A kind of edge cutting equipment for wooden door processing

Abstract

The application relates to the cutting field and discloses a trimming equipment for wood door processing, which comprises a processing plate, a conveying assembly arranged on the processing plate, a bearing assembly for bearing wood doors arranged on the conveying assembly, a cutting assembly arranged on the processing plate, a rotating assembly arranged on the processing plate, a clamping assembly matched with the rotating assembly arranged at the output end of the cutting assembly, a driving assembly arranged on the processing plate and a pushing assembly arranged on the processing plate. The trimming equipment can realize multiple working modes, combines normal working mode, not completely locked working mode and completely locked working mode, effectively simulates the operation of workers, can adapt to automatic operation under abnormal conditions, realizes intelligent unmanned operation, improves the safety of workers, timely responds to abnormal conditions, avoids equipment damage, is beneficial to smooth trimming of wood doors, improves production continuity and improves the processing efficiency of wood doors.

Description

Technical Field

[0001] This invention relates to the field of cutting technology, and more particularly to a cutting device for processing wooden doors. Background Technology

[0002] Wooden door processing refers to the process of turning logs or engineered wood into finished door panels that meet design requirements and functional needs through a series of processes. This process typically includes multiple steps such as material selection, drying, cutting, planing, splicing, milling, sanding, and painting. The aim is to ensure that the wooden door meets standards in terms of structural stability, aesthetic appearance, and durability. Modern wooden door processing often combines mechanization with manual craftsmanship, which improves production efficiency while preserving the natural texture and feel of the wood. Depending on the intended use, wooden doors can also undergo special treatments such as fireproofing, moisture resistance, and sound insulation to meet the diverse needs of residential, engineering, or commercial spaces. During the wooden door processing, edge trimming is required.

[0003] In the wood door processing, workers typically manually push the door into a rotating cutter for edge trimming. However, when hard areas like knots exist, the cutter struggles to cut smoothly. If the operator fails to notice this and continues to force it in, the cutter can easily break due to overload. The shattered blades can then fly at high speed, potentially causing serious injury to workers operating nearby. Furthermore, this method, relying on manual judgment and intervention, cannot simulate the operator's experience or achieve intelligent, unmanned operation. It not only carries high safety risks but also easily damages equipment, reducing worker safety and hindering successful edge trimming. This affects production continuity and reduces the processing efficiency of wooden doors. For example, in the existing patent CN219485946U, a cutting device for wooden door production is disclosed. The upper end of the two support plates is provided with a size adjustment component, and a scale is provided on one side of the processing table. The lower and upper flat conveyor belts are provided on the rear side of the through groove and on the table surface, which realizes fixed-length cutting. At the same time, the wooden door can be evenly driven by the upper, lower and vertical flat conveyor belts, achieving a good cutting effect. This solution can achieve the effect of cutting the edges of wooden doors, but it still cannot achieve the problem of intelligent unmanned operation mode.

[0004] Therefore, how to provide an edge-cutting device for wooden door processing is a problem that urgently needs to be solved by those skilled in the art. Summary of the Invention

[0005] One object of the present invention is to provide a trimming device for wooden door processing. The trimming device of the present invention includes a processing plate, a conveying assembly on the processing plate, a carrying assembly for carrying the wooden door on the conveying assembly, a cutting assembly on the processing plate, a rotating assembly on the processing plate, an output end of the cutting assembly connected to the rotating assembly, a driving assembly on the processing plate, a pushing assembly on the processing plate, a connecting assembly adapted to the driving assembly and the conveying assembly on the pushing assembly, and a transmission assembly between the connecting assembly and the rotating assembly. During normal door advancement, the cutting assembly rotates to control the rotating assembly in a first state, and the conveying assembly conveys the wooden door through the rotating assembly and the transmission assembly. In an abnormal state, when the cutting assembly encounters resistance, the rotating assembly is in a second state, the conveying assembly stops conveying the wooden door, and the cutting assembly continues to cut the abnormal position of the wooden door.

[0006] Preferably, the conveying assembly includes a threaded rod connected to the processing plate by a bearing, a sliding block connected to the threaded rod, the threaded rod threaded through the sliding block, and the sliding block penetrating the processing plate.

[0007] Preferably, the bearing component includes a bearing plate disposed on the sliding block, a limit block disposed on the bearing plate, a hydraulic push rod disposed on the bearing plate, and an abutment block disposed at the output end of the hydraulic push rod. The limit block and the abutment block approach each other to form a clamping effect on the wooden door.

[0008] Preferably, the cutting assembly includes a cutting motor mounted on the processing plate, a rotating rod connected to a bearing on the processing plate, the rotating rod being connected to the output shaft of the cutting motor, and a cutting blade being fixedly sleeved on the rotating rod.

[0009] Preferably, the rotating assembly includes a rotating rod connected to the processing plate by a bearing, and a torque limiter connected to the rotating rod is provided on the rotating rod.

[0010] Preferably, when the torque limiter is normal, the rotating rod rotates along with the rotating rod; when the torque limiter is overloaded, the rotating rod does not rotate.

[0011] Preferably, the drive assembly includes a drive motor mounted on the processing plate, the output shaft of the drive motor is connected to a rotating cylinder, and the rotating cylinder has a friction groove inside.

[0012] Preferably, the pushing assembly includes an electric push rod disposed on the processing plate, and the output end of the electric push rod is provided with a push plate.

[0013] Preferably, the connecting assembly includes a connecting rod that is connected to the push plate by a bearing, a square rod at one end of the connecting rod that is inserted into the threaded rod, and a friction protrusion at the other end of the connecting rod that is adapted to the friction groove.

[0014] Preferably, the transmission assembly includes a driving bevel gear fixedly sleeved on the rotating rod, and a driven bevel gear meshing with the driving bevel gear is fixedly sleeved on the connecting rod.

[0015] The beneficial effects of this invention are as follows: This invention utilizes a load-bearing component to clamp the wooden door, activating the cutting component. The high-speed rotation of the cutting component drives a rotating component to form a unified structure, forcing the rotating component to rotate, which in turn drives a transmission component, which in turn drives a connecting component, which in turn drives a conveying component. The conveying component then propels the wooden door forward, allowing the cutting component to cut the continuously advancing door, achieving normal door advancement and edge trimming. In an abnormal state, when the cutting component is not completely locked (e.g., with small knots), although the cutting component can still rotate and cut, its cutting speed decreases, causing the rotating component to stop rotating. This reduces the load on the cutting component, increasing its cutting capacity, allowing it to forcefully cut the wooden door, removing smaller knots. After cutting, the cutting component returns to its normal speed, and the rotating component resumes rotation, repeating the normal process, allowing the cutting component to continue trimming the advancing door. In an abnormal state, when the cutting component is completely locked (e.g., with large knots), the cutting component cannot rotate, or may even stop completely. First, the cutting component is stopped, and the pushing component is started. This causes the pushing component to drive the connecting component to move, which in turn causes the connecting component to separate from the transmission component. The connecting component then connects with the drive component. The drive component is then started, causing the connecting component to rotate, which forces the conveying component to drive the carrying component back. This causes the wooden door on the carrying component to retract from the cutting component. The cutting component is then restarted, and the drive component is started in reverse, forcing the wooden door to move forward again. The cutting component repeatedly cuts the larger knots on the wooden door until the knots are completely severed. By controlling the pushing component, the transmission component is forced to engage, and the connecting component is separated from the drive component, allowing the system to return to normal operation. In summary, the edge-cutting device for wooden door processing disclosed in this application can achieve multiple working modes, combining normal working mode, incomplete locking working mode, and fully locked working mode. This not only effectively simulates human operation but also adapts to automatic operation under abnormal conditions, achieving intelligent unmanned operation, improving human safety, responding promptly to abnormal situations, avoiding equipment damage, facilitating smooth edge cutting of wooden doors, improving production continuity, and increasing the processing efficiency of wooden doors. Attached Figure Description

[0016] The accompanying drawings are provided to further illustrate the invention and form part of the specification. They are used in conjunction with embodiments of the invention to explain the invention and do not constitute a limitation thereof. In the drawings: Figure 1 This is a three-dimensional structural diagram of the present invention; Figure 2 This is a three-dimensional structural entity diagram of the present invention from another perspective; Figure 3 For the present invention Figure 1 Side view; Figure 4 This is a structural entity diagram of the load-bearing component of the present invention; Figure 5 This is a partial structural diagram of the present invention; Figure 6 This is a diagram showing the connection relationship between the rotating component and the snap-fit ​​component of the present invention; Figure 7 This is a connection diagram of the conveying component, driving component, and connecting component of the present invention; Figure 8 This is a structural entity diagram of the driving component of the present invention; Figure 9 This is a diagram showing the connection relationship between the driving component and the connecting component of the present invention.

[0017] In the diagram: 1. Processing plate; 2. Conveying assembly; 201. Threaded rod; 202. Sliding block; 3. Bearing assembly; 301. Bearing plate; 302. Limiting block; 303. Hydraulic push rod; 304. Contact block; 4. Cutting assembly; 401. Cutting motor; 402. Rotating rod; 403. Cutting blade; 5. Rotating assembly; 501. Rotating rod; 502. Torque limiter; 7. Drive assembly; 701. Drive motor; 702. Rotating cylinder; 703. Friction groove; 8. Pushing assembly; 801. Electric push rod; 802. Pushing plate; 9. Connecting assembly; 901. Connecting rod; 902. Square rod; 903. Friction protrusion; 10. Transmission assembly; 1001. Driving bevel gear; 1002. Driven bevel gear. Detailed Implementation

[0018] The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic diagrams, illustrating only the basic structure of the invention, and therefore only show the components relevant to the invention.

[0019] Example 1: like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7, Figure 8 and Figure 9 As shown, the present invention provides a trimming device for processing wooden doors, comprising a processing plate 1, which serves as a support component. A conveying assembly 2 is mounted on the processing plate 1 to transport the wooden door forward. A supporting assembly 3 is mounted on the conveying assembly 2 to support and clamp the wooden door. A cutting assembly 4 is mounted on the processing plate 1 for cutting. A rotating assembly 5 is mounted on the processing plate 1 for transmission. The output end of the cutting assembly 4 is connected to the rotating assembly 5. A driving assembly 7 is mounted on the processing plate 1 as a driving source. A pushing assembly 8 is mounted on the processing plate 1. The push component 8 drives the connecting component 9 to move back and forth. The push component 8 is equipped with a connecting component 9 that is compatible with the drive component 7 and the conveying component 2. The connecting component 9 serves as a connection. A transmission component 10 is provided between the connecting component 9 and the rotating component 5. The transmission component 10 has a transmission function. When the wooden door is being pushed normally, the rotation of the cutting component 4 controls the rotating component 5 to be in the first state. The rotating component 5 and the transmission component 10 control the conveying component 2 to convey the wooden door. In an abnormal state, the cutting component 4 encounters resistance, the rotating component 5 is in the second state, the conveying component 2 stops conveying the wooden door, and the cutting component 4 continues to cut the abnormal position of the wooden door.

[0020] Working principle: The load-bearing component 3 clamps the wooden door, and the cutting component 4 is activated. The high-speed rotation of the cutting component 4 drives the rotating component 5 to form a whole, forcing the rotating component 5 to rotate, which in turn drives the transmission component 10 to rotate. The transmission component 10 drives the connecting component 9 to rotate, which in turn drives the conveying component 2 to rotate. The conveying component 2 drives the wooden door forward, allowing the cutting component 4 to cut the continuously advancing wooden door, achieving normal door advancement and edge trimming. In abnormal conditions, and when the cutting component 4 is not completely locked, such as when the knots are small, although the cutting component 4 can... The cutting assembly 4 rotates and cuts, but the cutting speed of the cutting component 4 decreases, causing the rotating component 5 to stop rotating. This forces a reduction in the load on the cutting component 4, increasing its cutting capacity. The cutting component 4 then powerfully cuts the wooden door, removing smaller knots. After cutting, the cutting component 4 returns to its normal speed, and the rotating component 5 restarts its rotation, repeating the normal process. This allows the cutting component 4 to continue cutting the edges of the advancing wooden door. In abnormal conditions, especially when the cutting component 4 completely seizes up (e.g., with large knots), the cutting component 4 may become unable to rotate or even stop completely. When the phenomenon occurs, first stop the cutting assembly 4, start the pushing assembly 8, causing the pushing assembly 8 to drive the connecting assembly 9 to move, causing the connecting assembly 9 to separate from the transmission assembly 10, and the connecting assembly 9 to connect with the drive assembly 7. Start the drive assembly 7, which drives the connecting assembly 9 to rotate, forcing the conveying assembly 2 to drive the carrying assembly 3 to retract, causing the wooden door on the carrying assembly 3 to retract from the cutting assembly 4. Restart the cutting assembly 4, and at the same time start the drive assembly 7 in reverse, forcing the wooden door to advance again. The cutting assembly 4 repeatedly cuts the larger knots of the wooden door until the knots are completely cut off. This is achieved by controlling the pushing assembly 4. Component 8 forces the transmission component 10 to engage and causes the connecting component 9 to separate from the drive component 7, and the system returns to normal operation. In summary, the edge-cutting device for wooden door processing of this application can realize multiple working modes, combining normal working mode, incomplete locking working mode and complete locking working mode. It can not only effectively simulate the operation of the operator, but also adapt to the automatic operation under abnormal conditions, realize intelligent unmanned operation, improve the safety of the operator, respond to abnormal situations in a timely manner, avoid damage to the equipment, facilitate the smooth edge cutting of wooden doors, improve production continuity, and improve the processing efficiency of wooden doors.

[0021] Example 2: like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9As shown, the present invention provides a cutting device for processing wooden doors. The conveying component 2 includes a threaded rod 201 connected to the processing plate 1 by a bearing. The threaded rod 201 can engage with a sliding block 202 and can adjust the position of the sliding block 202. The sliding block 202 is connected to the threaded rod 201, and the threaded rod 201 threaded through the sliding block 202. The sliding block 202 passes through the processing plate 1.

[0022] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, the present invention provides a cutting device for processing wooden doors. The supporting component 3 includes a supporting plate 301 disposed on a sliding block 202. The supporting plate 301 is slidably disposed on the processing plate 1. Rollers can be installed on the supporting plate 301 to reduce friction. A limiting block 302 is disposed on the supporting plate 301 and is fixedly disposed on the supporting plate 301. A hydraulic push rod 303 is disposed on the supporting plate 301 and is fixedly disposed on the supporting plate 301. The hydraulic push rod 303 is existing technology. An abutment block 304 is disposed at the output end of the hydraulic push rod 303 and is fixedly disposed at the output end of the hydraulic push rod 303. The limiting block 302 and the abutment block 304 approach each other to form a clamping effect on the wooden door.

[0023] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, the present invention provides a cutting device for processing wooden doors. The cutting assembly 4 includes a cutting motor 401 mounted on a processing plate 1. The cutting motor 401 is fixedly mounted on the processing plate 1 and is a prior art device. A rotating rod 402 is connected to a bearing on the processing plate 1. The rotating rod 402 has a certain length and is connected to the output shaft of the cutting motor 401. A cutting blade 403 is fixedly sleeved on the rotating rod 402 and is a prior art device used for cutting wooden doors.

[0024] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9As shown, the present invention provides a cutting device for processing wooden doors. The rotating assembly 5 includes a rotating rod 501 with a bearing connected to the processing plate 1. The rotating rod 501 is arranged along the length direction of the rotating rod 402. A torque limiter 502 connected to the rotating rod 402 is provided on the rotating rod 501. The torque limiter 502 is prior art. The rotating rod 501 is connected to the internal structure of the torque limiter 502. When an overload occurs, the torque limiter 502 will disconnect.

[0025] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, in a cutting device for wooden door processing according to the present invention, when the torque limiter 502 is normal, the rotating rod 501 rotates with the rotating rod 402; when the torque limiter 502 is overloaded, the rotating rod 501 does not rotate.

[0026] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, the present invention provides a cutting device for processing wooden doors. The drive assembly 7 includes a drive motor 701 mounted on a processing plate 1. The drive motor 701 is fixedly mounted on the processing plate 1. The drive motor 701 is a prior art device. The output shaft of the drive motor 701 is connected to a rotating cylinder 702. The rotating cylinder 702 is fixedly connected to the output shaft of the drive motor 701. A friction groove 703 is provided inside the rotating cylinder 702. The inner wall of the friction groove 703 has friction properties.

[0027] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, the present invention provides a cutting device for processing wooden doors. The pushing component 8 includes an electric push rod 801 disposed on the processing plate 1. The electric push rod 801 is fixedly installed on the processing plate 1. The electric push rod 801 is the prior art. A pushing plate 802 is disposed at the output end of the electric push rod 801. The pushing plate 802 is disposed horizontally and is fixedly connected to the output end of the electric push rod 801.

[0028] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, the present invention provides a trimming device for wooden door processing. The connecting assembly 9 includes a connecting rod 901 that is connected to a push plate 802 by a bearing. The connecting rod 901 is arranged along the length direction of the threaded rod 201. A square rod 902 is provided at one end of the connecting rod 901. The square rod 902 is fixedly arranged on the connecting rod 901 and is always connected to the threaded rod 201. The square rod 902 is inserted into the threaded rod 201. A friction protrusion 903 that is adapted to the friction groove 703 is provided at the other end of the connecting rod 901. The friction protrusion 903 and the friction groove 703 are connected by friction through friction. The friction protrusion 903 is fixedly arranged on the connecting rod 901.

[0029] like Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, the present invention provides a cutting device for processing wooden doors. The transmission assembly 10 includes a driving bevel gear 1001 fixedly sleeved on a rotating rod 501, and a driven bevel gear 1002 meshing with the driving bevel gear 1001 fixedly sleeved on a connecting rod 901. The diameters of the driving bevel gear 1001 and the driven bevel gear 1002 are designed according to requirements, so that when the wooden door is pushed in, the cutting blade 403 cuts the edge of the wooden door.

[0030] Working principle: A wooden door is placed on the support plate 301. One end of the door is limited by the limiting block 302. The hydraulic push rod 303 is activated, causing the output end of the hydraulic push rod 303 to move the abutment block 304, which then abuts the other end of the door, clamping the door together. The cutting motor 401 is then activated, and its output shaft rotates, causing the rotating rod 402 to rotate. The rotating rod 402 then rotates the cutting blade 403, preparing it for cutting. The rotating rod 402 rotates at high speed along with the cutting motor 401, and the rotation of the rotating rod 402 drives the torque control... The internal rotation of the controller 502 forces the rotating rod 501 to rotate. The rotating rod 501 drives the active bevel gear 1001 to rotate, which in turn drives the driven bevel gear 1002 to rotate. The driven bevel gear 1002 then drives the connecting rod 901 to rotate, which in turn drives the square rod 902 to rotate, forcing the threaded rod 201 to rotate. Under the guidance of the processing plate 1, the sliding block 202 is forced to move forward. The sliding block 202 drives the bearing plate 301 to move forward, and the wooden door is clamped on the bearing plate 301, causing the wooden door to move forward continuously. This allows the cutting blade 403 to cut the wooden door, achieving normal advancement and edge cutting operations for the wooden door. In abnormal conditions, and when the cutting blade 403 and the wooden door are not completely locked, such as when the knots are small, although the cutting blade 403 can rotate and cut, the cutting speed of the cutting blade 403 is significantly reduced, causing the torque controller 502 to stop rotating, which in turn causes the rotating rod 501 to stop rotating. Since the threaded rod 201 does not rotate, the load on the cutting motor 401 is small, increasing the cutting capacity of the cutting blade 403. The cutting blade 403 performs a powerful cut on the wooden door, cutting off the smaller knots. After cutting, the cutting motor 401 returns to its normal speed and then repeats the above normal state, so that the cutting blade 403 continues to perform edge cutting operations on the advancing wooden door. In abnormal conditions, such as when the cutting blade 403 completely seizes up with the wooden door (e.g., when there are large knots), the cutting blade 403 cannot rotate, or even the cutting motor 401 stops. First, stop the cutting motor 401 and start the electric push rod 801. The output end of the electric push rod 801 drives the push plate 802 to move, which in turn drives the connecting rod 901. The connecting rod 901 causes the square rod 902 to slide within the threaded rod 201, making the friction protrusion 903 rub against the friction groove 703. The movement of the connecting rod 901 causes the driven bevel gear 1002 to separate from the driving bevel gear 1001, starting the drive motor 701. The output shaft of the drive motor 701 rotates, causing the rotating cylinder 702 to rotate. Under the action of the friction protrusion 903 and the friction groove 703, the rotating cylinder 702 drives the friction protrusion 903 to rotate, forcing the connecting rod 901 to rotate. Under the action of the rod 902, the connecting rod 901 drives the threaded rod 201 to rotate, and the threaded rod 201 drives the sliding block 202 to move in the opposite direction, causing the sliding block 202 to drive the bearing plate 301 to retract. Under the action of the limit block 302 and the abutment block 304, the bearing plate 301 is forced to drive the wooden door to retract, causing the wooden door to retract from the cutting blade 403. The cutting motor 401 is restarted, and the cutting blade 403 rotates normally again. At this time, the active bevel gear 1001 and the driven bevel gear 1002 are separated, and the drive motor 701 is started in the opposite direction, forcing the bearing plate 301 to drive the wooden door forward again. The cutting blade 403 repeatedly cuts the larger knots of the wooden door until the knots are completely cut off. By controlling the electric push rod 801, the active bevel gear 1001 and the driven bevel gear 1002 are forced to mesh again, and the friction protrusion 903 and the friction groove 703 are separated, ensuring that the system returns to normal.

[0031] This device has multiple operating modes: The first normal working mode: Through the torque controller 502 transmission and the meshing transmission of the active bevel gear 1001 and the driven bevel gear 1002, after the cutting motor 401 is started, the power is transmitted to the threaded rod 201, thereby realizing the normal state of conveying and cutting the wooden door at the same time. The second working mode of the cutting blade 403 is not completely locked: When encountering a small knot, the driving bevel gear 1001 and the driven bevel gear 1002 mesh and drive. At this time, the torque controller 502 does not rotate. After the cutting motor 401 starts, since the power cannot be transmitted to the threaded rod 201, the cutting ability of the cutting blade 403 is enhanced, and it cuts the small knots of the wooden door. The third type of cutting blade 403 is completely locked in operation mode: When encountering a large knot, the cutting motor 401 cannot cut after starting, causing the cutting motor 401 to stop rotating. By starting the electric push rod 801, the driving bevel gear 1001 and the driven bevel gear 1002 are separated, and the drive motor 701 is connected to the connecting rod 901. Starting the drive motor 701 forces the threaded rod 201 to rotate in the opposite direction, causing the wooden door to retract and forcing the wooden door to separate from the cutting blade 403.

[0032] This solution can realize multiple working modes, combining normal working mode, incomplete locking working mode and complete locking working mode. It can not only effectively simulate the operation of the operator, but also adapt to the automatic operation under abnormal conditions, realize intelligent unmanned operation, improve the safety of the operator, respond to abnormal situations in a timely manner, avoid equipment damage, facilitate the smooth cutting of wooden doors, improve production continuity, and improve the processing efficiency of wooden doors.

[0033] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A cutting edge device for processing wooden doors, characterized in that, The system includes a processing plate (1), a conveying assembly (2) on the processing plate (1), a carrying assembly (3) for carrying wooden doors on the conveying assembly (2), a cutting assembly (4) on the processing plate (1), a rotating assembly (5) on the processing plate (1), the output end of the cutting assembly (4) being connected to the rotating assembly (5), a driving assembly (7) on the processing plate (1), and a pushing assembly (8) on the processing plate (1). The pushing assembly (8) is equipped with components that are compatible with the driving assembly (7) and the conveying assembly (2). The connecting component (9) is adapted, and a transmission component (10) is provided between the connecting component (9) and the rotating component (5); wherein, when the wooden door is normally pushed, the cutting component (4) rotates to control the rotating component (5) to be in the first state, and the conveying component (2) is controlled to convey the wooden door through the rotating component (5) and the transmission component (10); in the abnormal state, the cutting component (4) encounters resistance, the rotating component (5) is in the second state, the conveying component (2) stops conveying the wooden door, and the cutting component (4) continues to cut the abnormal position of the wooden door.

2. The edge-cutting device for wooden door processing according to claim 1, characterized in that, The conveying assembly (2) includes a threaded rod (201) with a bearing connected to the processing plate (1), a sliding block (202) connected to the threaded rod (201), the threaded rod (201) being threaded through the sliding block (202), and the sliding block (202) penetrating the processing plate (1).

3. The edge-cutting device for wooden door processing according to claim 2, characterized in that, The bearing component (3) includes a bearing plate (301) disposed on the sliding block (202), a limit block (302) disposed on the bearing plate (301), a hydraulic push rod (303) disposed on the bearing plate (301), and an abutment block (304) disposed at the output end of the hydraulic push rod (303). The limit block (302) and the abutment block (304) approach each other to form a clamping effect on the wooden door.

4. The edge-cutting device for wooden door processing according to claim 3, characterized in that, The cutting assembly (4) includes a cutting motor (401) mounted on the processing plate (1), a rotating rod (402) is connected to the processing plate (1) by a bearing, the rotating rod (402) is connected to the output shaft of the cutting motor (401), and a cutting blade (403) is fixedly sleeved on the rotating rod (402).

5. The edge-cutting device for wooden door processing according to claim 4, characterized in that, The rotating assembly (5) includes a rotating rod (501) with a bearing connected to the processing plate (1), and a torque limiter (502) connected to the rotating rod (402) is provided on the rotating rod (501).

6. The edge-cutting device for wooden door processing according to claim 5, characterized in that, in, When the torque limiter (502) is working properly, the rotating rod (501) rotates in tandem with the rotating rod (402); when the torque limiter (502) is overloaded, the rotating rod (501) does not rotate.

7. The edge-cutting device for wooden door processing according to claim 6, characterized in that, The drive assembly (7) includes a drive motor (701) mounted on the processing plate (1), the output shaft of the drive motor (701) is connected to a rotating cylinder (702), and a friction groove (703) is provided inside the rotating cylinder (702).

8. The edge-cutting device for wooden door processing according to claim 7, characterized in that, The pushing assembly (8) includes an electric push rod (801) disposed on the processing plate (1), and a push plate (802) is disposed at the output end of the electric push rod (801).

9. A cutting device for processing wooden doors according to claim 8, characterized in that, The connecting assembly (9) includes a connecting rod (901) that is connected to the push plate (802) by a bearing. A square rod (902) is provided at one end of the connecting rod (901), and the square rod (902) is inserted into the threaded rod (201). A friction protrusion (903) that is adapted to the friction groove (703) is provided at the other end of the connecting rod (901).

10. A cutting device for processing wooden doors according to claim 9, characterized in that, The transmission assembly (10) includes a driving bevel gear (1001) fixedly sleeved on the rotating rod (501), and a driven bevel gear (1002) that meshes with the driving bevel gear (1001) is fixedly sleeved on the connecting rod (901).

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