A cutting machine material collecting device
By using a laser measuring instrument and PLC controller in conjunction with components such as air pumps and motors, the positions of the side plates and stacking plates are automatically adjusted, solving the problem of uneven material stacking in the material collection device of the cutting machine and achieving stable and efficient material collection.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HONGCHENG SCI & TECH LTD
- Filing Date
- 2025-07-16
- Publication Date
- 2026-07-07
AI Technical Summary
The existing material collection device for cutting machines cannot be adjusted according to the size of the material, resulting in uneven stacking of collected materials and an inability to adapt to the collection needs of materials of different sizes, affecting the stability and efficiency of material collection.
Using a laser measuring instrument and PLC controller, along with components such as air pumps and motors, the position of the side plates and stacking plates is adjusted in real time to ensure that the materials are stacked neatly. Workers are notified in time to pick up materials through a bell button, thus realizing automated control.
It achieves stability and neatness in material collection, adapts to the stacking requirements of materials of different sizes, and improves the efficiency and stability of material handling.
Smart Images

Figure CN224464802U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of cutting machine technology, and specifically relates to a material collection device for a cutting machine. Background Technology
[0002] Material collection is a crucial step in the production of cutting machines, primarily achieved through mechanical structures and intelligent control systems to ensure efficient and neat material handling. Common material collection devices cannot adjust to the size of the materials, leading to uneven stacking. Furthermore, workers cannot accurately assess the collection status and cannot process the collected materials promptly.
[0003] In summary, existing technologies have limitations in ensuring the stability of material collection and in adapting to the collection needs of materials of different sizes. Utility Model Content
[0004] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of the present invention, to avoid obscuring the purpose of these documents, and such simplifications or omissions should not be construed as limiting the scope of the present invention.
[0005] Therefore, the purpose of this utility model is to provide a material collection device for a cutting machine, which can solve the problems of existing technologies that cannot ensure the stability of material collection and cannot adapt to the collection needs of materials of different sizes. This utility model provides a material collection device for a cutting machine, which includes a collection box. The upper half of the side of the collection box is provided with a feeding door, and the feeding door has a matching conveyor belt. One side of the conveyor belt is located inside the collection box and connected by a rotating roller, while the other side is connected to a first motor and a first positioning block on two support legs on the outside of the collection box via a first rotating shaft. The top of the collection box is provided with a first sliding groove, and a first slider is provided on the first sliding groove. The first slider is connected to an internal side plate, and the side plate is connected to a first air pump on the outer side of the collection box via a first telescopic column. The first air pump is opposite to the side where the feeding door is located, and the side plate is adapted to the inner side of the collection box.
[0006] Optionally, the top of the side panel has a fixed protective box, inside which a laser measuring instrument is installed, with the laser measuring instrument perpendicular to the bottom surface of the collection box.
[0007] Optionally, the bottom of the collection box is provided with a bottom drive, which is vertically fixedly connected to the connecting block via a second telescopic column. A stacking plate is installed above the connecting block, and the stacking plate and the connecting block are connected by fixing bolts.
[0008] Optionally, the bottom drive includes a second positioning block fixed to one side of the bottom of the collection box, a bidirectional screw fixed to the second positioning block, one side of the bidirectional screw connected to a rotating block at the bottom of the side of the collection box, a second slider mounted on the bidirectional screw, a second fixed box connected above the second slider, a fixed groove in the middle of the second fixed box, a second air pump inside the fixed groove, and the second air pump connected to a second telescopic column.
[0009] Optionally, the inner side of the second fixing box is provided with a bell, and the top is provided with a bell button, the bell button and the fixing bolt are matched in position.
[0010] Optionally, the first air pump, the second air pump, the first motor, the ringing button, and the laser measuring instrument are all connected to the PLC controller.
[0011] Optionally, a first fixed box is provided on the outside of the first air pump.
[0012] Optionally, the collection box has a rotating door on the front, one side of which is connected to a rotating shaft, which is fixed to the collection box. The rotating door has a handle on the front, and the width of the rotating door is 2cm less than the width of the side of the collection box.
[0013] In summary, this utility model has at least one of the following beneficial effects:
[0014] (1) This utility model uses a first air pump, a second air pump, a first motor, a ringing button, a laser measuring instrument, and a PLC controller connected together. It can control the position of the side plate and the stacking plate to meet the stacking requirements of materials of different sizes. The laser measuring instrument and the ringing button ensure the normal operation of this device and guarantee the stability of the operation of this device. Attached Figure Description
[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0016] Figure 1 This is a left perspective view of a material collection device for a cutting machine according to the present invention;
[0017] Figure 2 This is a right-side perspective view of a material collection device for a cutting machine according to the present invention;
[0018] Figure 3 This is a cross-sectional view of a material collection device for a cutting machine according to the present invention;
[0019] Figure 4This is a driving structure diagram of a material collection device for a cutting machine according to the present invention;
[0020] List of reference numerals in the attached diagram: 1. Collection box; 2. First slider; 3. Rotating shaft; 4. Rotary door; 5. Bottom drive; 6. Handle; 7. First motor; 8. Support foot; 9. First positioning block; 10. First rotating shaft; 11. Conveyor belt; 12. Feed gate; 13. First chute; 14. First fixed box; 15. Rotating block; 16. Laser measuring instrument; 17. Side plate; 18. Stacking plate; 19. Connecting block; 20. Fixing bolt; 21. First air pump; 22. First telescopic column; 23. Second air pump; 24. Second telescopic column; 25. Second fixed box; 26. Second slider; 27. Bidirectional screw; 28. Fixing groove; 29. Ringing button; 30. Second positioning block. Detailed Implementation
[0021] The following is in conjunction with the appendix Figure 1-4 This utility model will be described in further detail below.
[0022] Example 1, refer to Figure 1-4 In this embodiment, the problem that the existing technology cannot ensure the stability of material collection and cannot adapt to the collection needs of materials of different sizes is addressed. This utility model discloses a material collection device for a cutting machine, including a collection box 1. The upper half of the side of the collection box 1 is provided with a feeding door 12. The feeding door 12 has a matching conveyor belt 11. One side of the conveyor belt 11 is located inside the collection box 1 and connected by a rotating roller. The other side is connected to the first motor 7 and the first positioning block 9 on the two support legs 8 through a first rotating shaft 10. The top of the collection box 1 is provided with a first sliding groove 13. The first sliding groove 13 is provided with a first slider 2. The first slider 2 is connected to the inner side plate 17. The side plate 17 is connected to the first air pump 21 on the outer side of the collection box 1 through a first telescopic column 22. The first air pump 21 is opposite to the side where the feeding door 12 is located. The side plate 17 is matched with the inner side of the collection box 1. A first fixing box 14 is provided on the outside of the first air pump 21. The front of the collection box 1 is provided with a rotating door 4. One side of the rotating door 4 is connected to a rotating shaft 3. The rotating shaft 3 is fixed on the collection box 1. The front of the rotating door 4 is provided with a handle 6. The width of the rotating door 4 is 2cm less than the width of the side of the collection box 1. The internal thickness of the collection box 1 is 2cm. The first motor 7 drives the first rotating shaft 10 to rotate, which in turn drives the conveyor belt 11 to move and transport the material into the collection box 1. The first air pump 21 drives the side plate 17 through the first telescopic column 22 to control the distance between the conveyor belt 11 and the side plate 17. This distance is the size of the material, which avoids the problem of the material not stacking neatly due to too much reserved space. The first chute 13 and the first slider 2 are set to ensure the stability of the side plate 17 while allowing the position of the side plate 17 to be observed.
[0023] The top of the side panel 17 has a fixed protective box, inside which a laser measuring instrument 16 is installed. The laser measuring instrument 16 is perpendicular to the bottom of the collection box 1. The laser measuring instrument 16 determines the degree of material stacking by measuring the distance to the top material, and provides timely feedback to avoid excessive stacking affecting the material collection effect.
[0024] A further embodiment of this application includes a bottom drive 5 at the bottom of the collection box 1. The bottom drive 5 is vertically fixedly connected to the connecting block 19 via a second telescopic column 24. A stacking plate 18 is installed above the connecting block 19, and the stacking plate 18 and the connecting block 19 are connected by fixing bolts 20. The stacking plate 18 facilitates the removal and storage of collected materials, and different stacking plates 18 can be used to accommodate the stacking requirements of materials of different sizes. The bottom drive 5 includes a second positioning block 30 fixed to one side of the bottom of the collection box 1, a bidirectional screw 27 fixed to the second positioning block 30, one side of the bidirectional screw 27 connected to a rotating block 15 at the bottom side of the collection box 1, a second slider 26 mounted on the bidirectional screw 27, and a second fixed box 25 connected above the second slider 26. The second fixed box 25 has a fixing groove 28 in the middle, and a second air pump 23 inside the fixing groove 28. The second air pump 23 is connected to the second telescopic column 24. The position of the connecting block 19 is adjusted by rotating the rotating block 15 to meet the needs of stacking small-sized materials. The second air pump 23 controls the second telescopic column 24 to move up and down, avoiding the problem of poor stacking effect and unevenness caused by too large a drop between the conveyor belt 11 and the bottom.
[0025] The inner side of the second fixed box 25 is equipped with a bell, and the top is equipped with a bell button 29, which is matched with the fixing bolt 20. When the second telescopic column 24 retracts downward to the bottom fixing bolt 20 and the bell button 29, and pressure is generated, the bell rings, and the staff can promptly remove the collected materials. The first air pump 21, the second air pump 23, the first motor 7, the bell button 29, and the laser measuring instrument 16 are all connected to the PLC controller. The laser measuring instrument 16 continuously measures the distance between the top materials and adjusts the second air pump 23, which controls the distance between the stacking plate 18 and the conveyor belt 11. When the heights are consistent, the material stacking effect will be nearly identical, thus ensuring neat material collection. When the bell button 29 is activated, it transmits data to the PLC controller, which then controls the first motor 7 to stop operating. Subsequently, the PLC controller stops working. When the stacked materials are removed and the stacking plate 18 is repositioned, the device is activated, and the PLC controller restarts, receiving data from the laser measuring instrument 16. When the data is greater than the maximum distance between the stacking plate 18 and the laser measuring instrument 16, the first air pump 21 is activated to adjust the position of the laser measuring instrument 16. When the distance is within the set range, the second air pump 23 is controlled to drive the stacking plate 18 to the preset position for subsequent operations.
[0026] Specific implementation principle: When using this utility model, first pull the handle 6, the rotating door 4 rotates around the rotating shaft 3, opening the inside of the collection box 1. Select a suitable stacking plate 18, and use the fixing bolts 20 to fix the stacking plate 18 to the connecting block 19. Then start the device, and the laser measuring instrument 16 will measure the distance. When the distance is greater than the maximum distance between the laser measuring instrument 16 and the stacking plate 18, the first air pump 21 starts, driving the first telescopic column 22 to move left and right until the distance between the laser measuring instrument 16 and the stacking plate 18 is within the preset range. Then the PLC controller starts the second air pump 23 to control the second telescopic column 24 to move up and down until the measured distance is within the preset range. The data is a preset value, namely the distance from the bottom of the conveyor belt 11 to the laser measuring instrument 16. Then, the first motor 7 is started to accumulate materials. As the materials accumulate, the laser measuring instrument 16 continuously measures the distance from the top material to the laser measuring instrument 16 to ensure the stability of the distance. As the materials accumulate, the second telescopic column 24 will retract downward. When the bottom fixing bolt 20 touches the bell button 29, the bell rings and the first motor 7 stops working. Then, the second air pump 23 starts and moves upward a certain distance before the PLC controller stops working, so that the workers can remove the stacking plate 18 and replace it with a new stacking plate 18 for the next round of work.
[0027] The above are all preferred embodiments of this utility model, and are not intended to limit the scope of protection of this utility model. Therefore, all equivalent changes made to the structure, shape and principle of this utility model should be included within the scope of protection of this utility model.
Claims
1. A cutting machine material collecting device, comprising a collecting box (1), a feeding door (12) is arranged on the side of the upper half of the collecting box (1), the feeding door (12) is matched with a conveying belt (11), characterized in that, The conveying belt (11) is connected by rotating roller on one side inside the collecting box (1), and is connected with the first motor (7) and the first positioning block (9) on the two supporting feet (8) outside the collecting box (1) through the first rotating shaft (10) on the other side, the first chute (13) is arranged on the top of the collecting box (1), the first sliding block (2) is arranged on the first chute (13), the first sliding block (2) is connected with the side plate (17) inside, the side plate (17) is connected with the first air pump (21) outside the collecting box (1) through the first telescopic column (22), the first air pump (21) is opposite to the side where the feeding door (12) is located, and the side plate (17) is matched with the inner side of the collecting box (1).
2. A material collection device for a cutting machine according to claim 1, wherein, The top of the side plate (17) is provided with a fixed protection box, and the laser measuring instrument (16) is arranged in the protection box.
3. A material collection device for a cutting machine according to claim 2, wherein, The bottom of the collecting box (1) is provided with the bottom drive (5), the bottom drive (5) is fixedly connected with the connecting block (19) through the second telescopic column (24), the connecting block (19) is provided with the stacking plate (18), and the stacking plate (18) is connected with the connecting block (19) through the fixing bolt (20).
4. A material collection device for a cutting machine according to claim 3, wherein, The bottom drive (5) comprises a second positioning block (30) fixed on one side of the bottom of the collecting box (1), a bidirectional screw rod (27) fixed on the second positioning block (30), a rotating block (15) connected with one side of the bidirectional screw rod (27) and the bottom of the side of the collecting box (1), a second sliding block (26) arranged on the bidirectional screw rod (27), a second fixed box (25) connected with the top of the second sliding block (26), a fixed groove (28) in the middle of the second fixed box (25), a second air pump (23) in the fixed groove (28), and the second air pump (23) connected with the second telescopic column (24).
5. A material collection device for a cutting machine as claimed in claim 4, wherein, The inner side of the second fixed box (25) is provided with a ringer, and the top is provided with a ringer button (29), the ringer button (29) is matched with the position of the fixing bolt (20).
6. A material collection device for a cutting machine as defined in claim 4, wherein, The first air pump (21), the second air pump (23), the first motor (7), the ringer button (29) and the laser measuring instrument (16) are connected with the PLC controller.
7. A material collection device for a cutting machine as defined in claim 1, wherein, The first air pump (21) is provided with the first fixed box (14) outside.
8. A material collection device for a cutting machine as defined in claim 1, wherein, The front of the collecting box (1) is provided with a rotating door (4), one side of the rotating door (4) is connected with a rotating shaft (3), the rotating shaft (3) is fixed on the collecting box (1), the front of the rotating door (4) is provided with a handle (6), and the width of the rotating door (4) is less than the width of the side of the collecting box (1) by 2cm.