 is a partial schematic structural view of a turning assembly according to an embodiment of the present invention;

fig. 3 is a partial schematic structural view of another angle of the turnover assembly according to an embodiment of the present invention.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are illustrated in the accompanying drawings.

As shown in fig. 1, a plate turnover mechanism 1 for bidirectional operation includes a conveying belt 11 and a turnover assembly 12, the turnover assembly 12 includes a linkage shaft 121, a fixed clamping block 122, a movable clamping block 123, a clamping driving member 124 and a turnover driving member 125, the fixed clamping block 122 and the movable clamping block 123 are respectively rotatably disposed in the conveying belt 11, the movable clamping block 123 and the fixed clamping block 122 are aligned with each other, the clamping driving member 124 is disposed in the conveying belt 11, the clamping driving member 124 is connected to the movable clamping block 123, the clamping driving member 124 is configured to drive the movable clamping block 123 to approach or be away from the fixed clamping block 122, the linkage shaft 121 is rotatably disposed in the conveying belt 11, the linkage shaft 121 is respectively connected to the fixed clamping block 122 and the movable clamping block 123, the turnover driving member 125 is disposed in the conveying belt 11, the turnover driving member 125 is connected to the movable clamping block 123, and the turnover driving member 125 is configured to drive the movable clamping block 123 and the fixed clamping block to rotate synchronously with the fixed clamping block 122.

Specifically, the conveying belt 11 is used for conveying materials, for example, the conveying belt 11 is composed of two side plates, wherein the two side plates are arranged in parallel, each side plate is provided with a rotatable annular belt, and the materials are placed on the annular belts and can be driven by the annular belts to advance. The overturning component 12 is installed in the conveying belt 11, and the overturning component 12 is used for overturning the materials conveyed in the conveying belt 11. The fixed clamping block 122 and the movable clamping block 123 are both rotatably installed in the conveying belt 11, wherein the fixed clamping block 122 and the movable clamping block 123 are oppositely arranged. For example, the fixed clamping block 122 and the movable clamping block 123 are both fixedly mounted in the conveying belt 11 through bearings, so that the fixed clamping block 122 and the movable clamping block 123 can both rotate relative to the conveying belt 11. The linkage shaft 121 is rotatably installed in the conveyor belt 11 through a bearing, and the linkage shaft 121 is respectively connected with the fixed clamping block 122 and the movable clamping block 123, so that the fixed clamping block 122 and the movable clamping block 123 synchronously rotate. Further, the turning driving member 125 is installed in the conveying belt 11, and the turning driving member 125 is connected to the movable clamping block 123, so that the fixed clamping block 122 and the movable clamping block 123 are turned synchronously by the turning driving member 125. The clamping driving member 124 is installed in the conveying belt 11, and the clamping driving member 124 is connected to the movable clamping block 123, and the clamping driving member 124 can drive the movable clamping block 123 to approach or depart from the fixed clamping block 122. Therefore, when the plate-shaped material is conveyed by the conveyor belt 11 to a position between the fixed clamping block 122 and the movable clamping block 123, the clamping driving member 124 drives the movable clamping block 123 to be close to the fixed clamping block 122, so that the fixed clamping block 122 and the movable clamping block 123 clamp the plate-shaped material together, then the overturning driving member 125 drives the movable clamping block 123 to rotate, under the linkage action of the linkage shaft 121, the fixed clamping block 122 and the movable clamping block 123 clamp the plate-shaped material to rotate synchronously, so that the plate-shaped material is overturned, and then the clamping driving member 124 drives the movable clamping block 123 to be far away from the fixed clamping block 122 to loosen the clamping of the plate-shaped material. Thus, when the conveyer belt 11 continues to feed, the next plate-shaped material can eject the plate-shaped material which is between the fixed clamping block 122 and the movable clamping block 123 and is turned over, and then the next plate-shaped material is turned over. Preferably, the reversing assembly 12 is mounted in the middle of the conveyor belt 11. Further, preferably, the clamping driving member 124 is a cylinder, and the cylinder pushes the movable clamping block 123 to slide to approach or separate from the fixed clamping block 122. Further, preferably, the turning driving member 125 is a motor, and the fixed clamping block 122 and the movable clamping block 123 are turned synchronously by the motor. Further, it is preferable that the linkage shaft 121 has a hexagonal prism structure.

As shown in fig. 1, the turnover assembly 12 preferably includes a linkage 126, and the linkage 126 is connected to the linkage shaft 121 and the fixed clamping block 122 respectively.

Specifically, the linkage shaft 121 is connected to the fixed clamping block 122 through a linkage 126. Preferably, two linkage pieces 126 are provided, wherein one linkage piece 126 is connected with the linkage shaft 121 and the fixed clamping block 122 respectively, and the other linkage piece 126 is connected with the linkage shaft 121 and the movable clamping block 123 respectively.

As shown in fig. 1, preferably, the linkage 126 includes a belt 1261 and two pulleys 1262, wherein one pulley 1262 is fixedly disposed on the linkage shaft 121, the other pulley 1262 is fixedly disposed on the fixed clamping block 122, and the belt 1261 is respectively sleeved on the two pulleys 1262.

Specifically, to avoid the position of the linkage shaft 121 from obstructing the fixed clamping block 122 and the movable clamping block 123, the linkage 126 is provided as a combined structure of the belt 1261 and the two pulleys 1262. Thus, the interlocking shaft 121 can drive the fixed clamping block 122 to rotate through the belt 1261.

As shown in fig. 1, the linkage 126 preferably further includes a tension pulley 1263, the tension pulley 1263 is rotatably provided on the conveyor belt 11, and the tension pulley 1263 abuts against the belt 1261.

Specifically, the belt 1261 needs to be in a tight state, so that the fixed clamping blocks 122 can be synchronously linked with the linkage shaft 121, and therefore the tensioning wheel 1263 is installed to press the belt 1261, so that the belt 1261 is in the tight state.

As shown in fig. 1, preferably, the fixed clamping block 122 and the movable clamping block 123 are provided with clamping grooves on opposite sides.

Specifically, the fixed clamping block 122 and the movable clamping block 123 have the same structure, and for convenience of description, the fixed clamping block 122 is described as an embodiment. A material clamping groove 1221 is formed in one side face, close to the movable clamping block 123, of the fixed clamping block 122, and when the fixed clamping block 122 is in a horizontal state, the extending direction of the material clamping groove 1221 is consistent with the horizontal direction. In this way, the plate-like material moved from the conveyor belt 11 can slide into the material catching groove 1221. Similarly, a clamping groove is also formed on the side surface of the movable clamping block 123 close to the fixed clamping block 122. So, plate-like material can be by the inside wall bearing of two card silo. Therefore, when the clamping driving member 124 drives the movable clamping block 123 to be close to the fixed clamping block 122, the inner side walls of the clamping troughs on the fixed clamping block 122 and the movable clamping block 123 can stably clamp the plate-shaped material, and then the overturning driving member 125 drives the plate-shaped material to overturn 180 degrees.

As shown in fig. 2 and fig. 3, preferably, a return spring 127 is sleeved on the movable clamping block 123, and the return spring 127 is used for pushing the movable clamping block 123 to slide away from the fixed clamping block 122.

Specifically, in order to enable the plate-shaped material to smoothly slide into the clamping groove 1221, the fixed clamping block 122 and the movable clamping block 123 need to be in a state of being away from each other, so a return spring 127 is installed on the movable clamping block 123, and the movable clamping block 123 is pushed by the elastic force of the return spring 127 to slide along the axial direction to be away from the fixed clamping block 122. When the movable clamping block 123 needs to approach the fixed clamping block 122 to clamp the plate-like materials together, the movable clamping block 123 is pushed by the clamping driving member 124, so that the return spring 127 is compressed.

As shown in fig. 2 and fig. 3, preferably, the tilting assembly 12 further includes a locking block 128, the locking block 128 is fixedly disposed on the output shaft of the tilting driving element 125, the movable clamping block 123 is provided with a locking groove 1231, and the locking block 128 is fittingly slidably disposed in the locking groove 1231.

Specifically, the movable clamping block 123 can rotate relative to the conveying belt 11, the movable clamping block 123 can slide relative to the conveying belt 11, and the movable clamping block 123 is connected with the output shaft of the overturning driving element 125, so that the overturning driving element 125 can rotate the movable clamping block 123, but the overturning driving element 125 is fixedly installed on the conveying belt 11. Therefore, in order to enable the movable clamping block 123 and the output shaft of the turnover driving element 125 to be connected in a rotating manner and at the same time to be connected in a sliding manner, a clamping block 128 is fixed on the output shaft of the turnover driving element 125, then a clamping groove 1231 is formed in the axial position of the movable clamping block 123, and the clamping block 128 and the clamping groove 1231 are in a structure of being installed in a matching manner. For example, the locking block 128 has a square column structure, and the locking groove 1231 has a square hole structure matching with the locking block 128. So that the locking block 128 can slide along the locking groove 1231 and simultaneously drive the movable clamping block 123 to rotate synchronously.

As shown in fig. 2 and fig. 3, preferably, the flipping unit 12 further includes a pressing block 129, the pressing block 129 is fixedly disposed on the output shaft of the clamping driving member 124, and the pressing block 129 abuts against the movable clamping block 123.

Specifically, the clamping driving member 124 functions to drive the movable clamping block 123 to slide in the axial direction to approach the fixed clamping block 122. Therefore, in order to facilitate the clamping driving member 124 to push the movable clamping block 123, a pressing block 129 is fixedly installed on the output shaft of the clamping driving member 124, and when the output shaft of the clamping driving member 124 is operated, the pressing block 129 can push the movable clamping block 123 to be close to the fixed clamping block 122.

As shown in fig. 3, preferably, the pressing block 129 has an avoiding groove 1291, and the blocking block 128 is located in the avoiding groove 1291.

Specifically, since the pressing block 129 is fixedly mounted on the output shaft of the clamping driving member 124, the pressing block 129 cannot rotate, and in order to prevent the pressing block 129 from blocking the rotation of the position-locking block 128, an avoiding groove 1291 is formed in the pressing block 129, so that the position-locking block 128 passes through the avoiding groove 1291 to avoid the position-locking block 128.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A panel turnover mechanism of two-way operation, its characterized in that includes:

a conveyor belt; and

the upset subassembly, the upset subassembly includes the universal driving shaft, decides the clamp splice, moves clamp splice, centre gripping driving piece and upset driving piece, decide the clamp splice with move the clamp splice rotate respectively set up in the conveyer belt, just move the clamp splice with decide the clamp splice and align the setting each other, the centre gripping driving piece set up in the conveyer belt, just the centre gripping driving piece with it connects to move the clamp splice, the centre gripping driving piece is used for driving it is close to or keeps away from to move the clamp splice decide the clamp splice, the universal driving shaft rotate set up in the conveyer belt, just the universal driving shaft respectively with decide the clamp splice and move the clamp splice and connect, the upset driving piece set up in the conveyer belt, just the upset driving piece with it connects to move the clamp splice with decide the clamp splice and rotate in step.

2. The turn-over mechanism for bi-directional operation as claimed in claim 1, wherein the turn-over assembly comprises a linkage member, and the linkage member is connected to the linkage shaft and the fixed clamping block respectively.

3. The dual-direction operation panel turnover mechanism of claim 2, wherein the linkage member includes a belt and two belt pulleys, one of the belt pulleys is fixedly disposed on the linkage shaft, the other belt pulley is fixedly disposed on the fixed clamping block, and the belt is respectively sleeved on the two belt pulleys.

4. The bi-directional work flipper mechanism of claim 3, wherein said linkage further comprises a tension pulley, said tension pulley being rotatably disposed on said belt, and said tension pulley abutting said belt.

5. The plate turnover mechanism of claim 1, wherein the fixed clamping block and the movable clamping block are provided with clamping grooves on opposite sides.

6. The plate turnover mechanism for two-way operation according to claim 1, wherein a return spring is sleeved on the movable clamping block and used for pushing the movable clamping block to slide in a direction away from the fixed clamping block.

7. The plate turnover mechanism of claim 1, wherein the turnover assembly further comprises a locking block fixedly disposed on the output shaft of the turnover driving member, the movable clamping block is provided with a locking groove, and the locking block is slidably disposed in the locking groove in a fitting manner.

8. The bi-directional work roll-over mechanism of claim 1, wherein said roll-over drive is an electric motor.

9. The panel turnover mechanism of claim 7, wherein the turnover assembly further comprises a pressing block, the pressing block is fixedly arranged on the output shaft of the clamping driving member, and the pressing block abuts against the movable clamping block.

10. The plate turnover mechanism for two-way operation according to claim 9, wherein the top press block is provided with a clearance groove, and the clamping block is located in the clearance groove.

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