CN107401000B - Sleeve and sleeve cut piece splicing and sewing mechanism and splicing and sewing method - Google Patents

Abstract

The invention discloses an sleeve and sleeve cut-parts splicing and sewing mechanism and a splicing and sewing method thereof. The sleeve and sleeve cut-parts splicing and sewing mechanism comprises a machine table, a pressing device, a moving device and a sewing device. The machine table is provided with a workbench, and the upper surface of the workbench is provided with an air suction area. The pressing device is provided with a supporting plate, a mold, a first pressing part, a second pressing part and a third pressing part; the supporting plate is positioned on the upper surface of the workbench and is provided with a plurality of air suction holes; the mould is arranged above the supporting plate and is used for laying the sleeve and the sleeve cut pieces; the first pressing part, the second pressing part and the third pressing part are sequentially arranged on the supporting plate. The material moving device is arranged on the machine table and connected to the supporting plate so as to drive the supporting plate to move along the upper surface of the working table. The sewing device is arranged on the machine table and used for sewing the sleeve and the sleeve cut pieces. The sleeve and sleeve piece splicing and sewing mechanism saves time and labor and can improve the product quality.

Description

Sleeve and sleeve cut piece splicing and sewing mechanism and splicing and sewing method

Technical Field

The invention relates to the field of textile machinery, in particular to a sleeve and sleeve cut-part splicing and sewing mechanism and a splicing and sewing method.

Background

In the process of splicing and sewing the sleeve and the sleeve cut pieces, the prior operation is to fold the sleeve and the sleeve cut pieces manually, the seam allowance requirement needs to be maintained, and then the sleeve openings are placed into the sleeve openings manually and then are sent into the sewing machine for sewing.

Disclosure of Invention

Accordingly, there is a need for a mechanism and a method for splicing and sewing sleeve and sleeve cut pieces that can save labor and time and improve product quality.

The utility model provides an sleeve and sleeve cut-parts piece mechanism, includes:

the air suction device comprises a machine table, wherein a workbench is arranged on the machine table, and an air suction area is arranged on the upper surface of the workbench;

the pressing device is provided with a supporting plate, a mold, a first pressing part, a second pressing part and a third pressing part; the supporting plate is positioned on the upper surface of the workbench and is provided with a plurality of air suction holes; the mould is connected above the supporting plate and is used for laying sleeves and sleeve cut pieces; the first pressing part, the second pressing part and the third pressing part are connected to the supporting plate and are arranged in sequence;

the material moving device is arranged on the machine table and connected to the supporting plate so as to drive the supporting plate to move along the upper surface of the workbench; and

and the sewing device is arranged on the machine table and is used for sewing the sleeve and the sleeve cut pieces.

In one embodiment, the first pressing member includes a first pressing plate and a first pressing driving assembly, the first pressing driving assembly is disposed on the supporting plate and connected to the first pressing plate, and the first pressing driving assembly is configured to drive the first pressing plate to move so as to press the sleeve and the sleeve cut piece on the mold.

In one embodiment, the first nip drive assembly comprises a first transverse nip drive element and a first longitudinal nip drive element; the first longitudinal pressing driving element is connected to the first pressing plate for driving the first pressing plate to move longitudinally towards the mould; the first transverse pressing driving element is connected to the supporting plate and the first longitudinal pressing driving element, and the first transverse pressing driving element is used for driving the first longitudinal pressing driving element to drive the first pressing plate to move transversely relative to the die.

In one embodiment, the second pressing member includes a second pressing plate and a second pressing driving assembly, the second pressing driving assembly is disposed on the supporting plate and connected to the second pressing plate, and the second pressing driving assembly is configured to drive the second pressing plate to move so as to press the sleeve and the sleeve cut piece on the mold.

In one embodiment, the second nip drive assembly comprises a second transverse nip drive element and a second longitudinal nip drive element; the second longitudinal pressing driving element is connected to the second pressing plate and used for driving the second pressing plate to move longitudinally towards the die; the second transverse pressing driving element is connected to the supporting plate and the second longitudinal pressing driving element, and the second transverse pressing driving element is used for driving the second longitudinal pressing driving element to drive the second pressing plate to move transversely relative to the die.

In one embodiment, the third pressing member includes a third pressing plate and a third pressing driving assembly, the third pressing driving assembly is disposed on the supporting plate and connected to the third pressing plate, and the third pressing driving assembly is configured to drive the third pressing plate to move so as to press the sleeve and the sleeve cut piece on the mold.

In one embodiment, the third nip drive assembly comprises a third transverse nip drive element and a third longitudinal nip drive element; the third longitudinal pressing driving element is connected to the third pressing plate for driving the third pressing plate to move longitudinally towards the die; the third transverse pressing driving element is connected to the supporting plate and the third longitudinal pressing driving element, and the third transverse pressing driving element is used for driving the third longitudinal pressing driving element to drive the third pressing plate to move transversely relative to the die.

In one embodiment, the material moving device is provided with a material moving guide rail, a material moving seat and a material moving driving part, wherein the material moving guide rail is arranged on the upper surface of the workbench; the material moving seat is arranged on the material moving guide rail and connected to the supporting plate, and the material moving driving part is connected to the material moving seat and used for driving the material moving seat to drive the supporting plate to move along the material moving guide rail.

In one embodiment, the air suction device is provided with a suction fan and a suction pipe, the suction fan is connected to the machine table and located below the workbench, the suction fan is communicated with the air suction area through the suction pipe, and the suction fan can suck air through the air suction area.

A sleeve and sleeve cut piece splicing method comprises the following steps:

the material moving device drives the supporting plate to move to an air suction area on the workbench, and an air suction hole in the supporting plate corresponds to the air suction area;

laying sleeves and sleeve cut pieces on a mould, and folding the sleeves and the sleeve cut pieces according to a preset requirement; the first material pressing component and the second material pressing component are pressed downwards at one side of the folded splicing seam of the sleeve and the sleeve cut piece;

the material moving device drives the supporting plate to move to a sewing device and then moves according to a preset sewing track, and the sewing device sews the parts of the sleeve and the sleeve cut pieces pressed by the first material pressing part and the second material pressing part; after sewing is finished, stopping the sewing device;

the first material pressing part is reset, and the third material pressing part presses the other side of the splicing seam of the sleeve and the sleeve cut piece; the material moving device drives the supporting plate to continuously move according to the preset sewing track, and the sewing device sews the parts of the sleeve and the sleeve cutting piece pressed by the second pressing part and the third pressing part.

Foretell sleeve and sleeve cut-parts piece seam mechanism through press device, move material device and sewing device's cooperation, practices thrift the supplementary folding back of manual work and presses down the location action, through press device, can liberate manual operation, and degree of automation is high, the process degree of difficulty greatly reduced. Because the sleeve is cylindric, even have the jag with sleeve cut-parts piece seam kneck, nevertheless be not enough to make the sleeve can expand completely and shakeout, consequently the sleeve can not once the sewing shaping with the sleeve cut-parts, the material of pressing through foretell sleeve and sleeve cut-parts piece seam mechanism presses material part, second and presses the material of material part and realize the sewing of sleeve and sleeve cut-parts one section, rethread second presses material part and third and presses another section of sleeve and sleeve cut-parts, has so both realized the continuous sewing of non-level cut-parts, the sewing quality is high, practices thrift the manpower, save time.

Drawings

FIG. 1 is a schematic view of an example of a sleeve and sleeve panel splicing and sewing mechanism;

FIG. 2 is another angle schematic view of the sleeve and sleeve panel splicing and sewing mechanism shown in FIG. 1;

FIG. 3 is another angle schematic view of the sleeve and sleeve panel splicing and sewing mechanism shown in FIG. 1;

fig. 4 is a schematic view of the material pressing device and the material moving device of the sleeve and sleeve cut-part splicing and sewing mechanism shown in fig. 1.

Description of the reference numerals

10. The sleeve and the sleeve cut piece splicing and sewing mechanism; 100. a machine platform; 110. a work table; 111. a suction area; 200. a material pressing device; 210. a support plate; 211. an air suction hole; 220. a mold; 230. a first swaging member; 231. a first pressure plate; 232. a first swaging drive assembly; 2321. a first transverse swaging drive element; 2322. a first longitudinal swaging drive element; 240. a second swaging part; 241. a second pressure plate; 242. a second swaging drive assembly; 2421. a second transverse swaging drive element; 2422. a second longitudinal swaging drive element; 250. a third swaging component; 251. a third material pressing plate; 252. a third material pressing driving component; 2521. a third transverse swaging drive element; 2522. a third longitudinal pressing driving element; 300. a material moving device; 310. a material moving guide rail; 320. a material moving seat; 330. a material moving driving part; 400. a sewing device; 500. a control device; 600. an air suction device; 700. a touch screen.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 and 2, the present embodiment relates to a sleeve and sleeve panel splicing and sewing mechanism 10. The sleeve and sleeve panel splicing and sewing mechanism 10 comprises a machine table 100, a pressing device 200, a moving device 300, a sewing device 400 and a control device 500. Preferably, the control device 500 may be a PLC.

Referring to fig. 1 and 2, a worktable 110 is disposed on the machine 100, and an air suction area 111 is disposed on an upper surface of the worktable 110.

Referring to fig. 2 and 4, the pressing device 200 includes a support plate 210, a mold 220, a first pressing member 230, a second pressing member 240, and a third pressing member 250. The supporting plate 210 is located on the upper surface of the working platform 110, and the supporting plate 210 has a plurality of air suction holes 211. The mold 220 is connected above the supporting plate 210 for laying the sleeves and the sleeve panels. The first pressing member 230, the second pressing member 240, and the third pressing member 250 are connected to the support plate 210 and arranged in sequence. The first pressing part 230, the second pressing part 240 and the third pressing part 250 are all electrically connected with the control device 500.

Referring to fig. 1 and 2, the material moving device 300 is disposed on the machine table 100 and connected to the pallet 210 for driving the pallet 210 to move along the upper surface of the working table 110. The material moving device 300 is electrically connected to the control device 500.

Referring to fig. 1 and 3, a sewing device 400 is provided on the machine 100 for sewing sleeves and sleeve panels. The sewing device 400 is electrically connected to the control device 500.

In one embodiment, referring to fig. 4, the first nip member 230 includes a first nip plate 231 and a first nip driving assembly 232. The first pressing driving assembly 232 is disposed on the supporting plate 210 and connected to the first pressing plate 231. The first pressing driving component 232 is used for driving the first pressing plate 231 to move so as to press the sleeve and the sleeve panel on the mold 220. The first pressing driving assembly 232 is electrically connected to the control device 500.

Further, the first pressing driving assembly 232 includes a first transverse pressing driving element 2321 and a first longitudinal pressing driving element 2322. The first longitudinal nip driving element 2322 is connected to the first nip plate 231 for driving the first nip plate 231 to move longitudinally towards the mold 220. The first transverse pressing driving element 2321 is connected to the supporting plate 210 and the first longitudinal pressing driving element 2322, and the first transverse pressing driving element 2321 is configured to drive the first longitudinal pressing driving element 2322 to drive the first pressing plate 231 to move transversely relative to the mold 220. The first transverse pressing driving element 2321 and the first longitudinal pressing driving element 2322 are electrically connected to the control device 500. The first transverse pressing driving element 2321 and the first longitudinal pressing driving element 2322 may both adopt a driving motor.

In one embodiment, referring to fig. 4, the second nip member 240 includes a second nip plate 241 and a second nip driving assembly 242. The second pressing driving component 242 is disposed on the supporting plate 210 and connected to the second pressing plate 241, and the second pressing driving component 242 is used for driving the second pressing plate 241 to move so as to press the sleeve and the sleeve panel on the mold 220. The second pressing driving assembly 242 is electrically connected to the control device 500.

Further, the second nip driving assembly 242 includes a second transverse nip driving element 2421 and a second longitudinal nip driving element 2422. The second longitudinal pressing driving element 2422 is connected to the second pressing plate 241 for driving the second pressing plate 241 to move longitudinally towards the mold 220. The second transverse pressing driving element 2421 is connected to the supporting plate 210 and connected to the second longitudinal pressing driving element 2422, and the second transverse pressing driving element 2421 is configured to drive the second longitudinal pressing driving element 2422 to drive the second pressing plate 241 to move transversely relative to the mold 220. The second transverse pressing driving element 2421 and the second longitudinal pressing driving element 2422 are electrically connected to the control device 500. The second transverse pressing driving element 2421 and the second longitudinal pressing driving element 2422 may both adopt driving motors.

In one embodiment, referring to fig. 4, the third nip member 250 includes a third nip plate 251 and a third nip drive assembly 252. The third pressing driving component 252 is disposed on the supporting plate 210 and connected to the third pressing plate 251, and the third pressing driving component 252 is configured to drive the third pressing plate 251 to move so as to press the sleeve and the sleeve panel on the mold 220. The third pressing driving assembly 252 is electrically connected to the control device 500.

Further, the third nip drive assembly 252 includes a third transverse nip drive element 2521 and a third longitudinal nip drive element 2522. A third longitudinal nip drive element 2522 is connected to the third nip plate 251 for driving the third nip plate 251 to move longitudinally towards the die 220. The third transverse pressing driving element 2521 is connected to the supporting plate 210 and to the third longitudinal pressing driving element 2522, and the third transverse pressing driving element 2521 is configured to drive the third longitudinal pressing driving element 2522 to drive the third pressing plate 251 to move transversely relative to the mold 220. The third transverse pressing driving element 2521 and the third longitudinal pressing driving element 2522 are electrically connected to the control device 500. The third transverse swage drive element 2521 and the third longitudinal swage drive element 2522 may each employ a drive motor.

In one embodiment, referring to fig. 3, the material moving device 300 has a material moving guide 310, a material moving base 320, and a material moving driving part 330. The material moving guide 310 is disposed on the upper surface of the table 110, and the material moving guide 310 extends along the sewing track direction. The material moving base 320 is disposed on the material moving guide rail 310 and connected to the supporting plate 210, and the material moving driving part 330 is connected to the material moving base 320 for driving the material moving base 320 to drive the supporting plate 210 to move along the material moving guide rail 310. The material moving driving part 330 may adopt a driving motor.

In one embodiment, referring to fig. 3, the sleeve and sleeve panel splicing and sewing mechanism 10 further comprises an air suction device 600. The air suction device 600 has a suction fan and a suction duct. The suction fan is connected on the machine table 100 and located below the workbench 110, the suction fan is communicated with the air suction area 111 through the suction pipe, and the suction fan can suck air through the air suction area 111.

In one embodiment, referring to fig. 1, the apparatus further includes a touch screen 700, the touch screen 700 is disposed on the machine 100 and connected to the control device 500, and the touch screen 700 can belong to the preset parameters through touch.

The sleeve and sleeve cut piece splicing and sewing mechanism 10 related to the embodiment relates to a sleeve and sleeve cut piece splicing and sewing method when used for splicing and sewing the sleeve and the sleeve cut piece. The sleeve and sleeve cut piece splicing method comprises the following steps:

the material moving device 300 drives the supporting plate 210 to move to the air suction area 111 on the workbench 110, and the air suction holes 211 on the supporting plate 210 correspond to the air suction area 111.

Laying the sleeves and the sleeve cut pieces on the mold 220, and folding the sleeves and the sleeve cut pieces according to preset requirements; the first blank member 230 and the second blank member 240 are pressed down to one side of the folded sleeve and sleeve panel splicing seam.

The material moving device 300 drives the supporting plate 210 to move to the sewing device 400 and then move according to a preset sewing track, and the sewing device 400 sews the part of the sleeve and the sleeve panel pressed by the first pressing member 230 and the second pressing member 240; after the sewing is completed, the sewing device 400 stops operating.

The first pressing part 230 is reset, and the third pressing part 250 presses the other side of the splicing seam of the sleeve and the sleeve cut piece; the material moving device 300 drives the supporting plate 210 to move continuously according to the preset sewing track, and the sewing device 400 sews the parts of the sleeve and the sleeve panel pressed by the second pressing member 240 and the third pressing member 250.

Foretell sleeve and sleeve cut-parts piece mechanism 10 through press device 200, move material device 300 and sewing device 400's cooperation, practices thrift the artifical supplementary location action of pressing after folding, through press device 200, can liberate manual operation, and degree of automation is high, process degree of difficulty greatly reduced. Because the sleeve is cylindric, even have the jag with sleeve cut-parts piece seam kneck, nevertheless be not enough to make the sleeve can expand completely and shakeout, consequently sleeve and sleeve cut-parts can not once the sewing shaping, press the material through foretell sleeve and sleeve cut-parts piece seam mechanism 10 first material 230, second material 240 of pressing and realize the sewing of sleeve and one section of sleeve cut-parts, rethread second material 240 and third material 250 of pressing and push down another section of sleeve and sleeve cut-parts, both can realize the continuous sewing of non-smooth cut-parts like this, the sewing quality is high, practices thrift the manpower, save time.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. The utility model provides a piece mechanism for the disposable piece of sleeve and sleeve cut-parts, its characterized in that includes:

the air suction device comprises a machine table, wherein a workbench is arranged on the machine table, and an air suction area is arranged on the upper surface of the workbench;

the pressing device is provided with a supporting plate, a mold, a first pressing part, a second pressing part and a third pressing part; the supporting plate is positioned on the upper surface of the workbench and is provided with a plurality of air suction holes; the mould is connected above the supporting plate and is used for laying sleeves and sleeve cut pieces; the first material pressing component, the second material pressing component and the third material pressing component are connected to the supporting plate and are arranged in sequence, the first material pressing component and the second material pressing component can be pressed down to one side of a splicing seam of the sleeve and the sleeve cut piece after being folded according to preset requirements, and the second material pressing component and the third material pressing component can simultaneously press the other side of the splicing seam of the sleeve and the sleeve cut piece;

the material moving device is arranged on the machine table and connected to the supporting plate so as to drive the supporting plate to move along the upper surface of the workbench; and

the sewing device is arranged on the machine table and used for sewing the sleeve and the sleeve cut piece, the sewing device can be used for sewing the parts of the sleeve and the sleeve cut piece pressed by the first pressing component and the second pressing component, and the sewing device can also be used for sewing the parts of the sleeve and the sleeve cut piece pressed by the second pressing component and the third pressing component after the first pressing component is reset.

2. The stitching mechanism as claimed in claim 1, wherein the first pressing member includes a first pressing plate and a first pressing driving assembly, the first pressing driving assembly is disposed on the supporting plate and connected to the first pressing plate, and the first pressing driving assembly is configured to drive the first pressing plate to move so as to press the sleeve and the sleeve cut piece on the mold.

3. The seaming mechanism of claim 2, wherein the first nip drive assembly comprises a first transverse nip drive element and a first longitudinal nip drive element; the first longitudinal pressing driving element is connected to the first pressing plate for driving the first pressing plate to move longitudinally towards the mould; the first transverse pressing driving element is connected to the supporting plate and connected to the first longitudinal pressing driving element, and the first transverse pressing driving element is used for driving the first longitudinal pressing driving element to drive the first pressing plate to move transversely relative to the die.

4. The seaming mechanism according to any one of claims 1 to 3, wherein the second material pressing member comprises a second material pressing plate and a second material pressing driving assembly, the second material pressing driving assembly is disposed on the supporting plate and connected to the second material pressing plate, and the second material pressing driving assembly is configured to drive the second material pressing plate to move so as to press the sleeve and the sleeve cut piece on the mold.

5. The seaming mechanism of claim 4, wherein the second nip drive assembly comprises a second transverse nip drive element and a second longitudinal nip drive element; the second longitudinal pressing driving element is connected to the second pressing plate and used for driving the second pressing plate to move longitudinally towards the die; the second transverse pressing driving element is connected to the supporting plate and the second longitudinal pressing driving element, and the second transverse pressing driving element is used for driving the second longitudinal pressing driving element to drive the second pressing plate to move transversely relative to the die.

6. The seaming mechanism according to any one of claims 1 to 3, wherein the third pressing member includes a third pressing plate and a third pressing driving assembly, the third pressing driving assembly is disposed on the supporting plate and connected to the third pressing plate, and the third pressing driving assembly is configured to drive the third pressing plate to move so as to press the sleeve and the sleeve panel on the mold.

7. The seaming mechanism of claim 6, wherein the third nip drive assembly comprises a third transverse nip drive element and a third longitudinal nip drive element; the third longitudinal pressing driving element is connected to the third pressing plate for driving the third pressing plate to move longitudinally towards the die; the third transverse pressing driving element is connected to the supporting plate and the third longitudinal pressing driving element, and the third transverse pressing driving element is used for driving the third longitudinal pressing driving element to drive the third pressing plate to move transversely relative to the die.

8. The seaming mechanism according to any one of claims 1 to 3, wherein the material moving device is provided with a material moving guide rail, a material moving seat and a material moving driving part; the material moving guide rail is arranged on the upper surface of the workbench; the material moving seat is arranged on the material moving guide rail and connected to the supporting plate, and the material moving driving part is connected to the material moving seat and used for driving the material moving seat to drive the supporting plate to move along the material moving guide rail.

9. The seaming mechanism according to any one of claims 1 to 3, further comprising an air suction device, wherein the air suction device has a suction fan and a suction pipe, the suction fan is connected to the machine platform and located below the workbench, the suction fan is communicated with the air suction area through the suction pipe, and the suction fan can suck air through the air suction area.

10. A seaming method for seaming sleeves and sleeve panels, using the seaming mechanism of any one of claims 1 to 9, comprising the steps of:

the material moving device drives the supporting plate to move to an air suction area on the workbench, and an air suction hole in the supporting plate corresponds to the air suction area;

laying sleeves and sleeve cut pieces on a mould, and folding the sleeves and the sleeve cut pieces according to a preset requirement; the first material pressing component and the second material pressing component are pressed downwards at one side of the folded splicing seam of the sleeve and the sleeve cut piece;

the material moving device drives the supporting plate to move to a sewing device and then moves according to a preset sewing track, and the sewing device sews the parts of the sleeve and the sleeve cut pieces pressed by the first material pressing part and the second material pressing part; after sewing is finished, stopping the sewing device;

the first material pressing part is reset, and the third material pressing part presses the other side of the splicing seam of the sleeve and the sleeve cut piece; the material moving device drives the supporting plate to continuously move according to the preset sewing track, and the sewing device sews the parts of the sleeve and the sleeve cutting piece pressed by the second pressing part and the third pressing part.

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