A hand tool of the type having a blade

By designing a paddle-type manual chemical tooling, and utilizing thrust and feeding components, stable transportation and efficient recycling of the material bins are achieved, solving the problem of material bin stacking, improving processing efficiency, and reducing costs.

CN224466749UActive Publication Date: 2026-07-07BH TECH GRP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BH TECH GRP CO LTD
Filing Date
2025-06-30
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

When the product height is greater than the bin height, bins containing the product cannot be stacked, forcing workers to move bins from a distance, wasting time, extending the processing cycle, and increasing costs.

Method used

Design a paddle-type manual chemical loading device, which uses a thrust assembly and a feeding assembly, including a thrust plate, a thrust cylinder, a thrust plate, an operating plate, and a return frame. The thrust cylinder drives the material box to move in one direction, and the guide surface guides and embeds it into the limiting space. The operating plate and the return frame work together to achieve stable transportation and recycling of the material box.

Benefits of technology

It achieves stable transportation and efficient recycling of the material bins, avoids wasted motion, shortens the processing cycle, and reduces processing costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the field of tooling, in particular to a pushing piece type manual tooling which comprises a frame body and a thrust assembly, a plurality of material boxes are arranged on the surface of the frame body, the thrust assembly comprises a thrust plate, a thrust cylinder and a plurality of thrust pieces, the thrust cylinder is connected to the surface of the frame body, the piston rod axis of the thrust cylinder and the length direction of the frame body are parallel to each other, the thrust plate is connected to the surface of the piston rod of the thrust cylinder, and the plurality of thrust pieces are connected to the surface of the thrust plate in the direction of the material boxes, and a limiting space for embedding the material boxes is left between the adjacent thrust pieces. The arrangement of the thrust plate, the thrust cylinder and the thrust pieces in the application enables the staff to conveniently take the products in the material boxes in sequence, the staff does not need to move the material boxes, the action waste is avoided, the processing efficiency of the products is improved, the processing period of the products is shortened, and the processing cost of the products is reduced.
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Description

Technical Field

[0001] This application relates to the field of tooling, and in particular to a paddle-type manual tooling. Background Technology

[0002] When the product height is greater than the bin height, bins containing products cannot be stacked. This forces workers to move bins further away after finishing processing the products in their nearest bin, resulting in wasted effort, extended processing cycles, and increased processing costs. Utility Model Content

[0003] To address the issue of product processing costs, this application provides a paddle-type manual chemical assembly.

[0004] This application provides a paddle-type manual chemical apparatus, which adopts the following technical solution:

[0005] A paddle-type manual chemical tool includes a frame and a thrust assembly. The surface of the frame is provided for multiple material boxes to be placed at intervals. The thrust assembly includes a thrust plate, a thrust cylinder, and multiple thrust plates. The thrust cylinder is connected to the surface of the frame, and the piston rod axis of the thrust cylinder is parallel to the length direction of the frame. The thrust plate is connected to the surface of the piston rod of the thrust cylinder. The multiple thrust plates are connected at intervals to the surface of the thrust plate facing the material box. A limiting space is left between adjacent thrust plates for embedding the material box.

[0006] By adopting the above technical solution, a limiting space for the material box to be embedded is left between adjacent thrust plates. When multiple material boxes are embedded into multiple limiting spaces one by one, the two thrust plates abut against the two ends of the material box to form a limit, realizing unidirectional movement of the material box. The thrust cylinder drives the material boxes in the limiting space to approach the worker in turn, so that the worker can easily pick up the products in the material box in turn without the worker having to move the material box, avoiding wasted movement, improving the processing efficiency of the product, shortening the processing cycle of the product, and thus reducing the processing cost of the product.

[0007] Optionally, the thrust plate end face is provided with a guide surface, the inclination height of the guide surface increases as the distance to the thrust plate decreases, and the guide surface can abut against the bottom of the material box and guide the material box to be embedded in the limiting space.

[0008] By adopting the above technical solution, the tilt height of the guide surface increases as the distance to the thrust plate decreases. When the bottom of the hopper is embedded in the limiting space, the guide surface abuts against the bottom of the hopper and guides the hopper to be embedded in the limiting space, making it difficult for the hopper to fall out of the limiting space, thereby improving the limiting stability of the hopper in the limiting space.

[0009] Optionally, the frame is connected to a feeding assembly, which includes an operating plate and a return frame. The surface of the frame has a rotating cavity for the operating plate to rotate. The rotation axis of the operating plate is parallel to the width direction of the frame. When the surface of the operating plate is flush with the surface of the frame, the thrust plate pushes the material box to be placed on the surface of the operating plate. The return frame is connected to the surface of the frame, and the material box is placed on the surface of the return frame. The inclination height of the return frame surface decreases as the distance to the rotating cavity decreases. When the operating plate rotates along the inner wall of the rotating cavity toward the direction closer to the return frame, the surface of the operating plate is flush with the surface of the return frame.

[0010] By adopting the above technical solution, when the product in the hopper needs to be processed, the thrust cylinder pushes the thrust plate to slide through the thrust plate. The thrust plate abuts against the surface of the hopper and drives the hopper to be placed on the operating plate. When the product in the hopper is processed, the operating plate is driven to rotate along the inner wall of the rotating cavity towards the return rack. The return rack surface is flush with the operating plate surface, and the tilt height of the operating plate decreases as the distance to the rotating cavity decreases. The hopper enters the return rack surface along the operating plate surface under its own weight, realizing the recycling of the empty hopper.

[0011] Optionally, the feeding assembly further includes a feeding cylinder, the bottom of which is rotatably connected to the inner wall of the rotating cavity, and the end of the piston rod of the feeding cylinder is rotatably connected to the end face of the operating plate facing the rotating cavity. When the piston rod of the feeding cylinder extends, the surface of the operating plate is flush with the surface of the frame. When the piston rod of the feeding cylinder retracts, it drives the operating plate to rotate, and the surface of the operating plate is flush with the surface of the return rack.

[0012] By adopting the above technical solution, when the piston rod of the feeding cylinder extends, it drives the operating plate to rotate along the inner wall of the rotating cavity in a direction away from the return rack. The surface of the operating plate is flush with the end face of the rack. The thrust plate drives the material box to approach the operating plate. The material box is placed on the surface of the operating plate. When the worker finishes processing the product in the material box, the piston rod of the feeding cylinder retracts, driving the operating plate to rotate along the inner wall of the rotating cavity in a direction closer to the return rack. The surface of the operating plate is flush with the surface of the return rack. The material box on the operating plate slides towards the return rack under its own weight, controlling the material boxes to be placed on the return rack surface in sequence, thus realizing the recycling of empty material boxes.

[0013] Optionally, the feeding assembly further includes a baffle connected to the surface of the return rack, the surface of which can abut against the surface of the hopper and confine the hopper to the surface of the return rack.

[0014] By adopting the above technical solution, when an empty material box enters the return rack surface, the edge surface abuts against the surface of the material box and confines the material box to the return rack surface, making it difficult for the empty material box to move and achieving stable storage of the empty material box in the designated area.

[0015] Optionally, the frame surface is rotatably connected with multiple rollers at intervals, the axis of the rollers is parallel to the width direction of the frame, and the wheel surface of the rollers makes rolling contact with the bottom of the material box.

[0016] By adopting the above technical solution, the roller surface makes rolling contact with the bottom of the hopper, and rolling friction replaces sliding friction, reducing wear on the hopper and thus extending its service life.

[0017] Optionally, the operating panel is rotatably connected with multiple rollers, the axes of the rollers are parallel to the axis of the rollers, and the surfaces of the rollers make rolling contact with the bottom of the material box.

[0018] By adopting the above technical solution, the two roller surfaces make rolling contact with the bottom of the material box, and rolling friction replaces sliding friction, reducing the friction force on the material box. This allows the material box on the operating panel to stably enter the return rack, thereby improving the stability of the material box in the return rack.

[0019] Optionally, the return rack is rotatably connected to multiple rollers three at intervals, the axes of the rollers three and the axis of the roller one are parallel to each other, and the roller surfaces of the rollers three are in rolling contact with the bottom of the material box.

[0020] By adopting the above technical solution, the tilt height of the reflux rack surface decreases as the distance to the rotating cavity decreases, and the three roller surfaces make rolling contact with the bottom of the material box. Rolling friction replaces sliding friction, driving the material box along the reflux rack surface into the bottom of the reflux rack, reducing the empty space between two adjacent material boxes, thereby increasing the storage capacity of the material box on the reflux rack surface.

[0021] In summary, this application includes at least one of the following beneficial technical effects:

[0022] 1. The design of the thrust plate, thrust cylinder, and thrust disc allows workers to easily pick up products from the material box one by one without having to move the material box, thus avoiding wasted effort, improving processing efficiency, shortening the processing cycle, and reducing processing costs.

[0023] 2. The guide surface is designed to abut against the bottom of the hopper and guide the hopper into the limiting space, making it less likely for the hopper to detach from the limiting space, thereby improving the limiting stability of the hopper within the limiting space;

[0024] 3. The operation panel and the return rack are set up so that the surface of the return rack is flush with the surface of the operation panel, and the tilt height of the operation panel decreases as the distance to the rotating cavity decreases. The material box enters the surface of the return rack along the surface of the operation panel under its own weight, so as to realize the recycling of the empty material box. Attached Figure Description

[0025] Figure 1This is a schematic diagram of the overall structure in an embodiment of this application.

[0026] Figure 2 This is a schematic diagram of the overall structure in the embodiments of this application, mainly showing the thrust cylinder.

[0027] Figure 3 This is a schematic diagram of the overall structure of the thrust-stopping component in the embodiments of this application.

[0028] Explanation of reference numerals in the attached drawings: 1. Frame; 11. Sliding cavity; 12. Rotating cavity; 2. Thrust assembly; 21. Thrust plate; 211. Slide rail; 22. Thrust cylinder; 23. Thrust disc; 231. Limiting space; 232. Guide surface; 3. Material box; 4. Slide rail; 5. Roller one; 6. Unloading assembly; 61. Control panel; 62. Return frame; 63. Unloading cylinder; 64. Side guard; 7. Roller two; 8. Roller three. Detailed Implementation

[0029] The following is in conjunction with the appendix Figure 1-3 This application will be described in further detail.

[0030] This application discloses a paddle-type manual chemical apparatus. (Refer to...) Figure 1 A paddle-type manual chemical tool includes a frame 1 and a thrust assembly 2. The bottom of the frame 1 abuts against the ground to form support, and the top of the frame 1 is for placing multiple material boxes 3 in sequence at intervals. The thrust assembly 2 is connected to the frame 1 and can drive the multiple material boxes 3 to move synchronously, so that the workers can easily pick up the products in the material boxes 3 in sequence without the need for the workers to move the material boxes 3, avoiding wasted movement, improving the processing efficiency of the products, shortening the processing cycle of the products, and thus reducing the processing cost of the products.

[0031] Reference Figure 1 and Figure 2 The thrust assembly 2 includes a thrust plate 21, a thrust cylinder 22, and multiple thrust plates 23. The thrust cylinder 22 is fixed to the bottom of the frame 1 by bolts. The piston rod axis of the thrust cylinder 22 is parallel to the length direction of the frame 1. The thrust plate 21 is fixed to the piston rod surface of the thrust cylinder 22 by bolts. A slide rail 4 is fixed on the surface of the frame 1 facing the thrust plate 21. The length direction of the slide rail 4 is parallel to the length direction of the frame 1. The surface of the thrust plate 21 has a slide rail 211 for the slide rail 4 to slide. When the thrust cylinder 22 drives the thrust plate 21 to slide, it drives the slide rail 4 to slide on the inner wall of the slide rail 211, making it less likely for the thrust plate 21 to deviate during the sliding process, thereby improving the stability of the thrust plate 21 sliding on the frame 1.

[0032] Reference Figure 1 and Figure 2Multiple thrust plates 23 are spaced apart on the surface of the thrust plate 21 facing the top of the frame 1. The arrangement direction of the thrust plates 23 is parallel to the length direction of the frame 1. Multiple sliding cavities 11 are spaced apart on the top surface of the frame 1 for the thrust plates 23 to slide. A limiting space 231 for the material box 3 to be embedded is left between adjacent thrust plates 23. Two adjacent thrust plates abut against the two ends of the material box 3 and limit the unidirectional movement of the material box 3, so as to realize the stable transportation of the material box 3. Moreover, the transportation speed of the material box 3 can be adjusted according to the speed of the thrust cylinder 22. The speed can be adjusted according to the product characteristics to avoid the material box 3 moving too much during the movement, thereby affecting the product accuracy.

[0033] Reference Figure 1 and Figure 2 The end of the thrust plate 23 protruding from the top surface of the frame 1 is provided with a guide surface 232. The inclination height of the guide surface 232 increases as the distance to the thrust plate 21 decreases. The guide surface 232 can abut against the bottom of the material box 3 and guide the material box 3 to be embedded in the limiting space 231, so that the material box 3 is not easy to deviate in the limiting space 231, thereby improving the limiting stability of the material box 3 in the limiting space 231.

[0034] Reference Figure 1 and Figure 2 Multiple rollers 5 are rotatably connected to the top surface of the frame 1 at intervals. The rollers 5 make rolling contact with the bottom of the material box 3. Rolling friction replaces sliding friction, reducing wear on the material box 3 and thus extending its service life.

[0035] Reference Figure 1 and Figure 3 The frame 1 is equipped with a feeding assembly 6, which includes an operation plate 61, a return rack 62, a feeding cylinder 63, and a stop 64. The top surface of the frame 1 has a rotating cavity 12 for the operation plate 61 to rotate. In this embodiment, the operation plate 61 is rotatably connected to the inner wall of the rotating cavity 12 by a hinge. The rotation axis of the operation plate 61 is parallel to the width direction of the frame 1. The return rack 62 is fixed to the bottom of the frame 1. The inclination height of the return rack 62 decreases as the distance to the rotating cavity 12 decreases. The return rack 62 is used to place an empty material box 3.

[0036] Reference Figure 1 and Figure 3The bottom of the feeding cylinder 63 is rotatably connected to the bottom wall of the rotating cavity 12, and the end of the piston rod of the feeding cylinder 63 is rotatably connected to the surface of the operating plate 61 facing the rotating cavity 12. When the piston rod of the feeding cylinder 63 extends, it drives the operating plate 61 to rotate along the inner wall of the rotating cavity 12 away from the rotating cavity 12. The surface of the operating plate 61 is flush with the surface of the frame 1. The surface of the thrust plate 23 abuts against the surface of the material box 3 and drives the material box 3 to slide towards the operating plate 61. The material box 3 is placed on the surface of the operating plate 61. When the product in the material box 3 on the operating plate 61 is finished, the piston rod of the feeding cylinder 63 retracts, driving the operating plate 61 to rotate along the inner wall of the rotating cavity 12 towards the return rack 62. The surface of the operating plate 61 is flush with the surface of the return rack 62. The empty material box 3 on the surface of the operating plate 61 slides towards the return rack 62 due to its own weight. The empty material box 3 is embedded in the surface of the return rack 62, realizing the storage of the empty material box 3.

[0037] Reference Figure 1 and Figure 3 The baffle 64 is connected to the surface of the return rack 62. The surface of the baffle 64 abuts against the surface of the empty material box 3 to form a limit, making it difficult for the empty material box 3 to move, thus achieving stable storage of the empty material box 3 within the designated area.

[0038] Reference Figure 1 and Figure 3 The operating plate 61 is rotatably connected to multiple rollers 7. The surface of the rollers 7 rolls in contact with the bottom of the material box 3, and the axis of the rollers 7 and the axis of the rollers 5 are parallel to each other. Rolling friction replaces sliding friction, reducing the friction force on the material box 3, so that the material box 3 on the surface of the operating plate 61 can be stably embedded in the surface of the return rack 62, improving the stability of the material box 3 stored in the return rack 62.

[0039] Reference Figure 1 and Figure 3 The return rack 62 has multiple rollers 3 8 rotatably connected at intervals. The axis of roller 3 8 is parallel to the axis of roller 1 5. The wheel surface of roller 3 8 makes rolling contact with the bottom of the material box 3. Rolling friction replaces sliding friction, which drives the material box 3 to enter the bottom of the return rack 62 along the rack surface, reducing the empty space between two adjacent material boxes 3, thereby increasing the storage capacity of the material box 3 on the rack surface of the return rack 62.

[0040] The implementation principle of a pusher-type manual chemical packaging according to an embodiment of this application is as follows: multiple material boxes 3 are sequentially embedded in multiple limiting spaces 231. Two adjacent pushers abut against both ends of the material box 3 and limit the unidirectional movement of the material box 3, thereby achieving stable transportation of the material box 3. This allows the staff to easily pick up the products in the material box 3 in sequence without having to move the material box 3, avoiding wasted movement, improving the processing efficiency of the product, shortening the processing cycle of the product, and thus reducing the processing cost of the product.

[0041] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A type of manual chemical apparatus using a pick-like mechanism, characterized in that: The device includes a frame (1) and a thrust assembly (2). The surface of the frame (1) is provided for multiple material boxes (3) to be placed at intervals. The thrust assembly (2) includes a thrust plate (21), a thrust cylinder (22) and multiple thrust plates (23). The thrust cylinder (22) is connected to the surface of the frame (1). The piston rod axis of the thrust cylinder (22) is parallel to the length direction of the frame (1). The thrust plate (21) is connected to the surface of the piston rod of the thrust cylinder (22). Multiple thrust plates (23) are connected at intervals on the surface of the thrust plate (21) facing the material box (3). A limiting space (231) for embedding the material box (3) is left between adjacent thrust plates (23).

2. The paddle-type manual chemical apparatus according to claim 1, characterized in that: The end face of the thrust plate (23) is provided with a guide surface (232). The inclination height of the guide surface (232) increases as the distance to the thrust plate (21) decreases. The guide surface (232) can abut against the bottom of the material box (3) and guide the material box (3) to be embedded in the limiting space (231).

3. The paddle-type manual chemical apparatus according to claim 1, characterized in that: The frame (1) is connected to a feeding assembly (6), which includes an operating plate (61) and a return rack (62). The surface of the frame (1) is provided with a rotating cavity (12) for the operating plate (61) to rotate. The rotation axis of the operating plate (61) is parallel to the width direction of the frame (1). When the surface of the operating plate (61) is flush with the surface of the frame (1), the thrust plate (21) pushes the material box (3) to place the surface of the operating plate (61). The return rack (62) is connected to the surface of the frame (1). The material box (3) is placed on the surface of the return rack (62). The inclination height of the return rack (62) decreases as the distance to the rotating cavity (12) decreases. When the operating plate (61) rotates along the inner wall of the rotating cavity (12) toward the direction closer to the return rack (62), the surface of the operating plate (61) is flush with the surface of the return rack (62).

4. A paddle-type manual chemical apparatus according to claim 3, characterized in that: The feeding assembly (6) also includes a feeding cylinder (63). The bottom of the feeding cylinder (63) is rotatably connected to the inner wall of the rotating cavity (12). The end of the piston rod of the feeding cylinder (63) is rotatably connected to the end face of the operating plate (61) facing the rotating cavity (12). When the piston rod of the feeding cylinder (63) extends, the surface of the operating plate (61) is flush with the surface of the frame (1). When the piston rod of the feeding cylinder (63) retracts, it drives the operating plate (61) to rotate, and the surface of the operating plate (61) is flush with the surface of the return rack (62).

5. A paddle-type manual chemical apparatus according to claim 3, characterized in that: The feeding assembly (6) also includes a baffle (64), which is connected to the surface of the return rack (62). The surface of the baffle (64) can abut against the surface of the hopper (3) and limit the hopper (3) to the surface of the return rack (62).

6. A paddle-type manual chemical apparatus according to claim 3, characterized in that: The frame (1) is rotatably connected to a plurality of rollers (5) at intervals. The axis of the rollers (5) is parallel to the width direction of the frame (1), and the wheel surface of the rollers (5) is in rolling contact with the bottom of the material box (3).

7. A paddle-type manual chemical apparatus according to claim 6, characterized in that: The operating plate (61) is rotatably connected to multiple rollers (7) at intervals. The axis of rollers (7) is parallel to the axis of roller (5), and the surface of rollers (7) is in rolling contact with the bottom of the material box (3).

8. A paddle-type manual chemical apparatus according to claim 6, characterized in that: The return rack (62) is rotatably connected with multiple rollers (8) at intervals. The axis of rollers (8) is parallel to the axis of roller (5), and the wheel surface of rollers (8) is in rolling contact with the bottom of the material box (3).