A type of wood production and processing equipment
By designing automated wood production equipment, and utilizing components such as servo motors and magnets, efficient winding of wood veneers and automatic processing of broken veneers are achieved. This solves the problems of low winding efficiency and cumbersome processing of broken veneers in traditional wood production, thereby improving production efficiency and product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SHUANGPAI SHUANGSHUN WOOD IND CO LTD
- Filing Date
- 2025-02-25
- Publication Date
- 2026-06-30
AI Technical Summary
In traditional timber production, the efficiency of rolling wood veneers is low, and the handling of broken veneers is cumbersome, time-consuming, and labor-intensive, affecting the quality and efficiency of the processing flow.
A wood processing equipment was designed, which utilizes servo motors, bidirectional lead screws, moving parts, locking parts, magnets and other components to work together to achieve automatic winding of wood veneers and automatic removal of broken veneers. The winding quality and efficiency are ensured by trimming and compression mechanisms.
It improves the efficiency and quality of wood veneer winding, reduces manual intervention, lowers processing costs and time consumption, and ensures the stability of subsequent processing and product quality.
Smart Images

Figure CN119773020B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of wood production technology, and in particular to a wood production and processing equipment. Background Technology
[0002] Timber production refers to the process of transforming logs or timber sections into various timber products through a series of processing steps. This includes multiple stages such as cutting, rotary cutting, sanding, splicing, and painting, in order to produce timber products that meet different needs, such as furniture, building materials, and wood products.
[0003] Wood veneer machines, as important equipment in the wood processing field, continuously cut wood using rotating blades to obtain thin wood veneers of uniform thickness, such as veneers. These veneers are widely used in industries such as engineered wood products and furniture manufacturing. However, because wood veneers are thin and fragile, they need to be rolled into manageable and maneuverable rolls to facilitate subsequent processing steps such as cutting, splicing, and veneering. Traditional rolling methods rely on workers using sticks to move the veneers to promote rolling. This method is not only time-consuming and labor-intensive but also makes it difficult to guarantee the quality and efficiency of rolling, thus seriously affecting the overall processing flow. Moreover, natural defects on the wood surface, such as knots and cracks, can easily cause the wood veneers to break during the veneer cutting process. These broken veneers need to be manually removed one by one from the conveyor belt to avoid adverse effects on subsequent processing and product quality. This process not only consumes a lot of physical labor but also increases processing costs and time.
[0004] Based on the above, this invention proposes a wood production and processing equipment that can automatically and efficiently complete the winding and crushing of wood veneers. Summary of the Invention
[0005] In order to overcome the shortcomings of traditional wood production processes, such as low efficiency in rolling wood veneers and cumbersome, time-consuming and labor-intensive processing of broken veneers, this invention proposes a wood production processing device that can automatically and efficiently complete the rolling of wood veneers and the processing of broken veneers.
[0006] The technical solution of this invention is: a wood processing equipment, comprising a veneer lathe, a support member fixedly connected to the veneer lathe, a drive motor mounted on the side of the support member near the veneer lathe, and symmetrically distributed connecting members fixedly connected to the side of the support member away from the veneer lathe. A conveying assembly is provided between the symmetrically distributed connecting members and the support member. A fixed base is fixedly connected to the veneer lathe, and a rotating plate is rotatably connected to the fixed base. A symmetrically distributed second conveyor belt is wound around the rotating plate. Each of the symmetrically distributed connecting members is fixedly connected to a connecting frame, and a servo motor is mounted on one of the connecting frames. The servo motor's output shaft is connected to the bidirectional lead screw via a coupling. Symmetrically distributed extrusion parts are fixed to the support near the connecting frame. Symmetrically distributed moving parts are threaded onto the bidirectional lead screw. The moving parts are slidably connected to the adjacent connecting frame. Lower locking parts are rotatably connected to the symmetrically distributed moving parts. Upper locking parts are slidably connected to the symmetrically distributed lower locking parts. Fixed springs are connected between the upper locking parts and the adjacent lower locking parts. Transmission components are provided between the drive shaft on the side away from the veneer and the symmetrically distributed connecting frame.
[0007] To further explain, the conveying assembly includes a drive shaft, one drive shaft is rotatably connected between symmetrically distributed connecting members, and another drive shaft is rotatably connected to the support member. The output shaft of the drive motor is connected to the adjacent drive shaft through a coupling. Each drive shaft is fixed with symmetrically distributed conveyor wheels. A first conveyor belt is wound around each of the two transverse conveyor wheels, and the two first conveyor belts also pass over the top wall of the support member.
[0008] To further explain, the transmission assembly includes transmission wheels. Symmetrically distributed transmission wheels are fixed to the transmission shaft on the side away from the veneer cutter. Transmission wheels are also rotatably connected to the symmetrically distributed connecting frames. Transmission belts are wound around the two transmission wheels in the transverse direction. The lower locking member passes through the adjacent transmission wheels. A second magnet is fixed to the transmission wheel on the side closer to the lower locking member. A first magnet is fixed to the side of the lower locking member that is far away from each other. The first magnet and the adjacent second magnet are magnetically attracted to each other.
[0009] To further explain, the upper locking component and the inner wall of the adjacent extrusion component are both extruded and fitted.
[0010] Further explanation: It also includes a rejection mechanism for removing the fragmented flakes from the conveyor belt. The rejection mechanism is mounted on the veneer and includes a connecting seat fixed to the veneer. A drive motor is mounted on the connecting seat. The output shaft of the drive motor is fixed to a rotating plate via a coupling. Symmetrically distributed limiting members are fixed to the rotating plate. A fixed frame is fixed to the side of the support member near the drive motor. A feed port is opened on the side of the fixed frame near the veneer. A storage box is snapped onto the fixed frame. A support rod is fixed to the support member. The bottom of the storage box contacts the top of the support rod.
[0011] To further explain, the bottom of each of the symmetrically distributed limiting components is equipped with evenly distributed rollers.
[0012] Further explanation: It also includes a trimming mechanism to ensure that the ends of the rolled-up wood veneer are aligned. The trimming mechanism is mounted on a bidirectional lead screw and includes a rotating component fixed to the middle of the bidirectional lead screw. Symmetrically distributed guide components are fixed to the rotating component. Symmetrically distributed L-shaped rods are fixed to the side of the support near the bidirectional lead screw. Sliding components are slidably connected to the symmetrically distributed L-shaped rods. Fixed rods are fixed to the sides of the sliding components that are close to each other. Adjusting screws are rotatably connected to the symmetrically distributed sliding components. Centering frames are threadedly connected to the symmetrically distributed adjusting screws. The centering frames and the support are slidably connected.
[0013] To further explain, each of the symmetrically distributed guide members has a bent groove, and the fixing rod is inserted into the adjacent bent groove.
[0014] Further explanation: It also includes a compression mechanism for compacting the broken pieces inside the storage box. The compression mechanism is mounted on the support member and includes a support frame. The support frame is fixed to the side of the support member near the drive motor. A drive rod is slidably connected to the support frame. A rotating frame is rotatably connected to the drive rod. The output shaft of the drive motor is fixed to a rotating member through a coupling. The rotating frame is also rotatably connected to the drive rod. A pressing frame is slidably connected to the top wall of the fixed frame. The pressing frame is located inside the storage box. A connecting rod is fixed to the side of the pressing frame near the drive rod.
[0015] To further explain, the transmission rod has an inclined groove inside, and the connecting rod slides within the inclined groove.
[0016] The beneficial effects of this invention are as follows: First, by adjusting the position of the rotating plate, the broken pieces generated during the wood cutting process can be automatically removed, eliminating the need for workers to manually pick them up. This not only avoids interference from broken pieces in subsequent processing but also reduces the workload of workers. Furthermore, through the cooperation of servo motors, bidirectional lead screws, moving parts, upper clamping parts, lower clamping parts, pressing parts, first magnets, and second magnets, efficient winding of wood veneers is achieved. This not only improves production efficiency but also ensures the quality of the wood veneers, providing strong support for subsequent processing and applications.
[0017] This invention first adjusts the distance between the two centering frames by adjusting the lead screw, ensuring that the equipment can be flexibly adjusted according to the size of the wood. Then, through the cooperation of rotating parts, guide parts, fixing rods, and centering frames, it can achieve automatic alignment and leveling during the wood veneer winding process, ensuring the stability of the winding process and product quality. This not only improves production efficiency but also reduces the cost and risk of manual intervention.
[0018] This invention controls the upward movement of the extrusion frame by means of a transmission motor, rotating parts, rotating frame, transmission rod, and connecting rod, thereby meeting the feeding and compaction requirements of the broken products. This not only improves work efficiency but also ensures the stable accumulation and compaction effect of the broken products in the storage box. Attached Figure Description
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0020] Figure 2 This is a three-dimensional structural diagram of the rotary cutting machine, support member, and drive motor of the present invention.
[0021] Figure 3 This is a three-dimensional structural diagram of the connector, the first conveyor belt, and the rotating plate of the present invention.
[0022] Figure 4 This is a three-dimensional structural diagram of the bidirectional lead screw, servo motor, and extrusion component of the present invention.
[0023] Figure 5 This is a three-dimensional structural diagram of the upper locking component, lower locking component, and transmission wheel of the present invention.
[0024] Figure 6 This is a three-dimensional structural diagram of the first magnet, the second magnet, and the moving part of the present invention.
[0025] Figure 7 This is an exploded three-dimensional view of the extrusion part, lower locking part, and fixing spring of the present invention.
[0026] Figure 8 This is a three-dimensional structural diagram of the drive motor, connecting seat, and limiting components of the present invention.
[0027] Figure 9 This is a three-dimensional structural diagram of the rotating plate, the second conveyor belt, and the limiting component of the present invention.
[0028] Figure 10 This is a three-dimensional structural diagram of the support rod, storage box, and other components of the present invention.
[0029] Figure 11 This is a three-dimensional structural diagram of the storage box and fixing frame of the present invention.
[0030] Figure 12 This is a three-dimensional structural diagram of the rotating component, guide component, and fixing rod of the present invention.
[0031] Figure 13 This is a three-dimensional structural diagram of the components of the present invention, including the bidirectional lead screw, the sliding member, and the centering bracket.
[0032] Figure 14This is a three-dimensional structural diagram of the rotating component, guide component, and fixing rod component of the present invention.
[0033] Figure 15 This is a three-dimensional structural diagram of the support frame, rotating component, and rotating frame of the present invention.
[0034] Figure 16 This is a three-dimensional structural cross-sectional view of the storage box, compression rack, and connecting rod components of the present invention.
[0035] Reference numerals: 1: veneer lathe, 11: support component, 12: drive motor, 13: first conveyor belt, 14: connector, 15: rotating plate, 16: second conveyor belt, 17: fixed base, 18: connecting frame, 19: servo motor, 110: extrusion component, 111: bidirectional lead screw, 112: moving component, 113: upper locking component, 114: lower locking component, 115: drive shaft, 1151: conveyor wheel, 116: drive wheel, 117: drive belt, 1 18: First magnet, 119: Second magnet, 120: Fixed spring, 2: Drive motor, 21: Connecting seat, 22: Limiting component, 23: Support rod, 24: Storage box, 25: Fixed frame, 3: Rotating component, 31: Guide component, 32: Fixed rod, 33: Sliding component, 34: Centering frame, 35: L-shaped rod, 36: Adjusting screw, 4: Support frame, 41: Rotating component, 42: Rotating frame, 43: Drive rod, 44: Connecting rod, 45: Extrusion frame. Detailed Implementation
[0036] The present invention will be further described below with reference to specific embodiments. It should also be noted that, unless otherwise explicitly specified and limited, terms such as "set," "install," "connect," and "link" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; 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; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in the present invention based on the specific circumstances.
[0037] Example 1: A wood production and processing equipment, such as Figures 1-7As shown, the device includes a veneer lathe 1. A support member 11 is fixedly connected to the right side of the veneer lathe 1. A drive motor 12 is mounted on the front left side of the support member 11. Connecting members 14, symmetrically distributed front and rear, are fixedly connected to the right side of the support member 11. A conveying assembly is provided between the two connecting members 14 and the support member 11. A fixed base 17 is fixedly connected to the middle of the right side of the veneer lathe 1. A rotating plate 15 is rotatably connected to the fixed base 17. A second conveyor belt 16, symmetrically distributed front and rear, is wound around the rotating plate 15. Connecting frames 18 are fixedly connected to both connecting members 14. A servo motor 19 is mounted on the front connecting frame 18. A bidirectional lead screw 111 is rotatably connected between the two connecting frames 18. The output shaft of the servo motor 19 is connected to the bidirectional lead screw 111 via a coupling. The right side of the support member 11 is fixed with symmetrically distributed extrusion members 110. The bidirectional screw 111 is threaded with symmetrically distributed moving members 112. The moving members 112 are slidably connected to the adjacent connecting frame 18. The upper part of each of the two moving members 112 is rotatably connected with a lower locking member 114. The upper locking member 113 is slidably connected to each of the two lower locking members 114. The upper locking member 113 and the adjacent lower locking member 114 are connected with a fixing spring 120. The upper locking member 113 and the lower locking member 114 both pass through the adjacent extrusion member 110. The right side drive shaft 115 is provided with a transmission component between the two connecting frames 18. The upper locking member 113 and the inner wall of the adjacent extrusion member 110 are pressed together.
[0038] like Figure 2 and Figure 3 As shown, the conveying assembly includes a drive shaft 115. One drive shaft 115 is rotatably connected between two connecting members 14, and the other drive shaft 115 is rotatably connected to the upper left side of the support member 11. The output shaft of the drive motor 12 is connected to the drive shaft 115 on the left side through a coupling. Two conveyor wheels 1151 are fixed on each drive shaft 115. A first conveyor belt 13 is wound around each of the two transverse conveyor wheels 1151. The two first conveyor belts 13 also pass over the top wall of the support member 11.
[0039] like Figures 5-7 As shown, the transmission assembly includes a transmission wheel 116. The right transmission shaft 115 is fixedly connected to the transmission wheel 116, which is symmetrically distributed front and rear. The upper parts of the two connecting frames 18 are also rotatably connected to the transmission wheel 116. The two adjacent transmission wheels 116 are each wound with a transmission belt 117. The lower locking member 114 passes through the adjacent transmission wheel 116. The left transmission wheel 116 is fixedly connected to the second magnet 119. The lower locking member 114 is fixedly connected to the side away from each other with the first magnet 118. The first magnet 118 and the adjacent second magnet 119 are magnetically attracted to each other.
[0040] like Figures 8-11As shown, it also includes a rejection mechanism for removing the broken pieces from the conveyor belt. The rejection mechanism is set on the veneer 1 and includes a connecting seat 21. The connecting seat 21 is fixed to the front right side of the veneer 1. A drive motor 2 is installed on the connecting seat 21. The output shaft of the drive motor 2 is fixed to the rotating plate 15 through a coupling. A symmetrically distributed limiting member 22 is fixed to the rotating plate 15. A fixed frame 25 is fixed to the front side of the support member 11. A feed port is opened on the left side of the fixed frame 25. A storage box 24 is snapped onto the fixed frame 25. A support rod 23 is fixed to the rear side of the support member 11. The bottom of the storage box 24 contacts the top of the support rod 23. Seven rollers are evenly distributed at the bottom of both limiting members 22.
[0041] Initially, the drive motor 2 is controlled to rotate the rotating plate 15 upward by about 45°, so that the rotating plate 15 is flush with the feed inlet of the fixed frame 25. The second conveyor belt 16 is controlled to convey the wood to the right. The wood to be processed is then fixed on the veneer 1. The rotating blade on the veneer 1 is controlled to continuously cut the wood. Due to natural defects on the surface of the wood, such as knots and cracks, these defects are prone to cause the wood veneer to break during the veneer cutting process. After the broken wood veneer comes out of the discharge window of the veneer 1, the wood veneer will enter between the limiting member 22 and the second conveyor belt 16. The second conveyor belt 16 will transport the broken wood veneer to the right and enter from the feed inlet of the fixed frame 25. Then it will accumulate in the storage box 24. As the wood veneer is transported to the right, the roller at the bottom of the limiting member 22 will rotate.
[0042] Once all defects on the wood surface have been removed, the drive motor 2 can be controlled to rotate the rotating plate 15 downwards and reset it. At the same time, the drive motor 12 can be controlled to rotate the left drive shaft 115. The right drive shaft 115 will also rotate through the transmission wheel 1151 and the first conveyor belt 13, enabling the first conveyor belt 13 to transport the wood to the right. The right drive shaft 115 will rotate through the transmission belt 117 and the transmission wheel 116, causing the second magnet 119 to rotate. At this time, the qualified wood veneer will slide down the rotating plate 15 onto the support member 11 and be transported to the right by the first conveyor belt 13.
[0043] Subsequently, the servo motor 19 can be controlled to drive the bidirectional lead screw 111 to rotate in the forward direction, thereby driving the moving part 112 to move the lower locking part 114, the upper locking part 113, and the first magnet 118 inward. The inwardly moving upper locking part 113 and lower locking part 114 will be located on the upper and lower sides of the wood veneer, respectively. When the inwardly moving upper locking part 113 contacts the inner wall of the pressing part 110, the inner wall of the pressing part 110 will abut against the upper locking part 113, causing it to slide downward, and the fixing spring 1... 20 will deform. At this time, the upper clamping part 113 and the lower clamping part 114 cooperate to clamp the wood sheet. When the first magnet 118 moves inward and contacts the second magnet 119, the first magnet 118 and the second magnet 119 will be attracted together under the action of magnetic force. The rotating second magnet 119 will drive the lower clamping part 114 and the upper clamping part 113 to rotate together through the first magnet 118. The rotating upper clamping part 113 and the lower clamping part 114 will drive the wood sheet to be rolled up.
[0044] After a piece of wood veneer is wound up, the servo motor 19 automatically drives the bidirectional lead screw 111 to rotate in the opposite direction, thereby driving the moving part 112 to move the lower locking part 114, the upper locking part 113, and the first magnet 118 outward. When the outwardly moving upper locking part 113 separates from the inner wall of the pressing part 110, under the elastic force of the fixing spring 120, the upper locking part 113 slides upward to reset, and the lower locking part 114 and the upper locking part 113 separate from the wound wood veneer. At the same time, when the outwardly moving first magnet 118 disengages from the second magnet 119, the first magnet 118 and the lower locking part 114... 14. The upper clamping component 113 also stops rotating. Similarly, when the next piece of wood veneer is conveyed, the servo motor 19 will first drive the bidirectional lead screw 111 to rotate forward, so that the upper clamping component 113 and the lower clamping component 114 cooperate to clamp and wind up the wood veneer. After winding is completed, the servo motor 19 will drive the bidirectional lead screw 111 to rotate in reverse, so that the upper clamping component 113, the lower clamping component 114 and the wound wood veneer are separated. The first conveyor belt 13 will continue to convey the wound wood veneer to the right. Since the staff placed the collection box at the right end of the device in advance, the wound wood veneer will fall directly into the collection box.
[0045] When the storage box 24 is full of broken pieces, it can be pulled back directly, and the storage box 24 will detach from the fixed frame 25. The staff can then process the broken pieces in the storage box 24 and push it back into its original position. In summary, by adjusting the position of the rotating plate 15, the broken pieces generated during the wood cutting process can be automatically removed, eliminating the need for workers to manually pick them up. This not only avoids the interference of broken pieces with subsequent processing but also reduces the workload of the staff. Furthermore, through the cooperation of the servo motor 19, the bidirectional lead screw 111, the moving part 112, the upper clamping part 113, the lower clamping part 114, the pressing part 110, the first magnet 118, and the second magnet 119, efficient winding of the wood veneer is achieved, which not only improves production efficiency but also ensures the quality of the wood veneer, providing a strong guarantee for subsequent processing and application.
[0046] Example 2: Based on Example 1, such as Figures 12-14 As shown, it also includes a trimming mechanism to ensure that the ends of the rolled-up wood veneer are aligned. The trimming mechanism is mounted on the bidirectional lead screw 111 and includes a rotating component 3. The rotating component 3 is fixed to the middle of the bidirectional lead screw 111. The rotating component 3 is fixed to guide components 31 that are symmetrically distributed front and rear. L-shaped rods 35 are fixed to the front and rear parts of the right side of the support component 11. Sliding components 33 are slidably connected to the two L-shaped rods 35. Fixed rods 32 are fixed to the sides of the sliding components 33 that are close to each other. Adjusting screws 36 are rotatably connected to the two sliding components 33. Centering frames 34 are threadedly connected to the two adjusting screws 36. The two centering frames 34 are slidably connected to the support component 11. The two guide components 31 have bent slots. The guide components 31 on the front and rear sides are arranged in an inverted V-shape. The fixed rods 32 are respectively inserted into the adjacent bent slots.
[0047] Initially, the distance between the two centering frames 34 is adjusted according to the width of the wood veneer. The specific operation is as follows: Turn the adjusting screw 36 to drive the centering frame 34 to move inward or outward until the distance between the centering frames 34 matches the width of the wood veneer. When the bidirectional screw 111 rotates in both directions, it will drive the rotating part 3 and the guide part 31 to rotate together. Since the fixed rod 32 is inserted into the guide part 31 and the guide parts 31 on the front and rear sides are arranged in an inverted V shape, as the guide part 31 continues to rotate, the guide part 31 will drive the fixed rod 32 to move back and forth, thereby driving the sliding part 33, the adjusting screw 36, and the centering frame 34 to move back and forth.
[0048] When the centering frame 34 moves inward and contacts the rolled-up wood veneer, it acts on both ends of the veneer. If the rolled-up veneer has one convex end and one concave end, the inward-moving centering frame 34 will promptly push the convex end inward to ensure that both ends of the rolled-up veneer are aligned. When the centering frame 34 moves outward and separates from the rolled-up veneer, the rolled-up veneer continues to move to the right along the predetermined path. In summary, by first adjusting the distance between the two centering frames 34 by adjusting the lead screw 36, the equipment can be flexibly adjusted according to the size of the wood. Then, through the cooperation of the rotating part 3, the guide part 31, the fixing rod 32, and the centering frame 34, automatic alignment and leveling of the wood veneer during the rolling process can be achieved, ensuring the stability of the rolling process and product quality. This not only improves production efficiency but also reduces the cost and risk of manual intervention.
[0049] like Figure 15 and Figure 16 As shown, it also includes a compression mechanism for compacting the broken pieces inside the storage box 24. The compression mechanism is mounted on the support member 11 and includes a support frame 4. The support frame 4 is fixed to the lower front side of the support member 11. A transmission rod 43 is slidably connected to the support frame 4, and a rotating frame 42 is rotatably connected to the transmission rod 43. The output shaft of the transmission motor 2 is fixedly connected to a rotating member 41 through a coupling. The rotating frame 42 is also rotatably connected to the transmission rod 43. A pressing frame 45 is slidably connected between the front and rear sides of the top wall of the fixed frame 25. The lower part of the pressing frame 45 is located inside the storage box 24. A connecting rod 44 is fixedly connected to the front side of the pressing frame 45. An inclined groove is opened in the transmission rod 43, and the connecting rod 44 slides in the inclined groove.
[0050] When the drive motor 2 drives the rotating plate 15 to rotate upward, the drive motor 2 also drives the rotating component 41 to rotate upward, thereby driving the transmission rod 43 to move to the right through the rotating frame 42, and then driving the extrusion frame 45 to move upward through the connecting rod 44. The upward movement of the extrusion frame 45 will cause it to retract from the storage box 24, providing space for broken parts to enter from the feed port of the fixed frame 25 and accumulate in the storage box 24. When the drive motor 2 drives the rotating plate 15 to rotate downward, the rotating component 41 also rotates downward and resets, thereby driving the transmission rod 43 to move to the right through the rotating frame 42, and then driving the extrusion frame 45 to move upward through the connecting rod 44. 2 drives the transmission rod 43 to move to the left, which in turn drives the extrusion frame 45 to move downward through the connecting rod 44. The downward-moving extrusion frame 45 will compact the broken items in the storage box 24, thereby increasing the holding capacity of the storage box 24. In summary, the extrusion frame 45 is controlled to move upward by the transmission motor 2, rotating part 41, rotating frame 42, transmission rod 43, and connecting rod 44, thereby meeting the feeding and compaction requirements of broken items. This not only improves work efficiency but also ensures the stable accumulation and compaction effect of broken items in the storage box 24.
[0051] The technical principles of the embodiments of the present invention have been described above with reference to specific examples. These descriptions are merely for explaining the principles of the embodiments of the present invention and should not be construed as limiting the scope of protection of the embodiments of the present invention in any way. Based on the explanation herein, those skilled in the art can conceive of other specific embodiments of the present invention without creative effort, and these embodiments will all fall within the scope of protection of the embodiments of the present invention.
Claims
1. A wood processing and manufacturing device, comprising a veneer lathe, a support member fixedly connected to the veneer lathe, a drive motor mounted on the side of the support member closest to the veneer lathe, and symmetrically distributed connecting members fixedly connected to the side of the support member away from the veneer lathe, wherein a conveying assembly is provided between the symmetrically distributed connecting members and the support member, characterized in that, It also includes a fixed base, which is fixed to the veneer cutting machine. A rotating plate is rotatably connected to the fixed base, and a symmetrically distributed second conveyor belt is wound around the rotating plate. Connecting frames are fixed to the symmetrically distributed connecting parts, one of which is equipped with a servo motor. A bidirectional lead screw is rotatably connected between the symmetrically distributed connecting frames. The output shaft of the servo motor is connected to the bidirectional lead screw via a coupling. A symmetrically distributed extrusion part is fixed to the side of the support near the connecting frame. A symmetrically distributed moving part is threadedly connected to the bidirectional lead screw. The moving parts are slidably connected to the adjacent connecting frame. A lower locking part is rotatably connected to each of the symmetrically distributed moving parts. Each symmetrically distributed lower locking member is slidably connected to an upper locking member. A fixing spring connects each upper locking member to an adjacent lower locking member. A transmission assembly is provided between the drive shaft on the side furthest from the veneer and the symmetrically distributed connecting frame. The conveying assembly includes a drive shaft; one drive shaft is rotatably connected between the symmetrically distributed connecting members, and the other drive shaft is rotatably connected to the support member. The output shaft of the drive motor is connected to an adjacent drive shaft via a coupling. Each drive shaft is fixedly connected to symmetrically distributed conveyor wheels. A first conveyor belt is wound around each of the two transverse conveyor wheels. The two first conveyor belts also extend from the top wall of the support member. The transmission assembly includes drive wheels, with symmetrically distributed drive wheels fixed to a drive shaft on the side away from the veneer. Drive wheels are also rotatably connected to symmetrically distributed connecting frames. A drive belt is wound around each of the two transverse drive wheels. Lower locking members pass through adjacent drive wheels. A second magnet is fixed to each drive wheel near the lower locking member, and a first magnet is fixed to each lower locking member on the side away from it. The first magnet and the adjacent second magnet are magnetically attracted to each other. The upper locking member is pressed against the inner wall of the adjacent extruder. The assembly also includes a rejection mechanism for removing broken flakes from the conveyor belt. The rejection mechanism is located within the veneer. The device also includes a trimming mechanism to ensure that the ends of the rolled-up wood veneer are aligned. The trimming mechanism is mounted on a bidirectional lead screw and includes a rotating component fixed to the middle of the bidirectional lead screw. Symmetrically distributed guide components are fixed to the rotating component. Symmetrically distributed L-shaped rods are fixed to the side of the support near the bidirectional lead screw. Sliding components are slidably connected to the symmetrically distributed L-shaped rods. Fixed rods are fixed to the sides of the sliding components that are close to each other. Adjusting screws are rotatably connected to the symmetrically distributed sliding components. Centering frames are threadedly connected to the symmetrically distributed adjusting screws. The centering frames and the support are slidably connected.
2. The wood processing equipment according to claim 1, characterized in that, The rejection mechanism includes a connecting seat, which is fixed to the veneer machine. A drive motor is installed on the connecting seat. The output shaft of the drive motor is fixed to the rotating plate through a coupling. Symmetrically distributed limiting members are fixed to the rotating plate. A fixed frame is fixed to the side of the support member near the drive motor. A feed port is opened on the side of the fixed frame near the veneer machine. A storage box is snapped onto the fixed frame. A support rod is fixed to the support member. The bottom of the storage box contacts the top of the support rod.
3. A wood processing equipment according to claim 2, characterized in that, The bottom of the symmetrically distributed limiting components is equipped with evenly distributed rollers.
4. A wood processing and manufacturing equipment according to claim 1, characterized in that, The symmetrically distributed guide members each have a bent groove, and the fixing rods are respectively inserted into the adjacent bent grooves.
5. A wood processing equipment according to claim 1, characterized in that, It also includes a compression mechanism for compacting the broken pieces inside the storage box. The compression mechanism is mounted on the support member and includes a support frame. The support frame is fixed to the side of the support member near the drive motor. A drive rod is slidably connected to the support frame. A rotating frame is rotatably connected to the drive rod. The output shaft of the drive motor is fixed to a rotating member through a coupling. The rotating frame is also rotatably connected to the drive rod. A pressing frame is slidably connected to the top wall of the fixed frame. The pressing frame is located inside the storage box. A connecting rod is fixed to the side of the pressing frame near the drive rod.
6. A wood processing and manufacturing equipment according to claim 5, characterized in that, The transmission rod has an inclined groove, and the connecting rod slides within the inclined groove.