CN113943987B - Intelligent production line for environment-friendly regenerated fabric school uniform - Google Patents

Abstract

The invention discloses an intelligent production line of environment-friendly regenerated fabric school uniform, which relates to the technical field of school uniform manufacturing and comprises a recovery process, a cloth decomposition process, a spinning and weaving process, a cloth cutting process and a sewing process, wherein the recovery process, the cloth decomposition process, the spinning and weaving process, the cloth cutting process and the sewing process are sequentially connected according to the production process, the cloth cutting process comprises a roller assembly, a transportation assembly and a cutting assembly, the cutting direction of the cutting assembly is not parallel to the transportation direction of the transportation assembly, the roller assembly is arranged at one side of the transportation assembly, the transportation direction of the cloth and the cutting direction of the cutting assembly are controlled to have a certain included angle, then the cutting assembly is controlled to cut the cloth back and forth, the cut cloth is in a regular rectangle, the waste of the cloth can be reduced, and the cloth can be continuously cut under the condition that the cloth does not stop running, the working efficiency is improved.

Description

Intelligent production line for environment-friendly regenerated fabric school uniform

Technical Field

The invention relates to the technical field of school uniform manufacturing, in particular to an intelligent production line of an environment-friendly regenerated fabric school uniform.

Background

The shortage and pollution of resources are problems facing the world at present. The textile industry is closely related to the life of people, and the textile industry in the world faces two problems: firstly, with the development of world economy and science and technology, the application field of textiles is gradually expanded, but the service life of the textiles is shortened, and in addition, the rapid increase of the world population, the consumption of the textiles is greatly increased, so that textile raw materials are in short supply, and the price is greatly increased. Secondly, a large amount of used old clothes are mostly buried or burned as garbage, which not only causes resource waste, but also pollutes the environment.

The Chinese patent with publication number CN108041707A discloses a frock school uniform made of environment-friendly circulating fabric, which comprises the following steps of S1, recycling waste textiles; step S2, classifying the waste textiles; step S3, preparing raw cotton-like cotton wool; step S4, mixing cotton and matching colors to obtain mixed cotton wool for spinning; step S5, spinning; step S6, sterilizing; step S7, yarn processing: comprises the substeps of yarn reversing, waxing and the like; step S8, weaving to obtain a fabric for clothing; and step S9, making clothes. The invention has the beneficial effects that: by reducing the waste textiles into new textiles for use, social resources are saved, and the recycling economy is realized.

However, the above invention and the background art center still have great disadvantages:

firstly: because the clothes are divided into the parts such as sleeves and clothes bodies, the cloth required by each part is cut out by the cloth cutting machine to obtain the cloth with a proper area, and then the cloth enters the sewing procedure to be sewn in a secondary processing mode, or the cloth is cut out manually, the efficiency of the manual cutting mode is low, the precision is low, the cloth cutting machine needs the cloth to cut out the rectangular cloth under the condition that the cloth is not moved, if the cloth is cut out by the cutting machine under the condition that the cloth moves, the cut-out cloth is in a parallelogram shape, the maximum usable area of the parallelogram is smaller than that of the rectangle, and thus, a large amount of leftover materials can be generated when the cloth is cut out by the cutting machine, and the waste of the cloth is caused;

secondly, the method comprises the following steps: the condition of fold can be produced to the cloth when cutting the cloth machine, leads to the cloth of cutting inhomogeneous, leads to the waste of cloth.

Disclosure of Invention

The invention aims to provide an intelligent production line for environment-friendly regenerated fabric school uniforms, which aims to solve the problems in the background technology.

The technical scheme of the invention is as follows: the utility model provides an environmental protection recycled fabric school uniform intelligence production line, includes recovery process, cloth decomposition process, spinning process of weaving, cloth tailoring process and sewing process, links up in proper order recovery process, cloth decomposition process, spinning process of weaving, cloth tailoring process and sewing process according to production process, and the cloth tailoring process includes drum assembly, transportation subassembly and tailors the subassembly, tailor the subassembly tailor the direction with transportation subassembly's direction of transportation non-parallel intercrossing, drum assembly sets up one side of transportation subassembly, tailor the subassembly setting and be in transportation subassembly's top.

Preferably, the recycling process comprises a recycling box, a plurality of containing boxes and labels are fixedly arranged in the recycling box, and the labels correspond to the containing boxes one to one.

Preferably, the roller assembly comprises a roller, a first support and a first support rod, the roller is provided with a wound cloth, one end of the cloth is fixedly connected with the roller, a guide plate is fixedly connected between the first support and the transportation assembly, the other end of the cloth is in lap joint with the transportation assembly along the guide plate, the roller is arranged on the first support, a driving motor is fixedly connected with the first support, the top of the first support rod is fixedly connected with the bottom of the first support, and the bottom of the first support rod is connected with the ground in a propping mode.

Preferably, the transportation subassembly includes second support, drive belt, second support bottom fixedly connected with second bracing piece, second bracing piece bottom supports with ground and leans on to be connected, fixedly connected with drive unit on the second support, the drive belt assembly is in on the drive unit, fixedly connected with protective housing on the second support, the cloth bottom with the drive belt contacts, the protective housing is in the cloth top, protective housing one side fixedly connected with third support, swing joint has the subassembly that stabilizes on the third support, stabilize the subassembly with it links to each other to tailor the subassembly.

Preferably, a protective layer is arranged on the transmission belt.

Preferably, the driving unit includes two rotating shafts and two rotating shafts, the two rotating shafts are respectively disposed at two sides of the second bracket, the rotating motor is fixed on the second bracket, and an output shaft of the rotating motor is fixedly connected to one of the rotating shafts.

Preferably, the stabilizing assembly comprises a sliding plate and a connecting rod, one end of the sliding plate is rotatably connected with the third support, the other end of the sliding plate is fixedly connected with the connecting rod, and one end, far away from the sliding plate, of the connecting rod is fixedly connected with the outer wall of the protective shell.

Preferably, the cutting assembly comprises a third supporting rod and a case, the top of the third supporting rod is fixedly connected with the case, a linear lead screw module is fixedly connected to the case, a sliding block is fixedly connected to the linear lead screw module, a connecting plate is fixedly connected to the bottom of the sliding block, a cutting assembly is fixedly connected to the bottom of the connecting plate, a roller is rotatably connected to one side wall of the connecting plate, a sliding groove is fixedly formed in the sliding plate, the roller is in rolling connection with the sliding groove, and arc-shaped guide surfaces are fixedly connected to two ports in the sliding groove.

Preferably, the cutting assembly is a laser cutter.

Preferably, the protective housing inner wall both sides are fixed and have been seted up the fluting, fixedly connected with spring assembly on the fluting, spring assembly is including upper and lower two sets of, and sets up respectively slotted top and bottom are two sets of fixedly connected with cardboard between the spring assembly, a plurality of axle sleeves of equidistance fixedly connected with on the cardboard, all rotate on every axle sleeve and be connected with the stripper bar, stripper bar and cloth roll connection.

The invention provides an intelligent production line of environment-friendly regenerated fabric school uniform by improvement, compared with the prior art, the intelligent production line has the following improvements and advantages:

one is as follows: the recovery process is used for recovering old clothes on the market, the cloth decomposition process can decompose the cloth into cotton wool, the spinning weaving process is used for re-spinning the cotton wool into woven cloth, then the cloth is rolled, the cloth is cut according to requirements through the cloth cutting process, the cut cloth is sent into the sewing process to be sewn into clothes, the recovered clothes are used for re-making school uniform, and the clothes sewing machine is economical and environment-friendly.

The second step is as follows: according to the cloth cutting device, the cutting direction of the cutting assembly is not parallel to the conveying direction of the conveying assembly, so that a certain included angle is formed between the conveying direction of the cloth and the cutting direction of the cutting assembly, the optimal value of the included angle is 45 degrees, the cutting assembly is controlled to cut the cloth for the first time, after the cloth stays for a period of time, the length of the cloth changes along with the movement of the cloth, and then the cloth is reset and cut for the second time.

And thirdly: according to the invention, the laser cutting can improve the cutting precision and reduce errors, because the conventional cutter can generate resistance along with the movement of cloth, the errors of the part can be reduced to the maximum extent through the laser cutting, and the protective layer can protect the transmission belt.

Fourthly, the method comprises the following steps: according to the invention, the linear lead screw module controls the slider to reciprocate and then drives the connecting plate to synchronously move, so that the cutting assembly can cut cloth, the cutting assembly can vibrate when moving, the moving stability of the cutting assembly is influenced, the cutting assembly can move along the sliding plate through the roller, the friction force is reduced through the roller, and the sliding plate can provide stable path guide for the movement of the cutting assembly, so that the moving stability of the cutting assembly is improved.

And fifthly: according to the invention, when the cloth is transported in the transmission belt, the cloth can vibrate to generate folds, the cloth can be compressed through the extrusion rod, so that the transportation of the cloth is more stable, meanwhile, the rotation of the extrusion rod cannot influence the normal transportation of the cloth, and the clamping plate can move in the groove through the spring group, so that the extrusion rod can move up and down, the cloth with different thicknesses can be extruded, and meanwhile, the vibration force transmitted to the cloth by the transmission belt can be buffered.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a flow diagram of a production line in the present invention;

FIG. 2 is a schematic view of an assembly structure of a roller assembly, a transportation assembly and a cutting assembly in the invention;

FIG. 3 is a perspective view of a cutting assembly according to the present invention;

FIG. 4 is a side view of a connection plate according to the present invention;

fig. 5 is a schematic perspective view of the protective case of the present invention;

FIG. 6 is a perspective view of the stabilizing assembly of the present invention;

FIG. 7 is a schematic plan view of a recovery tank of the present invention;

fig. 8 is a schematic diagram of an algorithm for cutting a fabric by the cutting assembly of the present invention.

Reference numerals: 1. a recovery step; 101. a recycling bin; 102. a containing box; 103. a label; 2. a cloth decomposition process; 3. spinning and weaving; 4. cloth cutting; 5. a roller assembly; 501. a roller; 502. a first bracket; 503. a first support bar; 504. a guide plate; 505. a drive motor; 6. a transport assembly; 601. a second bracket; 602. a transmission belt; 603. a second support bar; 604. a protective shell; 605. a third support; 606. a rotating electric machine; 607. a rotating shaft; 608. grooving; 609. a spring set; 610. clamping a plate; 611. a shaft sleeve; 612. an extrusion stem; 7. a cutting assembly; 701. a third support bar; 702. a chassis; 703. a linear lead screw module; 704. a slider; 705. a connecting plate; 706. a roller; 707. a chute; 708. a cutting assembly; 709. a guide surface; 8. a stabilizing assembly; 801. a slide plate; 802. a connecting rod; 9. and (5) sewing.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is to be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1-8, an embodiment of the present invention provides an intelligent production line for an environment-friendly regenerated fabric school uniform, which includes a recycling process 1, a fabric decomposition process 2, a spinning and weaving process 3, a fabric cutting process 4, and a sewing process 9, wherein the recycling process 1, the fabric decomposition process 2, the spinning and weaving process 3, the fabric cutting process 4, and the sewing process 9 are sequentially connected according to the production processes.

Specifically, the method comprises the following steps: the recovery process 1 is used for recovering old clothes on the market, the cloth decomposition process 2 can decompose the cloth, the spinning weaving process 3 is used for re-spinning the raw materials into woven cloth, then the cloth is assembled in the cloth cutting process 4, the cloth is cut according to requirements through the cloth cutting process 4, and the cut cloth is sent to the sewing process 9 to be sewn into the clothes.

Including collection box 101 in the recovery process 1, fixed a plurality of casees 102 and the label 103 of holding have been seted up in collection box 101, label 103 with hold case 102 one-to-one.

Specifically, the method comprises the following steps: a plurality of boxes 102 that hold are used for placing different recovery clothes, carry out the sign through label 103, and different colours can be marked to label 103 for place the recovery clothes of different colours in the box 102, improve classification efficiency.

The cloth cutting process 4 comprises a roller assembly 5, a conveying assembly 6 and a cutting assembly 7, wherein the cutting direction of the cutting assembly 7 is not parallel to the conveying direction of the conveying assembly 6, the roller assembly 5 is arranged at one side of the conveying assembly 6, the cutting assembly 7 is arranged above the conveying assembly 6, the roller assembly 5 comprises a roller 501, a first support 502 and a first support rod 503, cloth is arranged on the roller 501, one end of the cloth is fixedly connected with the roller 501, a guide plate 504 is fixedly connected between the first support 502 and the conveying assembly 6, the other end of the cloth is lapped on the conveying assembly 6 along the guide plate 504, the roller 501 is arranged on the first support 502, a driving motor 505 is fixedly connected on the first support 502, the top of the first support rod 503 is fixedly connected with the bottom of the first support 502, the bottom of the first support rod 503 is abutted against the ground, in the arrangement, the roller assembly 5 is used for feeding the woven cloth into the conveying assembly 6, and tailor subassembly 7 and can tailor the cloth when the cloth transportation, tailor efficiently.

Transportation subassembly 6 includes second support 601, drive belt 602, second support 601 bottom fixedly connected with second bracing piece 603, second bracing piece 603 bottom supports with ground and leans on to be connected, fixedly connected with drive unit on the second support 601, drive belt 602 assembles on the drive unit, fixedly connected with protective housing 604 on the second support 601, the cloth bottom contacts with drive belt 602, protective housing 604 is in the cloth top, protective housing 604 one side fixedly connected with third support 605, swing joint has firm subassembly 8 on the third support 605, firm subassembly 8 links to each other with cutting out subassembly 7.

The driving unit comprises two rotating motors 606 and two rotating shafts 607, the two rotating shafts 607 are respectively arranged at two sides of the second bracket 601, the rotating motors 606 are fixed on the second bracket 601, and the output shafts of the rotating motors 606 are fixedly connected with one of the rotating shafts 607.

Specifically, the method comprises the following steps: the cloth is wound in the roller 501, the roller 501 is driven to rotate by the driving motor 505, then the cloth is sent into the transmission belt 602 along the guide plate 504, the guide plate 504 can prevent the cloth from being suspended, the stability is improved, then the transmission belt 602 runs under the driving of the driving unit, the cloth is further driven to move in the running direction of the transmission belt 602 by the running of the transmission belt 602, then the linear lead screw module 703 controls the sliding block 704 to move, then the connection plate 705 is driven to synchronously move, so that the cutting assembly 708 at the bottom of the connection plate 705 can cut the cloth, wherein the cutting direction of the cutting assembly 7 is not parallel to the conveying direction of the conveying assembly 6, which means that the conveying direction of the cloth and the cutting direction of the cutting assembly 708 have a certain included angle, the optimal value of the included angle is 45 degrees, and then the cutting assembly 708 is controlled to cut the cloth for the first time, after the cloth stays for a period of time, the length of the cloth changes along with the continuous movement of the cloth, then the second reset cutting is carried out, and the included angle of 45 degrees is used for facilitating the calculation of the formula (the formula is specifically explained below), meanwhile, because the cutting assembly 708 needs to cut the cloth back and forth, the 45-degree included angle ensures that two edges of the cloth cut by the cutting assembly 708 are equal when the cutting assembly 708 cuts back and forth, the cut cloth is in a regular rectangle, the waste of the cloth can be reduced, the cloth can be continuously cut under the condition that the cloth does not stop running, and the working efficiency is improved;

Because the clothes are divided into the parts such as sleeves and clothes bodies, the cloth required by each part is cut out by the cloth cutting machine to obtain the cloth with a proper area, then the cloth enters the sewing process 9 for secondary processing for sewing, or the cloth is cut out manually, the efficiency of the manual cutting mode is low, the precision is low, the cloth cutting machine needs the cloth to cut out the rectangular cloth under the condition of no movement, if the cloth is cut out under the condition that the cloth moves, the cut-out cloth is parallelogram, the practical maximum area of the parallelogram is smaller than that of the rectangle, so that a large amount of leftover materials can be generated when the cloth is cut out by the cloth cutting machine, the waste of the cloth is caused, a certain included angle is formed between the conveying direction and the cutting direction of the cutting assembly 708, then the calculation is carried out according to the formula, and the speed for conveying the cloth is controlled, The cutting component 708 can cut the fabric into a rectangular shape without stopping, so that the cutting efficiency and quality are improved;

referring to fig. 8, the above formula is shown, the transport speed of the belt 602, that is, the moving speed of the cloth is set to V1, the cutting speed of the cutting unit 708 is set to V2, the time of one cutting by the cutting unit 708 is set to T1, the time of the stay of the cutting unit 708 after one cutting is set to T2, the length of the rectangular cloth is b, and the width of the rectangular cloth is a, and the following formula can be obtained according to a trigonometric function:

The formula I is as follows: b2+ (V1 · T1)2 ═ T1 · V2)2 equation two: a ═ V1 · (T1+ T2)

B and a in the formula are determined in advance according to the specification of the clothes, which is a known quantity, the speed of V2 is determined firstly, then V2 is started in advance to calculate the time T1 required by the cutting component 708 from one side of the cloth to the other side of the cloth, at this time, T1 is also a known quantity, so that the speed of V1 can be calculated according to the formula I, the conveying speed of the transmission belt 602 is determined, in this case, a regular rectangle can be cut, meanwhile, the length of a in the formula II is determined in advance according to the specification of the clothes, and therefore the time of T2, namely the time of stay of the cutting component 708 after the first cutting can be calculated according to the formula II.

The belt 602 is provided with a protective layer and the cutting assembly 708 is a laser cutter.

Specifically, laser cutting can improve the precision of cutting, reduces the error, because conventional cutter can produce the resistance along with the removal of cloth, and the error of this part passes through the reduction that laser cutting can the maximize, and the protective layer can protect drive belt 602.

The stabilizing assembly 8 comprises a sliding plate 801 and a connecting rod 802, one end of the sliding plate 801 is rotatably connected with the third support 605, the other end of the sliding plate 801 is fixedly connected with the connecting rod 802, and one end, far away from the sliding plate 801, of the connecting rod 802 is fixedly connected with the outer wall of the protective shell 604.

Tailor subassembly 7 and include third bracing piece 701, quick-witted case 702, third bracing piece 701 top and quick-witted case 702 fixed connection, the last linear lead screw module 703 of fixedly connected with of machine case 702, fixedly connected with slider 704 on the linear lead screw module 703, slider 704 bottom fixedly connected with connecting plate 705, connecting plate 705 bottom fixedly connected with cutting assembly 708, a connecting plate 705 lateral wall swivelling joint has gyro wheel 706, spout 707 has been seted up to the last fixed of slide 801, gyro wheel 706 and spout 707 roll connection, the equal curved spigot surface 709 of fixedly connected with of both ends mouth in the spout 707.

Specifically, the method comprises the following steps: the linear lead screw module 703 controls the reciprocating movement of the sliding block 704, and then drives the connecting plate 705 to move synchronously, so that the cutting assembly 708 can cut cloth, when the cutting assembly 708 moves, vibration can be generated, the moving stability of the cutting assembly 708 is affected, the cutting assembly 708 can move along the sliding plate 801 through the roller 706, the friction force is reduced through the roller 706, and the sliding plate 801 can provide stable path guide for the movement of the cutting assembly 708, thereby improving the moving stability of the cutting assembly 708.

Open grooves 608 are fixedly formed in two sides of the inner wall of the protective shell 604, spring groups 609 are fixedly connected to the open grooves 608, the spring groups 609 comprise an upper group and a lower group and are respectively arranged at the top and the bottom of the open grooves 608, clamping plates 610 are fixedly connected between the two groups of spring groups 609, a plurality of shaft sleeves 611 are fixedly connected to the clamping plates 610 at equal intervals, each shaft sleeve 611 is rotatably connected with an extrusion rod 612, and the extrusion rods 612 are in rolling connection with cloth.

Specifically, the method comprises the following steps: the condition of vibrations can take place when the cloth transports in drive belt 602, lead to the cloth to produce the fold, can compress tightly the cloth through squeeze bar 612, make more steady of cloth transportation, the normal transportation of cloth can not be influenced in the rotation of squeeze bar 612 simultaneously, and because cardboard 610 can remove in fluting 608 through spring assembly 609, make squeeze bar 612 can reciprocate, thereby can extrude the cloth of different thickness, also can cushion the vibrations dynamics that the drive belt 602 transmitted the cloth simultaneously.

The working principle is as follows: the recycling process 1 is used for recycling old clothes on the market, the cloth decomposing process 2 can crush the cloth, the spinning weaving process 3 is used for re-spinning the raw materials into woven cloth, the cloth is wound in the roller 501 for standby, the cloth is cut according to requirements through the cloth cutting process 4, the cut cloth is sent into the sewing process 9 to be sewn into clothes, the cloth is wound in the roller 501, the roller 501 is driven to rotate through the driving of the driving motor 505, the cloth is sent into the transmission belt 602 along the guide plate 504, the guide plate 504 can avoid the cloth from being suspended, the stability is improved, the transmission belt 602 runs under the driving of the driving unit, the cloth is further driven to move in the running direction of the transmission belt 602 through the running of the transmission belt 602, the linear lead screw module controls the slider 704 to move, and then the connection plate 705 is driven to synchronously move, the cutting assembly 708 at the bottom of the connecting plate 705 can cut cloth, wherein the cutting direction of the cutting assembly 7 is not parallel to the conveying direction of the conveying assembly 6, which means that the conveying direction of the cloth and the cutting direction of the cutting assembly 708 have a certain included angle, the optimal value of the included angle is 45 degrees, then the cutting assembly 708 is controlled to cut the cloth for the first time, after a period of time, along with the movement of the cloth, the length of the cloth changes, then the second reset cutting is performed, the 45-degree included angle is convenient for the calculation of a formula (the formula makes a specific explanation below), meanwhile, because the cutting assembly 708 needs to cut the cloth back and forth, the 45-degree included angle ensures that two edges of the cloth cut by the cutting assembly 708 are equal when the cutting assembly 708 cuts back and forth, the cut cloth is in a regular rectangle, and the waste of the cloth can be reduced, and can continuously cut the cloth under the condition that the cloth does not stop running, thereby improving the working efficiency, and then the sewing method in the sewing process 9 can be that a sewing machine is manually adopted for sewing.

The previous description is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. The utility model provides an environmental protection recycled fabric school uniform intelligence production line, includes recovery process (1), cloth decomposition process (2), spinning process (3), cloth tailoring process (4) and sewing process (9), its characterized in that: the method comprises the following steps that a recovery process (1), a cloth decomposition process (2), a spinning and weaving process (3), a cloth cutting process (4) and a sewing process (9) are sequentially connected according to a production process, the cloth cutting process (4) comprises a roller assembly (5), a conveying assembly (6) and a cutting assembly (7), the cutting direction of the cutting assembly (7) is intersected with the conveying direction of the conveying assembly (6), the roller assembly (5) is arranged on one side of the conveying assembly (6), and the cutting assembly (7) is arranged above the conveying assembly (6); the roller assembly (5) comprises a roller (501), a first support (502) and a first support rod (503), wherein wound cloth is arranged on the roller (501), one end of the cloth is fixedly connected with the roller (501), a guide plate (504) is fixedly connected between the first support (502) and the transportation assembly (6), the other end of the cloth is lapped on the transportation assembly (6) along the guide plate (504), the roller (501) is arranged on the first support (502), a driving motor (505) is fixedly connected on the first support (502), the top of the first support rod (503) is fixedly connected with the bottom of the first support (502), and the bottom of the first support rod (503) is connected with the ground in an abutting mode; the transportation assembly (6) comprises a second support (601) and a transmission belt (602), a second support rod (603) is fixedly connected to the bottom of the second support (601), the bottom of the second support rod (603) is connected with the ground in an abutting mode, a driving unit is fixedly connected to the second support (601), the transmission belt (602) is assembled on the driving unit, a protective shell (604) is fixedly connected to the second support (601), the bottom of cloth is in contact with the transmission belt (602), the protective shell (604) is positioned above the cloth, a third support (605) is fixedly connected to one side of the protective shell (604), a stabilizing assembly (8) is movably connected to the third support (605), and the stabilizing assembly (8) is connected with the cutting assembly (7); the driving unit comprises two rotating motors (606) and two rotating shafts (607), the two rotating shafts (607) are respectively arranged on two sides of the second support (601), the rotating motors (606) are fixed on the second support (601), and an output shaft of each rotating motor (606) is fixedly connected with one rotating shaft (607).

2. The intelligent production line of environment-friendly regenerated fabric school uniform as claimed in claim 1, characterized in that: the recycling process (1) comprises a recycling box (101), a plurality of containing boxes (102) and labels (103) are fixedly arranged in the recycling box (101), and the labels (103) correspond to the containing boxes (102) one to one.

3. The intelligent production line of the environment-friendly regenerated fabric school uniform as claimed in claim 1, characterized in that: a protective layer is arranged on the transmission belt (602).

4. The intelligent production line of the environment-friendly regenerated fabric school uniform as claimed in claim 1, characterized in that: the stabilizing assembly (8) comprises a sliding plate (801) and a connecting rod (802), one end of the sliding plate (801) is rotatably connected with the third support (605), the other end of the sliding plate (801) is fixedly connected with the connecting rod (802), and one end, far away from the sliding plate (801), of the connecting rod (802) is fixedly connected with the outer wall of the protective shell (604).

5. The intelligent production line of the environment-friendly regenerated fabric school uniform as claimed in claim 4, wherein: the cutting assembly (7) comprises a third supporting rod (701) and a case (702), the top of the third supporting rod (701) is fixedly connected with the case (702), a linear lead screw module (703) is fixedly connected with the case (702), a sliding block (704) is fixedly connected with the linear lead screw module (703), a connecting plate (705) is fixedly connected with the bottom of the sliding block (704), a cutting assembly (708) is fixedly connected with the bottom of the connecting plate (705), a side wall of the connecting plate (705) is rotatably connected with a roller (706), a sliding groove (707) is fixedly formed in the sliding plate (801), the roller (706) is connected with the sliding groove (707) in a rolling manner, and arc-shaped guide surfaces (709) are fixedly connected with two ports in the sliding groove (707).

6. The intelligent production line of environment-friendly regenerated fabric school uniform as claimed in claim 5, characterized in that: the cutting assembly (708) is a laser cutter.

7. The intelligent production line of the environment-friendly regenerated fabric school uniform as claimed in claim 1, characterized in that: the novel cloth protective structure is characterized in that two sides of the inner wall of the protective shell (604) are fixedly provided with slots (608), the slots (608) are fixedly connected with spring sets (609), each spring set (609) comprises an upper group and a lower group which are respectively arranged at the top and the bottom of the corresponding slot (608), a clamping plate (610) is fixedly connected between the two groups of spring sets (609), the clamping plates (610) are fixedly connected with a plurality of shaft sleeves (611) at equal intervals, each shaft sleeve (611) is rotatably connected with an extrusion rod (612), and the extrusion rods (612) are in rolling connection with cloth.

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