CN111776826B - Automatic production system for magnetic soft screen door - Google Patents

Abstract

The invention discloses an automatic production system of a magnetic soft screen door, which comprises a conveying groove, a magnetic strip feeding part, a magnetic block feeding part and a net-shaped screen sheet conveying part, wherein the conveying groove is provided with a magnetic strip feeding part; the magnetic strip feeding part and the magnetic block feeding part are sequentially arranged along the axial direction of the conveying groove; the magnetic strip feeding part comprises a magnetic strip unreeling unit and a magnetic strip cutting unit; the magnetic strip unreeling unit conveys the magnetic strip into the first groove section; the second groove section is formed in the magnetic stripe cutting unit, and the magnetic stripe cutting unit is used for cutting the magnetic stripe on the second groove section in a fixed length; the reticular yarn piece conveying part is used for conveying reticular yarn pieces. Compared with the prior art, the invention meets the production requirement of modernization automation, reduces the labor cost and improves the production efficiency.

Description

Automatic production system for magnetic soft screen door

Technical Field

The invention relates to the technical field of production of magnetic soft screen doors, in particular to an automatic production system of a magnetic soft screen door.

Background

Among the prior art, the soft screen door of magnetism includes the netted yarn piece of the equal width that two symmetries set up, netted yarn piece is the rectangle structure, top-down symmetry is equipped with a plurality of magnetism on two adjacent wraps of two netted yarn pieces and inhales the piece, wherein the magnetism inhales the piece and forms including long magnetic stripe and short magnetic path combination, and the fixed one end of door and frame of netted yarn piece is fixed with the magic subsides usually, among the prior art, usually take up magnetic path and magnetic stripe from former storage bucket through the manual work, and then in the packing into netted yarn piece, also be the manual work simultaneously and cut processes such as, waste time and energy, low in production efficiency, so need design one set of netted yarn piece automatic conveying, automatically, provide magnetic stripe and magnetic path, the automatic production system of the soft screen door of magnetism of automatic cutting.

Disclosure of Invention

The invention aims to provide an automatic production system of a magnetic soft screen door, which can be used for solving the technical problems in the prior art, can automatically convey a reticular screen sheet and cut the reticular screen sheet, and can assist in providing a magnetic strip and a magnetic block.

The invention provides an automatic production system of a magnetic soft screen door, which comprises a conveying groove, a magnetic strip feeding part, a magnetic block feeding part and a net-shaped screen sheet conveying part, wherein the conveying groove comprises:

the conveying groove is used for accommodating the magnetic strips and the magnetic blocks and guiding the magnetic strips and the magnetic blocks to be conveyed to a specified position along the axial direction of the conveying groove; the conveying groove comprises a first groove section, a second groove section, a third groove section and a fourth groove section which are sequentially connected along the conveying direction;

the magnetic strip feeding part and the magnetic block feeding part are sequentially arranged along the axial direction of the conveying groove;

the magnetic strip feeding part comprises a magnetic strip unreeling unit and a magnetic strip cutting unit;

the magnetic stripe unreeling unit is arranged at the starting end of the first groove section so as to convey the magnetic stripe into the first groove section; the magnetic stripe unreeling unit comprises a first rack, a first reel, a guide roller set and a first driving motor, wherein the first reel, the guide roller set and the first driving motor are all arranged on the first rack, the output end of the first driving motor is connected with the end part of the first reel so as to drive the first reel to rotate, one end of the magnetic stripe is coiled on the first reel, and the other end of the magnetic stripe is conveyed to the starting end of the first groove section after being guided by the guide roller set;

the guide roller group comprises a first guide roller, a second guide roller, a third guide roller and a fourth guide roller which are sequentially arranged along a conveying path, the first guide roller, the third guide roller and the fourth guide roller are all fixed at the top end of the first rack, and the second guide roller can be vertically fixed on the first rack in a reciprocating manner; the second groove section is formed in the magnetic stripe cutting unit, the head end of the second groove section is connected with the tail end of the first groove section, and the magnetic stripe cutting unit is used for cutting the magnetic stripe on the second groove section in a fixed length;

the third groove section is formed in the magnetic block feeding portion, the head end of the third groove section is connected with the tail end of the second groove section, the magnetic block feeding portion comprises a magnetic block storage box, a partition plate driving unit, a push plate and a push plate driving unit, wherein:

a storage space is formed in the magnetic block storage box, a plurality of groups of magnetic blocks are stacked in the storage space in the vertical direction, each group of magnetic blocks comprises a plurality of magnetic blocks, and the plurality of magnetic blocks are arranged in parallel in the horizontal direction;

a first opening, a second opening, a third opening and a fourth opening are formed in the magnetic block storage box, the first opening is located at the top of the storage space, the second opening is located on a first wall surface of the storage space, the third opening is located on a second wall surface of the storage space, the fourth opening is located on a third wall surface of the storage space, the second wall surface and the third wall surface are arranged oppositely, and the first wall surface is located between the second wall surface and the third wall surface; the third opening and the fourth opening are oppositely arranged, and the second opening is higher than the third opening;

one end of the partition board is fixed in the second opening in a clearance fit mode, and the partition board driving unit is connected with the other end of the partition board so as to drive the partition board to reciprocate in the horizontal direction;

one end of the push plate is fixed in the third opening in a clearance fit mode, and the push plate driving unit is connected with the other end of the push plate to drive the push plate to reciprocate in the horizontal direction, so that the magnetic blocks at the bottommost layer are pushed to be sent into the third groove section from the fourth opening one by one;

netted yarn piece conveying part includes second frame, second reel, driven roller, first tractive unit, second tractive unit and netted yarn piece cutting unit, wherein:

the second winding drum, the driven rollers, the first traction unit and the second traction unit are all arranged on the second rack, one end of a reticular yarn sheet is wound on the second winding drum, the other end of the reticular yarn sheet is conveyed to the reticular yarn sheet cutting unit after being sequentially pulled by the first traction unit and the second traction unit, and the driven rollers are arranged on a conveying path of the reticular yarn sheet;

the first drawing unit and the second drawing unit are used for drawing the reticular yarn sheet so as to provide power for conveying the reticular yarn sheet;

the mesh yarn piece cutting unit is used for cutting the mesh yarn piece at a fixed length.

The automatic production system for the magnetic soft screen door is characterized in that a bottom plate, a strip plate, support legs and a plurality of guide shaping devices are arranged in the first machine frame, wherein:

the lath is fixed on the bottom plate through a plurality of supporting legs, and the first groove section is formed at the top end of the lath;

the guide shaping devices are arranged in a plurality and are sequentially arranged along the axis direction of the first groove section, and each guide shaping device comprises a first base, a first mounting seat, a first air cylinder, a first shaping wheel, a second shaping wheel and a first lifting plate;

the first base is arranged at the bottom of the batten, and the first shaping wheel is rotatably supported on the first base;

first mount pad set up in the top of slat, the cylinder body of first cylinder is fixed in on the first mount pad, the piston rod of first cylinder runs through perpendicular downwardly extending behind the first mount pad, the piston rod of first cylinder end with first lifter plate is connected, first mount pad in the relative both sides of first cylinder all are equipped with first guide slot, clearance fit has first guide arm in the first guide slot, the bottom of first guide arm with first lifter plate is connected, the rotatable support of second sizing wheel in the bottom surface of first lifter plate, the second sizing wheel with first sizing wheel sets up relatively, first sizing wheel with be formed with between the second sizing wheel and be used for supplying the clearance that the magnetic stripe passes through.

As above, the automatic production system for magnetic soft screen door, wherein, preferably, the magnetic stripe cutting unit comprises a first base, a first belt pulley, a second driving motor, a third driving motor, a transmission rod, a first transmission belt, a first mounting plate, a first fixing column and a first cutter, wherein:

the first base is arranged at the tail end of the batten, the second groove section is formed at the top of the first base, the first base is provided with a first accommodating groove and a second accommodating groove in a concave manner in sequence in the axis direction of the second groove section, a first rotating shaft is rotatably supported in the first accommodating groove, a first end of the first rotating shaft penetrates through the first base and then is connected with an output shaft of the second driving motor, the second end of the first rotating shaft penetrates through the first base and then is connected with the first belt pulley, a third sizing wheel is sleeved on the first rotating shaft, a second rotating shaft is rotatably supported in the second accommodating groove, a second end of the second rotating shaft penetrates through the first base and then is connected with the second belt pulley, a fourth setting wheel is sleeved on the second rotating shaft, and two ends of the first transmission belt are respectively sleeved on the first belt pulley and the second belt pulley in a circle manner;

the first mounting plate is fixed on the first base through the first fixing columns, four first fixing columns are arranged and symmetrically arranged at four corners of the first mounting plate, a fifth sizing wheel and a sixth sizing wheel are rotatably supported on the bottom surface of the first mounting plate, the fifth sizing wheel is arranged relative to the third sizing wheel, and a gap for the magnetic stripe to pass through is formed between the third sizing wheel and the fifth sizing wheel; the sixth sizing wheel is arranged relative to the fourth sizing wheel, and a gap for the magnetic stripe to pass through is formed between the sixth sizing wheel and the fourth sizing wheel;

the surface of the first mounting plate is provided with a square groove in a penetrating mode, the third driving motor is fixed above the square groove through a motor mounting seat, the head end of the transmission rod is eccentrically connected to the output shaft of the third driving motor, the bottom end of the transmission rod is connected with the top end of the second lifting plate, the first cutter is fixed at the bottom end of the second lifting plate, the second lifting plate is provided with second guide grooves in two sides of the transmission rod respectively, the second guide grooves are internally provided with second guide rods in a clearance fit mode, and the bottom end of the second guide rods is connected with the second lifting plate.

The automatic production system for the magnetic soft screen door is characterized in that the partition driving unit preferably comprises a partition driving cylinder, a first transfer plate and a cylinder mounting seat, the cylinder mounting seat is fixed on the first wall surface of the magnetic block storage box, the cylinder body of the partition driving cylinder is fixed on the cylinder mounting seat, the piston rod of the partition driving cylinder is arranged on one side departing from the magnetic block storage box, the piston rod of the partition driving cylinder extends in the horizontal direction, the tail end of the piston rod is fixed to the top end of the first transfer plate, one end of the partition is connected with the bottom end of the first transfer plate, and the other end of the partition extends into the storage space from the second opening horizontally.

As above a soft screen door automated production system of magnetism, wherein, the preferred is, push pedal drive unit includes push pedal drive actuating cylinder and second keysets, the cylinder body that the push pedal driven actuating cylinder is fixed in on the fourth wall of magnetic path storage box, the fourth wall with first wall sets up relatively, the fourth wall set up in the second wall with between the third wall, the piston rod that the push pedal driven actuating cylinder set up in be close to the one end of second wall, the piston rod that the push pedal driven actuating cylinder extend along the horizontal direction and terminal with the top of second keysets is fixed, the one end of push pedal with the bottom of second keysets is connected, the other end of push pedal certainly the third opening horizontal extension enters in the storage space.

The automatic production system for the magnetic soft screen door is preferably further provided with a traction output unit, the traction output unit comprises a second base, a fourth driving motor, a third belt pulley, a fourth belt pulley, a second mounting plate, a third mounting plate, a second transmission belt and second fixing columns, the fourth groove section is formed on the top surface of the second base, the head end of the fourth groove section is connected with the tail end of the third groove section, the second mounting plate is fixed on the second base through the second fixing columns, the four second fixing columns are arranged at four corners of the second mounting plate, the third mounting plate is fixed on the second mounting plate, the extension direction of the third mounting plate is perpendicular to that of the second mounting plate, and the third belt pulley is rotatably arranged at the top of the third mounting plate, the fourth belt pulley is equipped with a plurality ofly, and is a plurality of the rotatable interval of fourth belt pulley set up in on the second mounting panel, it is a plurality of the extending direction of fourth belt pulley with the extending direction of fourth groove section is parallel, second transmission belt circle overlap in third belt pulley and a plurality of on the fourth belt pulley, second transmission belt quilt third belt pulley and two that are located both ends the tensioning of fourth belt pulley, second transmission belt is located the top of fourth groove section and laminate in magnetic stripe and the magnetic path in the fourth groove section, fourth driving motor's output with third belt pulley connection, in order to drive the third belt pulley rotates.

The automatic production system for the magnetic soft screen door as described above, preferably, the first pulling unit is located at the head end of the second frame, and includes a fifth driving motor, a first vertical plate, a first driving roller and a first pressing roller, the first vertical plate includes two first vertical plates, the two first vertical plates are symmetrically disposed on the second frame and located at two sides of the mesh screen sheet conveying path, two ends of the first driving roller are rotatably disposed on the two first vertical plates, an output end of the fifth driving motor is connected to a shaft end of the first driving roller to drive the first driving roller to rotate, a second vertical plate is fixed on a plate surface of the first vertical plate, the second vertical plate is located above the first driving roller, a third guide groove is concavely disposed on a plate surface of the second vertical plate, and a second guide plate is fixed in the third guide groove and can vertically and reciprocally lift, the two ends of the first pressing roller are rotatably arranged on the two second guide plates, the first pressing roller and the first driving roller are clamped and conveyed together to form the netted yarn piece, the top end of the second vertical plate is connected with a first adjusting bolt in a threaded mode, the bottom end of the first adjusting bolt extends into the third guide groove, a first spring is arranged in the third guide groove, the top end of the first spring is abutted to the bottom end of the first adjusting bolt, and the bottom end of the first spring is abutted to the top face of the second guide plate.

The automatic production system for the magnetic soft screen door is characterized in that the second drawing unit is located at the tail end of the second rack and comprises a sixth driving motor, a second driving roller and a platen, the platen is arranged on the second rack, a through groove penetrates through the platen, the second driving roller is rotatably supported on the second rack, the top surface of the second driving roller extends out of the through groove and is flush with the plate surface of the platen, the output end of the sixth driving motor is connected with the second driving roller to drive the second driving roller to rotate, a mounting frame is arranged on the platen, a plurality of compression roller driving cylinders are arranged on the mounting frame, piston rods of the compression roller driving cylinders reciprocate in the vertical direction, mounting seats are fixed at the tail ends of the piston rods of the compression roller driving cylinders, and second compression rollers are rotatably supported at the free ends of the mounting seats, and the second pressing rollers are positioned above the second driving rollers, and the second driving rollers clamp and convey the netted yarn sheets together.

The automatic production system of the magnetic soft screen door is characterized in that the mesh-shaped screen sheet cutting unit comprises a base, a third drawing unit, a second cutter, a seventh driving motor, a fifth belt pulley, a sixth belt pulley, a transmission shaft, a transmission disc and a transmission block, the base is arranged on one side of the second frame close to the second drawing unit, and the third drawing unit, the second cutter, the seventh driving motor, the fifth belt pulley, the sixth belt pulley, the transmission shaft, the transmission disc and the transmission block are all fixed on the base;

the third drawing unit is arranged between the second drawing unit and the second cutter and is used for receiving the reticular yarn sheet sent out by the second drawing unit and sending the reticular yarn sheet to the second cutter;

seventh driving motor's output shaft with fifth belt pulley connection, the transmission shaft rotate support in on the frame, the one end fixed connection of transmission shaft the sixth belt pulley, the fifth belt pulley with the sixth belt pulley passes through the belt tensioning and connects, the transmission dish the transmission piece all is equipped with two, two the transmission dish all eccentric connect in on the transmission shaft, the outer periphery epirelief of transmission dish is equipped with the lug, two the transmission piece and two the transmission dish one-to-one, the both ends of transmission piece respectively with the lug with the second cutter is connected.

As above soft screen door automated production system of magnetism, wherein, preferably, still be equipped with magic subsides and unreel the portion, including third frame, base plate, slide, third reel, branch roller, conveying unit, the drive unit that slides and hot press unit, wherein:

the base plate is fixed at the top of the third rack, the sliding plate can be horizontally and reciprocally fixed on the base plate in a sliding manner, and the sliding driving unit is connected with the sliding plate so as to drive the sliding plate to move reciprocally in the horizontal direction to be close to or far from the reticular gauze pieces;

the third reel the back roll the conveying unit and hot press unit all set up in on the slide, the one end of magic subsides is convoluteed on the third reel, the other end of magic subsides is through a plurality of carry after the guide of back roll on the transport route of netted yarn piece, conveying unit is used for providing the power that the magic was pasted and is carried, works as the magic subsides are carried to behind the transport route of netted yarn piece, hot press unit will the magic subsides with the limit portion hot pressing of netted yarn piece fuses fixedly.

The sliding driving unit comprises an eighth driving motor, a driving gear, a driving rack, a sliding rail and a first sliding groove, the cylinder body of the eighth driving motor is fixed on the third rack, the driving gear is fixed at the tail end of an output shaft of the eighth driving motor, the driving rack is fixed at the bottom of the sliding plate, the driving gear is meshed with the driving rack, the sliding rail is fixed on the base plate, the first sliding groove is fixed at the bottom of the sliding plate, and the sliding rail is in sliding fit with the first sliding groove.

The conveying unit comprises third vertical plates, a ninth driving motor, a third driving roller and third pressing rollers, the number of the third vertical plates is two, the third vertical plates are symmetrically fixed on the third rack, the third driving roller is rotatably arranged between the two third vertical plates, the output end of the ninth driving motor is connected with the shaft end of the third driving roller to drive the third driving roller to rotate, a second chute penetrates through the plate surface of the third vertical plate, a third lifting plate is fixed in the second chute in a reciprocating lifting mode, the third pressing rollers are rotatably arranged between the two third lifting plates, the third pressing rollers are located above the third driving roller, and a gap through which the magic tape passes is formed between the third pressing rollers and the third driving roller to clamp the magic tape for forward conveying.

A second adjusting bolt is fixed at the top end of the third vertical plate in a threaded manner, the bottom end of the second adjusting bolt extends into the second chute and then is connected with the top end of the third lifting plate, a second spring is arranged in the second chute, the top end of the second spring is abutted against the bottom surface of the third lifting plate, and the bottom end of the second spring is abutted against the bottom surface of the second chute.

Compared with the prior art, the invention is provided with a magnetic strip feeding part, a magnetic block feeding part and a mesh yarn sheet conveying part, wherein the mesh yarn sheet is coiled on a second winding drum, the wound mesh yarn sheet is unreeled from the second winding drum, a first pulling unit and a second pulling unit provide power for unreeling the mesh yarn sheet, a plurality of driven rollers guide the mesh yarn sheet to be conveyed to a mesh yarn sheet cutting unit along a set conveying path, the mesh yarn sheet cutting unit cuts the mesh yarn sheet discontinuously to enable the mesh yarn sheet to be cut to a specified length and then enters a next procedure, the magnetic strip feeding part is responsible for providing a cut magnetic strip on the way of conveying the mesh yarn sheet along the conveying path, the magnetic strip feeding part is responsible for providing a magnetic block, the magnetic strip is continuously conveyed in a conveying groove and is continuously conveyed to a fourth groove section by a first groove section and then is output, wherein the magnetic block is inserted between two magnetic strips in the third groove section and is conveyed by a fourth groove section of a traction output unit, the magnetic block and the magnetic strip are coated and fixed, and then the magnetic block and the magnetic strip are fixed on one side edge part of the advancing reticular yarn sheet in a thermal fusion mode, so that the magnetic block with the magnetic strip is fixed on the reticular yarn sheet.

Drawings

FIG. 1 is an isometric view of the overall structure of the present invention;

FIG. 2 is an isometric view of a magnetic strip supply portion;

FIG. 3 is an isometric view of a hidden heating and cooling device of a magnetic strip supply section;

FIG. 4 is an isometric view of the guide and sizing device;

FIG. 5 is an isometric view of a magnetic stripe cutting unit;

FIG. 6 is a partial view of a magnetic stripe cutting unit;

FIG. 7 is a first perspective view of the magnetic block supply portion;

FIG. 8 is a second perspective view of the magnetic block supply portion;

FIG. 9 is an isometric view of a magnetic block storage box;

FIG. 10 is an isometric view of the magnetic block storage box two;

FIG. 11 is an isometric view of the diaphragm drive unit;

FIG. 12 is an isometric view of the push plate drive unit;

FIG. 13 is an isometric view of the traction output unit;

FIG. 14 is an isometric view of a mesh screen transport;

fig. 15 is an isometric view of a first pull unit;

fig. 16 is an isometric view of a second pull unit;

FIG. 17 is an isometric view of a mesh yarn sheet cutting unit;

FIG. 18 is an isometric view of a mesh sliver cutting unit;

figure 19 is an isometric view of the swing frame.

Figure 20 is an isometric view of the hook and loop fastener unwind;

FIG. 21 is an isometric view of the glide drive unit;

fig. 22 is an isometric view of the delivery unit.

Description of reference numerals:

100-conveying trough, 101-first trough section, 102-second trough section, 103-third trough section, 104-fourth trough section;

200-a magnetic stripe unreeling unit, 201-a first frame, 202-a first reel, 203-a guide roller group, 2031-a first guide roller, 2032-a second guide roller, 2033-a third guide roller, 2034-a fourth guide roller and 204-a first driving motor;

300-magnetic stripe feeding part, 301-bottom plate, 302-ribbon board, 303-supporting legs, 304-guiding and shaping device, 3041-first base, 3042-first mounting seat, 3043-first cylinder, 3044-first shaping wheel, 3045-second shaping wheel, 3046-first lifting plate, 3047-first guide groove, 3048-first guide rod, 305-heating device and 306-cooling device;

400-a magnetic strip cutting unit, 401-a first base, 402-a first belt pulley, 403-a second belt pulley, 404-a first transmission belt, 405-a second driving motor, 406-a third driving motor, 407-a transmission rod, 408-a second lifting plate, 409-a first mounting plate, 410-a first fixing column, 411-a first cutter, 412-a square groove, 413-a second guide groove, 414-a second guide rod, 415-a first accommodating groove, 416-a second accommodating groove, 417-a third shaping wheel, 418-a fourth shaping wheel, 419-a fifth shaping wheel and 420-a sixth shaping wheel;

500-magnetic block supply part, 501-magnetic block storage box, 502-storage space, 503-first opening, 504-second opening, 505-third opening, 506-fourth opening, 507-first wall surface, 508-second wall surface, 509-third wall surface, 510-fourth wall surface, 511-magnetic strip output channel and 512-lightening hole;

600-partition driving unit, 601-partition, 602-partition driving cylinder, 603-first adapter plate, 604-cylinder mounting seat;

700-push plate driving unit, 701-push plate, 702-push plate driving cylinder and 703-second adapter plate;

800-traction output unit, 801-second base, 802-fourth driving motor, 803-third belt pulley, 804-fourth belt pulley, 805-second mounting plate, 806-third mounting plate, 807-second transmission belt and 808-second fixing column.

900-a magnetic stripe magnet fixing mechanism, 901-a hot press;

1000-mesh yarn sheet conveying part, 1001-second frame, 1002-second winding drum, 1003-driven roller, 1004-swinging rack, 1005-tension roller;

1100-a first pulling unit, 1101-a fifth driving motor, 1102-a first vertical plate, 1103-a first driving roller, 1104-a first pressing roller, 1105-a second vertical plate, 1106-a third guide groove, 1107-a second guide plate, 1108-a first adjusting bolt, 1109-a first spring;

1200-a second pulling unit, 1201-a sixth driving motor, 1202-a platen, 1203-a through slot, 1204-a mounting frame, 1205-a press roll driving cylinder, 1206-a mounting seat, 1207-a second press roll;

1300-mesh yarn piece cutting unit, 1301-machine base, 1302-second cutter, 1303-seventh driving motor, 1304-fifth belt pulley, 1305-sixth belt pulley, 1306-transmission shaft, 1307-transmission disc and 1308-transmission block;

1400-a third pulling unit;

1500-deviation rectifying device;

1600-mesh yarn sheet.

1700-magic tape unwinding part, 1701-third frame, 1702-substrate, 1703-sliding plate, 1704-third winding drum and 1705-support roller;

1800-a sliding driving unit, 1801-an eighth driving motor, 1802-a driving gear, 1803-a driving rack, 1804-a sliding rail and 1805-a first sliding groove;

1900-conveying unit, 1901-third vertical plate, 1902-ninth driving motor, 1903-third driving roller, 1904-third pressing roller, 1905-second sliding groove, 1906-third lifting plate, 1907-second adjusting bolt, 1908-second spring;

2000-hot pressing device;

2100-magic tape.

Detailed Description

The embodiments described below with reference to the drawings are illustrative only and should not be construed as limiting the invention.

As shown in fig. 1 to 22, an embodiment of the present invention provides an automatic production system for a magnetic soft screen door, which includes a conveying trough 100, a magnetic strip feeding part 300, a magnetic block feeding part 500, and a mesh screen sheet conveying part 1000, wherein:

the conveying groove 100 is used for accommodating magnetic stripes and magnetic blocks and guiding the magnetic stripes and the magnetic blocks to be conveyed to a designated position along the axial direction of the conveying groove 100, the magnetic stripe feeding part 300 and the magnetic block feeding part 500 are positioned at the side end of the mesh yarn piece conveying part 1000, one magnetic stripe and one magnetic block are combined, the mesh yarn piece of the mesh yarn piece conveying part 1000 is conveyed towards the direction, when the combined magnetic stripe and one magnetic block reach the designated position from the side end, the combined magnetic stripe and one magnetic block fall on the side end of the long side of the mesh yarn piece 1600, the combined magnetic stripe and one magnetic block are fixed on the mesh yarn piece through the hot press 901, the mesh yarn piece is conveyed forwards continuously and is cut into a designated length after passing through the mesh yarn piece cutting unit 1300; the conveying trough 100 comprises a first trough section 101, a second trough section 102, a third trough section 103 and a fourth trough section 104 which are sequentially connected along the conveying direction; the magnetic stripe is in a long strip shape before being cut, one end of the magnetic stripe is wound on a first winding drum 202 mentioned below, the other end of the magnetic stripe is conveyed towards the next process in the first groove section 101, and the conveying power sources comprise three places, namely active unwinding of the first winding drum 202 at the head end of the first groove section 101, active drawing of relevant structures in the magnetic stripe cutting unit 400 and drawing of a drawing output unit 800, wherein the shape of the magnetic stripe is matched with the inner contour of the conveying groove 100;

the magnetic strip feeding part 300 and the magnetic block feeding part 500 are sequentially arranged along the axial direction of the conveying groove 100;

the magnetic stripe feeding part 300 comprises a magnetic stripe unreeling unit 200 and a magnetic stripe cutting unit 400;

the magnetic stripe unwinding unit 200 is arranged at the starting end of the first groove section 101 to convey the magnetic stripe into the first groove section 101; the raw material of the magnetic strip is placed on the magnetic strip unreeling unit 200, the magnetic strip is in a long strip shape after being wound before being cut, and the magnetic strip in the winding state is unreeled to the first conveying groove 100 under the action of the magnetic strip unreeling unit 200;

the second groove section 102 is formed in the magnetic stripe cutting unit 400, the head end of the second groove section 102 is connected with the tail end of the first groove section 101, and the magnetic stripe cutting unit 400 is used for cutting the magnetic stripe on the second groove section 102 in a fixed length; the whole magnetic stripe is gradually conveyed to the magnetic stripe cutting unit 400 by the magnetic stripe transmission unit, and the magnetic stripe cutting unit 400 sequentially cuts the whole magnetic stripe into a section with equal width for subsequent production line needs.

The third groove section 103 is formed in the magnetic block feeding portion 500, a head end of the third groove section 103 is connected to a tail end of the second groove section 102, the magnetic block feeding portion 500 includes a magnetic block storage box 501, a partition 601, a partition driving unit 600, a push plate 701, and a push plate driving unit 700, wherein:

a storage space 502 is formed in the magnetic block storage box 501, a plurality of groups of magnetic blocks are stacked in the storage space 502 in the vertical direction, each group of magnetic blocks comprises a plurality of magnetic blocks, and the plurality of magnetic blocks are arranged in parallel in the horizontal direction;

a first opening 503, a second opening 504, a third opening 505 and a fourth opening 506 are formed in the magnetic block storage box 501, the first opening 503 is located at the top of the storage space 502 so that a worker can place multiple groups of magnetic blocks from the first opening 503, the second opening 504 is located on a first wall 507 of the storage space 502, the third opening 505 is located on a second wall 508 of the storage space 502, the fourth opening 506 is located on a third wall 509 of the storage space 502, the second wall 508 is opposite to the third wall 509, and the first wall 507 is located between the second wall 508 and the third wall 509; the third opening 505 and the fourth opening 506 are oppositely arranged, and the second opening 504 is higher than the third opening 505; in this embodiment, the inner diameters of the third opening 505 and the fourth opening 506 are both matched with the width of the magnetic block, the bottom surfaces of the third opening 505 and the fourth opening 506 are both flush with the bottom surface of the storage space 502, and the bottom surface of the second opening 504 is flush with the top surface of the third opening 505.

One end of the partition board 601 is fixed in the second opening 504 in a clearance fit manner, and the partition board driving unit 600 is connected with the other end of the partition board 601 to drive the partition board 601 to reciprocate in the horizontal direction; the free end of the partition board 601 may be provided with an inclined surface so as to be conveniently inserted into a gap between the upper and lower magnetic blocks, the partition board driving unit 600 may completely pull the partition board 601 out of the storage space 502, so as to facilitate the falling of the magnetic blocks, and on the other hand, may also be inserted between the two magnetic blocks to separate them, so as to facilitate the push plate 701 to push out the magnetic blocks of the lower layer one by one.

One end of the push plate 701 is fixed in the third opening 505 in a clearance fit manner, and the push plate driving unit 700 is connected with the other end of the push plate 701 to drive the push plate 701 to reciprocate in the horizontal direction, so as to further push the magnetic blocks at the bottommost layer to be sent into the third groove section 103 from the fourth opening 506 one by one. Thereby pushing the magnetic blocks at the bottommost layer to be sent out from the fourth opening 506 one by one.

By arranging the partition board 601 and the push board 701 in the magnetic block storage box 501, wherein the push board 701 is located below the partition board 601, in an initial state, the push board 701 is driven by the push board driving unit 700 and does not extend into the storage space 502, the partition board 601 extends into the storage space 502 completely, an operator stacks a plurality of sets of magnetic blocks into the storage space 502, the magnetic block of the bottommost layer is placed on the partition board 601, at this time, the partition board driving unit 600 drives the partition board 601 to move away from the storage space 502, the magnetic block of the bottommost layer falls between the partition board 601 and the bottom surface of the storage space 502, the partition board driving unit 600 works again, the partition board 601 is driven to be inserted into the storage space 502 again, so that the magnetic block of the previous penultimate layer is placed on the partition board 601, the magnetic block of the previous bottommost layer is placed between the partition board 601 and the bottom surface of the storage space 502, the push board driving unit 700 drives the push board 701 to push the magnetic blocks out of the magnetic blocks from the fourth opening 506 to a predetermined process position one by one step, when the group of magnetic blocks are all pushed out, the push plate driving unit 700 drives the push plate 701 to exit the storage space 502, and the cycle is repeated.

The mesh yarn sheet conveying portion 1000 includes a second frame 1001, a second winding drum 1002, a driven roller 1003, a first pulling unit 1100, a second pulling unit 1200, and a mesh yarn sheet cutting unit 1300, in which:

the second rack 1001 is a frame-type steel structure and is formed by overlapping a cross beam and a longitudinal beam, the second winding drum 1002, the driven roller 1003, the first pulling unit 1100 and the second pulling unit 1200 are all arranged on the second rack 1001, one end of a reticular yarn sheet 1600 is wound on the second winding drum 1002, the other end of the reticular yarn sheet 1600 is pulled by the first pulling unit 1100 and the second pulling unit 1200 in sequence and then conveyed to the reticular yarn sheet cutting unit 1300, the driven rollers 1003 are arranged on a conveying path of the reticular yarn sheet 1600, and the driven rollers 1003 are used for guiding the reticular yarn sheet 1600 to keep a predetermined tension and conveying path conveying;

the first pulling unit 1100 and the second pulling unit 1200 are both used for pulling the mesh yarn sheet 1600 so as to provide power for conveying the mesh yarn sheet 1600;

the mesh yarn piece cutting unit 1300 is used for cutting the mesh yarn piece 1600 at a fixed length.

Further, as shown in fig. 2, the magnetic stripe unwinding unit 200 includes a first frame 201, a first reel 202, a guide roller set 203 and a first driving motor 204, the first frame 201 is a frame-type steel body structure, and is formed by overlapping a plurality of beams and a plurality of longitudinal beams, and the fastness is improved at the overlapping position through a reinforcing rib, the first reel 202, the guide roller set 203 and the first driving motor 204 are all disposed on the first frame 201, the first reel 202 is used for winding the magnetic stripe, and two ends of the first reel 202 are rotatably supported on two longitudinal beams of the first frame 201 through a bearing seat.

The output end of the first driving motor 204 is connected with the end of the first reel 202 through a speed reducer so as to drive the first reel 202 to rotate, one end of the magnetic stripe is wound on the first reel 202, and the other end of the magnetic stripe is guided by the guide roller set 203 and then conveyed to the starting end of the first groove section 101; the guide roller set 203 comprises a plurality of guide rollers, wherein one function of the guide roller set 203 is to provide the belt-shaped magnetic strip with a necessary tension to keep the belt-shaped magnetic strip in a stretched state.

As shown in fig. 2, the guide roller set 203 includes a first guide roller 2031, a second guide roller 2032, a third guide roller 2033 and a fourth guide roller 2034 sequentially arranged along the conveying path, two ends of the first guide roller 2031, the second guide roller 2032, the third guide roller 2033 and the fourth guide roller 2034 are all fixed on two opposite beams, after passing through outer walls of the first guide roller 2031, the second guide roller 2032, the third guide roller 2033 and the fourth guide roller 2034 sequentially, a tensioning force is given to the strip-shaped magnetic stripe to smoothly convey the strip-shaped magnetic stripe to an opening of the first trough section 101, the first guide roller 2031, the third guide roller 2033 and the fourth guide roller 2034 are all fixed on a top end of the first rack 201, the second guide roller 2032 is fixed on the first rack 201 in a vertically reciprocating manner, the second guide roller 2032 is formed with a vertically extending strip trough by a matching manner of the strip trough 203203and a fastening bolt, the both ends of second deflector roll 2032 are fixed in the bar groove through fastening bolt's connected mode screw-thread fit respectively, and when needs adjustment position, unscrew fastening bolt, after adjusting the position, screw up fastening bolt can, through the position of adjustment second deflector roll 2032, can adjust the size of tensile force, make it can adapt to the magnetic stripe of many specifications.

Further, as shown in fig. 2 and fig. 3, a bottom plate 301, a strip plate 302, a leg 303, and a plurality of guiding and shaping devices 304 are disposed in the first frame 201, wherein:

the lath 302 is a strip-shaped plate body structure, the lath 302 is fixed on the bottom plate 301 through a plurality of supporting legs 303, and the first groove section 101 is formed at the top end of the lath 302; the first slot segment 101 forms openings at both opposite ends of the slat 302;

as shown in fig. 4, a plurality of guiding and shaping devices 304 are provided, the plurality of guiding and shaping devices 304 are sequentially arranged along the axial direction of the first trough section 101, the guiding and shaping devices 304 are used for assisting in transporting the magnetic stripe, and providing an acting force in the vertical direction to the magnetic stripe for shaping, and each guiding and shaping device 304 includes a first base 3041, a first mounting seat 3042, a first cylinder 3043, a first shaping wheel 3044, a second shaping wheel 3045, and a first lifting plate 3046;

the first base 3041 is disposed at the bottom of the slat 302, the first base 3041 is two oppositely disposed plate structures, the plate structures are provided with bearing seats, and the first shaping wheel 3044 is rotatably supported on the first base 3041 through a shaft body; a through groove is formed in the lath 302, the through groove penetrates through the lath 302, and the top end of the first shaping wheel 3044 extends through the through groove and is flush with the bottom surface of the first groove section 101;

the first mounting seat 3042 is disposed on the top of the slat 302, the first mounting seat 3042 is an L-shaped structure, the vertical plate is fixed on the bottom plate 301 and is located at the side end of the slat 302, the horizontal plate extends toward the top of the slat 302, the cylinder body of the first cylinder 3043 is fixed on the first mounting seat 3042, the piston rod of the first cylinder 3043 penetrates through the first mounting seat 3042 and vertically extends downward, the end of the piston rod of the first cylinder 3043 is connected with the first lifting plate 3046, the first mounting seat 3042 is provided with first guide slots 3047 on the two opposite sides of the first cylinder 3043, the first guide slot 3047 is internally and loosely fitted with a first guide bar 3048, the bottom end of the first guide bar 3048 is connected with the first lifting plate 3046, the bottom surface of the first lifting plate 3046 is provided with two oppositely disposed bearing seats, the second shaping wheel 3045 is supported between the two oppositely disposed bearing seats of the bottom surface of the first lifting plate 3046 through a shaft body, the second sizing wheel 3045 is rotatably supported on the bottom surface of the first lifting plate 3046, the second sizing wheel 3045 is opposite to the first sizing wheel 3044, and a gap for the magnetic stripe to pass through is formed between the first sizing wheel 3044 and the second sizing wheel 3045. The first cylinder 3043 operates to drive the first lifting plate 3046 to lift, so that the first and second sizing wheels 3044 and 3045 clamp the magnetic stripe together to keep it in a fixed shape.

Further, as shown in fig. 5 and 6, the magnetic stripe cutting unit 400 includes a first base 401, a first pulley 402, a second pulley 403, a second driving motor 405, a third driving motor 406, a transmission rod 407, a first transmission belt 404, a first installation plate 409, a first fixing column 410, and a first cutting knife 411, wherein:

the first base 401 is a block-shaped structure, the first base 401 is disposed at the tail end of the strip 302, the second groove section 102 is formed at the top of the first base 401, after the strip-shaped magnetic stripe is conveyed from the first groove section 101 to the second groove section 102, the strip-shaped magnetic stripe is cut into the block-shaped magnetic stripe by a first cutter 411 at equal intervals, a first accommodating groove 415 and a second accommodating groove 416 are sequentially recessed in the axis direction of the second groove section 102 of the first base 401, a first rotating shaft is rotatably supported in the first accommodating groove 415, a first end of the first rotating shaft penetrates through the first base 401 and then is connected with an output shaft of the second driving motor 405, a second end of the first rotating shaft penetrates through the first base 401 and then is connected with the first belt pulley 402, a third shaping wheel 417 is sleeved on the first rotating shaft, and a second rotating shaft is rotatably supported in the second accommodating groove 416, the second end of the second rotating shaft penetrates through the first base 401 and then is connected with the second belt pulley 403, a fourth sizing wheel 418 is sleeved on the second rotating shaft, two ends of the first transmission belt 404 are respectively sleeved on the first belt pulley 402 and the second belt pulley 403 in a looping mode, and the top surface of the third sizing wheel 417 and the top surface of the fourth sizing wheel 418 are flush with the bottom surface of the second groove section 102;

the first mounting plate 409 is fixed to the first base 401 through the first fixing columns 410, four first fixing columns 410 are provided, the four first fixing columns 410 are symmetrically arranged at four corners of the first mounting plate 409, a fifth sizing wheel 419 and a sixth sizing wheel 420 are rotatably supported on the bottom surface of the first mounting plate 409, the fifth sizing wheel 419 is arranged relative to the third sizing wheel 417, and a gap for the magnetic stripe to pass through is formed between the third sizing wheel 417 and the fifth sizing wheel 419; the sixth sizing wheel 420 is arranged opposite to the fourth sizing wheel 418, and a gap for the magnetic stripe to pass through is formed between the sixth sizing wheel 420 and the fourth sizing wheel 418; the fifth sizing wheel 419 and the third sizing wheel 417, and the sixth sizing wheel 420 and the fourth sizing wheel 418 are respectively matched with each other in pairs to clamp and size the magnetic stripes, and the second driving motor 405 works to drive the first rotating shaft to rotate, so that the second rotating shaft rotates through the power transmission of the first belt pulley 402 and the second belt pulley 403, and the third sizing wheel 417 and the fourth sizing wheel 418 synchronously roll to pull the magnetic stripes to be conveyed forwards.

A square groove 412 penetrates through the plate surface of the first mounting plate 409, the third driving motor 406 is fixed above the square groove 412 through a motor mounting seat, the head end of the driving rod 407 is eccentrically connected to an output shaft of the third driving motor 406, the bottom end of the driving rod 407 is connected with the top end of the second lifting plate 408, the first cutter 411 is fixed at the bottom end of the second lifting plate 408, second guide grooves 413 are respectively formed in two sides of the driving rod 407 on the second lifting plate 408, second guide rods 414 are in clearance fit in the two second guide grooves 413, and the bottom end of each second guide rod 414 is connected with the second lifting plate 408. The third driving motor 406 works, because the transmission rod 407 is eccentrically connected, the output shaft of the third driving motor 406 rotates, the transmission rod 407 makes reciprocating movement in the vertical direction to drive the first cutter 411 to make reciprocating movement in the vertical direction, the magnetic strips are continuously conveyed forwards, the first cutter 411 falls in place at intervals, the strip-shaped magnetic strips are cut into block-shaped magnetic strips, and the block-shaped magnetic strips meet the assembly requirements of the magnetic soft yarn door, so that the preparation of feeding is completed.

Further, since the tape-shaped magnetic stripe, when used as a raw material, is wound on the first bobbin 202, the shape of which may be deformed, and to further shape the ribbon, the ribbon may be heated, cooled, assisted by a guide 304, the magnetic stripe cooling device can be used for shaping, and also comprises a heating device 305 and a cooling device 306, the cooling and heating structures of the heating device 305 and the cooling device 306 can refer to the content of the prior art, as long as the magnetic stripe can be heated and cooled, and can refer to heating coil heating, condensed water refrigeration and the like, not described in detail, the heating device 305 and the cooling device 306 are sequentially arranged along the conveying direction of the magnetic strips, the heating device 305 is used for heating the magnetic strip on the first groove section 101 conveyed to a designated position, the cooling device 306 is used for cooling the magnetic strip heated by the heating device 305.

Further, as shown in fig. 7 to 11, the partition driving unit 600 includes a partition driving cylinder 602, a first transfer plate 603, and a cylinder mounting seat 604, the cylinder mounting seat 604 is fixed on the first wall 507 of the magnetic block storage box 501, a cylinder body of the partition driving cylinder 602 is fixed on the cylinder mounting seat 604, a piston rod of the partition driving cylinder 602 is disposed at a side away from the magnetic block storage box 501, the piston rod of the partition driving cylinder 602 extends in a horizontal direction, and a distal end of the piston rod is fixed to a top end of the first transfer plate 603, one end of the partition 601 is connected to a bottom end of the first transfer plate 603, and the other end of the partition 601 extends horizontally into the storage space 502 from the second opening 504. In an initial state, the partition board 601 is inserted into the storage space 502, a plurality of groups of magnetic blocks are stacked on the partition board 601, the partition board drives the cylinder 602 to work, a piston rod of the partition board drives the cylinder 602 to extend forwards, the partition board 601 can be completely drawn out of the storage space 502, so that the magnetic blocks can conveniently fall down, after the magnetic block group at the bottommost layer falls down, the partition board drives the cylinder 602 to work, the piston rod of the partition board drives the cylinder 602 to retract, the partition board 601 is inserted between the two magnetic blocks to be separated, and therefore the magnetic blocks at the lower layer can be conveniently pushed out one by the push plate 701 described later.

Further, as shown in fig. 12, the push plate driving unit 700 includes a push plate driving cylinder 702 and a second adapter plate 703, a cylinder body of the push plate driving cylinder 702 is fixed on a fourth wall surface 510 of the magnetic block storage box 501, the fourth wall surface 510 is opposite to the first wall surface 507, the fourth wall surface 510 is disposed between the second wall surface 508 and the third wall surface 509, a piston rod of the push plate driving cylinder 702 is disposed at one end close to the second wall surface 508, the piston rod of the push plate driving cylinder 702 extends in a horizontal direction, and a terminal end of the piston rod is fixed to a top end of the second adapter plate 703, one end of the push plate 701 is connected to a bottom end of the second adapter plate 703, and the other end of the push plate 701 extends horizontally into the storage space 502 from the third opening 505. In an initial state, the push plate 701 is pulled away from the storage space 502 so that the magnetic blocks fall on the bottom surface of the storage space 502, when the magnetic blocks fall, the push plate drives the piston rod of the air cylinder 702 to retract, the group of magnetic blocks are pushed out from the fourth opening 506 one by one, and after the magnetic blocks are completely pushed out, the piston rod of the air cylinder 702 is driven by the push plate to extend forwards, and the cycle is repeated.

Further, in order to guide the magnetic block pushed out from the fourth opening 506 to reach the designated working position, the magnetic strip output channel 511 is further included, the two ends of the magnetic strip output channel 511 are provided with plate structures in a penetrating mode, the magnetic strip output channel 511 is arranged in an inclined mode, the starting end of the magnetic strip output channel 511 is communicated with the fourth opening 506, and the tail end of the magnetic strip output channel 511 is connected with the third groove section 103.

The second wall 508 and the third wall 509 are provided with lightening holes 512, which is convenient for observing the states of the magnetic blocks in the magnetic block storage box 501, so as to prepare for magnetic block supplement or maintenance at any time.

Further, as shown in fig. 13, a traction output unit 800 is further provided, the traction output unit 800 includes a second base 801, a fourth driving motor 802, a third belt pulley 803, a fourth belt pulley 804, a second mounting plate 805, a third mounting plate 806, a second transmission belt 807 and second fixing posts 808, the second base 801 is a plate structure, the fourth groove section 104 is formed on the top surface of the second base 801, the head end of the fourth groove section 104 is engaged with the tail end of the third groove section 103, the magnetic strip and the magnetic block output from the third groove section 103 fall into the fourth groove section 104 and then are sent out through the fourth groove section 104, the second mounting plate 805 is fixed on the second base 801 by the second fixing posts 808, the four second fixing posts 808 are arranged at the four corners of the second mounting plate 805, the third mounting plate 806 is fixed on the second mounting plate 805, the extending direction of the third mounting plate 806 is perpendicular to the extending direction of the second mounting plate 805, the third pulley 803 is rotatably disposed on the top of the third mounting plate 806, the plurality of fourth pulleys 804 are disposed, the plurality of fourth pulleys 804 are rotatably disposed on the second mounting plate 805 at intervals, the extending direction of the plurality of fourth pulleys 804 is parallel to the extending direction of the fourth slot segment 104, the second transmission belt 807 is looped around the third pulley 803 and the plurality of fourth pulleys 804, the second transmission belt 807 is tensioned by the third pulley 803 and two fourth pulleys 804 at both ends, the second transmission belt is located above the fourth slot segment 104 and is attached to the magnetic strip and the magnetic block in the fourth slot segment 104, the output end of the fourth driving motor 802 is connected to the third pulley 803, to drive the third pulley 803 to rotate. The fourth driving motor 802 operates to drive the third belt pulleys 803 to rotate, and then drives the plurality of third belt pulleys 803 on the second mounting plate 805 to synchronously rotate, the second transmission belt 807 rotates, meanwhile, since the second transmission belt 807 is tightly attached to the magnetic blocks of the magnetic stripe on the fourth slot segment 104, therefore, the rotation of the second transmission belt 807 can drive the magnetic stripe magnet to move on the fourth groove section 104 by the action of friction force, the end of the fourth groove section 104 is provided with the magnetic stripe magnet fixing mechanism 900, the magnetic stripe magnet output by the magnetic stripe magnet fixing mechanism 900 is just aligned with the edge of the reticular yarn sheet 1600, after being sent out from the fourth groove section 104, the magnetic strips and the magnetic blocks are fixed through the magnetic strip and magnetic block fixing mechanism 900, the magnetic strip and magnetic block fixing mechanism 900 outputs fabric, one magnetic strip and one magnetic block are wrapped in one unit, and then the fabric is fixed on the edge of the reticular yarn sheet 1600 through hot pressing and fusion of the hot press 901. The structure of the magnetic stripe and magnetic block fixing mechanism 900 can refer to the content of the prior art, non-woven fabric is wound on a cylinder in a coiled manner and then is output through a conveying roller, during the process, the support of a guide roller provides tension, the tail end of the non-woven fabric covers one unit of magnetic block and magnetic strip of the magnetic stripe and the magnetic stripe of the magnetic block from one side perpendicular to the output direction of the magnetic stripe and is cut and then is hot-pressed and fused through a hot press 901, the structure of the part can refer to the attached drawings or the content of the prior art, so the tail end of the non-woven fabric is not a main innovation point of the embodiment and is not described herein any more, meanwhile, in the invention, an edge covering mechanism is also arranged to cover two long edges of the reticular yarn sheet 1600, the edge covering mechanism can refer to the content of the prior art, the edge covering mechanism is positioned at two sides of a reticular yarn sheet conveying path, the edge covering cloth is wound on the cylinder in a coiled manner and then is output through the conveying roller, during the process, the support of the guide roller provides tension, and the tail end of the edge covering cloth covers the long edges of the reticular yarn sheet 1600 in the horizontal direction, and after cutting, hot-pressing and fusing by a hot-pressing device.

Further, as shown in fig. 14 to 15, the first drawing unit 1100 is located at the head end of the second frame 1001, the free end of the wound mesh yarn sheet 1600 passes through the outer surface of a driven roller 1003 and enters the first drawing unit 1100, the first drawing unit 1100 unwinds the mesh yarn sheet 1600 from the second winding drum 1002 by drawing the mesh yarn sheet 1600, the first drawing unit 1100 includes a fifth driving motor 1101, a first vertical plate 1102, a first driving roller 1103 and a first pressing roller 1104, the first vertical plate 1102 is provided with two, the two first vertical plates 1102 are symmetrically arranged on the second frame 1001 and located at two sides of the conveying path of the mesh yarn sheet 1600, two ends of the first driving roller 1103 are rotatably arranged on the two first vertical plates 1102, the mesh yarn sheet 1600 is lapped on the first driving roller 1103, the output end of the fifth driving motor 1101 is connected with the shaft end of the first driving roller 1103, the mesh yarn sheet 1600 is conveyed by driving the first driving roller 1103 to rotate, a second vertical plate 1105 is fixed on the plate surface of each first vertical plate 1102, the second vertical plate 1105 is located above the first driving roller 1103, a third guide groove 1106 is concavely arranged on the plate surface of the second vertical plate 1105, a second guide plate 1107 is fixed in the third guide groove 1106 and can vertically reciprocate, a bearing seat is arranged on the second guide plate 1107, two ends of the first pressing roller 1104 are rotatably arranged on the bearing seats of the two second guide plates 1107, the first pressing roller 1104 is located right above the first driving roller 1103, the mesh yarn sheet 1600 is conveyed by the first pressing roller 1104 and the first driving roller 1103 together, the top end of the second vertical plate 1105 is connected with a first adjusting bolt 1108 through threads, and the bottom end of the first adjusting bolt 1108 extends into the third guide groove 1106, a first spring 1109 is disposed in the third guide groove 1106, a top end of the first spring 1109 abuts against a bottom end of the first adjusting bolt 1108, and a bottom end of the first spring 1109 abuts against a top surface of the second guide plate 1107. By adjusting the depth of the first adjusting bolt 1108 extending into the third channel 1106, the pressing force of the spring can be adjusted, which in turn adjusts the clamping force of the first pressing roller 1104 and the first driving roller 1103 on the mesh yarn sheet 1600.

Further, as shown in fig. 15, the second pulling unit 1200 is located at the tail end of the second machine frame 1001, and includes a sixth driving motor 1201, a second driving roller, and a platen 1202, the platen 1202 is horizontally disposed on the second machine frame 1001, a through groove 1203 penetrates through the platen 1202, the second driving roller is rotatably supported on the second machine frame 1001, the second driving roller is located at the bottom of the platen 1202, the top surface of the second driving roller extends out of the through groove 1203 and is flush with the plate surface of the platen 1202, the output end of the sixth driving motor 1201 is connected to the second driving roller to drive the second driving roller to rotate, a mounting frame 1204 is disposed on the platen 1202, the mounting frame 1204 includes a cross beam and two longitudinal beams, the two longitudinal beams of the mounting frame 1204 are disposed at opposite sides of the through groove 1203, a plurality of pressing roller driving cylinders 1205 are disposed on the cross beam of the mounting frame 1204, piston rod reciprocating motion in the vertical direction of compression roller driving cylinder 1205, the piston rod end of compression roller driving cylinder 1205 is fixed with the mount pad 1206, be equipped with two bearing frames of symmetry on the mount pad 1206, there is second compression roller 1207 through the rotatable support of bearing frame on the free end of mount pad 1206, and is a plurality of second compression roller 1207 all is located the top of second drive roller, the second drive roller with a plurality of the common centre gripping of second drive roller is carried netted yarn piece 1600. The pressure roller driving cylinder 1205 works to drive the second pressure roller 1207 to move towards the second driving roller, so that the second pressure roller 1207 and the second driving roller clamp the netted yarn sheet 1600 together, the sixth driving motor 1201 works to drive the second driving roller to rotate, and then the netted yarn sheet 1600 is pulled to move forwards to send out the second rack 1001.

Further, as shown in fig. 17 and 18, the mesh yarn sheet cutting unit 1300 includes a base 1301, a third pulling unit 1400, a second cutter 1302, a seventh driving motor 1303, a fifth pulley 1304, a sixth pulley 1305, a transmission shaft 1306, a transmission disc 1307, and a transmission block 1308, the base 1301 is disposed on a side of the second frame 1001 near the second pulling unit 1200, and the third pulling unit 1400, the second cutter 1302, the seventh driving motor 1303, the fifth pulley 1304, the sixth pulley 1305, the transmission shaft 1306, the transmission disc 1307, and the transmission block 1308 are all fixed on the base 1301.

The third pulling unit 1400 is disposed between the second pulling unit 1200 and the second cutting knife 1302, and the third pulling unit 1400 is configured to receive the mesh yarn sheet 1600 sent by the second pulling unit 1200 and send the mesh yarn sheet 1600 to the second cutting knife 1302; after the mesh yarn sheet 1600 is fed out from the second drawing unit 1200, the mesh yarn sheet is fed to the third drawing unit 1400, the structure of the third drawing unit 1400 is the same as that of the first drawing unit 1100, and the third drawing unit 1400 continues to draw the mesh yarn sheet 1600 and continuously feeds the mesh yarn sheet into the second cutter 1302, so that the cutting is completed.

An output shaft of the seventh driving motor 1303 is connected to the fifth belt pulley 1304, the transmission shaft 1306 is rotatably supported on the base 1301 through a bearing seat, one end of the transmission shaft 1306 is fixedly connected to the sixth belt pulley 1305, the fifth belt pulley 1304 and the sixth belt pulley 1305 are connected through a belt in a tensioned manner, two transmission discs 1307 and two transmission blocks 1308 are provided, the two transmission discs 1307 are eccentrically connected to the transmission shaft 1306, a lug is convexly arranged on the outer circumferential surface of each transmission disc 1307, the two transmission blocks 1308 and the two transmission discs 1307 are in one-to-one correspondence, and two ends of each transmission block 1308 are respectively connected to the lug and the second cutter 1302. The seventh driving motor 1303 works to drive the fifth belt pulley 1304 to rotate, and the power transmission of the belt and the sixth belt pulley 1305 drives the transmission shaft 1306 to rotate, so that the transmission disc 1307 is eccentrically connected, the circumferential rotation of the transmission shaft 1306 is converted into the vertical reciprocating motion of the transmission block 1308, the second cutter 1302 periodically rises and falls, and the cutting of the reticular yarn sheet 1600 is completed.

Further, the second frame 1001 is further provided with a deviation rectifying device 1500, the deviation rectifying device 1500 is disposed on the conveying path of the mesh-shaped yarn sheet 1600, so that the mesh-shaped yarn sheet 1600 is conveyed on the predetermined conveying path, and the structure of the deviation rectifying device 1500 may refer to a deviation rectifying structure for cloth, board or other materials in the prior art, which is not described herein again.

Furthermore, in order to keep the mesh yarn sheet 1600 in a tensioned state during the conveying process, a swing frame 1004 is further provided, the swing frame 1004 is disposed between the first pulling unit 1100 and the deviation rectifying device 1500, one end of the swing frame 1004 is pivotally fixed to the second rack 1001, the other end of the swing frame 1004 is fixed with a tension roller 1005, and the tension roller 1005 is disposed on the conveying path of the mesh yarn sheet 1600. After the swing frame 1004 is rotated to a proper position, the swing frame 1004 is fixed by screwing the bolt pieces, so that the net-shaped yarn sheet 1600 can keep a continuous tension state.

Further, as shown in fig. 20 to 22, a velcro tape unwinding portion 1700 is further provided for attaching velcro tapes to the long side of the mesh-like yarn sheet 1600, and includes a third frame 1701, a substrate 1702, a sliding plate 1703, a third reel 1704, a support roller 1705, a conveying unit 1900, a sliding drive unit 1800, and a hot press device 2000, wherein:

the third frame 1701 is a frame structure and is formed by overlapping cross beams and longitudinal beams, the substrate 1702 is fixed on the top of the third frame 1701, the substrate 1702 is used for providing a mounting surface, the sliding plate 1703 is fixed on the substrate 1702 in a horizontally reciprocating sliding manner, the sliding driving unit 1800 is connected with the sliding plate 1703 to drive the sliding plate 1703 to reciprocate in the horizontal direction to be close to or far from the mesh yarn sheet 1600, because the widths of the mesh yarn sheets 1600 with different specifications are different, so that the sliding driving unit 1800 is used for driving the sliding plate 1703 to change the position adaptively in order to ensure that the magic tape 2100 is just attached to the designated part of the edge of the mesh yarn sheet 1600 after being sent out;

the third reel 1704, the support rollers 1705, the transfer unit 1900, and the hot press apparatus 2000 are all disposed on the slide 1703, one end of the hook and loop fastener 2100 is wound around the third reel 1704, the other end of the magic tape 2100 is guided by the plurality of support rollers 1705 and then conveyed to the conveying path of the mesh yarn 1600, the conveying unit 1900 is used for providing power for conveying the magic tape 2100, so that the magic tape is continuously unwound from the third reel 1704, and then, after being guided by a plurality of rollers 1705, is sent to the transport path of the mesh yarn sheet 1600, after the magic tape 2100 is conveyed to the conveying path of the mesh yarn 1600, the hot pressing device 2000 fixes the magic tape 2100 and the edge of the mesh yarn 1600 by hot pressing and fusing, and the structure of the hot pressing device 2000 refers to the structure of the prior art, which is a conventional device and is not described herein.

By providing the third frame 1701, the substrate 1702, the sliding plate 1703, the third reel 1704, the support roller 1705, the conveying unit 1900, the sliding driving unit 1800, and the hot-pressing device 2000, the magic tape 2100 is wound around the third reel 1704 and conveyed to the conveying path of the mesh-like yarn sheet 1600 by the power supplied from the conveying device, and then the hot-pressing device 2000 fuses and fixes the magic tape 2100 and the edge portion of the mesh-like yarn sheet 1600 by hot pressing, and the sliding driving unit 1800 is used for driving the sliding plate 1703 to reciprocate so as to adjust the output position of the magic tape 2100 and keep the magic tape bonded to the edge portion of the mesh-like yarn sheet 1600.

Further, the sliding driving unit 1800 includes an eighth driving motor 1801, a driving gear 1802, a driving rack 1803, a sliding rail 1804, and a first sliding slot 1805, wherein a cylinder of the eighth driving motor 1801 is fixed on the third frame 1701, the driving gear 1802 is fixed at an end of an output shaft of the eighth driving motor 1801, the driving rack 1803 is fixed at a bottom of the sliding plate 1703, the driving gear 1802 is engaged with the driving rack 1803, the sliding rail 1804 is fixed on the substrate 1702, the first sliding slot 1805 is fixed at a bottom of the sliding plate 1703, and the sliding rail 1804 is slidably fitted on the second sliding slot 1905. The eighth driving motor 1801 operates to drive the driving gear 1802 to rotate, and since the driving rack 1803 is engaged with the driving gear 1802, the rotation of the driving gear 1802 is converted into horizontal movement of the driving rack 1803, so as to drive the sliding plate 1703 to horizontally slide.

Further, the conveying unit 1900 includes two third vertical plates 1901, a ninth driving motor 1902, a third driving roller 1903 and third pressing rollers 1904, where two of the third vertical plates 1901 are symmetrically fixed on the third frame 1701, the third driving roller 1903 is rotatably disposed between the two third vertical plates 1901, an output end of the ninth driving motor 1902 is connected with an axial end of the third driving roller 1903 to drive the third driving roller 1903 to rotate, a second chute 1905 penetrates through a plate surface of the third vertical plate 1901, a third lifting plate 1906 is reciprocally fixed in the second chute 1905, the third pressing roller 1904 is rotatably disposed between the two third lifting plates 1906, the third pressing roller 1904 is located above the third driving roller 1903, a gap through which the magic tape 2100 passes is formed between the third pressing roller 1904 and the third driving roller 1903, to hold the hook and loop fastener 2100 for forward delivery.

Further, in order to adjust the pressure of the third pressing roller 1904, a second adjusting bolt 1907 is screwed to the top end of the third vertical plate 1901, the bottom end of the second adjusting bolt 1907 extends into the second chute 1905 and then is connected to the top end of the third lifting plate 1906, a second spring 1908 is disposed in the second chute 1905, the top end of the second spring 1908 abuts against the bottom surface of the third lifting plate 1906, and the bottom end of the second spring 1908 abuts against the bottom surface of the second chute 1905. Two second springs 1908 are provided, and the two second springs 1908 are symmetrically disposed at the bottom of the third lifting plate 1906.

The magic tape 2100 is wound on the third winding drum 1704, the eighth driving motor 1801 operates to drive the driving gear 1802 to rotate, the driving rack 1803 is meshed with the driving gear 1802, so that the rotation of the driving gear 1802 is converted into the horizontal movement of the driving rack 1803 to drive the sliding plate 1703 to horizontally slide, after the magic tape 2100 is sent out, the magic tape is just attached to the designated part of the edge of the mesh-shaped yarn sheet 1600, the ninth driving motor 1902 operates to drive the third driving roller 1903 to rotate, the magic tape 2100 is clamped and conveyed forwards under the matching of the third pressing roller 1904, the magic tape 2100 is continuously unwound, after the magic tape 2100 is conveyed to the conveying path of the mesh-shaped yarn sheet 1600, and the hot pressing device 2000 hot-presses and fuses and fixes the magic tape 2100 and the edge of the mesh-shaped yarn sheet 1600.

The construction, features and functions of the present invention are described in detail in the embodiments illustrated in the drawings, which are only preferred embodiments of the present invention, but the present invention is not limited by the drawings, and all equivalent embodiments modified or changed according to the idea of the present invention should fall within the protection scope of the present invention without departing from the spirit of the present invention covered by the description and the drawings.

Claims (10)

1. The utility model provides a soft screen door automated production system of magnetism, its characterized in that includes conveyer trough, magnetic stripe feed portion, magnetic path feed portion and netted yarn piece conveying part, wherein:

the conveying groove is used for accommodating the magnetic strips and the magnetic blocks and guiding the magnetic strips and the magnetic blocks to be conveyed to a specified position along the axial direction of the conveying groove; the conveying groove comprises a first groove section, a second groove section, a third groove section and a fourth groove section which are sequentially connected along the conveying direction;

the magnetic strip feeding part and the magnetic block feeding part are sequentially arranged along the axial direction of the conveying groove;

the magnetic strip feeding part comprises a magnetic strip unreeling unit and a magnetic strip cutting unit;

the magnetic stripe unreeling unit is arranged at the starting end of the first groove section so as to convey the magnetic stripe into the first groove section; the magnetic stripe unreeling unit comprises a first rack, a first reel, a guide roller set and a first driving motor, wherein the first reel, the guide roller set and the first driving motor are all arranged on the first rack, the output end of the first driving motor is connected with the end part of the first reel so as to drive the first reel to rotate, one end of the magnetic stripe is coiled on the first reel, and the other end of the magnetic stripe is conveyed to the starting end of the first groove section after being guided by the guide roller set;

the guide roller group comprises a first guide roller, a second guide roller, a third guide roller and a fourth guide roller which are sequentially arranged along a conveying path, the first guide roller, the third guide roller and the fourth guide roller are all fixed at the top end of the first rack, and the second guide roller can be vertically fixed on the first rack in a reciprocating manner; the second groove section is formed in the magnetic stripe cutting unit, the head end of the second groove section is connected with the tail end of the first groove section, and the magnetic stripe cutting unit is used for cutting the magnetic stripe on the second groove section in a fixed length;

the third groove section is formed in the magnetic block feeding portion, the head end of the third groove section is connected with the tail end of the second groove section, the magnetic block feeding portion comprises a magnetic block storage box, a partition plate driving unit, a push plate and a push plate driving unit, wherein:

a storage space is formed in the magnetic block storage box, a plurality of groups of magnetic blocks are stacked in the storage space in the vertical direction, each group of magnetic blocks comprises a plurality of magnetic blocks, and the plurality of magnetic blocks are arranged in parallel in the horizontal direction;

a first opening, a second opening, a third opening and a fourth opening are formed in the magnetic block storage box, the first opening is located at the top of the storage space, the second opening is located on a first wall surface of the storage space, the third opening is located on a second wall surface of the storage space, the fourth opening is located on a third wall surface of the storage space, the second wall surface and the third wall surface are arranged oppositely, and the first wall surface is located between the second wall surface and the third wall surface; the third opening and the fourth opening are oppositely arranged, and the second opening is higher than the third opening;

one end of the partition board is fixed in the second opening in a clearance fit mode, and the partition board driving unit is connected with the other end of the partition board so as to drive the partition board to reciprocate in the horizontal direction;

one end of the push plate is fixed in the third opening in a clearance fit mode, and the push plate driving unit is connected with the other end of the push plate to drive the push plate to reciprocate in the horizontal direction, so that the magnetic blocks at the bottommost layer are pushed to be sent into the third groove section from the fourth opening one by one;

netted yarn piece conveying part includes second frame, second reel, driven roller, first tractive unit, second tractive unit and netted yarn piece cutting unit, wherein:

the second winding drum, the driven rollers, the first traction unit and the second traction unit are all arranged on the second rack, one end of a reticular yarn sheet is wound on the second winding drum, the other end of the reticular yarn sheet is conveyed to the reticular yarn sheet cutting unit after being sequentially pulled by the first traction unit and the second traction unit, and the driven rollers are arranged on a conveying path of the reticular yarn sheet;

the first drawing unit and the second drawing unit are used for drawing the reticular yarn sheet so as to provide power for conveying the reticular yarn sheet;

the mesh yarn piece cutting unit is used for cutting the mesh yarn piece at a fixed length.

2. The automatic production system of a magnetic soft screen door as claimed in claim 1, wherein a bottom plate, a slat, a leg and a plurality of guiding and shaping devices are disposed in the first frame, wherein:

the lath is fixed on the bottom plate through a plurality of supporting legs, and the first groove section is formed at the top end of the lath;

the guide shaping devices are arranged in a plurality and are sequentially arranged along the axis direction of the first groove section, and each guide shaping device comprises a first base, a first mounting seat, a first air cylinder, a first shaping wheel, a second shaping wheel and a first lifting plate;

the first base is arranged at the bottom of the batten, and the first shaping wheel is rotatably supported on the first base;

first mount pad set up in the top of slat, the cylinder body of first cylinder is fixed in on the first mount pad, the piston rod of first cylinder runs through perpendicular downwardly extending behind the first mount pad, the piston rod of first cylinder end with first lifter plate is connected, first mount pad in the relative both sides of first cylinder all are equipped with first guide slot, clearance fit has first guide arm in the first guide slot, the bottom of first guide arm with first lifter plate is connected, the rotatable support of second sizing wheel in the bottom surface of first lifter plate, the second sizing wheel with first sizing wheel sets up relatively, first sizing wheel with be formed with between the second sizing wheel and be used for supplying the clearance that the magnetic stripe passes through.

3. The automatic production system of a magnetic soft screen door according to claim 2, wherein the magnetic strip cutting unit comprises a first base, a first belt pulley, a second driving motor, a third driving motor, a transmission rod, a first transmission belt, a first mounting plate, a first fixing column and a first cutter, wherein:

the first base is arranged at the tail end of the batten, the second groove section is formed at the top of the first base, the first base is provided with a first accommodating groove and a second accommodating groove in a concave manner in sequence in the axis direction of the second groove section, a first rotating shaft is rotatably supported in the first accommodating groove, a first end of the first rotating shaft penetrates through the first base and then is connected with an output shaft of the second driving motor, the second end of the first rotating shaft penetrates through the first base and then is connected with the first belt pulley, a third sizing wheel is sleeved on the first rotating shaft, a second rotating shaft is rotatably supported in the second accommodating groove, a second end of the second rotating shaft penetrates through the first base and then is connected with the second belt pulley, a fourth setting wheel is sleeved on the second rotating shaft, and two ends of the first transmission belt are respectively sleeved on the first belt pulley and the second belt pulley in a circle manner;

the first mounting plate is fixed on the first base through the first fixing columns, four first fixing columns are arranged and symmetrically arranged at four corners of the first mounting plate, a fifth sizing wheel and a sixth sizing wheel are rotatably supported on the bottom surface of the first mounting plate, the fifth sizing wheel is arranged relative to the third sizing wheel, and a gap for the magnetic stripe to pass through is formed between the third sizing wheel and the fifth sizing wheel; the sixth sizing wheel is arranged relative to the fourth sizing wheel, and a gap for the magnetic stripe to pass through is formed between the sixth sizing wheel and the fourth sizing wheel;

the surface of the first mounting plate is provided with a square groove in a penetrating mode, the third driving motor is fixed above the square groove through a motor mounting seat, the head end of the transmission rod is eccentrically connected to the output shaft of the third driving motor, the bottom end of the transmission rod is connected with the top end of the second lifting plate, the first cutter is fixed at the bottom end of the second lifting plate, the second lifting plate is provided with second guide grooves in two sides of the transmission rod respectively, the second guide grooves are internally provided with second guide rods in a clearance fit mode, and the bottom end of the second guide rods is connected with the second lifting plate.

4. The automatic production system of a magnetic soft screen door as claimed in claim 3, wherein the partition driving unit comprises a partition driving cylinder, a first transfer plate and a cylinder mounting seat, the cylinder mounting seat is fixed on the first wall surface of the magnetic block storage box, the cylinder body of the partition driving cylinder is fixed on the cylinder mounting seat, the piston rod of the partition driving cylinder is arranged on one side departing from the magnetic block storage box, the piston rod of the partition driving cylinder extends in the horizontal direction, the tail end of the piston rod is fixed with the top end of the first transfer plate, one end of the partition is connected with the bottom end of the first transfer plate, and the other end of the partition extends into the storage space from the second opening horizontally.

5. The automatic production system of a soft screen door of magnetism of claim 4, characterized in that, push pedal drive unit includes push pedal drive cylinder and second keysets, the cylinder body that push pedal drive cylinder is fixed in on the fourth wall of magnetic path storage box, the fourth wall with first wall sets up relatively, the fourth wall set up in the second wall with between the third wall, the piston rod that push pedal drive cylinder set up in be close to the one end of second wall, the piston rod that push pedal drive cylinder extend along the horizontal direction and terminal with the top of second keysets is fixed, the one end of push pedal with the bottom of second keysets is connected, the other end of push pedal certainly the third opening horizontal extension goes into in the storage space.

6. The automatic production system of a magnetic soft screen door according to claim 5, further comprising a traction output unit, wherein the traction output unit comprises a second base, a fourth driving motor, a third belt pulley, a fourth belt pulley, a second mounting plate, a third mounting plate, a second transmission belt and second fixing columns, the fourth groove section is formed on the top surface of the second base, the head end of the fourth groove section is connected with the tail end of the third groove section, the second mounting plate is fixed on the second base through the second fixing columns, the four second fixing columns are arranged at four corners of the second mounting plate, the third mounting plate is fixed on the second mounting plate, the extension direction of the third mounting plate is perpendicular to the extension direction of the second mounting plate, and the third belt pulley is rotatably arranged on the top of the third mounting plate, the fourth belt pulley is equipped with a plurality ofly, and is a plurality of the rotatable interval of fourth belt pulley set up in on the second mounting panel, it is a plurality of the extending direction of fourth belt pulley with the extending direction of fourth groove section is parallel, second transmission belt circle overlap in third belt pulley and a plurality of on the fourth belt pulley, second transmission belt quilt third belt pulley and two that are located both ends the tensioning of fourth belt pulley, second transmission belt is located the top of fourth groove section and laminate in magnetic stripe and the magnetic path in the fourth groove section, fourth driving motor's output with third belt pulley connection, in order to drive the third belt pulley rotates.

7. The automatic production system of a magnetic soft screen door according to claim 6, wherein the first pulling unit is located at the head end of the second frame, and comprises a fifth driving motor, two first vertical plates, two first driving rollers and two first pressing rollers, the two first vertical plates are symmetrically arranged on the second frame and located at two sides of the mesh screen sheet conveying path, two ends of the first driving roller are rotatably arranged on the two first vertical plates, an output end of the fifth driving motor is connected with a shaft end of the first driving roller to drive the first driving roller to rotate, a second vertical plate is fixed on a plate surface of the first vertical plate, the second vertical plate is located above the first driving roller, a third guide groove is concavely arranged on a plate surface of the second vertical plate, and a second guide plate is fixed in the third guide groove and can vertically reciprocate up and down, the two ends of the first pressing roller are rotatably arranged on the two second guide plates, the first pressing roller and the first driving roller are clamped and conveyed together to form the netted yarn piece, the top end of the second vertical plate is connected with a first adjusting bolt in a threaded mode, the bottom end of the first adjusting bolt extends into the third guide groove, a first spring is arranged in the third guide groove, the top end of the first spring is abutted to the bottom end of the first adjusting bolt, and the bottom end of the first spring is abutted to the top face of the second guide plate.

8. The automatic production system of a magnetic soft screen door according to claim 7, wherein the second drawing unit is located at the tail end of the second frame and comprises a sixth driving motor, a second driving roller and a platen, the platen is arranged on the second frame, a through groove is formed in the platen, the second driving roller is rotatably supported on the second frame, the top surface of the second driving roller extends out of the through groove and is flush with the plate surface of the platen, the output end of the sixth driving motor is connected with the second driving roller to drive the second driving roller to rotate, a mounting frame is arranged on the platen, a plurality of pressing roller driving cylinders are arranged on the mounting frame, piston rods of the pressing roller driving cylinders reciprocate in the vertical direction, and mounting seats are fixed at the tail ends of the piston rods of the pressing roller driving cylinders, rotatable support has the second compression roller on the free end of mount pad, and is a plurality of the second compression roller all is located the top of second drive roller, the second drive roller with a plurality of the common centre gripping of second drive roller is carried netted yarn piece.

9. The automatic production system of a magnetic soft screen door according to claim 8, wherein the mesh yarn sheet cutting unit comprises a base, a third drawing unit, a second cutter, a seventh driving motor, a fifth belt pulley, a sixth belt pulley, a transmission shaft, a transmission disc and a transmission block, the base is arranged on one side of the second frame close to the second drawing unit, and the third drawing unit, the second cutter, the seventh driving motor, the fifth belt pulley, the sixth belt pulley, the transmission shaft, the transmission disc and the transmission block are all fixed on the base;

the third drawing unit is arranged between the second drawing unit and the second cutter and is used for receiving the reticular yarn sheet sent out by the second drawing unit and sending the reticular yarn sheet to the second cutter;

seventh driving motor's output shaft with fifth belt pulley connection, the transmission shaft rotate support in on the frame, the one end fixed connection of transmission shaft the sixth belt pulley, the fifth belt pulley with the sixth belt pulley passes through the belt tensioning and connects, the transmission dish the transmission piece all is equipped with two, two the transmission dish all eccentric connect in on the transmission shaft, the outer periphery epirelief of transmission dish is equipped with the lug, two the transmission piece and two the transmission dish one-to-one, the both ends of transmission piece respectively with the lug with the second cutter is connected.

10. The automatic production system of a magnetic soft screen door according to claim 9, further comprising a magic tape unwinding part including a third frame, a base plate, a sliding plate, a third winding drum, a supporting roller, a conveying unit, a sliding driving unit and a hot pressing device, wherein:

the base plate is fixed at the top of the third rack, the sliding plate can be horizontally and reciprocally fixed on the base plate in a sliding manner, and the sliding driving unit is connected with the sliding plate so as to drive the sliding plate to move reciprocally in the horizontal direction to be close to or far from the reticular gauze pieces;

the third winding drum, the supporting rollers, the conveying unit and the hot-pressing device are all arranged on the sliding plate, one end of a magic tape is wound on the third winding drum, the other end of the magic tape is guided by the supporting rollers and then conveyed to a conveying path of the reticular yarn sheet, the conveying unit is used for providing power for conveying the magic tape, and after the magic tape is conveyed to the conveying path of the reticular yarn sheet, the hot-pressing device is used for hot-pressing, fusing and fixing the magic tape and the edge of the reticular yarn sheet;

the sliding driving unit comprises an eighth driving motor, a driving gear, a driving rack, a sliding rail and a first sliding groove, wherein a cylinder body of the eighth driving motor is fixed on the third rack, the driving gear is fixed at the tail end of an output shaft of the eighth driving motor, the driving rack is fixed at the bottom of the sliding plate, the driving gear is meshed with the driving rack, the sliding rail is fixed on the base plate, the first sliding groove is fixed at the bottom of the sliding plate, and the sliding rail is in sliding fit with the first sliding groove;

the conveying unit comprises third vertical plates, a ninth driving motor, a third driving roller and third pressing rollers, the number of the third vertical plates is two, the two third vertical plates are symmetrically fixed on the third rack, the third driving roller is rotatably arranged between the two third vertical plates, the output end of the ninth driving motor is connected with the shaft end of the third driving roller so as to drive the third driving roller to rotate, a second chute penetrates through the plate surface of the third vertical plate, a third lifting plate is fixed in the second chute in a reciprocating lifting manner, the third pressing roller is rotatably arranged between the two third lifting plates and is positioned above the third driving roller, and a gap through which the magic tape passes is formed between the third pressing roller and the third driving roller so as to clamp the magic tape to convey forwards;

a second adjusting bolt is fixed at the top end of the third vertical plate in a threaded manner, the bottom end of the second adjusting bolt extends into the second chute and then is connected with the top end of the third lifting plate, a second spring is arranged in the second chute, the top end of the second spring is abutted against the bottom surface of the third lifting plate, and the bottom end of the second spring is abutted against the bottom surface of the second chute.

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