Workpiece stacking device for welding station

Abstract

The utility model relates to work piece stacking technology field especially relates to welding station work piece stacking device, including support plate, telescopic pneumatic cylinder and conveying assembly, support plate lower extreme is provided with support column, support plate upper end is provided with fixed plate, fixed plate upper end is provided with stacking frame, fixed plate upper end is provided with the placement platform, fixed plate one side is provided with conveying assembly, support plate lower extreme is provided with telescopic pneumatic cylinder, telescopic pneumatic cylinder output is provided with the top rod, the top rod upper end is provided with the top plate, the inboard of stacking frame is provided with the rotary rod, the rotary rod outside is provided with the clamping block, stacking frame one side is provided with the baffle, the device is through the mode of automatic stacking, the work piece of welding completion is automatically stacked to solve the problem that the most of stacking is operated by artificial, and the worker can cause safety accident due to fatigue or improper operation, and there is certain security risk, and artificial stacking needs the worker to carry out repetitive labor for a long time, and the labor intensity is bigger, and it is easy to cause the worker fatigue, and the production efficiency is affected.

Description

Technical Field

[0001] This utility model relates to the field of workpiece palletizing technology, and in particular to a workpiece palletizing device for welding stations. Background Technology

[0002] A welding workstation is a piece of equipment used in industrial manufacturing for efficient and precise welding of workpieces. It typically consists of several core components, including a welding robot, a control system, a welding power source, welding tools, a sensor system, and a worktable.

[0003] In existing welding stations, most of the palletizing is done manually. Workers may have accidents due to fatigue or improper operation, which poses certain safety hazards. Manual palletizing requires workers to perform repetitive labor for a long time, which is labor-intensive and can easily lead to worker fatigue, affecting production efficiency.

[0004] Therefore, in existing welding stations, palletizing is mostly done manually. Workers may experience accidents due to fatigue or improper operation, posing certain safety hazards. Manual palletizing requires workers to perform repetitive labor for extended periods, resulting in high labor intensity and fatigue, thus affecting production efficiency. A workpiece palletizing device can be designed for welding stations to automatically stack welded workpieces, thereby solving the problems of manual palletizing, worker fatigue, and high labor intensity, which are associated with safety hazards and reduced productivity. Utility Model Content

[0005] To address the shortcomings of existing technologies, the purpose of this utility model is to provide a workpiece palletizing device for welding stations. This workpiece palletizing device aims to solve the technical problems that under the existing technology, palletizing is mostly done manually, which may lead to safety accidents due to worker fatigue or improper operation, posing certain safety hazards. Manual palletizing requires workers to perform repetitive labor for a long time, which is labor-intensive and easily leads to worker fatigue, affecting production efficiency.

[0006] The technical solution of this utility model is as follows: a workpiece stacking device for a welding station, comprising a support plate, a telescopic cylinder, and a conveying assembly; a support column is provided at the lower end of the support plate, a fixed plate is provided at the upper end of the support plate, a stacking frame is provided at the upper end of the fixed plate, a placement platform is provided at the upper end of the fixed plate, a conveying assembly is provided on one side of the fixed plate, a telescopic cylinder is provided at the lower end of the support plate, a top rod is provided at the output end of the telescopic cylinder, a top plate is provided at the upper end of the top rod, a rotating rod is provided on the inner side of the stacking frame, a locking block is provided on the outer side of the rotating rod, a baffle is provided on one side of the stacking frame, a first motor is provided at the upper end of the stacking frame, a threaded rod is provided at the output end of the first motor, and a push plate is provided on the outer side of the threaded rod.

[0007] Preferably, a groove is provided at the corresponding position of the support plate and the top rod, and the top rod is slidably connected inside the groove of the support plate.

[0008] Preferably, a slot is provided at the corresponding position of the palletizing frame and the card block, and the card block is rotatably connected inside the slot of the palletizing frame.

[0009] Preferably, two sets of rotating rods, locking blocks, and baffles are provided, and the rotating rods, locking blocks, and baffles are symmetrically arranged on one side of the support plate.

[0010] Preferably, a groove is provided at the corresponding position of the palletizing rack and the push plate, and the push plate is slidably connected inside the groove of the palletizing rack.

[0011] Preferably, the conveying assembly includes a second motor, with the second motor located on one side of the fixed plate, a drive roller located at the output end of the second motor, a conveyor belt located outside the drive roller, and a driven roller located inside the conveyor belt.

[0012] Preferably, a groove is provided at the corresponding position of the fixed plate and the driven roller, and the driven roller is rotatably connected inside the driven roller groove.

[0013] The beneficial effects of this utility model are as follows: Compared with traditional welding stations, where palletizing is mostly done manually, workers may experience safety accidents due to fatigue or improper operation, posing certain safety hazards. Manual palletizing requires workers to perform repetitive labor for a long time, which is labor-intensive and easily leads to worker fatigue, affecting production efficiency. This device automatically stacks the welded workpieces, thus solving the problems of manual palletizing, which may lead to safety accidents due to worker fatigue or improper operation, posing certain safety hazards, and requiring workers to perform repetitive labor for a long time, which is labor-intensive and easily leads to worker fatigue, affecting production efficiency. Attached Figure Description

[0014] Figure 1 The diagram shown is a three-dimensional structural schematic of the workpiece stacking device for welding stations according to this utility model.

[0015] Figure 2 The diagram shown is a three-dimensional structural diagram of the top plate of the workpiece stacking device for the welding station of this utility model.

[0016] Figure 3 The diagram shown is a three-dimensional structural schematic of the workpiece stacking device for welding stations according to this utility model.

[0017] Figure 4 The diagram shown is a cross-sectional view of the conveying component of the workpiece stacking device for a welding station according to this utility model.

[0018] Explanation of reference numerals in the attached drawings: 1. Support plate; 2. Support column; 3. Fixing plate; 4. Stacking rack; 5. Placement platform; 601. Telescopic cylinder; 602. Top rod; 603. Top plate; 604. Rotating rod; 605. Locking block; 606. Baffle; 607. First motor; 608. Threaded rod; 609. Push plate; 701. Second motor; 702. Driven roller; 703. Conveyor belt; 704. Driven roller. Detailed Implementation

[0019] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0020] Please see Figure 1 - Figure 4This utility model provides an embodiment of a workpiece stacking device for a welding station, comprising a support plate 1, a telescopic cylinder 601, and a conveying assembly; a support column 2 is provided at the lower end of the support plate 1, a fixing plate 3 is provided at the upper end of the support plate 1, a stacking frame 4 is provided at the upper end of the fixing plate 3, a placement platform 5 is provided at the upper end of the fixing plate 3, a conveying assembly is provided on one side of the fixing plate 3, a telescopic cylinder 601 is provided at the lower end of the support plate 1, a top rod 602 is provided at the output end of the telescopic cylinder 601, a top plate 603 is provided at the upper end of the top rod 602, a rotating rod 604 is provided on the inner side of the stacking frame 4, a locking block 605 is provided on the outer side of the rotating rod 604, a baffle 606 is provided on one side of the stacking frame 4, and a first electric current device is provided at the upper end of the stacking frame 4. The machine 607 has a threaded rod 608 at its output end, and a push plate 609 on the outside of the threaded rod 608. A slot is formed at the corresponding position of the support plate 1 and the push rod 602. The push rod 602 is slidably connected inside the slot of the support plate 1. The slots in the support plate 1 and the push rod 602 provide a limiting effect when the push rod 602 slides inside the slot. A slot is formed at the corresponding position of the stacking frame 4 and the locking block 605. The locking block 605 is rotatably connected inside the slot of the stacking frame 4. The slots in the stacking frame 4 and the locking block 605 provide a limiting effect when the locking block 605 rotates inside the slot. The rotating rod 604, the locking block 605, and the baffle are also included. Each of the 606 components has two sets of rotating rods 604, locking blocks 605, and baffles 606 symmetrically arranged on one side of the support plate 1. The presence of two sets of rotating rods 604, locking blocks 605, and baffles 606 allows the locking blocks 605 to support the workpiece, making the stacking more stable. The stacking frame 4 has slots at corresponding positions to the push plate 609. The push plate 609 is slidably connected inside the slots of the stacking frame 4. These slots limit the rotation of the push plate 609 within the slots. Activating the telescopic cylinder 601 moves the top rod 602, which in turn moves the top plate 603. The top plate 603 then moves the welded components... The welded workpiece rises, and the welded workpiece drives the clamping block 605 to rotate outside the rotating rod 604. When the welded workpiece rises above the clamping block 605, the clamping block 605 rotates due to gravity, causing the clamping block 605 to return to its original position. Then, the telescopic cylinder 601 retracts, placing the welded workpiece above the clamping block 605. The baffle 606 holds the clamping block 605 in place, ensuring the welded workpiece is stably placed above the clamping block 605. When a certain number of workpieces are stacked, the first motor 607 is started. The first motor 607 drives the threaded rod 608 to rotate, and the threaded rod 608 drives the push plate 609 to slide. The push plate 609 pushes the workpiece onto the placement table 5, and the stacking continues.

[0021] Please see Figure 4In this embodiment, the conveying assembly includes a second motor 701. The second motor 701 is provided on one side of the fixed plate 3, and an active roller 702 is provided at the output end of the second motor 701. A conveyor belt 703 is provided on the outer side of the active roller 702, and a driven roller 704 is provided on the inner side of the conveyor belt 703. A groove is provided at the corresponding position of the fixed plate 3 and the driven roller 704. The driven roller 704 is rotatably connected to the inside of the groove of the driven roller 704. The groove provided at the corresponding position of the fixed plate 3 and the driven roller 704 provides a limiting effect when the driven roller 704 rotates inside the groove.

[0022] During operation, the second motor 701 is activated, which drives the drive roller 702 to rotate. The drive roller 702 drives the conveyor belt 703 to rotate, which in turn drives the driven roller 704 to rotate. The conveyor belt 703 carries the welded workpiece into the stacking rack 4. The telescopic cylinder 601 is then activated, which moves the top rod 602. The top rod 602 moves the top plate 603, which lifts the welded workpiece. The welded workpiece causes the locking block 605 to rotate outside the rotating rod 604. When the welded workpiece... When the workpiece rises above the clamping block 605, the clamping block 605 rotates due to gravity, causing it to return to its original position. Then, the telescopic cylinder 601 retracts, placing the welded workpiece above the clamping block 605. The baffle 606 holds the clamping block 605 in place, ensuring the welded workpiece is stably positioned above it. When a certain number of workpieces are stacked, the first motor 607 is activated. The first motor 607 drives the threaded rod 608 to rotate, which in turn drives the push plate 609 to slide. The push plate 609 pushes the workpieces onto the placement table 5, continuing the stacking process.

[0023] Through the above steps, the telescopic cylinder 601 is activated, which drives the top rod 602 to move. The top rod 602 drives the top plate 603 to move, and the top plate 603 lifts the welded workpiece. The welded workpiece causes the locking block 605 to rotate outside the rotating rod 604. When the welded workpiece rises above the locking block 605, the locking block 605 rotates due to gravity, causing the locking block 605 to return to its original position. Then, the telescopic cylinder 601 is retracted, placing the welded workpiece above the locking block 605. The baffle 606 holds the locking block 605 in place, ensuring that the welded workpiece is stably placed above the locking block 605. When a certain number of workpieces are stacked, the first motor 607 is activated, which drives the threaded rod 608 to rotate. The threaded rod 608 drives the push plate 609 to slide, and the push plate 609 pushes the workpiece onto the placement table 5 for continued stacking.

Claims

1. A workpiece stacking device for a welding station, comprising a support plate (1); characterized in that: It also includes a telescopic cylinder (601) and a conveying assembly; a support column (2) is provided at the lower end of the support plate (1), a fixed plate (3) is provided at the upper end of the support plate (1), a stacking rack (4) is provided at the upper end of the fixed plate (3), a placement platform (5) is provided at the upper end of the fixed plate (3), a conveying assembly is provided on one side of the fixed plate (3), a telescopic cylinder (601) is provided at the lower end of the support plate (1), a top rod (602) is provided at the output end of the telescopic cylinder (601), a top plate (603) is provided at the upper end of the top rod (602), a rotating rod (604) is provided inside the stacking rack (4), and a rotating rod (604) is provided outside the rotating rod (604). A clamping block (605) is provided, a baffle (606) is provided on one side of the stacking rack (4), a first motor (607) is provided at the upper end of the stacking rack (4), a threaded rod (608) is provided at the output end of the first motor (607), a push plate (609) is provided on the outside of the threaded rod (608), and the conveying assembly includes a second motor (701). A second motor (701) is provided on one side of the fixed plate (3), an active roller (702) is provided at the output end of the second motor (701), a conveyor belt (703) is provided on the outside of the active roller (702), and a driven roller (704) is provided on the inside of the conveyor belt (703).

2. The workpiece palletizing device for a welding station according to claim 1, characterized in that: The support plate (1) and the top rod (602) are provided with grooves at corresponding positions, and the top rod (602) is slidably connected inside the groove of the support plate (1).

3. The workpiece palletizing device for a welding station according to claim 1, characterized in that: The palletizing rack (4) and the corresponding position of the card block (605) are provided with slots, and the card block (605) is rotatably connected to the inside of the slot of the palletizing rack (4).

4. The workpiece palletizing device for a welding station according to claim 1, characterized in that: Two sets of rotating rod (604), locking block (605) and baffle (606) are provided, and the rotating rod (604), locking block (605) and baffle (606) are symmetrically arranged on one side of support plate (1).

5. The workpiece palletizing device for a welding station according to claim 1, characterized in that: The palletizing rack (4) and the push plate (609) are provided with grooves at corresponding positions, and the push plate (609) is slidably connected inside the groove of the palletizing rack (4).

6. The workpiece palletizing device for a welding station according to claim 1, characterized in that: The fixed plate (3) has a groove at the corresponding position of the driven roller (704), and the driven roller (704) is rotatably connected inside the groove of the driven roller (704).

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