A new rubber cutting machine
By setting up a conveyor belt and clamping assembly in the rubber cutting machine, and using elastic elements to buffer the impact force, the problem of folding caused by the slow downward sliding speed of the rubber after cutting is solved, and the rubber can be stacked and stored flat.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XIAMEN XING KE TAI ELECTRONICS CO LTD
- Filing Date
- 2025-04-10
- Publication Date
- 2026-06-09
AI Technical Summary
Existing rubber cutting machines tend to fold when the rubber slides down slowly after being cut into strips, making it difficult to move horizontally into the collection box and affecting the stacking and storage of the rubber.
By setting up a conveyor belt and clamping assembly, the cut rubber is horizontally dragged into the storage bin. The clamping assembly holds and fixes the rubber away from the cutting assembly, and the elastic element buffers the impact force to ensure that the rubber falls flat into the storage bin.
This allows for the flat stacking and storage of rubber, preventing folding during the material preparation process and improving storage efficiency.
Smart Images

Figure CN224334545U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of rubber production equipment, specifically a new type of rubber cutting machine. Background Technology
[0002] Chinese patent CN116238951A discloses an intelligent rubber sheet feeding machine, including a frame and a hopper, feeding assembly, cutting assembly, size adjustment assembly, and control assembly mounted on the frame. One end of the rubber sheet roll in the hopper is fed to the cutting assembly via the feeding assembly. The size adjustment assembly is located after the cutting assembly, and the adjustment frame is tilted downwards from the side of the cutting assembly to the other side. The control assembly includes a material detection sensor and an end size sensor. The material detection sensor detects whether rubber sheet is passing through to control the action of the feeding assembly. When the end size sensor reaches its position, it sends a cutting signal to the control assembly. The feeding assembly stops feeding, the cutting assembly moves, and the rubber sheet is cut. The cutting assembly returns to its initial position, and the cut rubber sheet falls naturally. This invention is simple to use; cutting one piece of rubber sheet takes only 11 seconds, equivalent to the workload of two people for 6.5 days, solving the problem of this process. In existing technology, after rubber cutting machines cut rubber into strips, most of the rubber slides into the collection box through an inclined feeding ramp. However, when the rubber slides down slowly, the strip rubber does not slide off the ramp quickly enough and is prone to folding, which is not conducive to the rubber moving horizontally into the collection box.
[0003] Based on this, a new type of rubber cutting machine was designed to solve the problem. Utility Model Content
[0004] The purpose of this utility model is to provide a new type of rubber cutting machine to solve the above-mentioned technical problems.
[0005] To achieve the above objectives, the utility model provides the following technical solution: a novel rubber cutting machine, which uses a conveyor belt extending into the cutting assembly to move the rubber that has been cut and processed inside the cutting assembly out of the cutting assembly. The unloading assembly matches the end of the conveyor belt away from the cutting assembly, and drags the rubber moving along the conveyor belt horizontally into the storage bin, so that multiple sets of rubber can be stacked in the storage bin.
[0006] By adopting the above technical solution, the first telescopic component drives the clamping component to move back and forth along the first guide rail, which facilitates dragging the rubber moving along the conveyor belt out of the conveyor belt, so that the rubber falls into the storage box sequentially from the end near the cutting component to the end away from the cutting component, avoiding the rubber from folding when it is moved into the storage box, which is not conducive to the stacking and storage of multiple sets of rubber.
[0007] By adopting the above technical solution, the clamping plate in the fixture assembly is driven by the first cylinder to move towards the substrate, which facilitates the clamping plate and the substrate to abut and match each other, clamping and fixing the end of the rubber away from the cutting component. This is beneficial for moving the rubber away from the conveyor belt.
[0008] By adopting the above technical solution, the first elastic element can be made of a spring. Both ends of the first elastic element abut against the abutment plate and the support frame, respectively. When the clamping assembly moves away from the cutting assembly, the abutment plate first abuts against the inner wall of the mounting frame. As the clamping assembly continues to move, it compresses the first elastic element, causing it to deform. This elastic deformation absorbs and mitigates the impact force generated during the movement of the clamping assembly, preventing the clamping assembly from directly colliding with the end face of the inner wall of the mounting frame during its movement.
[0009] By adopting the above technical solution, a first limiting block and a first limiting hole are provided between the abutment plate and the inner wall of the mounting frame, which are mutually inserted and matched. The first limiting block and the first limiting hole are mutually matched to limit and position the abutment plate and the inner wall of the mounting frame, which helps to ensure that the position of the abutment plate remains fixed when the first elastic element is squeezed, and will not slide or shift with it.
[0010] By adopting the above technical solution, a push plate is also provided on the side of the slide rod away from the abutment plate. When the abutment plate and the inner wall of the mounting frame abut against each other and match, and the clamp assembly is still moving away from the cutting assembly, the slide rod passes through the support frame and slides towards the cutting assembly, driving the push plate on the side of the slide rod away from the abutment plate to slide along the upper side of the base plate in the clamp assembly. This helps to push the rubber on the base plate away from the base plate, so that the rubber and the clamp assembly are separated from each other.
[0011] By adopting the above technical solution, the second telescopic component drives the support plate to slide along the second guide rail and extend into the lower side of the conveyor belt. When the rubber is driven away from the conveyor belt by the clamping component, it falls onto the support plate. The rubber continues to move on the support plate by the clamping component. When the rubber paper projection matches the storage box, the clamping component stops moving, and the support plate moves away from the rubber and the clamping component, which helps the rubber fall into the storage box. When the side of the rubber away from the clamping component falls into the storage box, the clamping component releases the clamp and continues to move away from the cutting component, so that the end of the rubber that matches the clamping component also falls into the storage box.
[0012] By adopting the above technical solution, by setting a first limiting plate at one end of the conveyor belt near the feeding component, and by using the first limiting plate to abut and match with the feeding component, it is beneficial to limit the distance the feeding component moves toward the cutting component.
[0013] Compared with the prior art, the beneficial effects of this utility model are as follows: This utility model sets a feeding component between the discharge end of the cutting component and the storage box. The clamping component in the feeding component clamps and fixes the end of the strip rubber away from the cutting component, and drags the rubber horizontally onto the support plate. When the projection of the rubber paper matches the storage box, the support plate is retracted, and the rubber falls horizontally into the storage box. Finally, the clamping component is released and separates from the rubber, and the end of the rubber away from the cutting component falls into the storage box, thereby achieving the purpose of making the rubber flatly stacked in the storage box. Attached Figure Description
[0014] To more clearly illustrate the technical solutions of the utility model embodiments, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0016] Figure 2 This is a cross-sectional view of the overall structure of this utility model.
[0017] The attached diagram lists the components represented by each number as follows:
[0018] 1-Cutting assembly, 2-Conveyor belt, 21-First limiting plate, 3-Unloading assembly, 31-Mounting frame, 32-First guide rail, 33-First telescopic assembly, 34-Second guide rail, 35-Support plate, 36-Second telescopic assembly, 4-Storage bin, 5-Clamping assembly, 51-Base plate, 52-Clamping plate, 53-Support frame, 54-First cylinder, 6-Buffer assembly, 61-Abutting plate, 62-Slide rod, 63-First elastic element, 64-First limiting block, 65-First limiting hole, 66-Push plate. Detailed Implementation
[0019] The technical solutions of the utility model embodiments will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the utility model, and not all embodiments. Based on the embodiments of the utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the utility model.
[0020] Combination Figure 1-2 :
[0021] Reference Figure 1As shown, a novel rubber cutting machine includes a cutting assembly 1, which is an electrically driven rubber cutter. A conveyor belt 2 is located at the output end of the cutting assembly 1. One side of the conveyor belt 2 extends into the cutting assembly 1 through the output end. A drive motor at the end of the conveyor belt 2 drives its upper side to move away from the cutting assembly 1. A feeding assembly 3 is located on the side of the conveyor belt 2 away from the cutting assembly 1, and a storage box 4 is located below the feeding assembly 3. The feeding assembly 3 is used to move the rubber moving along the conveyor belt 2 into the storage box 4. By setting a conveyor belt extending into the cutting assembly, the rubber that has been cut and processed inside the cutting assembly is moved out of the cutting assembly. The feeding assembly matches the end of the conveyor belt away from the cutting assembly, dragging the rubber moving along the conveyor belt horizontally into the storage box, facilitating the stacking of multiple sets of rubber in the storage box.
[0022] Reference Figure 1 , 2As shown, the unloading assembly 3 includes a mounting frame 31 and a clamping assembly 5. The mounting frame 31 is located at the end of the conveyor belt 2 away from the cutting assembly 1. The mounting frame 31 has a first guide rail 32 for the clamping assembly 5 to slide. The first guide rail 32 has a first telescopic assembly 33 at the end away from the cutting assembly 1. The first telescopic assembly 33 is an electric telescopic rod. The end of the first telescopic assembly 33 away from the cutting assembly 1 is connected to the inner wall of the first guide rail 32. The end of the first telescopic assembly 33 near the cutting assembly 1 is connected to the clamping assembly 5. The storage box 4 is located at the bottom of the mounting frame 31 at the end away from the cutting assembly 1. The clamping assembly 5 includes a base plate 51 and a clamping plate 52. The base plate 51 has a support frame 53 on the side away from the cutting assembly 1. The support frame 53 has a first cylinder 54 on the side near the cutting assembly 1. The output end of the first cylinder 54 is facing the base plate 51. The clamping plate 52 is located at the output end of the first cylinder 54. The clamping plate 52 is driven by the first cylinder 54 to move towards the base plate 51. The clamping plate 52 and the base plate 51 abut against each other. A buffer assembly 6 is provided on the side of the support frame 53 away from the first cylinder 54. The buffer assembly 6 includes an abutment plate 61 and a slide rod 62. The slide rod 62 is slidably connected to the support frame 53. The abutment plate 61 is located at the end of the slide rod 62 away from the cutting component 1. A first elastic element 63 is slidably sleeved on the side of the slide rod 62 away from the cutting component 1. One side of the first elastic element 63 abuts against the support frame 53, and the other side of the first elastic element 63 abuts against the abutment plate 61. The side of the abutment plate 61 away from the slide rod 62 abuts against the inner wall of the mounting frame 31 away from the cutting component 1. A first limiting block 64 is provided on the side of the abutment plate 61 away from the slide rod 62. A first limiting hole 65 is provided on the inner wall of the mounting frame 31 away from the cutting component 1 for the first limiting block 64 to insert into. The abutment plate 61 and the inner wall of the mounting frame 31 are positioned by the insertion and matching of the first limiting block 64 and the first limiting hole 65. The first telescopic component drives the clamping component to reciprocate along the first guide rail, facilitating the removal of the rubber moving along the conveyor belt. This allows the rubber to fall sequentially from the end closest to the cutting component to the end furthest from it into the storage bin, preventing folding during entry and avoiding the stacking of multiple rubber units. The clamping plate in the clamping component is driven by the first cylinder to move towards the substrate, facilitating contact and clamping of the rubber furthest from the cutting component. This also helps to remove the rubber from the conveyor belt. The first elastic element can be made of a spring. Both ends of the first elastic element abut against the abutment plate and the support frame, respectively. When the clamping component moves away from the cutting component, the abutment plate first abuts against the inner wall of the mounting frame. As the clamping component continues to move, it compresses the first elastic element, causing deformation. This elastic deformation absorbs and mitigates the impact force generated during the movement of the clamping component, preventing direct collision between the clamping component and the inner wall of the mounting frame.A first limiting block and a first limiting hole are provided between the abutment plate and the inner wall of the mounting frame. The abutment plate and the inner wall of the mounting frame are matched and mutually inserted. The abutment plate and the inner wall of the mounting frame are restricted and positioned by the matching of the first limiting block and the first limiting hole. This helps to ensure that the position of the abutment plate remains fixed when the first elastic element is squeezed and will not slide or shift with it.
[0023] Reference Figure 1 , 2 As shown, a push plate 66 is provided on the side of the slide rod 62 near the cutting assembly 1. The push plate 66 is driven by the slide rod 62 to move along the upper side of the substrate 51 toward the cutting assembly 1. A push plate is also provided on the side of the slide rod away from the abutment plate. When the abutment plate abuts and matches with the inner wall of the mounting frame, and the clamping assembly is still moving away from the cutting assembly, the slide rod slides through the support frame toward the cutting assembly, driving the push plate on the side of the slide rod away from the abutment plate to slide along the upper side of the substrate in the clamping assembly. This helps to push the rubber on the substrate away from the substrate, so that the rubber is separated from the clamping assembly.
[0024] Reference Figure 1 , 2 As shown, the mounting bracket 31 extends into the lower side of the conveyor belt 2 near the cutting component 1. The mounting bracket 31 is provided with a second guide rail 34, which is located below the first guide rail 32 and extends into the lower side of the conveyor belt 2. A support plate 35 is slidably provided inside the second guide rail 34. The support plate 35 is used to support the rubber. A second telescopic component 36 is provided between the support plate 35 and the inner wall end face of the second guide rail 34. The second telescopic component 36 is made of an electric telescopic rod. The two ends of the second telescopic component 36 are fixedly connected to the support plate 35 and the inner wall end face of the second guide rail 34, respectively. The second telescopic component drives the support plate to slide along the second guide rail and extend into the lower side of the conveyor belt. When the rubber is driven away from the conveyor belt by the clamping component, it falls onto the support plate. The rubber continues to move on the support plate by the clamping component. When the rubber paper projection matches the storage box, the clamping component stops moving, and the support plate moves away from the rubber and the clamping component, which helps the rubber fall into the storage box. When the side of the rubber away from the clamping component falls into the storage box, the clamping component releases the clamp and continues to move away from the cutting component, so that the end of the rubber that matches the clamping component also falls into the storage box.
[0025] Reference Figure 1 , 2As shown, a first limiting plate 21 is provided on the side of the conveyor belt 2 near the unloading component 3. The first limiting plate 21 is groove-shaped, with the groove facing the direction of the conveyor belt 2. The side of the first limiting plate 21 away from the cutting component 1 abuts against the unloading component 3. By providing a first limiting plate at the end of the conveyor belt near the unloading component, and utilizing the abutment and matching between the first limiting plate and the unloading component, it is beneficial to limit the movement distance of the unloading component towards the cutting component.
[0026] Specific application examples of this utility model:
[0027] By setting up a conveyor belt that extends into the cutting assembly, the rubber that has been cut and processed inside the cutting assembly is moved out of the cutting assembly. The unloading assembly matches the end of the conveyor belt away from the cutting assembly, and the rubber that moves along the conveyor belt is dragged horizontally into the storage bin, which facilitates the stacking of multiple sets of rubber in the storage bin.
[0028] The first telescopic component drives the clamping component to reciprocate along the first guide rail, which facilitates dragging the rubber moving along the conveyor belt out of the conveyor belt, so that the rubber falls into the storage box sequentially from the end near the cutting component to the end away from the cutting component, avoiding the rubber from folding when moving into the storage box, which is not conducive to the stacking and storage of multiple sets of rubber.
[0029] In the clamping assembly, the clamping plate is driven by the first cylinder to move towards the substrate, facilitating the clamping plate and the substrate to abut and match, clamping and fixing the end of the rubber away from the cutting component. This also helps to move the rubber away from the conveyor belt.
[0030] The first elastic element can be made of a spring. Both ends of the first elastic element abut against the abutment plate and the support frame, respectively. When the clamping assembly moves away from the cutting assembly, the abutment plate first abuts against the inner wall of the mounting frame. As the clamping assembly continues to move, it squeezes the first elastic element to deform. The elastic deformation absorbs and mitigates the impact force generated during the movement of the clamping assembly, thus preventing the clamping assembly from directly colliding with the end face of the inner wall of the mounting frame during the movement.
[0031] A first limiting block and a first limiting hole are provided between the abutment plate and the inner wall of the mounting frame. The abutment plate and the inner wall of the mounting frame are matched and mutually inserted. The abutment plate and the inner wall of the mounting frame are restricted and positioned by the matching of the first limiting block and the first limiting hole. This helps to ensure that the position of the abutment plate remains fixed when the first elastic element is squeezed and will not slide or shift with it.
[0032] A push plate is also provided on the side of the slide bar away from the abutment plate. When the abutment plate and the inner wall of the mounting frame abut against each other and match, and the clamp assembly is still moving away from the cutting assembly, the slide bar passes through the support frame and slides towards the cutting assembly. This drives the push plate on the side of the slide bar away from the abutment plate to slide along the upper side of the base plate in the clamp assembly. This helps to push the rubber on the base plate away from the base plate, so that the rubber and the clamp assembly are separated from each other.
[0033] The second telescopic component drives the support plate to slide along the second guide rail and extend into the lower side of the conveyor belt. When the rubber is driven away from the conveyor belt by the clamping component, it falls onto the support plate. The rubber continues to move on the support plate by the clamping component. When the rubber paper projection matches the storage box, the clamping component stops moving, and the support plate moves away from the rubber and the clamping component, which helps the rubber fall into the storage box. When the side of the rubber away from the clamping component falls into the storage box, the clamping component releases the clamp and continues to move away from the cutting component, so that the end of the rubber that matches the clamping component also falls into the storage box.
[0034] By setting a first limiting plate at one end of the conveyor belt near the unloading component, and using the first limiting plate to abut and match the unloading component, it is beneficial to limit the distance the unloading component moves toward the cutting component.
[0035] In the description of the utility model, it should be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "side", "top", "inner", "front", "center", "both ends", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings. They are only for the convenience of describing the utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on the utility model.
[0036] In utility models, unless otherwise explicitly specified and limited, the terms "installation," "setting," "connection," "fixing," and "screw-on" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal connection of two components or the interaction between two components. Unless otherwise explicitly limited, those skilled in the art can understand the specific meaning of the above terms in the utility model according to the specific circumstances.
[0037] Although embodiments of the utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A novel rubber cutting machine, comprising a cutting assembly (1), characterized in that: The cutting assembly (1) is an electric drive rubber cutter. The output end of the cutting assembly (1) is provided with a conveyor belt (2). One side of the conveyor belt (2) extends into the cutting assembly (1) through the output end of the cutting assembly (1). The upper side of the conveyor belt (2) is driven by a drive motor at the end to move away from the cutting assembly (1). The side of the conveyor belt (2) away from the cutting assembly (1) is provided with a feeding assembly (3). The lower side of the feeding assembly (3) is provided with a storage box (4). The feeding assembly (3) is used to move the rubber moving along the conveyor belt (2) into the storage box (4).
2. The novel rubber cutting machine according to claim 1, characterized in that: The feeding assembly (3) includes a mounting frame (31) and a clamping assembly (5). The mounting frame (31) is located at the end of the conveyor belt (2) away from the cutting assembly (1). The mounting frame (31) is provided with a first guide rail (32) for the clamping assembly (5) to slide. The first guide rail (32) is provided with a first telescopic assembly (33) at the end away from the cutting assembly (1). The first telescopic assembly (33) is an electric telescopic rod. The end of the first telescopic assembly (33) away from the cutting assembly (1) is connected to the inner wall end face of the first guide rail (32). The end of the first telescopic assembly (33) close to the cutting assembly (1) is connected to the clamping assembly (5). The storage box (4) is located at the bottom of the mounting frame (31) at the end away from the cutting assembly (1).
3. The novel rubber cutting machine according to claim 2, characterized in that: The clamping assembly (5) includes a base plate (51) and a clamping plate (52). A support frame (53) is provided on the side of the base plate (51) away from the cutting assembly (1). A first cylinder (54) is provided on the support frame (53) near the cutting assembly (1). The output end of the first cylinder (54) is arranged towards the base plate (51). The clamping plate (52) is located at the output end of the first cylinder (54). The clamping plate (52) is driven by the first cylinder (54) to move towards the base plate (51). The clamping plate (52) and the base plate (51) abut against each other.
4. A novel rubber cutting machine according to claim 3, characterized in that: The support frame (53) has a buffer assembly (6) on the side away from the first cylinder (54). The buffer assembly (6) includes an abutment plate (61) and a slide rod (62). The slide rod (62) is slidably connected to the support frame (53). The abutment plate (61) is located at the end of the slide rod (62) away from the cutting assembly (1). A first elastic element (63) is slidably sleeved on the side of the slide rod (62) away from the cutting assembly (1). One side of the first elastic element (63) abuts against the support frame (53), and the other side of the first elastic element (63) abuts against the abutment plate (61). The side of the abutment plate (61) away from the slide rod (62) abuts against the inner wall of the mounting frame (31) away from the cutting assembly (1).
5. A novel rubber cutting machine according to claim 4, characterized in that: The abutment plate (61) is provided with a first limiting block (64) on the side away from the slide rod (62), and the mounting bracket (31) is provided with a first limiting hole (65) on the inner wall of the side away from the cutting component (1) for the first limiting block (64) to be inserted. The abutment plate (61) and the inner wall of the mounting bracket (31) are positioned to abut against each other by the mutual insertion and matching of the first limiting block (64) and the first limiting hole (65).
6. A novel rubber cutting machine according to claim 4, characterized in that: The slide bar (62) is provided with a push plate (66) on the side near the cutting assembly (1). The push plate (66) is driven by the slide bar (62) to move along the upper side of the substrate (51) toward the cutting assembly (1).
7. A novel rubber cutting machine according to claim 2, characterized in that: The mounting bracket (31) extends into the lower side of the conveyor belt (2) near the cutting component (1). A second guide rail (34) is provided inside the mounting bracket (31). The second guide rail (34) is located below the first guide rail (32) and extends into the lower side of the conveyor belt (2). A support plate (35) is slidably provided inside the second guide rail (34). The support plate (35) is used to support the rubber. A second telescopic component (36) is provided between the support plate (35) and the inner wall end face of the second guide rail (34). The second telescopic component (36) is made of an electric telescopic rod. The two ends of the second telescopic component (36) are fixedly connected to the support plate (35) and the inner wall end face of the second guide rail (34), respectively.
8. A novel rubber cutting machine according to claim 1, characterized in that: The conveyor belt (2) is provided with a first limiting plate (21) on the side near the unloading component (3). The first limiting plate (21) is groove-shaped and the groove of the first limiting plate (21) is oriented towards the conveyor belt (2). The side of the first limiting plate (21) away from the cutting component (1) abuts against the unloading component (3).