CN209816430U - Intelligent automatic double-side overedger - Google Patents

Intelligent automatic double-side overedger Download PDF

Info

Publication number
CN209816430U
CN209816430U CN201920090779.9U CN201920090779U CN209816430U CN 209816430 U CN209816430 U CN 209816430U CN 201920090779 U CN201920090779 U CN 201920090779U CN 209816430 U CN209816430 U CN 209816430U
Authority
CN
China
Prior art keywords
cloth
label
plate
cutter
adjusting
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN201920090779.9U
Other languages
Chinese (zh)
Inventor
吴文斌
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Suzhou Dazhao Intelligent Technology Co Ltd
Original Assignee
Suzhou Dazhao Intelligent Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Suzhou Dazhao Intelligent Technology Co Ltd filed Critical Suzhou Dazhao Intelligent Technology Co Ltd
Priority to CN201920090779.9U priority Critical patent/CN209816430U/en
Application granted granted Critical
Publication of CN209816430U publication Critical patent/CN209816430U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Abstract

The utility model discloses an automatic two side overedger of intelligence, include: the cloth cuts off disc cutter machine, two-way granny rag feeder, 2 auxiliary frames, cuts the mark and send mark all-in-one, overedger, regulation platform, hold-in range transport motion structure and tangent line heat to glue the mechanism, the cloth cuts off disc cutter machine rear and is provided with two-way granny rag feeder, 2 auxiliary frames are the mirror image setting respectively and are in both sides about two-way granny rag feeder, every be provided with 1 on the auxiliary frame and cut the mark and send mark all-in-one, 2 overedgers, 2 regulation platform, 2 hold-in range transport motion structure and 2 tangent lines heat to glue the mechanism. In this way, the utility model provides an automatic two side overedger of intelligence has realized producing the arbitrary regulation of product specification in accommodation range as required, has reached automation equipment's requirement, does not need artifical loaded down with trivial details going the adjustment, and degree of automation is higher, satisfies the production demand.

Description

Intelligent automatic double-side overedger
Technical Field
The utility model relates to a cloth automated processing equipment field especially relates to an automatic two side overedger equipment of intelligence.
Background
At present, all parts of the double-side sewing equipment are independent and move in hundreds of directions. The automatic size adjusting function is omitted, manual adjustment is very complicated, multiple persons are required to work simultaneously, the adjusting period is long, a large amount of manpower, material resources and adjusting time are wasted, the large production capacity is lost, the automation degree of the existing bilateral sewing equipment is low, the productivity cannot be effectively improved, and the production requirement is met.
Disclosure of Invention
The utility model discloses the main technical problem who solves provides an automatic two side hemming equipment of intelligence, has realized producing the arbitrary regulation of product specification in accommodation range as required, has reached automation equipment's requirement, does not need artifical loaded down with trivial details going the adjustment, and degree of automation is higher, satisfies the production demand.
In order to solve the technical problem, the utility model discloses a technical scheme be: there is provided an intelligent automatic double-sided overlock machine comprising: a cloth cutting disc cutter, a bidirectional cloth pulling feeder, 2 auxiliary frames, a label cutting, folding and feeding integrated machine, a overedger, an adjusting platform, a synchronous belt conveying motion structure and a tangent line thermal bonding mechanism, a bidirectional cloth spreading feeder is arranged behind the cloth cutting disc cutter, 2 auxiliary frames are respectively arranged on the left side and the right side of the bidirectional cloth spreading feeder in a mirror image manner, each auxiliary frame is provided with 1 label cutting, folding and label feeding integrated machine, 2 overedgers, 2 adjusting platforms, 2 synchronous belt conveying motion structures and 2 tangent line hot bonding mechanisms, each adjusting platform is fixed with 1 synchronous belt conveying motion structure and 1 tangent line hot bonding mechanism, the thread cutting and hot adhering mechanism is far away from the arrangement of a cloth cutting disc cutter, the overedger is arranged on one side of the adjusting platform, and the label cutting, folding and conveying all-in-one machine is arranged close to the arrangement of the cloth cutting disc cutter.
In a preferred embodiment of the present invention, the cloth cutting disc cutter comprises: the cloth feeding frame is transversely arranged at the front end of the cutter frame, the disc cutter mechanism is arranged at the upper end of the cutter frame, and the waste collecting device is arranged at the bottom of the disc cutter mechanism and located inside the cutter frame.
In a preferred embodiment of the present invention, the bidirectional spreading feeder includes: the cloth spreading mechanism and the left and right cloth moving mechanisms are arranged on the upper portion of the table board, the cloth spreading mechanism and the left and right cloth moving mechanisms are of T-shaped structures, the cloth spreading mechanism is arranged in the middle of the upper portion of the main frame in the X-axis direction, the left and right cloth moving mechanisms are arranged on the left and right sides of the cloth spreading mechanism in the Y-axis direction respectively, and the infrared gratings are arranged at the front end and the top end of the upper portion of the main frame respectively and are of right-angle structures.
The utility model discloses a preferred embodiment, label cutting, label folding and label sending all-in-one machine includes main installing support, workstation, mark dish installing support, send label cutting mechanism, label folding mechanism and send mark cylinder mechanism, the workstation establish the upper end at main installing support, mark dish installing support, send label cutting mechanism, label folding mechanism and send mark cylinder mechanism all to set up the upper end at the workstation, the mark dish set up on the workstation and lie in one side top of main installing support through mark dish installing support, label folding mechanism transversely set up the rear end of sending label cutting mechanism, send mark cylinder mechanism set up at the side of label folding mechanism and with send label cutting mechanism to be connected.
In a preferred embodiment of the present invention, 2 of the adjusting platforms, one of the adjusting platforms is fixed, and an automatic size adjusting device is disposed below the other movable adjusting platform, and the automatic size adjusting device adjusts the size using the fixed adjusting platform as a reference point.
In a preferred embodiment of the present invention, the automatic size adjusting device includes: first motor, motor support, shaft coupling, fixed plate, bearing, lead screw, screw nut and connecting block, install the motor support on the first motor, shaft coupling one end and the output shaft of first motor, the other end of shaft coupling passes fixed plate and bearing and screw connection, the cover is equipped with screw nut and connecting block on the lead screw, the connecting block is fixed to be set up at mobilizable regulation platform lower surface.
In a preferred embodiment of the present invention, each of the synchronous belt conveying movement structures includes: the synchronous belt conveying and moving integrated assembly plate comprises a housing, a synchronous belt conveying and moving integrated assembly plate, a connecting fixing plate, a height adjusting seat and a second motor, wherein the connecting fixing plate, the height adjusting seat and the second motor are arranged in the housing, the upper end surface of the connecting fixing plate is fixedly connected with the housing, the lower end surface of the connecting fixing plate is fixedly connected with the height adjusting seat, one side of the connecting fixing plate is fixedly connected with the synchronous belt conveying and moving integrated assembly plate, the second motor is fixedly arranged on the height adjusting seat, the outer side of the housing is provided with a protective housing, one end of the synchronous belt conveying and moving integrated assembly plate is provided with a plurality of single-row guide wheels and a single-row tension wheel, the other end of the synchronous belt conveying and moving integrated assembly plate is provided with a plurality of double-row guide wheels and a double-row tension wheel, the front end of the synchronous belt conveying and moving integrated, the bottom side of the synchronous belt conveying motion integration assembly plate is provided with a plurality of single-row presser feet and a plurality of double-row presser feet from front to back, and the middle part and the rear end of the bottom side of the synchronous belt conveying motion integration assembly plate are respectively provided with a first guide sheet and a second guide sheet.
In a preferred embodiment of the present invention, each of the tangent lines thermally adhering mechanisms comprises: the device comprises a base, wherein two ends of the base are connected with corner braces, a lower sensor mounting seat is arranged between the two corner braces, one side of the lower sensor mounting seat is provided with a dust blowing plate, the dust blowing plate is connected with a regulating valve, the upper end of the base is connected with a mounting seat, the mounting seat is provided with a dust suction seat, the rear end of the dust suction seat is provided with 2 cylindrical suction pipes, a heat insulation table is arranged above the dust suction seat, a heating plate is arranged in the heat insulation table, a heating core is arranged in the heating plate, an upper sensor mounting seat is arranged above the heat insulation table, 2 first cutter cylinders are arranged on the upper sensor mounting seat, a first cutter mounting seat is connected below each first cutter cylinder, a cutter is connected on the first cutter mounting seat, a vertical connecting plate is arranged on one side of the base, and a power supply protection cover shell and an upper cover shell are arranged on the vertical connecting plate, the power supply protection housing is arranged below the upper housing, a ceramic terminal seat is arranged in the power supply protection housing, and the lower sensor mounting seat and the upper sensor mounting seat are respectively provided with 2 correlation inductive switches.
In a preferred embodiment of the present invention, each of the sub-frames is provided with a plurality of optical axes, and the optical axes are provided with an overlock machine and an adjusting platform.
In a preferred embodiment of the present invention, the 2 overedgers, the 2 adjusting platforms, the 2 synchronous belt conveying mechanisms and the 2 tangent lines thermal adhering mechanisms are equally divided into mirror images respectively disposed at the front and rear ends of the sub-frame.
The utility model has the advantages that: the utility model discloses an automatic two side overedger of intelligence, have following advantage: 1. the production line realizes the random adjustment of the specification of the product in the adjustment range according to the requirement, meets the requirement of automatic equipment, does not need manual complicated adjustment, has higher automation degree, and meets the production requirement;
1. the cloth cutting disc cutter ensures the accuracy of the cloth cutting position, ensures the quality of cloth, greatly improves the movement speed, can extend the cutting length according to requirements, effectively improves the working efficiency, can collect waste materials, prevents the waste materials from blocking other parts so as to influence the use of mechanical equipment, prevents dust, is convenient to clean the waste materials, ensures the tidiness of the use environment, and has the advantages of simple debugging and the like;
2. the bidirectional cloth spreading feeder is suitable for different kinds of cloth, realizes automatic production of cloth spreading feeding operation, can perform cloth spreading and cloth moving feeding in both the X axis and the Y axis, is accurate in size of the cloth spreading and cloth moving feeding, is large in clamping force of a cloth spreading clamping jaw, is large in contact surface of an upper cloth spreading clamping jaw and a lower cloth spreading clamping jaw, can be firmly clamped even if the cloth is very thin, has the advantages of being capable of correcting deviation and preventing collision, greatly improving safety performance, not prone to damage to mechanical parts and the like, and also has the function of preventing the cloth from warping;
3. the label cutting, folding and conveying integrated machine is compact in overall structure, can automatically finish cutting, folding and conveying of labels, is smooth in action, greatly improves the efficiency of the whole production process, finally achieves the production effect of high production efficiency and low labor intensity, and meets the production and processing requirements;
4. two cutters on the tangent hot-sticking mechanism are separated to separately cut the thread and simultaneously fuse the thread, the length of the thread end can be controlled to be about 1mm by accurately controlling the tangent through a correlation laser switch without cutting the product, the product quality and the yield are improved, and the production cost is greatly reduced;
6. the position that the anterior segment list hold-in range structure of the integrated assembly panel of hold-in range transport motion can be more close to the hemming motion has been solved and has been carried and the out-of-step problem of hemming process in-process cooperation, the contact surface that two hold-in range structures can increase hold-in range and surface fabric is used to the back end, make the surface fabric can not produce deformation at the removal in-process, various problem factors such as distortion, the hold-in range transport motion integrated assembly panel that combines to add the elongated sends the material again and goes out after the tangent line process is accomplished, the back tangent line precision has been guaranteed, the quality inspection, automatic back production process accuracy such as fold cloth.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained without inventive work, wherein:
fig. 1 is a schematic structural diagram of a preferred embodiment of the intelligent automatic double-side overedger of the present invention;
FIG. 2 is a schematic diagram of a preferred embodiment of the fabric cutting circular knife machine of FIG. 1;
FIG. 3 is another angular configuration of FIG. 2;
FIG. 4 is an assembled view of FIG. 3;
FIG. 5 is a schematic diagram of a preferred embodiment of the bi-directional tenter feeding machine of FIG. 1;
FIG. 6 is a schematic structural view of the cloth spreading mechanism in FIG. 5;
FIG. 7 is a schematic structural view of the left-right cloth moving mechanism in FIG. 5;
FIG. 8 is a schematic structural diagram of a preferred embodiment of the label cutting, folding and delivering machine of FIG. 1;
FIG. 9 is a schematic view of the label feeding and cutting mechanism of FIG. 8;
FIG. 10 is a schematic view of the structure of FIG. 9 from another angle;
FIG. 11 is a schematic view of the signature mechanism of FIG. 8;
FIG. 12 is a schematic mechanical view of the index cylinder mechanism of FIG. 8;
FIG. 13 is a schematic view of the adjustment stage and optical axis of FIG. 1;
FIG. 14 is a schematic view of the adjustment platform of FIG. 1 mounted on the sub-frame;
FIG. 15 is a schematic view of the automatic size adjustment apparatus of FIG. 14;
FIG. 16 is a schematic diagram of the conveying mechanism of the synchronous belt of FIG. 1;
FIG. 17 is a schematic structural view of the synchronous belt conveying motion integrated assembling plate in FIG. 16;
FIG. 18 is an exploded view of the tangential thermal bonding mechanism of FIG. 1;
fig. 19 is a partially enlarged view of fig. 18.
Shown in the figure: 1. a cloth cutting disc cutter machine, 2, a bidirectional cloth pulling feeder, 3, an auxiliary frame, 4, a label cutting, folding and label feeding all-in-one machine, 5, a overedger, 6, an adjusting platform, 7, a synchronous belt conveying motion structure, 701, a housing, 702, a synchronous belt conveying motion integrated assembly plate, 703, a height adjusting seat, 704, a second motor, 705, a connecting and fixing plate, 706, a protective shell, 707, a single-row guide wheel, 708, a double-row guide wheel, 709, a downward pressing cylinder, 710, a front cloth pressing wheel, 711, a single-row tensioning wheel, 712, a double-row wheel, 713, a single-row presser foot, 714, a double-row presser foot, 715, a first guide sheet, 716, a second guide sheet, 8, a tangent thermal bonding mechanism, 801, a base, 802, a corner brace, 803, a lower sensor mounting seat, 804, a dust blowing plate, 805, an adjusting valve, 806, a mounting seat, 807, a dust suction seat, 808, a cylindrical air suction pipe, 809 and a separation table, 810. heating plate 811, heating core 812, upper sensor mounting seat 813, first cutter cylinder 814, first cutter mounting seat 815, cutter 816, vertical connecting plate 817, power protection housing 818, upper housing 819, ceramic terminal seat 820, correlation laser switch 9, optical axis 10, automatic size adjusting device 101, first motor 102, motor support 103, coupling 104, fixing plate 105, bearing 106, lead screw 107, lead screw nut 108, connecting block 11, cutter frame 12, cloth feeding frame 121, cloth guide frame support 122, cloth guide shaft 123, cloth blocking wheel 124, door frame 13, disc cutter mechanism 1301, cutter fixing bottom plate 1302, fixing left side plate 1303, fixing right side plate 1304, bed knife 1305, cloth supporting plate 1306, cloth pressing plate 1307, cloth supporting cylinder 1308, first cloth pressing cylinder 1309, cutter, Air cylinder connecting seat, 1310, guide rail fixing plate, 1311, guide rail, 1312, guide rail sliding block, 1313, synchronous power wheel, 1314, synchronous guide wheel, 1315, synchronous belt, 1316, power motor, 1317, motor seat, 1318, first rotary air cylinder, 1319, first air cylinder fixing plate, 1320, rotary motor, 1321, circular cutter, 14, waste collecting device, 141, waste trough, 142, waste box, 15, rack door, 16, adjusting supporting foot, 21, main rack, 22, infrared grating, 23, table board, 24, spreading mechanism, 2401, spreading guide rail, 2402, first guide chain, 2403, spreading sensor, 2404, third motor, 2405, spreading synchronous belt, 2406, spreading clamping jaw mounting seat, 2407, swing arm seat, 2408, 2409, cloth clamping air cylinder, 2410, lower main spreading clamping jaw, 2411, upper main spreading jaw, 2412, upper short moving spreading clamping jaw 2413, mounting plate, and connecting frame, 2415. a deviation-correcting sensor, 2416, a collision-proof probe, 25, a left-right cloth-moving mechanism, 2501, a cloth-moving guide rail, 2502, a fourth motor, 2503, a second guide chain, 2504, a cloth-moving sensor, 2505, a left-right cloth-moving synchronous belt, 2506, a second cloth-pressing cylinder, 2507, a width-adjusting bracket, 2508, a first adjusting plate, 2509, a rubber pressure plate, 2510, a guide chain mounting plate, 2511, a second adjusting plate, 2512, a rake angle air-blowing pipeline, 26, an adjusting shaft, 27, an adjusting slider, 28, a lock catch, 29, a first position-positioning plate, 210, a second position-positioning plate, 41, a main mounting bracket, 42, a workbench, 43, a scale plate, 44, a scale plate mounting bracket, 45, a cutting-feeding mechanism, 4501, a scale-feeding base, 4502, a scale-passing optical axis, 4503, a scale-feeding adjusting block, 4504, a sensor mounting base, 4505, a reed, 4506, a reed pressure plate base, 4507, a scale adjusting base, a fixed base, 450, 4509. a second cutter mounting seat, 4510, a color mark sensor, 4511, a five-claw label detection plate, 4512, a driving wheel, 4513, a driven wheel, 4514, a belt, 4515, a mark post, 4516, a mark adjusting wheel, 4517, a driven marking wheel, 4518, a driving mark feeding wheel, 4519, a compression spring, 4520, an adjusting bearing, 4521, a moving cutter, 4522, a static cutter, 4523, a second cutter cylinder, 4524, a mark clamping plate, 46, a mark folding mechanism, 4601, a mark bottom plate, 4602, a second cylinder fixing plate, 4603, a rotating fixing seat, 4604, a rotating seat, 4605, an upper clamp mark shaft, 4606, a lower clamp mark shaft, 4607, a marking cylinder, 4608, a top block, 4609, a cylinder adjusting plate, 4610, a marking cylinder, 4611, an adjusting seat, 4612, an over mark plate, 4613, a pipe joint, 4614, a second rotating cylinder, 4615, a screw, a pin, a spring 16, a pin roll 4617, a spring, a gas cylinder, a marking cylinder, a driving cylinder, 4701, a driving cylinder, a driving mechanism, 4703. lifting cylinder 4704, stretching cylinder 4705, label feeding cylinder 4706, label clamping cylinder 4707, label upper clamp plate 4708, label lower clamp plate 4709, fixing screw 48 and label.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely below, and it should be apparent that the described embodiments are only some embodiments of the present invention, but not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.
Referring to fig. 1-19, an embodiment of the present invention includes:
as shown in fig. 1, an intelligent automatic double-side overedger comprises: the cloth cutting disc cutter 1, the bidirectional cloth pulling feeder 2, the 2 auxiliary frames 3, the label cutting, folding and label feeding all-in-one machines 4, the overedger 5, the adjusting platform 6, the synchronous belt conveying and moving structure 7 and the tangent line thermal bonding mechanism 8, the bidirectional cloth pulling feeder 2 is arranged behind the cloth cutting disc cutter 1, the 2 auxiliary frames 3 are respectively arranged on the left side and the right side of the bidirectional cloth pulling feeder 2 in a mirror image manner, each auxiliary frame 3 is provided with the 1 label cutting, folding and label feeding all-in-one machine 4, the 2 overedger 5, the 2 adjusting platform 6, the 2 synchronous belt conveying and moving structure 7 and the 2 tangent line thermal bonding mechanisms 8, each adjusting platform 6 is fixedly provided with the 1 synchronous belt conveying and moving structure 7 and the 1 tangent line thermal bonding mechanism 8, the tangent line thermal bonding mechanism 8 is far away from the arrangement of the cloth cutting disc cutter 1, the overedger 5 is arranged on one side of the adjusting platform 6, the label cutting, folding and conveying all-in-one machine 4 is arranged close to the cloth cutting disc cutter 1. Each auxiliary frame 3 is provided with 4 optical axes 9, and the optical axes 9 are provided with overedgers 5 and adjusting platforms 6. 2 hemming machine 5, 2 adjust 6, 2 hold-in range transport motion structures 7 and 2 tangent lines heat and glue mechanism 8 and equally divide and do not be the mirror image setting both ends around auxiliary frame 3.
As shown in fig. 2 to 4, the cloth cutting circular cutter 1 includes: the cloth feeding frame 12 is transversely arranged at the front end of the cutter frame 11, the disc cutter mechanism 13 is arranged at the upper end of the cutter frame 11, and the waste collecting device 14 is arranged at the bottom of the disc cutter mechanism 13 and located inside the cutter frame 11.
In the above, the cutter frame 11 adopts a stepped structure with a high front part and a low rear part, so that the cloth feeding frame 12 and the disc cutter mechanism 13 are conveniently and fixedly installed. In this embodiment, the front end of the cutter frame 11 is provided with a frame door 15, so that the maintenance or debugging is convenient to open, and the waste material is convenient to clean. The bottom of the cutter frame 11 is also provided with an adjusting supporting leg 16, so that the use is convenient, and the height can be adjusted as required.
The cloth feeding frame 12 adopts a double-layer structure, and can simultaneously feed two pieces of cloth and simultaneously produce the cloth. The cloth feeding frame 12 comprises a door frame 124, cloth guiding frame supports 121, cloth guiding shafts 122 and cloth blocking wheels 123, the cloth guiding frame supports 121 are symmetrically arranged on the left side and the right side of the upper end of the door frame 124 respectively, the cloth guiding shafts 122 are arranged between the cloth guiding frame supports 121 in double rows and multiple columns respectively, the cloth blocking wheels 123 are sleeved on the cloth guiding shafts 122 respectively, the tension of cloth is increased when the cloth is fed, the cloth is prevented from deforming, and the anti-wrinkle effect is achieved.
The disc cutter mechanism 13 comprises a cutter fixing bottom plate 1301, a fixed left side plate 1302, a fixed right side plate 1303, a bottom cutter 1304, a cloth supporting plate 1305, a cloth pressing plate 1306, a cloth supporting cylinder 1307, a first cloth pressing cylinder 1308, a cylinder connecting seat 1309, a guide rail fixing plate 1310, a guide rail 1311, a guide rail sliding block 1312, a synchronous power wheel 1313, a synchronous guide wheel 1314, a synchronous belt 1315, a power motor 1316, a motor seat 1317, a first rotating cylinder 1318, a first cylinder fixing plate 1319, a rotating motor 1320 and a circular cutter 1321, the fixed left side plate 1308 and the fixed right side plate 1303 are respectively fixed on two side edges of the upper end of the cutter fixing bottom plate 1301, the cloth supporting plate 1305 is arranged above the cutter fixing bottom plate 1301 through the cloth supporting cylinder 1307, the bottom cutter 1304 is arranged on the bottom cutter fixing bottom plate 1301 and is positioned behind the cloth supporting plate 1305, the cloth pressing plate 1306 is arranged above the cloth supporting plate 1305, the first cloth pressing cylinder 1302 is respectively fixed on the fixed left side plate 1303 and the fixed right side plate 1309 through the cylinder connecting seat 1309 The guide rail fixing plate 1310 is transversely arranged between the upper parts of the fixed left side plate 1302 and the fixed right side plate 1303, the guide rail 1311 is arranged at the lower end of the guide rail fixing plate 1310, the power motor 1316 is arranged at the upper end of the guide rail fixing plate 1310 through a motor base 1317 and is connected with a synchronous power wheel 1313, the synchronous guide wheel 1314 is arranged at the rear side of the fixed right side plate 1303 and is arranged at the side of the guide rail 1311, the synchronous guide wheels 1314 are respectively arranged at the rear side of the fixed left side plate 1302, the synchronous belt 1315 is wound around and is arranged on the synchronous power wheel 1313 and the synchronous guide wheel 314, the first air cylinder fixing plate 1319 moves left and right in the length range of the guide rail 1311 through a guide rail slider 1312, and the rotary motor 1320 is arranged at the lower end of the first air cylinder fixing plate 1319 through a first rotary air cylinder 1318, the circular cutter 1321 is mounted on the rotary motor 1320 and cooperates with the edge of the bed knife 1304.
In the above, the number of the synchronous power wheels 1313 is one, and the number of the synchronous guide wheels 1314 is three; wherein, the positions of the two synchronous guide wheels 1314 are respectively and symmetrically arranged with the synchronous power wheel 1313 and the other synchronous guide wheel 1314.
The waste collecting device 4 comprises a waste groove 141 and a waste box 142, the waste groove 141 is obliquely arranged at the bottom of the cutter fixing bottom plate 1301, and the waste box 142 is horizontally placed in the cutter frame 11 and horizontally connected with the waste groove 141. Cutter PMKD 1301 is hollow out construction, and waste material groove 141 sets up and is used for collecting the cloth and drop to the waste material of cutter PMKD 1301 through disc cutter mechanism 13 in the bottom of cutter PMKD 1301, thereby prevents that the waste material from blocking other parts and influencing mechanical equipment's use, prevents the dust, takes out waste material box 142 after opening frame door 15, conveniently clears up the waste material.
As shown in fig. 5, the bidirectional rag feeder 2 includes: the cloth pulling mechanism 24 and the left-right cloth moving mechanism 25 are of a T-shaped structure, the cloth pulling mechanism 24 is arranged in the middle of the upper portion of the main frame 21 in the X-axis direction, the left-right cloth moving mechanism 25 is arranged on the left side and the right side of the cloth pulling mechanism 24 in the Y-axis direction, and the infrared gratings 22 are arranged at the front end and the top end of the upper portion of the main frame 21 respectively and are of a right-angle structure.
Infrared ray grating 22: the function is to prevent the handle and other human body parts or tools from extending into or falling into the production mechanism in operation when workers are in production operation, and personal injury and tool damage to the workers are caused. Once the infrared grating is triggered, the production equipment stops all production movements urgently.
In this embodiment, the disc cutter mechanism 13 may be integrally disposed in the main frame 21. When any misoperation such as operating handle or tool is put into the position of the cutter mechanism, the operation can be stopped immediately after the infrared grating 22 senses automatically, so that danger is prevented, and the safety performance is high.
In the above, the cloth pulling mechanism 24 and the left and right cloth moving mechanism 25 both adopt a "T" shaped structure. The number of the left and right cloth moving mechanisms 25 is 2, and the left and right cloth moving mechanisms are respectively arranged on the left and right sides of the cloth pulling mechanism 24 in a mirror image manner.
Furthermore, the two side edges of the table top 23 are respectively provided with a first position positioning plate 29 and a second position positioning plate 210 which extend outwards, the first position positioning plate 29 and the second position positioning plate 210 respectively adopt mirror symmetry structures, the second position positioning plate 210 and the table top 23 adopt an integrally formed structure, the size can be adjusted through the first position positioning plate 29 and the second position positioning plate 210, and the table top is used for matching and positioning of an overlock machine and other sewing equipment.
As shown in fig. 6, the spreading mechanism 24 includes a spreading guide track 2401, a first guide chain 2402, a spreading sensor 2403, a third motor 2404, a spreading synchronous belt 2405, a spreading clamping jaw mounting seat 2406, a swing arm seat 2407, a connecting arm 2408, a cloth clamping cylinder 2409, a lower main spreading clamping jaw 2410, an upper main spreading clamping jaw 2411, an upper short-moving spreading clamping jaw 2412 and a deviation-correcting sensor 2415. The first guide chain 2402 is arranged on one side edge of the front end of the granny rag guide track 2401 in parallel through a mounting plate 2413, the third motor 2404 is arranged on the other side edge of the rear end of the granny rag guide track 2401, the granny rag sensors 2403 are respectively arranged on the front end and the rear end of the side edge of the granny rag guide track 2401 and are positioned at the front end of the third motor 2404, the deviation-correcting sensor 2415 is arranged in the middle of the side edge of the granny rag guide track 2401 and is positioned between the two granny rag sensors 2403, the granny rag synchronous belt 2405 is movably arranged at the front end of the granny rag guide track 2401, the lower ends of the granny rag guide track 2401 and the first guide chain 2402 are connected at the middle of the rear end of the granny rag claw mounting seat 406 through a connecting frame 2414, the lower main granny rag claw 2410 is arranged at the front end of the granny rag claw mounting seat 2406, the swing arm seats 2407 are, the cloth clamping cylinders 2409 are respectively arranged at the rear ends of the cloth pulling clamping jaw mounting seats 2406 and are connected with the connecting arms 2408.
In the above, the length of the lower main spreading clamping jaw 2410 is greater than that of the upper main spreading clamping jaw 2411, and the length of the upper main spreading clamping jaw 2411 is greater than that of the upper short movable spreading clamping jaw 2412. The upper main spreading clamping jaw 2411 and the upper short moving spreading clamping jaw 2412 are arranged above the lower main spreading clamping jaw 2410, and the upper short moving spreading clamping jaw 2412 is respectively positioned on two side edges of the upper main spreading clamping jaw 2411.
The spreading sensor 2403 and the deviation correction sensor 2415 are used for accurately positioning the position of the cloth to prevent the position deviation of the cloth, the cloth is pulled to the required size and position by the cooperation of the downward pressing of the upper main spreading clamping jaw 2411 and the upper short movable spreading clamping jaw 2412 and the lower main spreading clamping jaw 2410, and the cloth is clamped firmly even if the thin cloth is very thin by adopting a lower clamping type clamping structure during spreading.
In this embodiment, the cloth spreading mechanism 24 further includes an anti-collision probe 2416, the anti-collision probe 2416 is arranged on the connecting frame 2414, when the anti-collision probe 2416 is impacted out of control during operation, the equipment stops operating, the safety performance is high, mechanical parts are not easily damaged, and the steps of maintenance are reduced.
As shown in fig. 7, the left-right cloth moving mechanism 25 includes a cloth moving guide rail 2501, a fourth motor 2502, a second guide chain 2503, a cloth moving sensor 2504, a left-right cloth moving timing belt 2505, a second cloth pressing cylinder 2506, a width adjusting bracket 2507, a first adjusting plate 2508 and a 2-rubber press plate 2509. The second guide chain 2503 is horizontally arranged on one side of the cloth moving guide rail 2501 through a guide chain mounting plate 2510, the fourth motor 2502 is connected to the cloth moving guide 2501 and is located behind the cloth moving guide 2501, the cloth moving sensors 2504 are respectively arranged at the other side of the cloth moving guide rail 2501, the left and right cloth-moving synchronous belt 2505 is movably arranged at the front end of the cloth-moving guide rail 2501, the second guide chain 2503 is connected to the width adjustment bracket 2507 via a guide chain mounting plate 2510, the second cloth pressing cylinder 2506 is arranged at the lower end of the guide chain mounting plate 2510 and connected with the second guide chain 2503, the first adjusting plates 2508 are respectively horizontally arranged on both sides of the width adjusting bracket 2507, the second adjusting plates 2511 are respectively horizontally arranged at the middle positions of the rear ends of the width adjusting brackets 2507 and are vertical to the first adjusting plates 2508, the rubber pressing plates 2509 are respectively disposed at the bottom of the first adjusting plate 2508 and the bottom of the width adjusting bracket 2507.
Wherein, rubber pressure plate 2509 on still be provided with the pressure plate spring (not shown), rubber pressure plate 2509 carry out up-and-down motion through the pressure plate spring. The number of the rubber pressing plates 2509 is increased or decreased according to different sizes and the production requirements of fabrics. In this embodiment, the number of the rubber pressing plates 2509 is 6, 2 the rubber pressing plates 2509 are respectively arranged at the bottom of the free end of the first adjusting plate 2508, the height of the rubber pressing plates 2509 can be adjusted freely according to the thickness of the cloth, and in addition, the rubber pressing plates 2509 are respectively arranged at the bottom of the middle position of the width adjusting bracket 2507, and the height of the rubber pressing plates 2509 can be adjusted freely according to the thickness of the cloth.
The rubber pressing plate 2509 is made of rubber materials and plays a role of skid resistance on cloth; the first adjusting plate 2508 can be adjusted to any size, and the size can be adjusted according to the size of the cloth, wherein the size is 650mm at most and 150mm at least.
Further, both ends and middle optional position about width regulation support 2507 all be provided with the rake angle pipeline 2512 of blowing, blow the corner of cloth through rake angle pipeline 2512 and blow flat, prevent the rake phenomenon of cloth.
The cloth is pulled down by the cloth pulling mechanism 23 to the required size and position, then the cloth is cut off by the cloth cutting disc cutter 1, and then the position of the cut-off cloth is corrected by the left and right cloth moving mechanism 25 and is moved to the specified position by the first adjusting plate 2508 and the rubber pressure plate 2509, and meanwhile, the cloth edge warping prevention function is achieved.
In this embodiment, the main frame 21 is further provided with an adjusting shaft 26, an adjusting slider 27 and a lock catch 28, the adjusting shaft 26 is connected with the adjusting slider 27 and is located above the left-right cloth moving mechanism 25, and the lock catch 28 is arranged on the adjusting shaft 26 and is located at the front end of the adjusting slider 27.
Each group of the left and right cloth moving mechanisms 25 is fixed on two parallel adjusting shafts 26 by connecting two adjusting sliding blocks 27, and is fixed together with a connecting plate of the adjusting sliding blocks 27 by lock catches 28 arranged on the adjusting shafts 26, and when the cloth size is adjusted, only the two lock catches 28 are required to be unscrewed, and the cloth is adjusted to a required position to be locked, so that the size adjustment is completed.
In the above, each cylinder is provided with a magnetic switch (not shown), the magnetic switch is used for knowing through magnetic induction of the magnetic switch after the operation of the next cylinder is completed, and feeding back a system command to complete the next step, if the magnetic switch is not sensed, a fault may occur, the operation of the next step is stopped, and the fault is prompted on a display screen to inform the process. Maintenance personnel do not need to search fault points disorderly, and maintenance time is prolonged.
As shown in fig. 8, the label cutting, folding and delivering all-in-one machine 4 includes: main installing support 41, workstation 42, mark dish 43, mark dish installing support 44, send label cutting mechanism 45, book mark mechanism 46 and send mark cylinder mechanism 47, workstation 42 establish the upper end at main installing support 41, mark dish installing support 44, send label cutting mechanism 45, book mark mechanism 46 and send mark cylinder mechanism 47 all to set up the upper end at workstation 42, mark dish 43 set up on workstation 42 and lie in one side top of main installing support 41 through mark dish installing support 44, book mark mechanism 46 transversely set up the rear end of sending label cutting mechanism 45, send mark cylinder mechanism 47 set up the side of book mark mechanism 46 and with send label cutting mechanism 45 to be connected.
As shown in fig. 9, the label feeding and cutting mechanism 45 includes a label feeding base 4501, a label passing axis 4502, a label feeding adjustment block 4503, a sensor mounting base 4504, a reed press plate 4505, a reed press plate base 4506, a label adjusting base 4507, a label feeding wheel fixing base 4508, a second cutter mounting base 4509, a color mark sensor 4510, a five-claw label detection plate 4511, a driving wheel 4512, a driven wheel 4513 and a belt 4514, the label passing axis 4502 is disposed at the front end of the label feeding base 4501 through the label feeding adjustment block 4503, the sensor mounting base 4504 is disposed at the front end of the label feeding base 4501 and above the label passing axis 4502, the reed press plate 4505 is movably disposed at the upper end of the sensor mounting base 4504 through the reed press plate base 4506, the label adjusting base 4507, the label feeding wheel fixing base 4508 and the second cutter mounting base 4509 are disposed on the label feeding base 4501 and behind the sensor mounting base 4504 through the reed press plate 4511, and the five-claw sensor mounting base 45011 is disposed at the upper end of the sensor mounting base 4504 through the reed press plate 4511 and the sensor mounting base 4504 A motor (not shown) is further disposed inside the label feeding base 4501 behind the plate 4505, the driving wheel 4512 and the driven wheel 4513 are respectively connected with the motor, and the belt 4514 is obliquely wound between the driving wheel 4512 and the driven wheel 4513.
As shown in fig. 10, the label feeding and cutting mechanism 45 further includes a label passing bar 4515, a label adjusting wheel 4516, a driven label pressing wheel 4517, a driving label feeding wheel 4518, a pressure spring 4519, an adjusting bearing 4520, a movable cutting knife 4521, a static cutting knife 4522, a second cutting knife cylinder 4523 and a label clamping plate 4524, the label passing bar 4515 is transversely disposed between the lower portions of the label adjusting bases 4507, the label adjusting wheels 4516 are respectively disposed at the middle positions of the label passing bars 4515, the label feeding wheel fixing bases 4508 are respectively disposed at the upper rear ends of the label adjusting bases 4507, the pressure spring 4519 is disposed at the bottom of the label feeding wheel fixing bases 4508 and is in contact with the adjusting bearing 4520, the adjusting bearings 4520 are respectively disposed at the two ends of the driven label pressing wheel 4517, the driving label feeding wheel 4518 is disposed below the dynamic label pressing wheel 4517, the movable cutting knife 4521 is disposed at the upper portion of the second cutting knife mounting base 4509, the static cutting knife 4522 is fixed at the lower portion of the label pressing wheel mounting base 4509, the second cutter cylinder 4523 is arranged at the bottom of the second cutter mounting seat 4509 and is connected with the movable cutter 4521, and the label clamping plate 4524 is arranged behind the movable cutter 4521 and above the static cutter 4522.
In this embodiment, the surfaces of the driven marking wheel 4517 and the driving marking wheel 4518 both adopt an encapsulated slotted structure, so as to prevent the label from being damaged by passing through the label, and the ribbon label can also be applied without hooking filaments.
As shown in fig. 11, the signature mechanism 46 includes a signature bottom plate 4601, a second cylinder fixing plate 4602, a rotating fixing base 4603, a rotating base 4604, an upper signature clamping shaft 4605, a lower signature clamping shaft 4606, a signature cylinder 4607, a top block 4608, a cylinder adjusting plate 4609, a signature cylinder 4610, an adjusting base 4611, a cursor passing plate 4612, a pipe joint 4613 and a second rotating cylinder 4614, the second cylinder fixing plate 4602 and the rotating fixing base 4603 are respectively vertically arranged at two side edges of the signature bottom plate 4601, the rotating bases 4604 are respectively symmetrically arranged at the upper parts of the second cylinder fixing plate 4602 and the rotating fixing base 4603, the upper signature clamping shaft 4605 and the lower signature clamping shaft 4606 are arranged in parallel between the two rotating bases 4604, the signature cylinders 4607 are respectively arranged at the inner side edge of the second cylinder fixing plate 4602 and below the lower signature clamping shaft 4606, the top blocks 4608 are respectively connected to the upper side edge of the signature cylinder fixing plate 4607, and the signature cylinder adjusting plate 4609 is arranged at one side edge of the signature cylinder fixing plate 4601, the index plate 4612 is disposed on the upper end of the index cylinder 4610 through an adjusting seat 4611, the second rotating cylinder 4614 is disposed on the outer side edge of the second cylinder fixing plate 4602, and a plurality of pipe joints 4613 are respectively connected to the index cylinder 4610 and the second rotating cylinder 4614. Wherein, the number of the transition plates 4612 is 2.
In the above, the upper clipping axis 4605 is located above the lower clipping axis 4606. In this embodiment, two ends of the upper clipping mark shaft 4605 and the lower clipping mark shaft 4605 are connected through a pin 4616, and a spring 4617 is further sleeved on the pin 4616. Screws 4615 are further arranged between the upper index clamping shaft 4605 and the lower index clamping shaft 4606, and the screws 4615 are respectively arranged at two ends of the upper index clamping shaft 4605 and the lower index clamping shaft 4606 in a staggered manner and are located right above the index pressing cylinder 4607.
As shown in fig. 12, the label feeding cylinder mechanism 7 comprises a cylinder mounting seat 4701, a label feeding driving cylinder 4702, a lifting cylinder 4703, a stretching cylinder 4704, a label feeding cylinder 4705, a label clamping cylinder 4706, a trademark upper clamping plate 4707 and a trademark lower clamping plate 4708, the cylinder mounting seat 4701 is fixedly arranged with the workbench 42 through a fixing screw 4709, the label feeding driving cylinder 4702 is arranged on one side of the cylinder mounting seat 4701, the lifting cylinder 4703 is vertically arranged on the upper end of the cylinder mounting seat 4701, the stretching cylinder 4704 is transversely arranged at the front end of the lifting cylinder 4703 and is positioned above the label feeding driving cylinder 4702, the label feeding cylinder 4705 is arranged at the rear part of the side edge of the stretching cylinder 4704 through a cylinder connecting plate 4710, the label clamping cylinder 4706 is arranged at the front end of the label feeding driving cylinder 4702 and is positioned at the side edge of the label feeding cylinder 4705, the trademark upper clamping plate 4707 and the trademark lower clamping plate 4708 are respectively connected with the trademark clamping cylinder 4706.
Wherein the upper brand clamp plate 4707 and the lower brand clamp plate 4708 are positioned above the label passing plate 4612 in the label folding mechanism 46 and are used in cooperation for clamping the label 48.
As shown in fig. 13, one of the 2 adjusting platforms 6 is fixed (in fig. 13, the adjusting platform 1 near the inner side is a fixed adjusting platform), an automatic size adjusting device 10 is arranged below the other movable adjusting platform 6, and the automatic size adjusting device 10 adjusts the size with the fixed adjusting platform 6 as a reference point. The automatic size adjusting device 10 is electrically connected to a controller (not shown), and the size can be adjusted by directly inputting a desired size on a setting panel of the controller. 2 adjust 6 belows of platform and be provided with 2 optical axes 9, 2 adjust 6 relative settings of platform, mobilizable regulation platform 6 moves on 2 optical axes 9.
As shown in fig. 14, 2 optical axes 9 are fixedly arranged on the sub-frame 3, another 2 optical axes 9 are fixedly arranged on the sub-frame 3, and 2 corresponding overedgers 5 are arranged on the other 2 optical axes 9 in a matching manner (only one overedger 5 and one adjusting platform 6 are shown in fig. 14).
As shown in fig. 15, the automatic size adjustment apparatus 10 includes: first motor 101, motor support 102, shaft coupling 103, fixed plate 104, bearing 105, lead screw 106, screw nut 107 and connecting block 108, install motor support 102 on the first motor 101, shaft coupling 103 one end is connected with the output shaft of first motor 101, the other end of shaft coupling 103 passes fixed plate 104 and bearing 105 and is connected with screw 106, the cover is equipped with screw nut 107 and connecting block 108 on the lead screw 106, connecting block 108 is fixed to be set up at mobilizable regulation platform 6 lower surface. The first motor 101 is fixed on the sub-frame 3, and the screw 106 drives the movable adjusting platform 6 to move on 2 optical axes 4 through the transmission of the first motor 101.
As shown in fig. 16 to 17, each of the timing belt conveying moving structures 7 includes: the synchronous belt conveying motion integrated assembly plate comprises a housing 701, a synchronous belt conveying motion integrated assembly plate 702, a connecting fixing plate 705, a height adjusting seat 703 and a second motor 704, wherein the connecting fixing plate 705, the height adjusting seat 703 and the second motor 704 are arranged in the housing 701, the upper end surface of the connecting fixing plate 705 is fixedly connected with the housing 701, the lower end surface of the connecting fixing plate 705 is fixedly connected with the height adjusting seat 703, one side of the connecting fixing plate 705 is fixedly connected with the synchronous belt conveying motion integrated assembly plate 702, the second motor 704 is fixedly arranged on the height adjusting seat 703, a protective shell 706 is arranged on the outer side of the housing 701, one end of the synchronous belt conveying motion integrated assembly plate 702 is provided with a plurality of single-row guide wheels 707 and a single-row tension wheel 711, the other end of the synchronous belt conveying motion integrated assembly plate 702 is provided with a plurality of double-row guide wheels 708 and a double-row tension wheel 712, and the front end of the, a front cloth pressing wheel 710 is arranged below the lower pressing cylinder 709, a plurality of single-row pressing feet 713 and a plurality of double-row pressing feet 714 are respectively installed on the bottom side of the synchronous belt conveying movement integration assembling plate 702 from front to back, and a first guide vane 715 and a second guide vane 716 are respectively arranged at the middle part and the rear end of the bottom side of the synchronous belt conveying movement integration assembling plate 702.
As shown in fig. 18-19, each of the tangential thermal bonding mechanisms 8 comprises: the device comprises a base 801, corner supports 802 are connected to two ends of the base 801, a lower sensor mounting seat 803 is arranged between the two corner supports 802, a dust blowing plate 804 is arranged on one side of the lower sensor mounting seat 803, an adjusting valve 805 is connected to the dust blowing plate 804, a mounting seat 806 is connected to the upper end of the base 801, a dust suction seat 807 is arranged on the mounting seat 806, 2 cylindrical suction pipes 808 are arranged at the rear end of the dust suction seat 807, a temperature insulating table 809 is arranged above the dust suction seat 807, a heating plate 810 is arranged in the temperature insulating table 809, a heating core 811 is arranged in the heating plate 810, an upper sensor mounting seat 812 is arranged above the temperature insulating table 809, 2 first cutter cylinders 813 are arranged on the upper sensor mounting seat 812, a first cutter mounting seat 814 is connected below each first cutter cylinder 813, and a cutter 815 is connected to the first cutter mounting seat 814, the mouth of the cutter 815 is made into an arc shape with a certain angle, so that the thread end can be better ironed, a vertical connecting plate 816 is installed on one side of the base 801, a power supply protection housing 817 and an upper housing 818 are installed on the vertical connecting plate 816, the power supply protection housing 817 is arranged below the upper housing 818, a ceramic terminal seat 819 is arranged in the power supply protection housing 817, and 2 opposite laser switches 820 are respectively arranged on the lower sensor mounting seat 803 and the upper sensor mounting seat 812.
The working principle is as follows: in specific implementation, after the cloth is pulled by the cloth pulling mechanism 24, the cloth is pulled to the required size and position, then the cloth is cut by the cloth cutting disc cutter 1, when the cloth is cut, the cloth enters between the cloth supporting plate 1305 and the cloth pressing plate 1306 of the disc cutter mechanism 13 through the cloth feeding frame 12, firstly, the cloth feeding frame 12 adjusts and controls the width position and the tension of the cloth, then the cloth pressing plate 1306 presses the cloth above the cloth supporting plate 1305, the position reached by the magnetic switch induction on the cloth supporting cylinder 1307 and the cloth pressing cylinder 1308 is sensed, after the required size and the position of the cloth are pulled down, the cloth supporting plate 1305 and the cloth pressing plate 1306 retract together, the first rotary cylinder 1318 controls the circular cutter 1321 to move left and right, the cloth is cut by the matching use of the circular cutter 1321 and the bottom cutter 1304, the circular cutter 1321 stops at the other end after the cloth is cut, the next command is waited, the first rotary cylinder 1318 adjusts the angle of the circular cutter 1321, the rotating motor 1320 rotates in the reverse direction, the cloth is cut and then returns to the original point, the two cutting operations are a cycle, and the cut cloth flock automatically falls into the waste material tank 141. Then the position of the cut cloth is corrected by the left and right cloth moving mechanism 25 and is moved to the position of the label cutting, folding and label sending integrated machine 4 by the adjusting plate 2508 and the rubber press plate 2509, the label sending and cutting mechanism 45 sends a label 48 according to the set length, the label 48 is vertically and crossly wound on a five-claw label detecting plate 4508 and then enters a label pressing wheel 4514 to be sent to a cutting line, when the color mark sensor 4507 senses a cutting line, the movable cutter 4512 moves downwards to cooperate with the static cutter 4513 to cut off the label 48, the cut label 48 is subjected to label clamping action through the upper trademark clamping plate 4707 and the lower trademark clamping plate 4708 of the label feeding cylinder mechanism 47, then, the label is folded by the label folding mechanism 46 according to the set position, and after the label folding is completed, the label is clamped by the upper trademark clamp plate 4707 and the lower trademark clamp plate 4708 of the label feeding cylinder mechanism 47, and the folded label 48 is fed out. The cloth is stitched by a stitching machine 7, then the cloth enters under a front cloth pressing wheel 710, a photoelectric sensor (not shown) at one side of the front cloth pressing wheel 710 senses the cloth, the front cloth pressing wheel 710 is pressed down by a pressing cylinder 709, a second motor 704 drives a synchronous belt to move, the pressure of each single-row presser foot 713 and each double-row presser foot 714 is adjusted according to the thickness of the cloth in the moving process, the balance of the pressure is ensured, a single synchronous belt is arranged at the front section of the synchronous belt conveying movement integrated assembly plate 702, double synchronous belts are arranged at the rear section of the synchronous belt conveying movement integrated assembly plate 702, the single synchronous belt structure at the front section can be closer to the position of the stitching movement, the problem of the matching asynchronization in the conveying and stitching processes is solved, the contact surface of the synchronous belts and the cloth can be enlarged by the double synchronous belts at the rear section, so that the cloth, distortion, and the like. After the cloth is stitched by the overedger 7, the cloth is conveyed to the position of the cutter 815 through a synchronous belt, the tangent hot bonding mechanism 8 is provided with 2 cutters 815, 2 first cutter cylinders 813 and 2 correlation laser switches 820, when the cloth passes through the first correlation laser switch 820, the corresponding first cutter 815 is cut downwards through the first cutter cylinder 813, when the cloth passes through the second correlation laser switch 820, the corresponding second cutter 815 is cut downwards through the first cutter cylinder 813, the length of the thread end can be controlled to be about 1mm without cutting the broken product, 2 the cutter 815 can follow the passing speed of the cloth through the first cutter cylinder alone, the phenomenon that the movement time of the cutter cylinder cannot follow the movement speed of the cloth and the product is cut or the thread end is not cut in time in response, the cylindrical suction pipe 808 sucks the thread end cut each time, the thread end is prevented from being piled up to shield the correlation laser switches 820 to cause misjudgment, be provided with in the board 810 that heats core 811, heat the board 810 and carry out the line through the heating core 811 hot bonding, the core 811 temperature that generates heat is controlled by the controller, and it is effectual to keep constant temperature, can not scald bad cloth, uses the energy consumption little, separates on temperature platform 809 can not transmit the temperature to the cloth product also can not transmit base 801.
To sum up, the utility model discloses an automatic two side overseam equipment of intelligence who points out has following advantage:
1. the product specification can be adjusted within the adjusting range according to the requirement, the requirement of automatic equipment is met, and manual complicated adjustment is not needed;
2. the cloth cutting disc cutter ensures the accuracy of the cloth cutting position, ensures the quality of cloth, greatly improves the movement speed, can extend the cutting length according to requirements, effectively improves the working efficiency, can collect waste materials, prevents the waste materials from blocking other parts so as to influence the use of mechanical equipment, prevents dust, is convenient to clean the waste materials, ensures the tidiness of the use environment, and has the advantages of simple debugging and the like;
3. the bidirectional cloth spreading feeder is suitable for different kinds of cloth, realizes automatic production of cloth spreading feeding operation, can perform cloth spreading and cloth moving feeding in both the X axis and the Y axis, is accurate in size of the cloth spreading and cloth moving feeding, is large in clamping force of a cloth spreading clamping jaw, is large in contact surface of an upper cloth spreading clamping jaw and a lower cloth spreading clamping jaw, can be firmly clamped even if the cloth is very thin, has the advantages of being capable of correcting deviation and preventing collision, greatly improving safety performance, not prone to damage to mechanical parts and the like, and also has the function of preventing the cloth from warping;
4. the label cutting, folding and conveying integrated machine is compact in overall structure, can automatically finish cutting, folding and conveying of labels, is smooth in action, greatly improves the efficiency of the whole production process, finally achieves the production effect of high production efficiency and low labor intensity, and meets the production and processing requirements;
5. two cutters on the tangent hot-sticking mechanism are separated to separately cut the thread and simultaneously fuse the thread, the length of the thread end can be controlled to be about 1mm by accurately controlling the tangent through a correlation laser switch without cutting the product, the product quality and the yield are improved, and the production cost is greatly reduced;
6. the position that the anterior segment list hold-in range structure of the integrated assembly panel of hold-in range transport motion can be more close to the hemming motion has been solved and has been carried and the out-of-step problem of hemming process in-process cooperation, the contact surface that two hold-in range structures can increase hold-in range and surface fabric is used to the back end, make the surface fabric can not produce deformation at the removal in-process, various problem factors such as distortion, the hold-in range transport motion integrated assembly panel that combines to add the elongated sends the material again and goes out after the tangent line process is accomplished, the back tangent line precision has been guaranteed, the quality inspection, automatic back production process accuracy such as fold cloth.
The above only is the embodiment of the present invention, not limiting the patent scope of the present invention, all of which utilize the equivalent structure or equivalent flow transformation made by the content of the specification of the present invention, or directly or indirectly applied to other related technical fields, all included in the same way in the patent protection scope of the present invention.

Claims (10)

1. The utility model provides an automatic two side overedger of intelligence which characterized in that includes: a cloth cutting disc cutter, a bidirectional cloth pulling feeder, 2 auxiliary frames, a label cutting, folding and feeding integrated machine, a overedger, an adjusting platform, a synchronous belt conveying motion structure and a tangent line thermal bonding mechanism, a bidirectional cloth spreading feeder is arranged behind the cloth cutting disc cutter, 2 auxiliary frames are respectively arranged on the left side and the right side of the bidirectional cloth spreading feeder in a mirror image manner, each auxiliary frame is provided with 1 label cutting, folding and label feeding integrated machine, 2 overedgers, 2 adjusting platforms, 2 synchronous belt conveying motion structures and 2 tangent line hot bonding mechanisms, each adjusting platform is fixed with 1 synchronous belt conveying motion structure and 1 tangent line hot bonding mechanism, the thread cutting and hot adhering mechanism is far away from the arrangement of a cloth cutting disc cutter, the overedger is arranged on one side of the adjusting platform, and the label cutting, folding and conveying all-in-one machine is arranged close to the arrangement of the cloth cutting disc cutter.
2. The intelligent automatic double-sided overedger apparatus of claim 1, wherein said cloth cutting disc cutter comprises: the cloth feeding frame is transversely arranged at the front end of the cutter frame, the disc cutter mechanism is arranged at the upper end of the cutter frame, and the waste collecting device is arranged at the bottom of the disc cutter mechanism and located inside the cutter frame.
3. The intelligent automatic double-sided overlock machine of claim 1, wherein the bidirectional rag feeder comprises: the cloth spreading mechanism and the left and right cloth moving mechanisms are arranged on the upper portion of the table board, the cloth spreading mechanism and the left and right cloth moving mechanisms are of T-shaped structures, the cloth spreading mechanism is arranged in the middle of the upper portion of the main frame in the X-axis direction, the left and right cloth moving mechanisms are arranged on the left and right sides of the cloth spreading mechanism in the Y-axis direction respectively, and the infrared gratings are arranged at the front end and the top end of the upper portion of the main frame respectively and are of right-angle structures.
4. The intelligent automatic double-side overedger according to claim 1, wherein the label cutting, folding and conveying all-in-one machine comprises a main mounting support, a workbench, a label plate mounting support, a label conveying and cutting mechanism, a label folding mechanism and a label conveying cylinder mechanism, the workbench is arranged at the upper end of the main mounting support, the label plate mounting support, the label conveying and cutting mechanism, the label folding mechanism and the label conveying cylinder mechanism are all arranged at the upper end of the workbench, the label plate is arranged on the workbench through the label plate mounting support and located above one side of the main mounting support, the label folding mechanism is transversely arranged at the rear end of the label conveying and cutting mechanism, and the label conveying cylinder mechanism is arranged at the side edge of the label folding mechanism and connected with the label conveying and cutting mechanism.
5. The intelligent automatic double-side overedger according to claim 1, wherein one of the 2 adjusting platforms is fixed, and an automatic size adjusting device is arranged below the other movable adjusting platform, and the automatic size adjusting device adjusts the size by taking the fixed adjusting platform as a reference point.
6. The intelligent automatic double-sided overlock machine according to claim 5, wherein said automatic size adjustment device comprises: first motor, motor support, shaft coupling, fixed plate, bearing, lead screw, screw nut and connecting block, install the motor support on the first motor, shaft coupling one end and the output shaft of first motor, the other end of shaft coupling passes fixed plate and bearing and screw connection, the cover is equipped with screw nut and connecting block on the lead screw, the connecting block is fixed to be set up at mobilizable regulation platform lower surface.
7. The intelligent automatic double-sided overlock machine of claim 1, wherein each of the synchronous belt conveying motion structures comprises: the synchronous belt conveying and moving integrated assembly plate comprises a housing, a synchronous belt conveying and moving integrated assembly plate, a connecting fixing plate, a height adjusting seat and a second motor, wherein the connecting fixing plate, the height adjusting seat and the second motor are arranged in the housing, the upper end surface of the connecting fixing plate is fixedly connected with the housing, the lower end surface of the connecting fixing plate is fixedly connected with the height adjusting seat, one side of the connecting fixing plate is fixedly connected with the synchronous belt conveying and moving integrated assembly plate, the second motor is fixedly arranged on the height adjusting seat, the outer side of the housing is provided with a protective housing, one end of the synchronous belt conveying and moving integrated assembly plate is provided with a plurality of single-row guide wheels and a single-row tension wheel, the other end of the synchronous belt conveying and moving integrated assembly plate is provided with a plurality of double-row guide wheels and a double-row tension wheel, the front end of the synchronous belt conveying and moving integrated, the bottom side of the synchronous belt conveying motion integration assembly plate is provided with a plurality of single-row presser feet and a plurality of double-row presser feet from front to back, and the middle part and the rear end of the bottom side of the synchronous belt conveying motion integration assembly plate are respectively provided with a first guide sheet and a second guide sheet.
8. The intelligent automatic double-sided overedger apparatus of claim 1, wherein each of said tangential thermal bonding mechanisms comprises: the device comprises a base, wherein two ends of the base are connected with corner braces, a lower sensor mounting seat is arranged between the two corner braces, one side of the lower sensor mounting seat is provided with a dust blowing plate, the dust blowing plate is connected with a regulating valve, the upper end of the base is connected with a mounting seat, the mounting seat is provided with a dust suction seat, the rear end of the dust suction seat is provided with 2 cylindrical suction pipes, a heat insulation table is arranged above the dust suction seat, a heating plate is arranged in the heat insulation table, a heating core is arranged in the heating plate, an upper sensor mounting seat is arranged above the heat insulation table, 2 first cutter cylinders are arranged on the upper sensor mounting seat, a first cutter mounting seat is connected below each first cutter cylinder, a cutter is connected on the first cutter mounting seat, a vertical connecting plate is arranged on one side of the base, and a power supply protection cover shell and an upper cover shell are arranged on the vertical connecting plate, the power supply protection housing is arranged below the upper housing, a ceramic terminal seat is arranged in the power supply protection housing, and the lower sensor mounting seat and the upper sensor mounting seat are respectively provided with 2 correlation inductive switches.
9. The intelligent automatic double-side overedger according to claim 1, wherein each subframe is provided with a plurality of optical axes, and an overedger and an adjusting platform are arranged on the optical axes.
10. The intelligent automatic double-side overedger according to claim 1, wherein the 2 overedgers, the 2 adjusting platforms, the 2 synchronous belt conveying motion structures and the 2 tangent line hot sticking mechanisms are respectively arranged at the front end and the rear end of the auxiliary frame in a mirror image manner.
CN201920090779.9U 2019-01-21 2019-01-21 Intelligent automatic double-side overedger Active CN209816430U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201920090779.9U CN209816430U (en) 2019-01-21 2019-01-21 Intelligent automatic double-side overedger

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201920090779.9U CN209816430U (en) 2019-01-21 2019-01-21 Intelligent automatic double-side overedger

Publications (1)

Publication Number Publication Date
CN209816430U true CN209816430U (en) 2019-12-20

Family

ID=68871368

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201920090779.9U Active CN209816430U (en) 2019-01-21 2019-01-21 Intelligent automatic double-side overedger

Country Status (1)

Country Link
CN (1) CN209816430U (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113151991A (en) * 2021-04-26 2021-07-23 浙江欣普自动化科技有限公司 Strip cutting structure of splicing machine

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113151991A (en) * 2021-04-26 2021-07-23 浙江欣普自动化科技有限公司 Strip cutting structure of splicing machine
CN113151991B (en) * 2021-04-26 2022-05-03 浙江欣普自动化科技有限公司 Strip cutting structure of splicing machine

Similar Documents

Publication Publication Date Title
US8042478B2 (en) Automatic panel cutting and seaming system
CN103757827A (en) Towel machine with high product quality
CN204265970U (en) A kind of Novel towel machine
CN204917387U (en) Soft sheet automatically cropped machine
CN209816430U (en) Intelligent automatic double-side overedger
CN109763267A (en) A kind of intelligence automatic double overseam equipment
CN111941863A (en) Full-automatic mask machine
CN104514101A (en) Novel towel machine
CN108638520A (en) A kind of automation flanging heat pressing forming machines
CN105197659A (en) Automatic cloth ironing machine of filter element plate of filter
CN108406905A (en) A kind of servo cuts ear correction all-in-one machine
CN210525852U (en) Non-woven fabric edge folding heat-sealing machine
US4741233A (en) Cluster spreading and cutting system
CN210561117U (en) Automatic right-angle fillet four-side sewing equipment
US7412996B2 (en) Apparatus for hot applying strips or films on textile or non textile supports
CN110923969A (en) Automatic edge folding and sewing storage machine for fabric
CN107675371B (en) Auxiliary sewing device
CN212375504U (en) Automatic edge folding and sewing storage machine for fabric
CN214005001U (en) Automatic sewing equipment
CN214882187U (en) Full-automatic towel production line of complete set of sewing equipment
CN112663232B (en) Automatic feeding sewing device and working method thereof
CN214452463U (en) Device for quickly sealing bag
CN217026461U (en) Shirt production is with vertical automatic cloth cutting machine
CN214324246U (en) Full-automatic mask machine with mask seals
CN211893861U (en) Novel full-automatic soft packet of feed shaping all-in-one

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant