New type paper and fiber blended mat weaving machine

By using a drive rod and an adjusting plate in the fiber-paper blended mat weaving machine, the problem of inconsistent sheds caused by changes in spring force was solved, achieving shed consistency and weft yarn guidance stability, thus improving weaving quality and equipment stability.

CN224494473UActive Publication Date: 2026-07-14ANJI SHUANGXIN HOME FURNISHING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANJI SHUANGXIN HOME FURNISHING CO LTD
Filing Date
2025-08-22
Publication Date
2026-07-14

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Abstract

The utility model discloses a novel fiber paper line blended mat braider, including the casing, the left side in the casing is provided with the line distribution board, and the right -hand member of line distribution board is provided with the line distribution hole respectively, still includes the opening mechanism, the opening mechanism: it includes the protection box, sliding column no.
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Description

Technical Field

[0001] This utility model relates to the technical field of mat weaving equipment, specifically a novel fiber-paper blend mat weaving machine. Background Technology

[0002] Fiber-paper-yarn blended cooling mats are made from strips of special paper and yarn. These mats replace bamboo strips and are an environmentally friendly, biodegradable fiber material. The new fiber-paper-yarn blended cooling mat weaving machine utilizes advanced equipment for producing these mats. This equipment boasts high production efficiency, uniform weaving density, and stable quality, significantly reducing labor costs. (Existing technology: Authorization Publication No. CN 110230143) Patent B discloses a weaving machine including a support assembly, a front heald frame, a rear heald frame, and a reed. The support assembly includes a support base, a first vertical guide rail and a second vertical guide rail that are vertically fixed to the support base and parallel to each other, a connector located at the front end of the support base, and a rotating rod with its lower end hinged to the connector. The upper end of the rotating rod has a slot. Although this device can move the shed by the cooperation of a spring and a rack plate to form a new shed, the spring performance is affected by environmental factors such as temperature and humidity. In high temperature or humid environments, the spring is prone to rust or changes in elasticity. Because the size of the shed changes with the spring elasticity, the change in spring elasticity will cause the shed size to be inconsistent during the weaving process, affecting the introduction of weft yarn and ultimately resulting in uneven weaving. Therefore, we propose a new type of fiber-paper blended mat weaving machine. Summary of the Invention

[0003] The technical problem this invention aims to solve is to overcome existing defects and provide a novel fiber-paper blended mat weaving machine. Through the coordinated arrangement of a drive rod and an adjusting plate, it can simultaneously move both the first thread ring and the second thread separating ring, with the first and second thread separating rings moving the same distance. This replaces the traditional method of adjusting the positions of the first and second thread separating rings using springs, solving the problem of the adjustment effect being affected by changes in spring force. It ensures the consistency of the shed and also increases the stability of the shuttle guiding the weft yarn, effectively solving the problems in the background technology.

[0004] To achieve the above objectives, this utility model provides the following technical solution: a novel fiber-paper blended mat weaving machine, including a machine housing, a thread separating plate arranged on the left side inside the machine housing, thread separating holes arranged on the right end of the thread separating plate, and an opening mechanism;

[0005] The shed opening mechanism includes a protective box, a sliding column one, a thread divider one, a sliding column two, a thread divider two, and an adjusting component. The protective box is located in the middle of the bottom wall of the machine housing. Sliding columns one and two are slidably connected in sliding holes on the left and right sides of the top wall of the protective box. Thread divider one and thread divider two are respectively located at the upper ends of sliding columns one and two. Thread divider one is spaced apart from the longitudinally adjacent thread divider two, and the left and right positions of thread divider one and thread divider two correspond to the transversely adjacent thread divider holes. The adjusting component is located inside the protective box. Thread divider one and thread divider two are driven by the adjusting component. Through the cooperation of the drive rod and the adjusting plate, thread divider one and thread divider two can be moved simultaneously. The moving distance of thread divider one and thread divider two is the same, replacing the traditional method of adjusting the position of thread divider one and thread divider two by springs. This solves the problem of the adjustment effect being affected by changes in spring force, ensuring the consistency of the shed opening and increasing the stability of the shuttle guiding the weft thread.

[0006] Furthermore, a microcontroller is installed at the front end of the housing. The input terminal of the microcontroller is electrically connected to an external power supply, enabling it to regulate the electrical components inside the device.

[0007] Furthermore, the adjustment assembly includes a fixed rod, a connecting plate, a drive rod, a push plate, and an adjustment plate. The fixed rods are respectively located on the left and right sides inside the protective box. The upper ends of two longitudinally adjacent fixed rods are slidably connected to guide holes corresponding to the lower ends of a connecting plate. The lower ends of longitudinally adjacent sliding rod one and sliding rod two are respectively fixedly connected to the upper ends of a vertically adjacent connecting plate. The rear ends of the two connecting plates are each provided with a drive rod. A push plate is slidably connected in an installation groove opened on the rear side of the bottom wall of the protective box. An adjustment plate is provided at the upper end of the push plate. Adjustment grooves are provided on the left and right sides of the front end of the adjustment plate. The rear ends of the drive rods are located inside the longitudinally adjacent adjustment grooves, which can drive sliding rod one and sliding rod two to move.

[0008] Furthermore, the adjustment assembly also includes a screw, a bellows, and a servo motor. The screw is rotatably connected to the rear side inside the protective box. The push plate is threaded to the middle of the outer arc surface of the screw through a threaded hole in the middle of its right end. Bellows are respectively provided between the left and right ends of the push plate and the inner wall of the protective box, and the bellows are respectively sleeved on the outside of the left and right sides of the screw. The servo motor is located on the lower side of the right end of the protective box. The left end of the servo motor output shaft is fixedly connected to the right end of the screw. The input end of the servo motor is electrically connected to the output end of the microcontroller, which can drive the push plate to move.

[0009] Furthermore, a limiting plate is provided on the right side inside the housing, and a fixing plate is provided on the right side of the bottom wall of the housing. A vertical plate is slidably connected in a groove opened on the right side of the bottom wall of the housing. A reed is provided at the upper end of the vertical plate. The reed is located between the right side of the protective box and the left side of the limiting plate. An electric push rod is provided in the middle of the left end of the fixing plate. The left end of the telescopic end of the electric push rod is fixedly connected to the right end of the vertical plate. The input end of the electric push rod is electrically connected to the output end of the microcontroller. The reed can tighten the weft yarn after weaving.

[0010] Furthermore, a conveying roller and a winding roller are rotatably connected to the right side inside the housing. The conveying roller is located between the left end of the winding roller and the right end of the limiting plate. A second conveying motor is provided on the lower side of the housing. The rear end of the output shaft of the second conveying motor is fixedly connected to the front end of the winding roller. The input end of the second conveying motor is electrically connected to the output end of the microcontroller, which can release the warp thread wound on the outer arc surface by the unwinding roller.

[0011] Furthermore, a wire feeding roller and a guide roller are rotatably connected to the left side of the inside of the housing. The guide roller is located to the left of the wire separating plate, and the wire feeding roller is located to the left of the guide roller. A first conveyor motor is provided on the lower side of the front end of the housing. The rear end of the output shaft of the first conveyor motor is fixedly connected to the front end of the wire feeding roller. The input end of the first conveyor motor is electrically connected to the output end of the microcontroller, which can roll up the woven fiber paper blend mat.

[0012] Compared with the prior art, the beneficial effects of this utility model are as follows: This novel fiber-paper blended mat weaving machine has the following advantages:

[0013] By coordinating the drive rod and the adjusting plate, both the first thread ring and the second thread divider can be moved simultaneously. The first thread ring and the second thread divider move the same distance, replacing the traditional method of adjusting the positions of the first thread ring and the second thread divider using springs. This solves the problem of the adjustment effect being affected by changes in the spring force, ensuring the consistency of the shed and increasing the stability of the shuttle when guiding the weft thread. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the structure of this utility model;

[0015] Figure 2 This is a schematic cross-sectional view of the right side of this utility model;

[0016] Figure 3 This is a schematic diagram of the opening mechanism of this utility model;

[0017] Figure 4 This is a schematic diagram of the internal structure of the protective box of this utility model;

[0018] Figure 5 This is an enlarged structural diagram of point A in this utility model;

[0019] Figure 6 This is a schematic diagram of the structure of the present invention during the weaving process;

[0020] Figure 7 This is a schematic diagram of the front planar structure of the present invention during the weaving process.

[0021] In the diagram: 1. Housing; 2. Microcontroller; 3. Pay-off roller; 4. Guide roller; 5. Dividing plate; 6. Opening mechanism; 61. Protective box; 62. Sliding column one; 63. Dividing ring one; 64. Sliding column two; 65. Dividing ring two; 66. Adjustment assembly; 661. Fixing rod; 662. Connecting plate; 663. Drive rod; 664. Push plate; 665. Adjustment plate; 666. Screw; 667. Corrugated pipe; 668. Servo motor; 7. Conveying roller; 8. Rewinding roller; 9. Limiting plate; 10. Fixing plate; 11. Vertical plate; 12. Reed; 13. Electric push rod; 14. Conveying motor one; 15. Conveying motor two. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Please see Figure 1-7 This embodiment provides a technical solution: a novel fiber-paper blended mat weaving machine, including a housing 1, a thread separating plate 5 is provided on the left side inside the housing 1, thread separating holes are provided on the right end of the thread separating plate 5, and an opening mechanism 6 is also included.

[0024] Opening mechanism 6: It includes a protective box 61, a sliding column 62, a dividing ring 63, a sliding column 64, a dividing ring 65, and an adjusting component 66. The protective box 61 is located in the middle of the bottom wall of the housing 1. The sliding columns 62 and 64 are slidably connected in the sliding holes on the left and right sides of the top wall of the protective box 61, respectively. The upper ends of the sliding columns 62 and 64 are respectively provided with the dividing rings 63 and 65. The dividing rings 63 and 65 are spaced apart from the longitudinally adjacent dividing rings 65. The dividing rings 63 and 65 correspond to the left and right positions of the transversely adjacent dividing holes. The adjusting component 66 is located inside the protective box 61. The dividing rings 63 and 65 are driven by the adjusting component 66. The adjusting component 66 includes a fixing rod 661. The protective box 61 is equipped with a connecting plate 662, a drive rod 663, a push plate 664, and an adjusting plate 665. Fixed rods 661 are respectively located on the left and right sides inside the protective box 61. The upper ends of two longitudinally adjacent fixed rods 661 are slidably connected to guide holes corresponding to the lower ends of a connecting plate 662. The lower ends of longitudinally adjacent sliding pins 62 and 64 are respectively fixedly connected to the upper ends of a vertically adjacent connecting plate 662. Drive rods 663 are located at the rear ends of both connecting plates 662. A push plate 664 is slidably connected to an installation groove on the rear side of the bottom wall of the protective box 61. An adjusting plate 665 is located at the upper end of the push plate 664. Adjusting grooves are located on the left and right sides of the front end of the adjusting plate 665. The rear ends of the drive rods 663 are located on the longitudinally adjacent... Inside the adjustment slot, the adjustment assembly 66 also includes a screw 666, a bellows 667, and a servo motor 668. The screw 666 is rotatably connected to the rear side inside the protective box 61. The push plate 664 is threadedly connected to the middle of the outer arc surface of the screw 666 through a threaded hole in the middle of its right end. Bellows 667 are respectively provided between the left and right ends of the push plate 664 and the inner wall of the protective box 61. The bellows 667 are respectively sleeved on the outside of the left and right sides of the screw 666. The servo motor 668 is located on the lower side of the right end of the protective box 61. The left end of the output shaft of the servo motor 668 is fixedly connected to the right end of the screw 666. The input end of the servo motor 668 is electrically connected to the output end of the microcontroller 2. The output shaft of the servo motor 668 drives the screw 666 to rotate. During rotation, screw 666 drives push plate 664 to move to the right via threaded connection. At this time, bellows 667 on the left extends and bellows 667 on the right retracts. Bellows 667 prevent screw 666 from direct contact with the external environment. Push plate 663 drives adjusting plate 665 to move. Drive rod 663 slides and rotates relative to the adjusting groove inside the adjusting groove, causing it to move along the inclined surface of the adjusting groove. Drive rod 663 drives sliding pin 1 62 and sliding pin 2 64 to move via connecting plate 662. Sliding pin 1 62 and sliding pin 2 64 then drive dividing ring 1 63 and dividing ring 2 65 to move. Dividing ring 1 63 moves downwards, while dividing ring 2 65 moves upwards.When the left drive rod 663 contacts the bottom wall of the left adjustment groove, the right drive rod 663 will contact the top wall of the right adjustment groove. This indicates that the thread loop 1 63 and the thread separator 2 65 have moved to the designated working position. This replaces the traditional method of adjusting the positions of the thread loop 1 63 and the thread separator 2 65 using springs, solving the problem of the adjustment effect being affected by changes in spring force. It ensures the consistency of the shed and also increases the stability of the shuttle guiding the weft thread.

[0025] Among them: a microcontroller 2 is set at the front end of the housing 1. The input terminal of the microcontroller 2 is electrically connected to an external power supply and can regulate the electrical components inside the device.

[0026] The casing 1 has a limit plate 9 on its right side and a fixing plate 10 on its right side bottom wall. A vertical plate 11 is slidably connected to a groove on the right side of the bottom wall of the casing 1. A reed 12 is located at the upper end of the vertical plate 11, between the right side of the protective box 61 and the left side of the limit plate 9. An electric push rod 13 is located in the middle of the left end of the fixing plate 10. The left end of the telescopic end of the electric push rod 13 is fixedly connected to the right end of the vertical plate 11. The input end of the electric push rod 13 is electrically connected to the output end of the microcontroller 2. Under the control of the microcontroller 2, the electric push rod 13 starts to operate, its telescopic end shortens, and the electric push rod 13 passes through the vertical plate 1... 1. Move the reed 12 to the right. During the movement of the reed 12, the right end of the reed 12 will contact the left end of the weft thread. Then the reed 12 will move to the right with the weft thread passing through the shed. At this time, the sliding contact between the upright plate 11 and the inner wall of the groove on the right side of the bottom wall of the machine housing 1 will provide a guiding support, reduce the radial force applied by the reed 12 to the electric push rod 13, and prevent the extension end of the electric push rod 13 from bending and deforming (the radial force of the electric push rod 13 is borne by the sliding of the upright plate 11, and the electric push rod 11 is only subjected to the left and right axial forces). When the right end of the reed 12 contacts the left end of the limiting plate 9, it means that the weft thread passing through the shed has been moved to the appropriate position.

[0027] The machine housing 1 has a conveyor roller 7 and a take-up roller 8 rotatably connected to the right side of the housing. The conveyor roller 7 is located between the left end of the take-up roller 8 and the right end of the limiting plate 9. The lower side of the housing 1 is equipped with a second conveyor motor 15. The rear end of the output shaft of the second conveyor motor 15 is fixedly connected to the front end of the take-up roller 8. The input end of the second conveyor motor 15 is electrically connected to the output end of the microcontroller 2. Through the control of the microcontroller 2, the first conveyor motor 14 starts to run. The output shaft of the first conveyor motor 14 drives the unwinding roller 3 to rotate and unwind the wire.

[0028] The machine housing 1 has a wire feeding roller 3 and a guide roller 4 rotatably connected to the left side of the interior. The guide roller 4 is located to the left of the wire separating plate 5, and the wire feeding roller 3 is located to the left of the guide roller 4. A conveyor motor 14 is installed on the lower side of the front end of the machine housing 1. The rear end of the output shaft of the conveyor motor 14 is fixedly connected to the front end of the wire feeding roller 3. The input end of the conveyor motor 14 is electrically connected to the output end of the microcontroller 2. Through the control of the microcontroller 2, the conveyor motor 25 starts to run. The output shaft of the conveyor motor 25 drives the winding roller 8 to wind up the woven fiber paper blend mat.

[0029] The working principle of the novel fiber-paper blended mat weaving machine provided by this utility model is as follows: During the use of the novel fiber-paper blended mat weaving machine, the conveyor motor 14 starts running under the control of the microcontroller 2. The output shaft of the conveyor motor 14 drives the pay-off roller 3 to rotate. During the rotation of the pay-off roller 3, it releases the warp threads wound on the outer arc surface. Then, the operator pulls these warp threads to the right. During the movement of the warp threads, the lower surface of the warp threads first contacts the outer arc surface of the guide roller 4. Then, these warp threads pass sequentially through the dividing opening at the right end of the dividing plate 5. Next, the warp threads pass sequentially through the dividing ring 63 and the dividing ring 65. Because the heights of the dividing rings 63 and 65 are different... Therefore, the warp threads are divided into upper and lower layers. The channel formed between these two layers is called the shed. The operator continues to pull the warp threads to the right, allowing them to pass sequentially through the clearance groove at the right end of the reed. The lower surface of the warp threads then contacts the outer arc surface of the conveying roller 7, at which point the two layers of warp threads merge. Finally, the merged warp threads are wound around the outside of the winding roller 8. During winding, the operator adjusts the tension of the warp threads according to the actual situation. After winding, the conveying motor 14 stops running under the control of the microcontroller 2. Then, the external mechanism drives the external shuttle to move. During the shuttle's movement, the shuttle guides the weft threads through the shed from front to back. After the shuttle guides the weft threads through the shed from front to back, the external mechanism... The control device sends a signal to the microcontroller 2 via its built-in data transmission module. The microcontroller 2 receives the signal through its built-in serial communication port. Then, under the control of the microcontroller 2, the electric push rod 13 starts operating. The telescopic end of the electric push rod 13 shortens, and the electric push rod 13 drives the reed 12 to move to the right via the upright plate 11. During the movement of the reed 12, its right end contacts the left end of the weft thread. Then, the reed 12 carries the weft thread passing through the shed to the right. At this time, the upright plate 11 provides a guiding support, reducing the radial force exerted by the reed 12 on the electric push rod 13 and preventing the telescopic end of the electric push rod 13 from bending and deforming (the radial force of the electric push rod 13 is borne by the sliding of the upright plate 11, and the electric push rod 11 is only subjected to...). (To the left and right axial force), when the right end of the reed 12 contacts the left end of the limiting plate 9, it means that the right end of the weft thread is in contact with the intersection of the two layers of warp threads, which can tighten the weft thread. At this time, through the control of the microcontroller 2, the telescopic end of the electric push rod 13 shortens. The electric push rod 13 drives the reed 12 to move to the left and reset through the upright plate 11. The telescopic length and the extension length of the electric push rod 13 are the same. Then, through the control of the microcontroller 2, the first conveyor motor 14 and the second conveyor motor 15 start to run. The output shaft of the first conveyor motor 14 drives the unwinding roller 3 to rotate and unwind the thread. The output shaft of the second conveyor motor 15 drives the winding roller 8 to wind up the woven fiber paper blend mat. The unwinding length and the winding length are equal to the width of the weft thread.The microcontroller 2 controls the length of wire feeding by the feeding roller 3 and the length of wire winding by the winding roller 8 via the first conveyor motor 14 and the second conveyor motor 15. After the feeding and winding operations are completed, the microcontroller 2 controls the feeding roller 14 and the second conveyor motor 15 to stop running. The locking components inside the feeding roller 14 and the second conveyor motor 15 can lock the rotor after power is cut off, thereby achieving a self-locking effect. At the same time, the microcontroller 2 controls the servo motor 668 to start running. The output shaft of the servo motor 668 drives the screw 666 to rotate. During the rotation of the screw 666, it drives the pusher plate 664 to move to the right through the threaded connection. At this time, the bellows 667 on the left extends and the bellows 667 on the right retracts. The bellows 667 prevents the screw 666 from directly contacting the external environment. The push plate 663 drives the adjusting plate 665 to move. At this time, the drive rod 663 slides and rotates relative to the adjusting groove inside the adjusting groove, thereby moving the drive rod 663 along the inclined surface of the adjusting groove. The drive rod 663 drives the sliding column 1 62 and sliding column 2 64 to move through the connecting plate 662. The sliding column 1 62 and sliding column 2 64 drive the dividing ring 1 63 and dividing ring 2 65 to move. At this time, the dividing ring 1 63 moves downward, while the dividing ring 2 65 moves downward. Moving upwards, when the left drive rod 663 contacts the bottom wall of the left adjustment groove, the right drive rod 663 will also contact the top wall of the right adjustment groove. This indicates that the first thread ring 63 and the second thread dividing ring 65 have moved to the designated working position. Then, through the control of the microcontroller 2, the servo motor 668 stops running. The slope, height, and width of the two adjustment grooves are the same, so the moving distance of the first thread ring 63 and the second thread dividing ring 65 is also the same. The first thread ring 63 and the second thread dividing ring 65 will drive the corresponding warp threads to move. The warp threads that were originally at the higher position will descend, while the warp threads at the bottom will rise. This will create a new shed between the warp threads, and the subsequent single-chip microcontroller... Microcontroller 2 transmits a signal to an external control device via its built-in serial communication port. The external control device receives the signal from microcontroller 2 through its built-in data transmission module, and then uses an external drive device to move the shuttle. During the shuttle's movement, the shuttle guides the weft yarn through the shed from back to front. Once the shuttle guides the weft yarn through the shed from back to front, it signifies the completion of one complete weaving cycle. This weaving operation is repeated to produce the desired fiber-paper blended cooling mat. Both the weft and warp yarns are made of a mixture of special paper and yarn. This type of mat is used to replace bamboo strips and is an environmentally friendly, biodegradable fiber material.

[0030] It is worth noting that the microcontroller 2 disclosed in the above embodiments can be an AT89C51, the servo motor 668 can be a 130ZFMA1-0003CBNM, the electric actuator 13 can be a dytp2000-550 / 50-x, and the first conveyor motor 14 and the second conveyor motor 15 can be DV132S4 / BMG. The microcontroller 2 controls the operation of the servo motor 668, the electric actuator 13, the first conveyor motor 14, and the second conveyor motor 15 using methods commonly used in the prior art.

[0031] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.

Claims

1. A novel fiber-paper blended mat weaving machine, comprising a housing (1), wherein a thread separating plate (5) is provided on the left side inside the housing (1), and thread separating holes are respectively provided on the right end of the thread separating plate (5), characterized in that: It also includes an opening mechanism (6); Opening mechanism (6): It includes a protective box (61), a sliding column one (62), a dividing ring one (63), a sliding column two (64), a dividing ring two (65), and an adjusting component (66). The protective box (61) is located in the middle of the bottom wall of the housing (1). The sliding columns one (62) and two (64) are slidably connected in the sliding holes on the left and right sides of the top wall of the protective box (61). The upper ends of the sliding columns one (62) and two (64) are respectively provided with dividing ring one (63) and two (65). The dividing ring one (63) is spaced apart from the longitudinally adjacent dividing ring two (65). The dividing ring one (63) and two (65) correspond to the left and right positions of the transversely adjacent dividing holes. The adjusting component (66) is located inside the protective box (61). The dividing ring one (63) and two (65) are driven by the adjusting component (66).

2. The novel fiber-paper blended mat weaving machine according to claim 1, characterized in that: The front end of the housing (1) is provided with a microcontroller (2), and the input terminal of the microcontroller (2) is electrically connected to an external power supply.

3. The novel fiber-paper blended mat weaving machine according to claim 2, characterized in that: The adjustment assembly (66) includes a fixed rod (661), a connecting plate (662), a drive rod (663), a push plate (664), and an adjustment plate (665). The fixed rods (661) are respectively located on the left and right sides inside the protective box (61). The upper ends of two longitudinally adjacent fixed rods (661) are slidably connected to the guide sliding holes corresponding to the lower ends of a connecting plate (662). The lower ends of longitudinally adjacent sliding pins one (62) and sliding pin two (64) are respectively fixedly connected to the upper ends of a vertically adjacent connecting plate (662). The rear ends of the two connecting plates (662) are each provided with a drive rod (663). The push plate (664) is slidably connected in the mounting groove opened on the rear side of the bottom wall of the protective box (61). The upper end of the push plate (664) is provided with an adjustment plate (665). The left and right sides of the front end of the adjustment plate (665) are respectively provided with adjustment grooves. The rear ends of the drive rod (663) are respectively located inside the longitudinally adjacent adjustment grooves.

4. The novel fiber-paper blended mat weaving machine according to claim 3, characterized in that: The adjustment assembly (66) also includes a screw (666), a bellows (667), and a servo motor (668). The screw (666) is rotatably connected to the rear side inside the protective box (61). The push plate (664) is threaded to the middle of the outer arc surface of the screw (666) through a threaded hole set in the middle of its right end. Bellows (667) are respectively set between the left and right ends of the push plate (664) and the inner wall of the protective box (61). The bellows (667) are respectively sleeved on the outside of the left and right sides of the screw (666). The servo motor (668) is set on the lower side of the right end of the protective box (61). The left end of the output shaft of the servo motor (668) is fixedly connected to the right end of the screw (666). The input end of the servo motor (668) is electrically connected to the output end of the microcontroller (2).

5. The novel fiber-paper blended mat weaving machine according to claim 2, characterized in that: A limiting plate (9) is provided on the right side inside the housing (1). A fixing plate (10) is provided on the right side of the bottom wall of the housing (1). A vertical plate (11) is slidably connected in the groove opened on the right side of the bottom wall of the housing (1). A steel reed (12) is provided at the upper end of the vertical plate (11). The steel reed (12) is located between the right side of the protective box (61) and the left side of the limiting plate (9). An electric push rod (13) is provided in the middle of the left end of the fixing plate (10). The left end of the telescopic end of the electric push rod (13) is fixedly connected to the right end of the vertical plate (11). The input end of the electric push rod (13) is electrically connected to the output end of the microcontroller (2).

6. The novel fiber-paper blended mat weaving machine according to claim 5, characterized in that: Inside the housing (1), on the right side, a conveying roller (7) and a winding roller (8) are rotatably connected. The conveying roller (7) is located between the left end of the winding roller (8) and the right end of the limiting plate (9). A second conveying motor (15) is provided on the lower side of the housing (1). The rear end of the output shaft of the second conveying motor (15) is fixedly connected to the front end of the winding roller (8). The input end of the second conveying motor (15) is electrically connected to the output end of the microcontroller (2).

7. The novel fiber-paper blended mat weaving machine according to claim 2, characterized in that: Inside the housing (1), on the left side, a wire feeding roller (3) and a guide roller (4) are rotatably connected. The guide roller (4) is located on the left side of the wire separator (5), and the wire feeding roller (3) is located on the left side of the guide roller (4). A first conveyor motor (14) is provided on the lower side of the front end of the housing (1). The rear end of the output shaft of the first conveyor motor (14) is fixedly connected to the front end of the wire feeding roller (3). The input end of the first conveyor motor (14) is electrically connected to the output end of the microcontroller (2).