Modular wide fabric loom
By using modularly designed interlocking panels, installation and splicing components, moving components, and connecting components, the operational difficulties of handling and maintaining wide-width fabric looms have been solved, enabling convenient disassembly and assembly and improving operational efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- SHIJIAZHUANG TEXTILE MACHINERY
- Filing Date
- 2026-04-13
- Publication Date
- 2026-06-05
AI Technical Summary
Existing wide-width fabric looms require synchronized operation during handling and maintenance, which makes operation difficult and inconvenient.
The modular design allows for the disassembly and assembly of the loom through the cooperation of interlocking plates, mounting and splicing components, moving components, and connecting components, facilitating handling and maintenance.
It enables convenient handling and maintenance of looms, reduces reliance on specialized tools, and improves targeting and operational efficiency.
Smart Images

Figure CN122147600A_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of weaving technology, specifically, it relates to a modular wide-width fabric weaving machine. Background Technology
[0002] Wide-width fabric looms are key equipment in weaving machinery used to produce wide-width fabrics. They are characterized by high efficiency and flexibility. The loom feeds the warp yarns evenly through the warp feeding mechanism, the weft insertion mechanism introduces the weft yarns into the shed formed by the warp yarns, the beat-up mechanism pushes the weft yarns towards the weft end, causing the warp and weft yarns to interweave, and finally the take-up mechanism winds up the woven fabric.
[0003] When processing wide-width fabrics, the width of the fabric is large, and therefore the width of the loom is also large. If the fabric is moved or some parts of the loom are repaired, the entire loom needs to be moved synchronously using large equipment, which is difficult and troublesome to operate and makes it difficult to carry out targeted repairs and moving. Therefore, a modular wide-width fabric loom is proposed. Summary of the Invention
[0004] The purpose of this invention is to provide a modular wide-width fabric loom that solves the technical problem in related technologies where the entire loom needs to be moved synchronously during transport or maintenance, which is quite troublesome.
[0005] At least one embodiment of the present invention provides a modular wide-width fabric loom, including a main frame, a warp feeding mechanism, and a take-up mechanism, and further including a splicing plate, a mounting and splicing assembly, a moving assembly, and a connecting assembly. Two splicing plates are fixedly installed on the side of the main frame. The mounting and splicing assembly is disposed on the take-up mechanism for mounting the take-up mechanism on the side of the main frame. The moving assembly is disposed on the take-up mechanism for pushing the take-up mechanism to move. The connecting assembly is disposed on the warp feeding mechanism for connecting the warp feeding mechanism and the take-up mechanism.
[0006] To facilitate the movement of the winding mechanism or its installation on the side of the main frame, the moving assembly further includes a crossbar, first moving wheels, and a pushing assembly. Two crossbars are mounted on the winding mechanism, and several first moving wheels are mounted on the bottom end of each crossbar. The pushing assembly is disposed on the crossbar and includes a mounting block, a bracket, a first bolt, and a push rod. Two mounting blocks are fixedly mounted on the side of the crossbar. Slots are provided on the sides of the mounting blocks, and the bracket is installed within the slots. Threaded holes are provided on the mounting blocks and the brackets, and the first bolt is threaded into the threaded holes. The push rod is fixedly installed between the two brackets.
[0007] To enable the winding mechanism to be installed on the side of the main frame, the mounting assembly further includes a splicing frame, a fixing frame, and a stabilizing component. Two splicing frames are provided, both fixedly installed on the side of the winding mechanism. The fixing frame is fixedly installed between the two mating plates. The stabilizing component is mounted on the fixing frame and includes a stabilizing column and a stabilizing frame. Two stabilizing columns are provided, both slidably mounted on the fixing frame. The stabilizing frame is fixedly installed on the stabilizing column. The top of the fixing frame has a through groove that matches the bottom of the stabilizing frame, allowing the stabilizing frame to be inserted into the through groove. The sides of the mating plates have slots that match the sides of the splicing frame, and the tops of the splicing frame and the mating plates have stabilizing grooves that match the stabilizing columns, allowing the splicing frame to be inserted into the slots of the mating plates, thus performing initial installation.
[0008] To enable the warp feeding mechanism to be installed on the side of the main frame, the connecting assembly further includes a connecting block, a connecting plate, and a second bolt. The connecting blocks are fixedly installed on both sides of the main frame, and the connecting plates are rotatably installed on both sides of the warp feeding mechanism via a rotating shaft. Threaded holes are provided on the sides of both the connecting blocks and the connecting plates, and the second bolt is threaded into the threaded holes. A placement groove is provided on the connecting block, the width of which is greater than the width of the connecting plate, allowing the connecting plate to be rotated into the placement groove of the connecting block, thereby achieving connection. After connection and installation, several second moving wheels are installed at the bottom of the warp feeding mechanism. The second moving wheels, the first moving wheels, and the bottom of the main frame are all located at the same horizontal position. At this time, all parts of the device are located at the same horizontal position, thus enabling operation.
[0009] The present invention provides a modular wide-width fabric loom, which can be disassembled as a whole through the cooperation between the splicing plate, the installation splicing component, the moving component and the connecting component. When the loom needs to be used and installed, the warp feeding mechanism and the winding mechanism can be installed on both sides of the main frame by the installation splicing component and the connecting component respectively. After installation, the loom can be put into operation. After the operation is completed, if the loom needs to be moved or transported, the main frame, warp feeding mechanism and winding mechanism can be disassembled and transported in sequence. During the transport, the warp feeding mechanism can be moved by the second moving wheel at the bottom, and the winding mechanism can be moved by the moving component. Therefore, the movement is convenient and labor-saving. No special tools are required for disassembly and assembly, and the maintenance is highly targeted. Attached Figure Description
[0010] To more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0011] Figure 1 This is a schematic diagram of the overall structure provided in an embodiment of the present invention; Figure 2 This is an embodiment of the present invention. Figure 1 A schematic diagram of the structure of the winding mechanism, the moving component, the fitting plate, and the mounting and splicing component; Figure 3 This is an embodiment of the present invention. Figure 2 A magnified view of a portion of point A in the middle; Figure 4 This is an embodiment of the present invention. Figure 2 A magnified view of a portion of point B in the middle; Figure 5 This is a schematic diagram of the structure of the connecting component, the yarn feeding mechanism, and the second moving wheel of the present invention. Figure 6 This is a schematic diagram of the structure of the main frame, the fitting plate, and the connecting block of the present invention. Figure 7 This is a schematic diagram showing the disassembled assembly of the winding mechanism, the interlocking plate, and the splicing frame of the present invention. Figure 8 This is a schematic diagram of the structure of the winding mechanism, crossbar, warp feeding mechanism and connecting plate of the present invention.
[0012] In the diagram: 1. Main frame; 2. Warp feeding mechanism; 3. Winding mechanism; 4. Fitting plate; 5. Crossbar; 6. First moving wheel; 7. Mounting block; 8. Insert frame; 9. First bolt; 10. Push rod; 11. Splicing frame; 12. Fixing frame; 13. Stabilizing column; 14. Stabilizing frame; 15. Connecting block; 16. Connecting plate; 17. Second bolt; 18. Second moving wheel. Detailed Implementation
[0013] The specific embodiments of this disclosure will be described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are for illustration and explanation only and are not intended to limit this disclosure. For ease of understanding, the English abbreviations and related technical terms involved in the embodiments of this disclosure will be explained and described below.
[0014] It should be understood that the described embodiments are merely some, not all, of the embodiments disclosed herein. All other embodiments obtained by those skilled in the art based on the embodiments of this disclosure without inventive effort are within the scope of protection of this disclosure.
[0015] The terminology used in the embodiments of this disclosure is for the purpose of describing particular embodiments only and is not intended to be limiting of this disclosure. The singular forms “a,” “the,” and “the” as used in the embodiments of this disclosure and the appended claims are also intended to include the plural forms unless the context clearly indicates otherwise.
[0016] It should be understood that the term "and / or" used in this article is merely a way of describing the logical relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent: A existing alone, A and B existing simultaneously, and B existing alone. Additionally, the character " / " in this article generally indicates that the preceding and following related objects have an "or" relationship.
[0017] Depending on the context, the word "if" as used here can be interpreted as "when" or "when" or "in response to determination" or "in response to detection." Similarly, depending on the context, the phrase "if determination" or "if detection (of the stated condition or event)" can be interpreted as "when determination" or "in response to determination" or "when detection (of the stated condition or event)" or "in response to detection (of the stated condition or event)."
[0018] It should be understood that the terms "first," "second," etc., used in this disclosure are for distinguishing purposes only and should not be construed as indicating or implying relative importance or order.
[0019] In the description of this disclosure, the terms “center,” “upper,” “lower,” “front,” “back,” “left,” “right,” “vertical,” “horizontal,” “top,” “bottom,” “inner,” and “outer,” etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of describing this disclosure and simplifying the description, and are not intended to indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and should not be construed as a limitation of this disclosure.
[0020] In the description of this disclosure, it should be noted that, unless otherwise expressly specified and limited, the terms "installation", "connection" and "joining" should be interpreted broadly, for example, they can be fixed connections, detachable connections, mating connections or integral connections; those skilled in the art can understand the specific meaning of the above terms in this disclosure according to the specific circumstances.
[0021] like Figures 1-8 As shown, it illustrates a modular wide-width fabric loom according to an embodiment of the present invention, including a main frame 1, a warp feeding mechanism 2, and a winding mechanism 3. The warp feeding mechanism 2 continuously supplies warp yarns at a constant tension and uniform speed during the weaving process, thereby conveying them at a constant tension to the weaving core area of the main frame 1 for placement. After the main frame 1 has finished weaving, the winding mechanism 3 uniformly and at a constant tension winds up the woven fabric into a roll.
[0022] When weaving fabrics, such as Figure 2 , Figure 3 and Figure 7 As shown, the winding mechanism 3 is first installed on the side of the main frame 1 by installing splicing components. The splicing components include splicing frame 11, fixing frame 12 and stabilizing components. There are two splicing frames 11, and both splicing frames 11 are fixedly installed on the side of the winding mechanism 3. The fixing frame 12 is fixedly installed between two interlocking plates 4. The stabilizing components are set on the fixing frame 12. The stabilizing components include stabilizing columns 13 and stabilizing frames 14. There are two stabilizing columns 13, and both stabilizing columns 13 are slidably installed through the fixing frame 12. The stabilizing frames 14 are fixedly installed on the stabilizing columns 13.
[0023] The main frame 1 is divided into multiple sections. It should be noted that the main frame 1 adopts a welded steel frame structure. After the section frame is welded, it undergoes overall aging treatment and precision machining. The splicing interface is achieved by positioning pins + splicing flanges + high-strength bolts. The electrical components on the frame are equipped with multi-core aviation plugs, which connect with the aviation sockets reserved on the frame. The pneumatic components are equipped with pneumatic quick connectors, which connect with the air pipe splitter on the frame. The air pipes are arranged in the air pipe grooves of the frame, with unified air supply and individual pressure control.
[0024] Furthermore, the drive shaft and transmission shaft of the weft-beating mechanism on the main frame 1 are connected by a hydraulic coupling. During connection, the inner sleeve of the hydraulic coupling is hot-fitted / cold-fitted to the connecting end of the drive shaft, and the outer sleeve is fitted to the connecting end of the transmission shaft of the weft-beating mechanism. Then, the segmented frame is slowly pushed so that the drive shaft and transmission shaft of the inner and outer sleeves come closer to each other, completing the fitting and docking of the inner and outer sleeves of the coupling. Then, the high-pressure oil pipe is connected to the radial oil inlet of the hydraulic coupling, and the other oil pipe is connected to the axial oil inlet. The hydraulic oil pump is started, and high-pressure oil is injected into the radial oil passage first, so that the outer sleeve of the coupling expands under oil pressure and the inner sleeve contracts, forming an elastic interference fit clearance. Simultaneously, low-pressure oil is injected into the axial oil passage, pushing the outer sleeve of the coupling to slowly slide along the tapered surface of the shaft section to the preset positioning position. The segmented connection of the drive shaft and transmission shaft can also be achieved through the hydraulic coupling.
[0025] Specifically, the winding mechanism 3 is pushed towards the main frame 1 until the splicing frame 11 on the side of the winding mechanism 3 contacts and aligns with the fitting plate 4 on the side of the main frame 1. This stops the movement because the side of the fitting plate 4 has a slot that matches the side of the splicing frame 11, and the top of the splicing frame 11 and the fitting plate 4 have a stabilizing groove that matches the stabilizing post 13. At this time, the splicing frame 11 is inserted into the slot of the fitting plate 4. The stabilizing post 13 can then be lowered so that the bottom end of the stabilizing post 13 passes through the stabilizing groove of the fitting plate 4 and the splicing frame 11, thereby fixing the splicing frame 11 in the fitting plate 4. Since the top of the fixing frame 12 has a through groove that matches the bottom end of the fixing frame 14, the fixing frame 14 passes through the through groove of the fixing frame 12, thereby further reinforcing the connection.
[0026] When moving the winding mechanism 3, such as Figure 2 and Figure 4 As shown, the mechanism can be easily moved by a moving component, which includes a crossbar 5, first moving wheels 6, and a pushing component. Two crossbars 5 are mounted on the winding mechanism 3. Several first moving wheels 6 are mounted on the bottom end of the crossbars 5. The pushing component is mounted on the crossbars 5 and includes mounting blocks 7, inserts 8, first bolts 9, and push rods 10. Two mounting blocks 7 are fixedly mounted on the side of the crossbar 5. Slots are provided on the side of the mounting blocks 7, and inserts 8 are installed in the slots of the mounting blocks 7. Threaded holes are provided on the mounting blocks 7 and inserts 8, and the first bolts 9 are threaded into the threaded holes. The push rods 10 are fixedly mounted on the two inserts 8. Specifically, the crossbar 5 is fixedly installed on the support frame of the winding mechanism 3. Before pushing, the operator can insert the two inserts 8 into the slots of the two mounting blocks 7 respectively, and then connect them with the first bolt 9 to fix the inserts 8 and the mounting blocks 7. When pushing, the operator can use the push rod 10 to drive the winding mechanism 3 to move through the first moving wheel 6 at the bottom. After installation, the first bolt 9 can be unscrewed, and the inserts 8 and push rod 10 can be removed from the crossbar 5, thus leaving space on the side of the winding mechanism 3 for installation when the winding mechanism 3 needs to be pushed later.
[0027] It should be added that the winding mechanism 3 is divided into multiple segments. The winding frame and winding shaft of the winding mechanism 3 are connected by flanges and fastening bolts during subsequent splicing. The winding shaft of the winding mechanism 3 is also divided into multiple segments, and these segments are connected by internal splines. Specifically, the spline connection ends of the segmented winding shafts are finely processed. After the winding frame is spliced and installed using positioning pins and high-strength bolts, the bearing seats of each winding shaft are on the same horizontal axis. Then, the internal spline sleeve is heated to 150~200℃ using a heat fitting method, and then smoothly fitted onto the external spline connection end of one segment of the winding shaft using thermal expansion and contraction. After natural cooling, an interference fit is formed. Then, the other segmented winding shaft is slowly pushed, and its external spline shaft end is precisely inserted into the internal spline sleeve along the horizontal axis, completing the core connection of the two shaft segments.
[0028] like Figure 8 As shown, it should also be noted that the movable wheel 5 is telescopically and detachably installed at the bottom of the crossbar 5 and the yarn feeding mechanism 2. The movable wheel 5 is installed when moving and retracted or detached when moving to the designated position, so that the yarn feeding mechanism 2 and the crossbar 5 can contact the ground for support, thus avoiding damage to the movable wheel 5 caused by relying solely on the movable wheel 5 for support.
[0029] After the winding mechanism 3 is installed, as follows Figure 5 As shown, the yarn feeding mechanism 2 can be installed on the side of the main frame 1 via a connecting assembly. The connecting assembly includes a connecting block 15, a connecting plate 16, and a second bolt 17. Connecting blocks 15 are fixedly installed on both sides of the main frame 1, and connecting plates 16 are rotatably installed on both sides of the yarn feeding mechanism 2 via a rotating shaft. Threaded holes are provided on the sides of both the connecting blocks 15 and the connecting plates 16, and the second bolt 17 is threaded into these holes. Specifically, because several second moving wheels 18 are installed at the bottom of the yarn feeding mechanism 2, the yarn feeding mechanism 2 can be moved and transported via the second moving wheels 18. When transported to the side of the main frame 1, a placement groove is provided on the connecting block 15, and the width of the placement groove... The width of the connecting plate 16 is greater than that of the connecting plate 16, so that the connecting plate 16 can be rotated smoothly into the placement slot of the connecting block 15. After the connecting plate 16 is rotated into the placement slot of the connecting block 15, the threaded holes of the connecting block 15 and the connecting plate 16 correspond. At this time, the second bolt 17 can be threaded to connect the warp feeding mechanism 2 to the main frame 1. The second moving wheel 18, the first moving wheel 6 and the bottom of the main frame 1 are all at the same horizontal position. After the loom is assembled, the main frame 1, the warp feeding mechanism 2 and the winding mechanism 3 are all placed horizontally on the ground. At this time, the first moving wheel 6 and the second moving wheel 18 can be self-locked, and then subsequent operations can be carried out.
[0030] It should be added that the warp feeding mechanism is divided into multiple sections, which allows for segmented transportation during transport and splicing of multiple sections during use. During installation, the use of positioning pins and fastening flanges enables millimeter-level alignment of the frames between sub-units through high-precision positioning pins and quick locking through flanges. At the same time, the frame splicing points are reinforced. The tension sensor of each sub-unit is connected to the central tension control system of the whole machine. After splicing, the system automatically identifies the number of sub-units and distributes the total warp tension evenly to each section according to the weaving process.
[0031] In addition, each warp beam is equipped with a flange on its side. Multiple bolt holes are arranged around the flange. By tightening the bolts, the flanges can be spliced together, thereby connecting multiple warp beams. At the bottom of each flange, 2-3 rotating rollers are rotatably mounted on a support base. The bottom of the flange contacts the top of the rotating rollers. When the flange rotates with the warp beam, the rotating rollers at the bottom can provide support and rotate synchronously with the flange.
[0032] Working principle: When working with wide-width lightweight fabrics, the operator first inserts two brackets 8 into the slots of two mounting blocks 7, and then connects them with the first bolt 9 to fix the brackets 8 and mounting blocks 7. During pushing, the operator can use the push rod 10 to move the winding mechanism 3 via the first moving wheel 6 at the bottom until the splicing frame 11 is inserted into the slot of the interlocking plate 4. At this point, the stabilizing column 13 can be lowered, with its bottom end penetrating the stabilizing groove of the interlocking plate 4 and the splicing frame 11, thus fixing the splicing frame 11 within the interlocking plate 4. Then, the stabilizing frame 14 is inserted through the through groove of the fixing frame 12 for further reinforcement. Then, the second moving wheel 18 is used to move the yarn feeding mechanism 2 to the side of the main frame 1, and the connecting plate 16 is rotated into the placement groove of the connecting block 15. At this time, the threaded holes of the connecting block 15 and the connecting plate 16 correspond to each other, and the second bolt 17 can be threaded to connect the yarn feeding mechanism 2 to the main frame 1. The second moving wheel 18, the first moving wheel 6 and the bottom of the main frame 1 are all at the same horizontal position. At this time, the main frame 1, the yarn feeding mechanism 2 and the winding mechanism 3 are all placed horizontally on the ground. Finally, the first moving wheel 6 and the second moving wheel 18 are self-locked, and then the subsequent operations are carried out.
[0033] During operation, the warp beam of the warp feed mechanism 2 rotates at a constant speed according to the weaving speed of the main frame 1 under the drive of the motor, releasing the wound warp yarns. The damping wheel at the end of the warp beam adjusts the initial unwinding resistance, completing the coarse adjustment of the warp yarn tension. After the warp yarns are released, they pass through the warp tension sensor of the warp feed mechanism 2 in sequence. The sensor collects the warp yarn tension data and uploads it to the control system. The control system adjusts the speed of the warp feed motor in a timely manner to ensure that the warp yarn tension is uniform in the width direction, so that it is delivered straight and at a constant speed to the weaving core area of the main frame 1. It should be added that the weft insertion mechanism is fixed to the weaving core area of the main frame 1 and aligned with the warp yarn delivery trajectory of the warp feed mechanism 2 to ensure weaving accuracy.
[0034] The drive motor rotates the high-speed shaft, which serves as the main power shaft. Through the transmission components, it drives multiple reducers to move synchronously. On one hand, power is transmitted to the beat-up mechanism, and on the other hand, power is transmitted to the heald frame opening mechanism. The power diverted to the beat-up mechanism drives the reed seat to beat up the weft through the four-bar linkage. Through the reciprocating motion of the four-bar linkage, the yarn introduced into the shed is compacted to the weft opening, making the warp and weft yarns tightly interwoven. Another power diverted to the heald frame opening mechanism drives the heald frame to move up and down reciprocally through the cam profile. The healds on the heald frame drive the warp yarns to move up and down alternately, forming the shed for the weft yarn to pass through. Furthermore, the shuttle beat-up motor has an independent support structure, without oscillating inertial impact, thus ensuring that the beat-up force of the four-bar linkage is uniform across the entire width, avoiding uneven warp and weft density or wrinkling in some areas of the fabric.
[0035] The shaped fabric continuously output from the main frame 1 is first attached to the curved support plate and conveyed forward. The fabric is then conveyed from the main frame 1 to the winding mechanism 3. The curved surface of the curved support plate matches the natural drooping curvature of the wide and lightweight fabric, thereby supporting the fabric and preventing it from sagging in the middle, which could cause stretching or creases. After the fabric is output from the curved support plate, it passes through the two guide rollers of the winding mechanism 3 in sequence, completing the final orientation before winding. Both ends of the two guide rollers are equipped with servo motors. The two servo motors are driven by the control system to send a unified speed command, so that the rotation of the guide rollers is synchronously driven with completely consistent speed and torque, thereby ensuring that the wide and lightweight fabric is wound in a regular posture.
[0036] It should be added that the wide-width lightweight fabric is a lightweight material, so it will not put too much pressure on the device when it is lifted. In addition, the first moving wheel 6 and the second moving wheel 18 are made of the same material and both adopt the universal wheel with a foot pedal self-locking structure. During weaving, they can be fixed by self-locking to prevent slippage, and then unlocked during transportation.
[0037] Finally, it should be noted that the above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A modular wide-width fabric loom, comprising a main frame (1), a warp feeding mechanism (2), and a winding mechanism (3), characterized in that, Also includes: Two of the aforementioned interlocking plates (4) are fixedly installed on the side of the main frame (1). The splicing assembly is installed on the winding mechanism (3) and is used to install the winding mechanism (3) on the side of the main frame (1); A movable component is disposed on the winding mechanism (3) for pushing the winding mechanism (3) to move; A connecting component is disposed on the warp feeding mechanism (2) for connecting the warp feeding mechanism (2) and the winding mechanism (3).
2. The modular wide-width fabric weaving machine according to claim 1, characterized in that, The moving component includes: Crossbar (5), two of the crossbars (5) are installed on the winding mechanism (3); The first moving wheel (6) is installed at the bottom end of the crossbar (5). A pushing component is disposed on the crossbar (5).
3. A modular wide-width fabric weaving machine according to claim 2, characterized in that, The actuating component includes: Mounting blocks (7), two mounting blocks (7) are fixedly installed on the side of the crossbar (5); The bracket (8) has a slot on the side of the mounting block (7), and the bracket (8) is installed in the slot of the mounting block (7). The first bolt (9) has threaded holes on the mounting block (7) and the insert (8), and the first bolt (9) is threadedly installed in the threaded holes; A push rod (10) is fixedly installed between the two inserts (8).
4. A modular wide-width fabric weaving machine according to claim 3, characterized in that, The installation and splicing components include: Splicing frame (11), two splicing frames (11) are provided, and both splicing frames (11) are fixedly installed on the side of the winding mechanism (3); A fixing frame (12) is fixedly installed between the two interlocking plates (4); A stabilizing component is disposed on the fixing frame (12).
5. A modular wide-width fabric weaving machine according to claim 4, characterized in that, The stabilizing component includes: Stabilizing column (13), two stabilizing columns (13) are provided, and both stabilizing columns (13) are slidably mounted on the fixing frame (12); The stabilizing frame (14) is fixedly installed on the stabilizing column (13).
6. A modular wide-width fabric weaving machine according to claim 5, characterized in that, The connection component includes: Connecting blocks (15) are fixedly installed on both sides of the main frame (1). The connecting plate (16) is rotatably mounted on both sides of the feeding mechanism (2) via a rotating shaft. The second bolt (17) has threaded holes on the sides of both the connecting block (15) and the connecting plate (16), and the second bolt (17) is threadedly installed in the threaded holes.
7. A modular wide-width fabric weaving machine according to claim 2, characterized in that, The bottom end of the feeding mechanism (2) is equipped with several second moving wheels (18), and the bottom ends of the second moving wheels (18), the first moving wheel (6) and the main frame (1) are all located at the same horizontal position.
8. A modular wide-width fabric weaving machine according to claim 5, characterized in that, The side of the splicing plate (4) is provided with a slot that matches the side of the splicing frame (11), and the top of the splicing frame (11) and the splicing plate (4) are provided with a stabilizing groove that matches the stabilizing column (13).
9. A modular wide-width fabric weaving machine according to claim 5, characterized in that, The top of the fixed frame (12) is provided with a through groove that matches the bottom of the stabilizing frame (14).
10. A modular wide-width fabric weaving machine according to claim 6, characterized in that, The connecting block (15) has a placement groove, the width of which is greater than the width of the connecting plate (16).