A flexible assembly polymer sheet slitting mechanism

The flexible assembly polymer sheet slitting mechanism solves the problems of high resource consumption and poor applicability in existing technologies, and realizes efficient slitting of multi-specification equipment, improving processing efficiency and functionality.

CN224446181UActive Publication Date: 2026-07-03安徽高伟新材料科技有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
安徽高伟新材料科技有限公司
Filing Date
2025-07-15
Publication Date
2026-07-03

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Abstract

The utility model discloses a kind of high molecular sheet material slitting mechanisms of flexible assembly, belong to high molecular sheet material processing technical field.A kind of high molecular sheet material slitting mechanisms of flexible assembly, including bearing assembly frame, the inside of bearing assembly frame is preassigned tool assembly bearing cavity, the two side positions of bearing assembly frame back are fixedly installed with primary positioning fastening screw rod, the two side positions of bearing assembly frame back are movably installed with positioning firm support, the bottom of positioning firm support is fixedly installed with alignment mounting bracket, the inside movably installed with sliding counterplate of alignment mounting bracket.The utility model is assembled between with forming equipment or conveying equipment rack, realize the use effect of replacing existing slitting equipment with non-driving mechanism, can be pushed by forming equipment or conveying equipment to the pushing force generated by high molecular sheet material, realize sheet material discharging slitting use effect in discharging position.
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Description

Technical Field

[0001] This utility model relates to the field of polymer sheet processing technology, and more specifically, to a flexible assembly polymer sheet cutting mechanism. Background Technology

[0002] Slitting is a crucial processing step in the production and use of polymer sheets. Slitting is performed according to the required application scenarios to meet the usage conditions of polymer sheets in different situations.

[0003] However, most existing slitting mechanisms used in polymer sheet processing suffer from several drawbacks. They are largely driven by a single device, resulting in high resource consumption and increased costs. Furthermore, they are often independent slitting machines, requiring transfer and movement of the polymer sheets after forming, further increasing processing time and slowing down overall processing efficiency. Additionally, the slitting mechanisms are not compatible with various equipment specifications, hindering flexible assembly and significantly limiting applicability. Moreover, the slitting blades cannot be adjusted in distance, position, or quantity according to specific slitting needs, further restricting functionality. Ultimately, these slitting mechanisms have a narrow application scope and limited prospects in the polymer sheet slitting field. Utility Model Content

[0004] The purpose of this invention is to overcome the shortcomings of the prior art and provide a flexible assembly polymer sheet cutting mechanism to solve the above-mentioned deficiencies.

[0005] To achieve the above objectives, the technical solution provided by this utility model is as follows:

[0006] This utility model discloses a flexible assembly polymer sheet cutting mechanism, including a load-bearing assembly frame. The load-bearing assembly frame has a pre-set tool assembly bearing cavity inside. Primary positioning and fastening screws are symmetrically fixed on both sides of the back of the load-bearing assembly frame. Positioning and stabilizing brackets are symmetrically and movably installed on both sides of the back of the load-bearing assembly frame. A loading receiving block is movably installed inside the tool assembly bearing cavity. A receiving sliding adjustment rod is horizontally fixed on the upper side of the positioning and stabilizing bracket. An alignment mounting bracket is fixedly installed at the bottom of the positioning and stabilizing bracket. A sliding clamping plate is movably installed inside the alignment mounting bracket.

[0007] As a preferred embodiment of the polymer sheet cutting mechanism for flexible assembly described in this utility model, wherein: positioning sliding adjustment grooves are symmetrically and laterally opened at the upper and lower ends of both sides of the back of the bearing assembly frame; alignment sliding connection adjustment blocks are symmetrically and fixedly installed at the upper and lower ends of the side of the receiving sliding adjustment rod; the external specifications of the alignment sliding connection adjustment blocks correspond and match with the internal specifications of the positioning sliding adjustment grooves; and the receiving sliding adjustment rod is slidably connected to the positioning sliding adjustment grooves through the alignment sliding connection adjustment blocks.

[0008] As a preferred embodiment of the flexible assembly polymer sheet cutting mechanism of this utility model, wherein: an assembly width adjustment groove is laterally opened at the middle position of the outer side of the receiving sliding adjustment rod, the height dimension of the assembly width adjustment groove corresponds to and matches the outer diameter dimension of the primary positioning fastening screw, the primary positioning fastening screw is movably installed with a primary positioning fastening screw sleeve through the assembly width adjustment groove, and the internal thread specification of the primary positioning fastening screw sleeve corresponds to and matches the external thread specification of the primary positioning fastening screw.

[0009] By using the sliding connection structure between the alignment sliding connection adjustment block and the positioning sliding adjustment groove, and adopting the threaded adaptation structure between the primary positioning fastening screw and the primary positioning fastening sleeve, the overall assembly width dimension can be appropriately adjusted and fastened according to the specific frame specifications being assembled.

[0010] As a preferred embodiment of the flexible assembly polymer sheet slitting mechanism of this utility model, the following features are provided: a tool adjustment loading groove is laterally provided at the bottom of the tool assembly bearing cavity; a directional fastening groove is laterally provided at the upper end of the bearing assembly frame; the directional fastening groove passes through the upper end of the bearing assembly frame and communicates with the inside of the tool assembly bearing cavity; the external specifications of the loading receiving block correspond to and match the internal specifications of the tool assembly bearing cavity; a tool adjustment sliding connecting block is fixedly installed at the bottom of the loading receiving block; the loading receiving block is slidably connected to the tool adjustment loading groove through the tool adjustment sliding connecting block; the external specifications of the tool adjustment sliding connecting block correspond to and match the internal specifications of the tool adjustment loading groove; a secondary positioning fastening screw is fixedly installed at the upper end of the loading receiving block; a secondary positioning fastening sleeve is movably installed on the secondary positioning fastening screw through the directional fastening groove; the internal thread specifications of the secondary positioning fastening sleeve are compatible with the external thread specifications of the secondary positioning fastening screw.

[0011] By using a sliding connection structure and corresponding fastening structure to load the receiving blocks inside the tool assembly bearing cavity, the mechanism can adjust the distribution distance and number of the loading receiving blocks inside the tool assembly bearing cavity according to specific cutting requirements, thus meeting different cutting quantity requirements.

[0012] In a preferred embodiment of the flexible assembly polymer sheet cutting mechanism of this utility model, the alignment mounting bracket has symmetrically formed clamping sliding grooves on both sides of its upper inner end. Clamping sliding connecting blocks are symmetrically fixedly installed on both sides of the upper upper end of the sliding clamping plate. The sliding clamping plates are slidably connected to the clamping sliding grooves via the clamping sliding connecting blocks. The external dimensions of the clamping sliding connecting blocks correspond to and match the internal dimensions of the clamping sliding grooves. A clamping thread groove is pre-set at the middle position of the outer side of the alignment mounting bracket. An alignment connecting rotating seat is fixedly installed at the middle position of the side of the sliding clamping plate. The clamping thread... A fastening adjusting bolt is movably installed inside the groove. A rotating connecting block is fixedly connected to the end of the fastening adjusting bolt. The external specifications of the rotating connecting block correspond to and match the internal specifications of the aligning connecting rotating seat. The external thread specifications of the fastening adjusting bolt are compatible with the internal thread specifications of the clamping thread groove. The fastening adjusting bolt is rotatably connected to the aligning connecting rotating seat through the rotating connecting block. Clamping compression pads are fixedly installed on the other side of the sliding clamping plate and the inner side of the aligning mounting bracket. At the same time, positioning and fastening screw holes are symmetrically opened on the bottom of the sliding clamping plate and the bottom of the inner side of the aligning mounting bracket.

[0013] By designing the mounting bracket as a flexible assembly structure with internal clamping and threaded fastening, the mechanism can be adjusted to the appropriate installation size according to the target equipment, achieving a flexible assembly effect applicable to various equipment specifications. The overall functionality is greatly enriched, thereby expanding the overall applicability.

[0014] As a preferred embodiment of the flexible assembly polymer sheet slitting mechanism of this utility model, wherein: a tool loading block is fixedly installed on the outside of the loading receiving block, a tool carrying assembly is movably installed inside the tool loading block, positioning and fastening sleeves are symmetrically fixedly installed at the upper and lower ends inside the tool loading block, positioning and assembly through holes are symmetrically opened at the upper and lower ends outside the tool carrying assembly, the internal specifications of the positioning and assembly through holes correspond and match with the external specifications of the positioning and fastening sleeves, a tool assembly fastening bolt is movably installed through the positioning and assembly through holes, the external thread specifications of the tool assembly fastening bolts are compatible with the internal thread specifications of the positioning and fastening sleeves, and a slitting tool is fixedly connected to the bottom of the tool carrying assembly, the cutting edge of the slitting tool facing the opposite direction of the tool assembly carrying cavity opened inside the carrying assembly frame;

[0015] By aligning and assembling the cutting blades outside the loading and receiving block, the cutting blades in this mechanism can be selected according to the specific needs of actual application and operation, making it suitable for polymer sheet cutting operations in different working environments, thus effectively enhancing its applicability.

[0016] Compared with the prior art, the technical solution provided by this utility model has the following advantages:

[0017] This utility model discloses a flexible assembly polymer sheet slitting mechanism. Through structural optimization and improvement, it is assembled with the frame of forming or conveying equipment to achieve the effect of replacing existing slitting equipment with a driveless mechanism. It can achieve sheet slitting at the discharge position by using the pushing force generated by the forming or conveying equipment. The overall multi-directional adjustable structure can perform flexible assembly operations with stable installation with various specifications of equipment, greatly improving the overall applicability. Furthermore, by adopting a sliding adjustment structure with fastening accessories for the cutter assembly, the mechanism can meet various usage requirements of polymer sheets during normal operation, effectively enriching the overall functionality and thus improving the overall comprehensive performance. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the front view of the disassembled structure of this utility model;

[0019] Figure 2 This is a schematic diagram of the rear view of the disassembled structure of this utility model;

[0020] Figure 3 This is a schematic diagram of the overall front structure of this utility model;

[0021] Figure 4 This is a schematic diagram of the overall rear view structure of this utility model;

[0022] Figure 5 This is a front view schematic diagram of the overall assembly width flexible adjustment structure of this utility model;

[0023] Figure 6 This is a front view schematic diagram of the overall assembly width flexible adjustment structure of this utility model;

[0024] Figure 7 This is a top-view structural diagram of the disassembled alignment and mounting bracket of this utility model;

[0025] Figure 8 This is a schematic diagram of the assembly structure of the slitting tool of this utility model.

[0026] In the diagram: 1. Load-bearing assembly frame; 2. Tool assembly load-bearing cavity; 3. Primary positioning fastening screw; 4. Positioning and stabilizing bracket; 5. Receiving sliding adjustment rod; 6. Alignment mounting bracket; 7. Positioning sliding adjustment groove; 8. Tool adjustment loading groove; 9. Orientation fastening groove; 10. Loading receiving block; 11. Assembly width adjustment groove; 12. Alignment sliding connection adjustment block; 13. Sliding clamping plate; 14. Clamping threaded groove; 15. Alignment connection rotating seat; 16. Clamping compression pad. 17. Adjusting bolt; 18. Positioning and fastening bolt hole; 19. Rotary connecting block; 20. Clamping sliding groove; 21. Clamping sliding connecting block; 22. Primary positioning fastening bolt sleeve; 23. Secondary positioning fastening bolt; 24. Tool loading block; 25. Secondary positioning fastening bolt sleeve; 26. Tool bearing assembly; 27. Positioning fastening sleeve; 28. Positioning assembly through hole; 29. ​​Tool assembly fastening bolt; 30. Slitting tool; 31. Tool adjusting sliding connecting block. Detailed Implementation

[0027] 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.

[0028] To further understand the content of this utility model, a detailed description of this utility model will be provided in conjunction with the accompanying drawings.

[0029] Combination Figures 1-8This utility model discloses a flexible assembly polymer sheet cutting mechanism, comprising a load-bearing assembly frame 1, a tool assembly load-bearing cavity 2, a primary positioning fastening screw 3, a positioning stabilizing bracket 4, a receiving sliding adjustment rod 5, an alignment mounting bracket 6, a positioning sliding adjustment groove 7, a tool adjustment loading groove 8, a directional fastening groove 9, a loading receiving block 10, an assembly width adjustment groove 11, an alignment sliding connection adjustment block 12, a sliding clamping plate 13, a clamping threaded groove 14, an alignment connection rotating seat 15, a clamping compression pad 16, a fastening adjustment bolt 17, a positioning mounting fastening screw hole 18, a rotating connection block 19, a clamping sliding groove 20, a clamping sliding connection block 21, a primary positioning fastening screw sleeve 22, a secondary positioning fastening screw 23, and a tool loading block 24. The system includes a secondary positioning fastening screw sleeve 25, a tool bearing assembly 26, a positioning fastening sleeve 27, a positioning assembly through hole 28, a tool assembly fastening bolt 29, a slitting tool 30, and a tool adjusting sliding connecting block 31. The bearing assembly frame 1 has a pre-set tool assembly bearing cavity 2. Primary positioning fastening screws 3 are symmetrically fixed on both sides of the back of the bearing assembly frame 1. Positioning stabilizing brackets 4 are symmetrically and movably installed on both sides of the back of the bearing assembly frame 1. A loading receiving block 10 is movably installed inside the tool assembly bearing cavity 2. A receiving sliding adjusting rod 5 is horizontally fixed on the upper side of the positioning stabilizing bracket 4. An alignment mounting bracket 6 is fixedly installed at the bottom of the positioning stabilizing bracket 4. A sliding clamp is movably installed inside the alignment mounting bracket 6. Plate 13, bearing the assembly frame 1, has symmetrically horizontally positioned sliding adjustment grooves 7 at the upper and lower ends of both sides of its back. Alignment sliding connection adjustment blocks 12 are symmetrically fixedly installed at the upper and lower ends of the sides of the receiving sliding adjustment rod 5. The external dimensions of the alignment sliding connection adjustment blocks 12 correspond to and match the internal dimensions of the positioning sliding adjustment grooves 7. The receiving sliding adjustment rod 5 is slidably connected to the positioning sliding adjustment grooves 7 via the alignment sliding connection adjustment blocks 12. An assembly width adjustment groove 11 is horizontally positioned at the middle of the outer side of the receiving sliding adjustment rod 5. The internal height of the assembly width adjustment groove 11 corresponds to and matches the outer diameter of the primary positioning fastening screw 3. The primary positioning fastening screw 3 passes through the assembly width adjustment groove 11 and is movably installed. The device is equipped with a primary positioning fastening sleeve 22, the internal thread specification of which corresponds to and matches the external thread specification of the primary positioning fastening screw 3. A tool adjustment loading groove 8 is laterally formed at the bottom of the tool assembly bearing cavity 2. A directional fastening groove 9 is laterally formed at the upper end of the bearing assembly frame 1, penetrating the upper end of the bearing assembly frame 1 and communicating with the interior of the tool assembly bearing cavity 2. The external specifications of the loading receiving block 10 correspond to and match the internal specifications of the tool assembly bearing cavity 2. A tool adjustment sliding connecting block 31 is fixedly installed at the bottom of the loading receiving block 10, and the loading receiving block 10 is slidably connected to the tool adjustment loading groove 8 via the tool adjustment sliding connecting block 31.The external specifications of the tool adjustment sliding connecting block 31 correspond and match with the internal specifications of the tool adjustment loading slide 8. A secondary positioning fastening screw 23 is fixedly installed on the upper end of the loading receiving block 10. The secondary positioning fastening screw 23 passes through the directional fastening slide 9 and is movably installed with a secondary positioning fastening screw sleeve 25. The internal thread specifications of the secondary positioning fastening screw sleeve 25 are compatible with the external thread specifications of the secondary positioning fastening screw 23. A clamping sliding groove 20 is symmetrically opened on both sides of the upper end of the alignment mounting bracket 6. A clamping sliding connecting block 21 is symmetrically fixedly installed on both sides of the upper end of the sliding clamping plate 13. The sliding clamping plate 13 is connected by... The clamping sliding connecting block 21 and the clamping sliding groove 20 are slidably connected to each other. The external dimensions of the clamping sliding connecting block 21 and the internal dimensions of the clamping sliding groove 20 correspond to each other. A clamping threaded groove 14 is pre-set at the middle position of the outer side of the alignment mounting bracket 6. An alignment connecting rotating seat 15 is fixedly installed at the middle position of the side of the sliding clamping plate 13. A fastening adjusting bolt 17 is movably installed inside the clamping threaded groove 14. A rotating connecting block 19 is fixedly connected to the end of the fastening adjusting bolt 17. The external dimensions of the rotating connecting block 19 and the internal dimensions of the alignment connecting rotating seat 15 correspond to each other. The external thread specification is compatible with the internal thread specification of the clamping thread groove 14. The fastening adjusting bolt 17 is rotatably connected to the alignment connecting rotating seat 15 through the rotating connecting block 19. Clamping compression pads 16 are fixedly installed on the other side of the sliding clamping plate 13 and the inner side of the alignment mounting bracket 6. At the same time, positioning and fastening screw holes 18 are symmetrically opened on the bottom of the sliding clamping plate 13 and the bottom of the inner side of the alignment mounting bracket 6. A tool loading block 24 is fixedly installed on the outside of the loading receiving block 10. A tool carrying assembly 26 is movably installed inside the tool loading block 24. The upper and lower ends of the tool loading block 24 are symmetrically fixed. The tool carrier assembly 26 is equipped with a positioning and fastening sleeve 27. Symmetrical positioning and assembly through holes 28 are provided at both the upper and lower ends of the external surface of the tool carrier assembly 26. The internal dimensions of the positioning and assembly through holes 28 correspond and match the external dimensions of the positioning and fastening sleeve 27. A tool carrier assembly fastening bolt 29 is movably installed on the positioning and fastening sleeve 27 through the positioning and assembly through holes 28. The external thread specifications of the tool carrier assembly fastening bolt 29 are compatible with the internal thread specifications of the positioning and fastening sleeve 27. A slitting tool 30 is fixedly connected to the bottom of the tool carrier assembly 26. The cutting edge of the slitting tool 30 faces the opposite direction of the tool carrier cavity 2 within the carrier assembly frame 1.

[0030] Specifically, through the sliding connection structure between the alignment sliding connection adjustment block 12 and the positioning sliding adjustment groove 7, and the threaded adaptation structure between the primary positioning fastening screw 3 and the primary positioning fastening sleeve 22, the overall assembly width can be appropriately adjusted and fastened according to the specific frame specifications. By using a sliding connection structure and corresponding fastening structure within the tool assembly bearing cavity 2, the loading receiving block 10 can adjust the distribution distance and quantity of the loading receiving block 10 within the tool assembly bearing cavity 2 according to specific cutting requirements, thus meeting different cutting quantity needs. This is achieved through alignment... The mounting bracket 6 is designed with an internal clamping and threaded fastening flexible assembly structure, which allows the mechanism to be adjusted to the appropriate installation size according to the target equipment, achieving a flexible assembly effect suitable for various equipment specifications. The overall functionality is greatly enriched, thereby expanding the overall applicability. Through the alignment and assembly structure of the slitting blade 30 outside the loading and receiving block 10, the slitting blade 30 in this mechanism can be selected according to the specific usage requirements in actual application, making it suitable for polymer sheet slitting operations in different working environments, and effectively enhancing its applicability.

[0031] Working Principle: The entire mechanism is stably assembled onto the end discharge position of the extrusion, molding, or conveying equipment frame of polymer sheet using the supporting assembly frame 1 as a carrier. Based on the specific dimensions of the assembled frame, the positioning and stabilizing bracket 4 is external to the supporting assembly frame 1, and the sliding adjustment rod 5 and positioning sliding adjustment groove 7 are slidably connected to each other. The width of the positioning and stabilizing bracket 4 on both sides of the back of the supporting assembly frame 1 is adjusted appropriately. Through the corresponding sliding connection between the alignment sliding connection adjustment block 12 and the positioning sliding adjustment groove 7, the positioning and stabilizing brackets 4 on both sides and the bottom alignment mounting bracket 6 are slid together. Finally, the primary positioning fastening screw sleeve 22 on the outside of the primary positioning fastening screw 3 is tightened at the appropriate position. After a stable and tight-fitting operation is performed on the overall adjusted position, the entire load-bearing assembly frame 1 is then stably assembled onto the target frame using the alignment mounting bracket 6. The alignment mounting bracket 6 can rotate the fastening adjustment bolt 17 according to the specific dimensions of the side protective baffle of the frame. Utilizing the threaded adaptation connection structure between the fastening adjustment bolt 17 and the clamping threaded groove 14, combined with the rotational connection structure between the rotating connecting block 19 and the alignment connecting rotating seat 15, and supported by the sliding connection structure between the clamping sliding groove 20 and the clamping sliding connecting block 21, the sliding clamping plate 13 is driven to slide directionally within the alignment mounting bracket 6 and perform clamping assembly operations on the frame baffle between the inner side of the alignment mounting bracket 6. The clamping compression pad 16 can enhance the alignment mounting bracket 6's clamping assembly with the frame baffle. The stability of the clamping assembly of the frame can also be achieved by using external adapter bolts passing through the positioning and fastening screw holes 18 and threaded fastening them to the corresponding adapter holes of the target assembly frame. After the entire load-bearing assembly frame 1 is securely installed on the target assembly frame, the number of slitting cutters 30 to be assembled can be determined according to the specific usage requirements in actual application. Specifically, based on the required slitting quantity of the target polymer sheet, the loading support block 10 is used inside the cutter assembly load-bearing cavity 2. Through the sliding connection between the cutter adjustment sliding connection block 31 and the cutter adjustment loading slide 8, the entire sliding loading support block 10 slides and adjusts within the cutter assembly load-bearing cavity 2, allowing the corresponding number of loading support blocks 10 to slide within the cutter assembly load-bearing cavity 2. Adjusting to a symmetrical and evenly spaced distribution, and utilizing the corresponding matching threaded connection structure, tighten the secondary positioning fastening screw 23 through the secondary positioning fastening sleeve 25 fitted outside the directional fastening groove 9 to fasten the position adjustment operation of the loading support block 10 inside the tool assembly support cavity 2. Then, the slitting tool 30 is fitted inside the tool loading block 24 through the corresponding adaptation structure between the positioning assembly through hole 28 on the outside of the tool support assembly 26 and the positioning fastening sleeve 27. Through the threaded adaptation structure between the tool assembly fastening bolt 29 and the positioning fastening sleeve 27, the assembly structure of the slitting tool 30 outside the loading support block 10 is limited and fastened, thereby effectively ensuring the overall assembly stability.Under the discharge force of the corresponding equipment, polymer sheets are cut by the cutting blade 30 from the discharge port at the end of the frame, achieving continuous and smooth polymer sheet output and slitting. This effectively enhances the overall functionality and practicality of the equipment, thus greatly expanding its applicability. It helps improve the processing efficiency of polymer sheets, saves working time, and avoids the need for material transfer to the slitting equipment after discharge, as is required in traditional slitting operations. Therefore, it has excellent application prospects in polymer sheet processing.

[0032] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0033] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention.

Claims

1. A flexible assembly polymer sheet cutting mechanism, comprising a load-bearing assembly frame (1), characterized in that: The bearing assembly frame (1) has a pre-set tool assembly bearing cavity (2) inside. The bearing assembly frame (1) has a first-level positioning fastening screw (3) symmetrically fixed on both sides of the back. The bearing assembly frame (1) has a positioning stabilizing bracket (4) symmetrically and movably installed on both sides of the back. The tool assembly bearing cavity (2) has a loading receiving block (10) movably installed inside. The upper side of the positioning stabilizing bracket (4) has a receiving sliding adjustment rod (5) laterally fixed. The bottom of the positioning stabilizing bracket (4) has an alignment mounting bracket (6) fixedly installed. The alignment mounting bracket (6) has a sliding clamping plate (13) movably installed inside.

2. The flexible assembled polymeric sheet slitting mechanism of claim 1, wherein: The upper and lower ends of the back of the supporting assembly frame (1) are symmetrically provided with positioning sliding adjustment grooves (7). The upper and lower ends of the side of the receiving sliding adjustment rod (5) are symmetrically fixed with alignment sliding connection adjustment blocks (12). The external specifications of the alignment sliding connection adjustment blocks (12) and the internal specifications of the positioning sliding adjustment grooves (7) correspond to each other. The receiving sliding adjustment rod (5) is slidably connected to the positioning sliding adjustment grooves (7) through the alignment sliding connection adjustment blocks (12).

3. The flexible assembled polymeric sheet slitting mechanism of claim 1, wherein: An assembly width adjustment groove (11) is provided in the middle of the outer side of the receiving sliding adjustment rod (5). The height dimension of the assembly width adjustment groove (11) corresponds to and matches the outer diameter dimension of the primary positioning fastening screw (3). The primary positioning fastening screw (3) is movably installed with a primary positioning fastening sleeve (22) through the assembly width adjustment groove (11). The internal thread specification of the primary positioning fastening sleeve (22) corresponds to and matches the external thread specification of the primary positioning fastening screw (3).

4. The flexible assembled polymeric sheet slitting mechanism of claim 3, wherein: A tool adjustment loading groove (8) is laterally provided at the bottom of the tool assembly bearing cavity (2). A directional fastening groove (9) is laterally provided at the upper end of the bearing assembly frame (1). The directional fastening groove (9) passes through the upper end of the bearing assembly frame (1) and communicates with the inside of the tool assembly bearing cavity (2). The external specifications of the loading support block (10) correspond to and match the internal specifications of the tool assembly bearing cavity (2). A tool adjustment sliding connection block (31) is fixedly installed at the bottom of the loading support block (10). The loading support block (10) is adjusted by the tool. The sliding connecting block (31) and the tool adjustment loading slide (8) are slidably connected to each other. The external specifications of the tool adjustment sliding connecting block (31) and the internal specifications of the tool adjustment loading slide (8) correspond to each other. The upper end of the loading receiving block (10) is fixedly installed with a secondary positioning fastening screw (23). The secondary positioning fastening screw (23) passes through the directional fastening slide (9) and is movably installed with a secondary positioning fastening screw sleeve (25). The internal thread specifications of the secondary positioning fastening screw sleeve (25) and the external thread specifications of the secondary positioning fastening screw (23) are mutually compatible.

5. The flexible assembled polymeric sheet material slitting mechanism of claim 1 wherein: The upper part of the alignment mounting bracket (6) is symmetrically provided with clamping sliding grooves (20) on both sides. The upper part of the sliding clamping plate (13) is symmetrically fixed with clamping sliding connecting blocks (21) on both sides. The sliding clamping plate (13) is slidably connected to the clamping sliding groove (20) through the clamping sliding connecting blocks (21). The external specifications of the clamping sliding connecting blocks (21) and the internal specifications of the clamping sliding groove (20) correspond to each other. The middle position of the outer side of the alignment mounting bracket (6) is preset with a clamping thread groove (14). The middle position of the side of the sliding clamping plate (13) is fixedly installed with an alignment connecting rotating seat (15). The clamping thread groove (14) is movably installed with a fastening adjusting bolt (17). A rotating connecting block (19) is fixedly connected to the end of the fastening adjusting bolt (17). The external specifications of the rotating connecting block (19) correspond to and match the internal specifications of the alignment connecting rotating seat (15). The external thread specifications of the fastening adjusting bolt (17) are compatible with the internal thread specifications of the clamping thread groove (14). The fastening adjusting bolt (17) is rotatably connected to the alignment connecting rotating seat (15) through the rotating connecting block (19). The other side of the sliding clamping plate (13) and the inner side of the alignment mounting bracket (6) are both fixedly installed with clamping compression pads (16). At the same time, the bottom of the sliding clamping plate (13) and the bottom of the inner side of the alignment mounting bracket (6) are symmetrically provided with positioning and fastening screw holes (18).

6. The flexible assembled polymeric sheet slitting mechanism of claim 5, wherein: The loading receiving block (10) is fixedly installed with a tool loading block (24) on the outside. The tool loading block (24) is movably installed with a tool carrying assembly (26) inside. The upper and lower ends of the tool loading block (24) are symmetrically fixedly installed with positioning fastening sleeves (27). The upper and lower ends of the tool carrying assembly (26) are symmetrically opened with positioning assembly through holes (28). The internal specifications of the positioning assembly through holes (28) correspond to and match the external specifications of the positioning fastening sleeves (27). The positioning fastening sleeves (27) are movably installed with tool assembly fastening bolts (29) through the positioning assembly through holes (28). The external thread specifications of the tool assembly fastening bolts (29) are compatible with the internal thread specifications of the positioning fastening sleeves (27). The bottom of the tool carrying assembly (26) is fixedly connected with a cutting tool (30). The cutting edge of the cutting tool (30) faces the opposite direction of the tool assembly carrying cavity (2) inside the carrying assembly frame (1).