CN112391828A - Full-automatic spinning is corner resection device for cloth processing - Google Patents

Abstract

The invention relates to the technical field of textile processing equipment, in particular to a full-automatic edge and corner cutting device for processing woven cloth, which comprises: a work table; the guide assembly is arranged at one end of the workbench, the cutting distance control mechanism is arranged at the top of the workbench, and the two lifting mechanisms are respectively arranged at two output ends of the cutting distance control mechanism; the two cutting machines are respectively arranged at the output ends of the two lifting mechanisms; the symmetry is provided with two discharge openings on the workstation, and two rim charge drainage mechanism symmetries set up in the both sides of workstation, rim charge conveying mechanism, there are two, and two rim charge conveying mechanism symmetries set up in the bottom of workstation, and winding mechanism sets up in the one end of workstation to winding mechanism keeps away from the workstation, and this technical scheme can carry out the corner excision to the both sides of spinning the cloth, and the excision width can be adjusted at any time moreover, and in time collect the rim charge after the excision, has saved the time of artifical clearance.

Description

Full-automatic spinning is corner resection device for cloth processing

Technical Field

The invention relates to the technical field of textile processing equipment, in particular to a full-automatic corner cutting device for processing woven cloth.

Background

The textile origin is a general name taken from spinning and weaving, but with the continuous development and perfection of a textile knowledge system and a subject system, particularly after non-woven textile materials and three-dimensional compound weaving and other technologies are produced, the textile is not only produced by traditional hand spinning and weaving, but also produced by non-woven fabric technology, modern three-dimensional weaving technology, modern electrostatic nano-web forming technology and the like, and is used for clothing, industry and decoration. Modern spinning therefore refers to a technique for the multi-scale structural processing of fibers or fiber assemblies. Ancient Chinese textile and printing and dyeing technology has a very long history, and ancient people have understood local materials in the early original society period in order to adapt to climate change, use natural resources as raw materials for textile and printing and dyeing and manufacture simple hand textile tools. Clothes, safety air bags and curtain carpets in daily life are products of textile and printing and dyeing technology; spin cloth also one of the product for weaving, the processing of spinning cloth needs to excise its leftover bits, traditional spinning cloth processing equipment can only excise spinning cloth, the leftover bits after the excision can't carry out timely cleaing away, so need provide a full-automatic spinning is corner resection device for cloth processing, can carry out the corner excision to the both sides of spinning cloth, and the excision width can be adjusted at any time moreover, and in time collect the leftover bits after the excision, the time of artifical clearance has been saved.

Disclosure of Invention

For solving above-mentioned technical problem, provide a full-automatic corner resection device for processing of spinning cloth, this technical scheme can carry out the corner resection to the both sides of spinning the cloth, and the resection width can be adjusted at any time moreover to in time collect the leftover bits after the resection, saved the time of artifical clearance.

In order to achieve the above purposes, the technical scheme adopted by the invention is as follows:

the utility model provides a full-automatic processing of spinning cloth is with corner resection device, includes:

a work table;

the guide assembly is arranged at one end of the workbench and is used for guiding the spinning cloth raw material;

the cutting distance control mechanism is arranged at the top of the workbench and is provided with two output ends;

the two lifting mechanisms are respectively arranged at two output ends of the cutting distance control mechanism;

the two cutting machines are respectively arranged at the output ends of the two lifting mechanisms;

the two rim charge drainage mechanisms are symmetrically arranged on two sides of the workbench, and output ends of the two rim charge drainage mechanisms are respectively positioned at the two discharge openings;

the two rim charge conveying mechanisms are symmetrically arranged at the bottom of the workbench and are used for conveying the rim charges;

the winding mechanism is arranged at one end of the workbench and is far away from the workbench, and the winding mechanism is used for winding the woven cloth.

Preferably, the guide assembly comprises:

the guide fixing frame is arranged at one end of the workbench;

first material roller and second material roller that draws, first material roller and second material roller are arranged from top to bottom and are set up on the guide mount to first material roller and second material roller all with guide mount rotatable coupling.

Preferably, the cutting distance control mechanism includes:

the top frame is arranged at the top of the workbench through a matching rack;

the first threaded rod is arranged on the top frame and is rotatably connected with the top frame, two sections of threads are arranged at two ends of the first threaded rod, and the two sections of threads are arranged oppositely;

the opening and closing driving assembly is arranged on the top frame, and the output end of the opening and closing driving assembly is in transmission connection with the first threaded rod;

first work piece and second work piece, first work piece and second work piece all overlap locate on the first threaded rod and rather than threaded connection, first work piece and second work piece all with top frame sliding connection, two elevating system set up respectively on first work piece and second work piece.

Preferably, the opening and closing driving assembly includes:

the first servo motor is arranged on the top frame;

the first belt pulley is arranged at the output end of the first servo motor;

the second belt pulley is sleeved on the first threaded rod and fixedly connected with the first threaded rod, and the first belt pulley is in transmission connection with the second belt pulley through a belt.

Preferably, the elevating mechanism includes:

the top supporting plate is arranged at the output end of the cutting distance control mechanism;

the first cylinder is arranged at the bottom of the top supporting plate;

the bottom plate sets up in the output of first cylinder, and the cutting machine sets up in the bottom of bottom plate, and the top of bottom plate is provided with first guide bar, and first guide bar runs through a backup pad and rather than sliding connection.

Preferably, the rim charge drainage mechanism comprises:

the containing support plate is positioned at the bottom of the discharge opening of the workbench, and a second guide rod and a second threaded rod are arranged on the containing support plate;

the vertical plate is arranged on one side of the workbench, and the second guide rod and the second threaded rod penetrate through the vertical plate;

and the horizontal driving mechanism is arranged on the vertical plate, and the output end of the horizontal driving mechanism is connected with the second threaded rod.

Preferably, the horizontal driving mechanism includes:

the second servo motor is arranged on the vertical plate;

the third belt pulley is arranged at the output end of the second servo motor;

the nut is sleeved on the second threaded rod and is in threaded connection with the second threaded rod, the nut is rotatably connected with the vertical plate, and the third belt pulley is in transmission connection with the nut through a belt.

Preferably, the rim charge conveying mechanism includes:

the rim charge fixing frame is arranged at the bottom of the workbench and close to the discharge opening of the workbench;

the first material transferring roller and the second material transferring roller are longitudinally arranged on the rim charge fixing frame and are rotatably connected with the rim charge fixing frame, a first gear is arranged at one end of the first material transferring roller, a second gear is arranged at one end of the second material transferring roller, and the first gear is meshed with the second gear;

and the rotary driving mechanism is arranged at the bottom of the workbench, and the output end of the rotary driving mechanism is connected with the stress end of the first material transferring roller.

Preferably, the rotation drive mechanism includes:

the third servo motor is arranged at the bottom of the workbench;

the first synchronous wheel is arranged at the output end of the third servo motor;

the second synchronizing wheel is sleeved at the stress end of the first material transferring roller and fixedly connected with the first material transferring roller, and the first synchronizing wheel and the second synchronizing wheel are connected through a synchronous belt in a transmission mode.

Preferably, the winding mechanism includes:

the rotating frame is arranged at one end of the workbench, and is far away from the guide assembly;

the winding roller is arranged on the rotating frame and is rotatably connected with the rotating frame;

and the fourth servo motor is arranged on the rotating frame, and the output end of the fourth servo motor is connected with the winding roller.

Compared with the prior art, the invention has the beneficial effects that: firstly, a worker penetrates a textile raw material through the output end of a guide assembly and winds the textile raw material at the output end of a winding mechanism, a cutting distance control mechanism starts to work, two output ends of the cutting distance control mechanism respectively drive two lifting mechanisms to be close to or away from each other, the two lifting mechanisms drive two cutting machines to be close to or away from each other, the cutting width of leftover materials at two sides of the textile is controlled by controlling the distance at which the two cutting machines are close to each other, when the cutting width distance is controlled well, the two lifting mechanisms start to work simultaneously, the output ends of the two lifting mechanisms push the two cutting machines to descend simultaneously until the output ends of the two cutting machines contact two sides of the textile, the two cutting machines start to work, the output ends of the two cutting machines cut two sides of the textile, the textile is driven by the winding mechanism to move along with the, the output ends of the two leftover material guiding and discharging mechanisms shrink simultaneously, so that the bottoms of two discharging openings of the workbench lose separation, the cut leftover materials on the two sides of the woven fabric are still in a state of being adhered to the main material, a worker cuts one end, close to the winding mechanism, of the leftover materials through scissors, then the leftover materials on the two sides penetrate through the two discharging openings respectively and are stuffed into the output ends of the two leftover material conveying mechanisms, the conveying speeds of the two leftover material conveying mechanisms are consistent with the winding speed of the winding mechanism, and the two leftover material strips are conveyed into a material collecting box through the two leftover material conveying mechanisms respectively and are contained;

1. by arranging the rim charge drainage mechanism, the discharge opening of the workbench can be sealed in a non-cutting state and still can carry out bearing action;

2. through the arrangement of the rim charge conveying mechanism, the rim charge can be conveyed and discharged;

3. through the setting of this equipment, can carry out the corner excision to the both sides of spinning the cloth, the width of excision can be adjusted at any time moreover to in time collect the leftover bits after the excision, saved the time of artifical clearance.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a schematic perspective view of the present invention;

FIG. 3 is a perspective view of the guide assembly of the present invention;

FIG. 4 is a front view of the cutting distance control mechanism and lift mechanism of the present invention;

FIG. 5 is an enlarged view taken at A of FIG. 4 in accordance with the present invention;

FIG. 6 is a first schematic perspective view of the rim charge purging mechanism of the present invention;

FIG. 7 is a schematic perspective view of a second embodiment of the rim charge purging mechanism of the present invention;

FIG. 8 is a first perspective view of the scrap conveying mechanism according to the present invention;

FIG. 9 is a second schematic perspective view of the scrap conveying mechanism of the present invention;

fig. 10 is a schematic perspective view of the winding mechanism of the present invention.

The reference numbers in the figures are:

1-a workbench;

2-a guide assembly; 2 a-guiding the fixing frame; 2 b-a first draw roll; 2 c-a second draw roll;

3-a cutting distance control mechanism; 3 a-a top frame; 3 b-a first threaded rod; 3 c-an opening and closing drive assembly; 3c 1-first servomotor; 3c2 — first pulley; 3c 3-second pulley; 3 d-first work block; 3 e-a second work block;

4-a lifting mechanism; 4 a-a top support plate; 4 b-a first cylinder; 4 c-a bottom plate; 4c1 — first guide bar;

5-a cutting machine;

6-a rim charge drainage mechanism; 6 a-a carrier plate; 6a1 — second guide bar; 6a2 — second threaded rod; 6 b-a vertical plate; 6 c-horizontal drive mechanism; 6c 1-second servomotor; 6c 2-third pulley; 6c 3-nut;

7-a rim charge conveying mechanism; 7 a-rim charge fixing frame; 7 b-a first transfer roll; 7b1 — first gear; 7 c-a second transfer roll; 7c1 — second gear; 7 d-a rotary drive mechanism; 7d 1-third servomotor; 7d2 — first synchronous wheel; 7d3 — second synchronizing wheel;

8, a winding mechanism; 8 a-a turret; 8 b-a wind-up roll; 8 c-a fourth servomotor.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

Referring to fig. 1 to 2, a full-automatic fabric processing corner cutting device includes:

a work table 1;

the guide assembly 2 is arranged at one end of the workbench 1, and the guide assembly 2 is used for guiding the textile raw material;

the cutting distance control mechanism 3 is arranged at the top of the workbench 1, and the cutting distance control mechanism 3 is provided with two output ends;

two lifting mechanisms 4 are provided, and the two lifting mechanisms 4 are respectively arranged at two output ends of the cutting distance control mechanism 3;

the two cutting machines 5 are arranged, and the two cutting machines 5 are respectively arranged at the output ends of the two lifting mechanisms 4;

the two rim charge drainage mechanisms 6 are symmetrically arranged on the workbench 1, the two rim charge drainage mechanisms 6 are symmetrically arranged on two sides of the workbench 1, and the output ends of the two rim charge drainage mechanisms 6 are respectively positioned at the two discharge openings;

the two rim charge conveying mechanisms 7 are symmetrically arranged at the bottom of the workbench 1, and the rim charge conveying mechanisms 7 are used for conveying rim charges;

the winding mechanism 8 is arranged at one end of the workbench 1, the winding mechanism 8 is far away from the workbench 1, and the winding mechanism 8 is used for winding the woven fabric;

firstly, a worker penetrates the spinning raw material through the output end of the guide assembly 2 and winds the spinning raw material at the output end of the winding mechanism 8, the cutting distance control mechanism 3 starts to work, the two output ends of the cutting distance control mechanism 3 respectively drive the two lifting mechanisms 4 to be close to or far away from each other, the two lifting mechanisms 4 drive the two cutting machines 5 to be close to or far away from each other, the cutting width of leftover materials at two sides of the spinning is controlled by controlling the distance at which the two cutting machines 5 are close to each other, after the cutting width distance is controlled, the two lifting mechanisms 4 simultaneously start to work, the output ends of the two lifting mechanisms 4 push the two cutting machines 5 to simultaneously descend until the output ends of the two cutting machines 5 contact with two sides of the spinning, the two cutting machines 5 start to work, the output ends of the two cutting machines 5 cut two sides of the spinning, two rim charge drainage mechanism 6 begin work, the output of two rim charge drainage mechanism 6 is shrink simultaneously, make two discharge opening bottoms of workstation 1 lose the separation, the leftover bits that spin the cloth both sides this moment and be cut still are in the state with the major ingredient adhesion, the staff cuts the leftover bits one end that is close to winding mechanism 8 through the scissors, then pass two discharge openings respectively with the leftover bits of both sides and fill in two rim charge conveying mechanism 7's output, two rim charge conveying mechanism 7's conveying speed is unanimous with winding mechanism 8's coiling speed, hold in two rim charge area carry the feeding bin through two rim charge conveying mechanism 7 respectively.

The guide assembly 2 as shown in fig. 3 comprises:

a guide fixing frame 2a arranged at one end of the workbench 1;

the device comprises a first material guiding roller 2b and a second material guiding roller 2c, wherein the first material guiding roller 2b and the second material guiding roller 2c are arranged on a guide fixing frame 2a in an up-and-down manner, and the first material guiding roller 2b and the second material guiding roller 2c are both rotatably connected with the guide fixing frame 2 a;

guide mount 2a is used for the fixed stay and guides the moving direction who spins cloth, and the staff will spin the cloth and pass between first guide roller 2b and the second guide roller 2c, cliies through first guide roller 2b and second guide roller 2c and spins cloth and cooperation rotation.

The cutting distance control mechanism 3 shown in fig. 4 includes:

the top frame 3a is arranged at the top of the workbench 1 through a matching rack;

the first threaded rod 3b is arranged on the top frame 3a, the first threaded rod 3b is rotatably connected with the top frame 3a, two sections of threads are arranged at two ends of the first threaded rod 3b, and the two sections of threads are arranged oppositely;

the opening and closing driving component 3c is arranged on the top frame 3a, and the output end of the opening and closing driving component 3c is in transmission connection with the first threaded rod 3 b;

the first working block 3d and the second working block 3e are sleeved on the first threaded rod 3b and are in threaded connection with the first threaded rod 3b, the first working block 3d and the second working block 3e are in sliding connection with the top frame 3a, and the two lifting mechanisms 4 are respectively arranged on the first working block 3d and the second working block 3 e;

cutting distance control mechanism 3 begins work, and the output of drive assembly 3c that opens and shuts drives first threaded rod 3b and rotates, and first threaded rod 3b drives first work piece 3d and second work piece 3e respectively and is close to or keeps away from each other, and first work piece 3d and second work piece 3e drive two elevating system 4 and are close to or keep away from each other.

The opening and closing drive assembly 3c shown in fig. 5 includes:

a first servo motor 3c1 provided on the top frame 3 a;

a first belt pulley 3c2 arranged at the output end of the first servo motor 3c 1;

the second belt pulley 3c3 is sleeved on the first threaded rod 3b and fixedly connected with the first threaded rod, and the first belt pulley 3c2 is in transmission connection with the second belt pulley 3c3 through a belt;

the opening and closing driving assembly 3c starts to work, the output end of the first servo motor 3c1 drives the first belt pulley 3c2 to rotate, the first belt pulley 3c2 drives the second belt pulley 3c3 to rotate through a belt, and the second belt pulley 3c3 drives the first threaded rod 3b to rotate.

As shown in fig. 4, the lifting mechanism 4 includes:

a top support plate 4a provided at an output end of the cutting distance control mechanism 3;

a first cylinder 4b provided at the bottom of the top support plate 4 a;

the bottom plate 4c is arranged at the output end of the first air cylinder 4b, the cutting machine 5 is arranged at the bottom of the bottom plate 4c, the top of the bottom plate 4c is provided with a first guide rod 4c1, and the first guide rod 4c1 penetrates through the top supporting plate 4a and is connected with the top supporting plate in a sliding mode;

the lifting mechanism 4 starts to work, the output end of the first air cylinder 4b pushes the bottom plate 4c to descend, the bottom plate 4c drives the cutting machine 5 to descend, the top supporting plate 4a is used for fixing and supporting, and the first guide rod 4c1 is used for guiding the moving direction of the bottom plate 4 c.

As shown in fig. 6, the rim charge purging mechanism 6 includes:

the loading plate 6a is positioned at the bottom of the discharge opening of the workbench 1, and a second guide rod 6a1 and a second threaded rod 6a2 are arranged on the loading plate 6 a;

the vertical plate 6b is arranged on one side of the workbench 1, and the second guide rod 6a1 and the second threaded rod 6a2 penetrate through the vertical plate 6 b;

the horizontal driving mechanism 6c is arranged on the vertical plate 6b, and the output end of the horizontal driving mechanism 6c is connected with the second threaded rod 6a 2;

the rim charge drainage mechanism 6 starts to work, the output end of the horizontal driving mechanism 6c drives the loading plate 6a to leave the discharge opening of the workbench 1 through the second threaded rod 6a2, the second guide rod 6a1 is used for guiding the moving direction of the loading plate 6a, and the vertical plate 6b is used for fixed support.

The horizontal driving mechanism 6c shown in fig. 7 includes:

a second servo motor 6c1 arranged on the vertical plate 6 b;

a third belt pulley 6c2 arranged at the output end of the second servo motor 6c 1;

the nut 6c3 is sleeved on the second threaded rod 6a2 and is in threaded connection with the second threaded rod, the nut 6c3 is rotatably connected with the vertical plate 6b, and the third belt pulley 6c2 is in transmission connection with the nut 6c3 through a belt;

the horizontal driving mechanism 6c starts to work, the output end of the second servo motor 6c1 drives the third belt pulley 6c2 to rotate, the third belt pulley 6c2 drives the nut 6c3 to rotate through the belt, and the nut 6c3 drives the loading plate 6a to leave the discharge opening of the workbench 1.

As shown in fig. 8, the rim charge transfer mechanism 7 includes:

the rim charge fixing frame 7a is arranged at the bottom of the workbench 1 and is close to the discharge opening of the workbench 1;

the first material transferring roller 7b and the second material transferring roller 7c are longitudinally arranged on the rim charge fixing frame 7a and are rotatably connected with the rim charge fixing frame 7a, a first gear 7b1 is arranged at one end of the first material transferring roller 7b, a second gear 7c1 is arranged at one end of the second material transferring roller 7c, and the first gear 7b1 is meshed with the second gear 7c 1;

the rotary driving mechanism 7d is arranged at the bottom of the workbench 1, and the output end of the rotary driving mechanism 7d is connected with the stress end of the first material transferring roller 7 b;

the staff will spin between cloth leftover bits and pieces pass first commentaries on classics material roller 7b and the second commentaries on classics material roller 7c, rotary drive mechanism 7d begins work, rotary drive mechanism 7 d's output drives first commentaries on classics material roller 7b and rotates, first commentaries on classics material roller 7b drives second gear 7c1 antiport through first gear 7b1, second gear 7c1 antiport drives second commentaries on classics material roller 7c and rotates, first commentaries on classics material roller 7b and second commentaries on classics material roller 7c are to opposite directions and drive and spin cloth leftover bits and pieces and discharge.

The rotation drive mechanism 7d shown in fig. 9 includes:

a third servo motor 7d1 provided at the bottom of the table 1;

a first synchronous wheel 7d2 arranged at the output end of the third servo motor 7d 1;

the second synchronizing wheel 7d3 is sleeved at the stress end of the first transferring roller 7b and is fixedly connected with the stress end, and the first synchronizing wheel 7d2 is in transmission connection with the second synchronizing wheel 7d3 through a synchronous belt;

the rotary driving mechanism 7d starts to work, the output end of the third servo motor 7d1 drives the first synchronizing wheel 7d2 to rotate, the first synchronizing wheel 7d2 drives the second synchronizing wheel 7d3 to rotate through the synchronous belt, and the second synchronizing wheel 7d3 drives the first material transferring roller 7b to rotate.

The winding mechanism 8 shown in fig. 10 includes:

a rotating frame 8a arranged at one end of the workbench 1, wherein the rotating frame 8a is far away from the guide assembly 2;

the winding roller 8b is arranged on the rotating frame 8a and is rotatably connected with the rotating frame;

the fourth servo motor 8c is arranged on the rotating frame 8a, and the output end of the fourth servo motor 8c is connected with the winding roller 8 b;

the winding mechanism 8 starts to work, the output end of the fourth servo motor 8c drives the winding roller 8b to rotate, the winding roller 8b drives the woven cloth to be wound, and the rotating frame 8a is used for fixing and supporting.

The working principle of the invention is as follows: firstly, a worker passes a spinning raw material between a first material guiding roller 2b and a second material guiding roller 2c and finally winds the spinning raw material on a winding roller 8b of a winding mechanism 8, a cutting distance control mechanism 3 starts working, an opening and closing driving component 3c starts working, an output end of a first servo motor 3c1 drives a first belt pulley 3c2 to rotate, a first belt pulley 3c2 drives a second belt pulley 3c3 to rotate through a belt, the second belt pulley 3c3 drives a first threaded rod 3b to rotate, the first threaded rod 3b drives a first working block 3d and a second working block 3e to be close to or far away from each other respectively, the first working block 3d and the second working block 3e drive two lifting mechanisms 4 to be close to or far away from each other, the two lifting mechanisms 4 drive two cutting machines 5 to be close to or far away from each other, and the cutting width of corner materials at two sides of the spinning cloth is controlled by controlling the distance of the two cutting machines 5 to be close to each other, after the cutting width distance is controlled, the two lifting mechanisms 4 start to work simultaneously, the output end of the first air cylinder 4b pushes the bottom plate 4c to descend, the bottom plate 4c drives the cutting machines 5 to descend until the output ends of the two cutting machines 5 contact with the two sides of the woven fabric, the two cutting machines 5 start to work, the output ends of the two cutting machines 5 cut the two sides of the woven fabric, the woven fabric is driven by the winding mechanism 8 to move along with the two side materials, the two side material guiding and discharging mechanisms 6 start to work, the horizontal driving mechanism 6c starts to work, the output end of the second servo motor 6c1 drives the third belt pulley 6c2 to rotate, the third belt pulley 6c2 drives the nut 6c3 to rotate through a belt, the nut 6c3 drives the loading plate 6a to leave the discharge opening of the workbench 1, so that the bottoms of the two discharge openings of the workbench 1 are not blocked, and the cut side materials on the two sides of the woven fabric, the staff cuts off the leftover bits through the scissors and is close to the one end of winding mechanism 8, then pass two discharge openings respectively with the leftover bits of both sides and fill in two leftover bits conveying mechanism 7's output, two leftover bits conveying mechanism 7's the conveying speed is unanimous with winding mechanism 8's rolling speed, rotary driving mechanism 7d begins to work, rotary driving mechanism 7 d's output drives first material transfer roller 7b and rotates, first material transfer roller 7b drives second gear 7c1 antiport through first gear 7b1, second gear 7c1 antiport drives second material transfer roller 7c and rotates, first material transfer roller 7b and second material transfer roller 7c antiport and drive the cloth leftover bits and discharge into the collection box and hold.

The device realizes the functions of the invention through the following steps, thereby solving the technical problems provided by the invention:

firstly, a worker enables a spinning raw material to pass through the output end of the guide component 2 and to be wound on the output end of the winding mechanism 8;

step two, the cutting distance control mechanism 3 starts to work, two output ends of the cutting distance control mechanism 3 respectively drive the two lifting mechanisms 4 to approach or separate from each other, the two lifting mechanisms 4 drive the two cutting machines 5 to approach or separate from each other, and the cutting width of the leftover materials at two sides of the woven cloth is controlled by controlling the distance between the two cutting machines 5 which approach each other;

step three, after the cutting width distance is controlled well, the two lifting mechanisms 4 start to work simultaneously, and the output ends of the two lifting mechanisms 4 push the two cutting machines 5 to descend simultaneously until the output ends of the two cutting machines 5 contact the two sides of the woven fabric;

step four, the two cutting machines 5 start to work, the output ends of the two cutting machines 5 cut the two sides of the woven fabric, and the woven fabric is driven to move along with the woven fabric through the winding mechanism 8;

fifthly, the rim charge drainage mechanisms 6 start to work, and the output ends of the two rim charge drainage mechanisms 6 contract simultaneously, so that the bottoms of the two discharge openings of the workbench 1 are not blocked;

step six, the cut leftover materials on the two sides of the woven fabric are still in a state of being adhered to the main material, a worker cuts one end, close to the winding mechanism 8, of the leftover materials through scissors, and then the leftover materials on the two sides respectively penetrate through the two discharging openings and are plugged into the output ends of the two leftover material conveying mechanisms 7;

seventhly, the conveying speed of the two rim charge conveying mechanisms 7 is consistent with the winding speed of the winding mechanism 8, and the two rim charge strips are conveyed into the material receiving box through the two rim charge conveying mechanisms 7 respectively to be stored.

The foregoing has described the general principles, principal features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a full-automatic processing of spinning cloth is with corner resection device which characterized in that includes:

a table (1);

the guide assembly (2) is arranged at one end of the workbench (1), and the guide assembly (2) is used for guiding the textile raw material;

the cutting distance control mechanism (3) is arranged at the top of the workbench (1), and the cutting distance control mechanism (3) is provided with two output ends;

the two lifting mechanisms (4) are arranged, and the two lifting mechanisms (4) are respectively arranged at two output ends of the cutting distance control mechanism (3);

the two cutting machines (5) are arranged, and the two cutting machines (5) are respectively arranged at the output ends of the two lifting mechanisms (4);

the two rim charge introducing and discharging mechanisms (6) are arranged, two discharging openings are symmetrically formed in the workbench (1), the two rim charge introducing and discharging mechanisms (6) are symmetrically arranged on two sides of the workbench (1), and the output ends of the two rim charge introducing and discharging mechanisms (6) are respectively positioned at the two discharging openings;

the two rim charge conveying mechanisms (7) are symmetrically arranged at the bottom of the workbench (1), and the rim charge conveying mechanisms (7) are used for conveying rim charges;

winding mechanism (8), set up in the one end of workstation (1) to workstation (1) is kept away from in winding mechanism (8), and winding mechanism (8) are used for carrying out the rolling to spinning cloth.

2. A full automatic fabric processing corner cutting device according to claim 1, wherein the guide assembly (2) comprises:

a guide fixing frame (2 a) arranged at one end of the workbench (1);

first material guide roller (2 b) and second material guide roller (2 c), first material guide roller (2 b) and second material guide roller (2 c) arrange from top to bottom and set up on guide mount (2 a) to first material guide roller (2 b) and second material guide roller (2 c) all with guide mount (2 a) rotatable coupling.

3. A full-automatic fabric processing corner cutting device according to claim 1, wherein the cutting distance control mechanism (3) comprises:

the top frame (3 a), the top frame (3 a) is arranged on the top of the workbench (1) through a matching rack;

the first threaded rod (3 b) is arranged on the top frame (3 a), the first threaded rod (3 b) is rotatably connected with the top frame (3 a), two threads are arranged at two ends of the first threaded rod (3 b), and the two threads are arranged oppositely;

the opening and closing driving component (3 c) is arranged on the top frame (3 a), and the output end of the opening and closing driving component (3 c) is in transmission connection with the first threaded rod (3 b);

first work piece (3 d) and second work piece (3 e), first work piece (3 d) and second work piece (3 e) all overlap locate first threaded rod (3 b) on and rather than threaded connection, first work piece (3 d) and second work piece (3 e) all with top frame (3 a) sliding connection, two elevating system (4) set up respectively on first work piece (3 d) and second work piece (3 e).

4. A full-automatic fabric processing corner cutting device according to claim 3, wherein the opening and closing driving assembly (3 c) comprises:

a first servo motor (3 c 1) provided on the top frame (3 a);

the first belt pulley (3 c 2) is arranged at the output end of the first servo motor (3 c 1);

and the second belt pulley (3 c 3) is sleeved on the first threaded rod (3 b) and is fixedly connected with the first threaded rod, and the first belt pulley (3 c 2) is in transmission connection with the second belt pulley (3 c 3) through a belt.

5. The full-automatic fabric processing corner cutting device according to claim 1, wherein the lifting mechanism (4) comprises:

a top support plate (4 a) arranged at the output end of the cutting distance control mechanism (3);

a first cylinder (4 b) provided at the bottom of the top support plate (4 a);

the bottom plate (4 c) is arranged at the output end of the first air cylinder (4 b), the cutting machine (5) is arranged at the bottom of the bottom plate (4 c), the top of the bottom plate (4 c) is provided with a first guide rod (4 c 1), and the first guide rod (4 c 1) penetrates through the top supporting plate (4 a) and is in sliding connection with the top supporting plate.

6. A full-automatic fabric processing corner cutting device according to claim 1, wherein the rim charge guiding and discharging mechanism (6) comprises:

the loading plate (6 a) is positioned at the bottom of the discharge opening of the workbench (1), and a second guide rod (6 a 1) and a second threaded rod (6 a 2) are arranged on the loading plate (6 a);

the vertical plate (6 b) is arranged on one side of the workbench (1), and both the second guide rod (6 a 1) and the second threaded rod (6 a 2) penetrate through the vertical plate (6 b);

and the horizontal driving mechanism (6 c) is arranged on the vertical plate (6 b), and the output end of the horizontal driving mechanism (6 c) is connected with the second threaded rod (6 a 2).

7. The full-automatic fabric processing corner cutting device according to claim 6, wherein the horizontal driving mechanism (6 c) comprises:

a second servo motor (6 c 1) arranged on the vertical plate (6 b);

the third belt pulley (6 c 2) is arranged at the output end of the second servo motor (6 c 1);

and the nut (6 c 3) is sleeved on the second threaded rod (6 a 2) and is in threaded connection with the second threaded rod, the nut (6 c 3) is rotatably connected with the vertical plate (6 b), and the third belt pulley (6 c 2) is in transmission connection with the nut (6 c 3) through a belt.

8. The full-automatic fabric processing corner cutting device according to claim 1, wherein the rim charge conveying mechanism (7) comprises:

the rim charge fixing frame (7 a) is arranged at the bottom of the workbench (1) and is close to the discharge opening of the workbench (1);

the scrap iron conveying device comprises a first material transferring roller (7 b) and a second material transferring roller (7 c), wherein the first material transferring roller (7 b) and the second material transferring roller (7 c) are longitudinally arranged on an edge material fixing frame (7 a) and are rotatably connected with the edge material fixing frame, a first gear (7 b 1) is arranged at one end of the first material transferring roller (7 b), a second gear (7 c 1) is arranged at one end of the second material transferring roller (7 c), and the first gear (7 b 1) is meshed with the second gear (7 c 1);

and the rotary driving mechanism (7 d) is arranged at the bottom of the workbench (1), and the output end of the rotary driving mechanism (7 d) is connected with the stress end of the first material transferring roller (7 b).

9. A full-automatic fabric processing corner cutting device according to claim 8, wherein the rotary driving mechanism (7 d) comprises:

a third servo motor (7 d 1) arranged at the bottom of the workbench (1);

a first synchronous wheel (7 d 2) arranged at the output end of the third servo motor (7 d 1);

the second synchronizing wheel (7 d 3) is sleeved at the stress end of the first transferring roller (7 b) and is fixedly connected with the stress end, and the first synchronizing wheel (7 d 2) is connected with the second synchronizing wheel (7 d 3) through a synchronous belt.

10. The full-automatic fabric processing corner cutting device according to claim 1, wherein the winding mechanism (8) comprises:

a rotating frame (8 a) arranged at one end of the workbench (1), wherein the rotating frame (8 a) is far away from the guide assembly (2);

the winding roller (8 b) is arranged on the rotating frame (8 a) and is rotatably connected with the rotating frame;

and the fourth servo motor (8 c) is arranged on the rotating frame (8 a), and the output end of the fourth servo motor (8 c) is connected with the winding roller (8 b).

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