CN221235734U - Double-end pocket machine - Google Patents

Abstract

The utility model discloses a double-end bag pasting machine which comprises a workbench, and a bag piece flanging station, a first sewing station and a second sewing station which are sequentially arranged on the workbench along the X-axis direction; the device also comprises a first frame pressing feeding device and a second frame pressing feeding device; the rear side of the workbench is provided with a group of X axial continuous guide rails, the first pressing frame feeding device is connected with a first driving seat assembly for driving the first pressing frame feeding device to move along the Y axial direction, the second pressing frame feeding device is connected with a second driving seat assembly for driving the second pressing frame feeding device to move along the Y axial direction, and the first driving seat assembly and the second driving seat assembly are arranged at left-right intervals and slidably arranged along the X axial continuous guide rails. The device has the advantages of compact structure, space saving and easy installation, adopts a continuous guide rail design, has good consistency of feeding directions of two press frames, and is favorable for better controlling the processing precision of secondary sewing.

Description

Double-end pocket machine

Technical Field

The utility model relates to the technical field of sewing machines, in particular to a double-head pocket sticking machine which is used for processing clothes and the like.

Background

Current pocket machines enable automatic sewing of pocket garments, such as shirts, jerseys, jeans, etc. The bag attaching machine comprises a single-end bag attaching machine and a double-end bag attaching machine, wherein the double-end bag attaching machine is used for secondarily sewing bag pieces, for example, CN 212293999U discloses a double-end bag attaching machine, and relates to the field of sewing equipment; the upper surface of the sewing working plane is provided with a first sewing machine and a second sewing machine, the first sewing machine is arranged between the first sewing conveying device and the second sewing conveying device, and the second sewing machine is arranged on the right side of the second sewing conveying device; the front parts of the pocket feeding device, the first sewing conveying device and the second sewing conveying device are all arranged above the sewing working plane; the front side of the frame is fixedly provided with a feeding device, and the rear part of the feeding device is arranged above the sewing working plane.

However, the first and second sewing and transporting devices are arranged at separate intervals, so that the space occupied on the machine is large, and the first and second sewing and transporting devices are limited by various factors (such as guide rail machining errors and installation errors) during installation, so that the guide rails of the first and second sewing and transporting devices are difficult to ensure complete consistency in the same direction, and the control of the accuracy of the bag sheet conveying positions by the first and second sewing and transporting devices is not facilitated.

Therefore, a new technical solution is needed to solve the above problems.

Disclosure of utility model

In view of the above, the present utility model aims at overcoming the defects of the prior art, and the main purpose of the present utility model is to provide a double-head bag pasting machine, which has the advantages of compact structure, space saving, easy installation, and good consistency of feeding directions of two press frames by adopting a continuous guide rail design, and is favorable for better controlling the processing precision of secondary sewing. In order to achieve the above purpose, the present utility model adopts the following technical scheme:

The double-end bag pasting machine comprises a workbench, and a bag sheet flanging station, a first sewing station and a second sewing station which are sequentially arranged on the workbench along the X-axis direction, wherein a flanging device, a first sewing device and a second sewing device are correspondingly arranged;

The device also comprises a first frame pressing feeding device and a second frame pressing feeding device; the first frame pressing feeding device is connected between the flanging device and the first sewing device, and the second frame pressing feeding device is connected between the first sewing device and the second sewing device;

The rear side of workstation is provided with a set of X axial continuous guide rail, first frame material feeding unit that presses is connected with and is used for the drive first drive seat subassembly that frame material feeding unit along Y axial displacement presses, second frame material feeding unit that presses is connected with and is used for the drive second drive seat subassembly that frame material feeding unit along Y axial displacement presses, first drive seat subassembly second drive seat subassembly left and right sides interval arrangement just follows X axial continuous guide rail slidable sets up.

As a preferable scheme, an X-axis translation driving device is arranged at the rear side of the workbench, and drives the first driving seat assembly and the second driving seat assembly to slide along the X-axis continuous guide rail.

As a preferable scheme, a first X-axis translation driving device and a second X-axis translation driving device are arranged at the rear side of the workbench, the first X-axis translation driving device drives the first driving seat assembly to slide along the X-axis continuous guide rail, and the second X-axis translation driving device drives the second driving seat assembly to slide along the X-axis continuous guide rail.

As a preferable scheme, the first X-axis translational driving device comprises a first motor and a first synchronous belt driven by the first motor, and the first driving seat assembly is connected with the first synchronous belt to move along the X-axis along with the first synchronous belt;

The second X-axis translation driving device comprises a second motor and a second synchronous belt driven by the second motor, and the second driving seat assembly is connected with the second synchronous belt to move along the X-axis along with the second synchronous belt.

As a preferable scheme, the front-back spacing of the X-axis continuous guide rails is two as a group, and the first synchronous belt and the second synchronous belt are positioned between the two X-axis continuous guide rails.

As a preferable scheme, the first driving seat assembly and the second driving seat assembly comprise driving seats, a Y-axis driving motor, a Y-axis synchronous belt and a Y-axis guide rail, wherein the Y-axis driving motor, the Y-axis synchronous belt and the Y-axis guide rail are arranged on the driving seats; the rear ends of the first pressing frame feeding device and the second pressing frame feeding device are connected with sliding blocks; the Y-axis driving motor drives the Y-axis synchronous belt, and the sliding block is arranged on the Y-axis guide rail in a sliding manner and connected with the Y-axis synchronous belt, so that the sliding block can be driven to slide along the Y-axis guide rail along with the Y-axis synchronous belt when the Y-axis driving motor works.

As a preferable scheme, the device also comprises a gasket punching and conveying device, wherein the gasket punching and conveying device comprises a punch, a vacuum adsorption carrier plate and a transverse conveying unit, the punch is driven by a punching driving unit to move up and down, and the top surface of the vacuum adsorption carrier plate is a first vacuum adsorption surface and is arranged below the punch for adsorbing gaskets punched and fallen by the punch; the vacuum adsorption carrier plate is connected with a first lifting unit to control the vacuum adsorption carrier plate to move up and down; the transverse conveying unit drives the first lifting unit and the vacuum adsorption carrier plate to transversely displace so as to convey the gasket to the position below the gasket groove in a translational mode from the position below the punch head, and the first lifting unit drives the vacuum adsorption carrier plate to lift to pass through the gasket groove so as to convey the gasket in place.

As a preferable scheme, a cloth piece deformation adsorption groove and a gasket groove are formed in the workbench corresponding to the lower part of the flanging device, a patch vacuum adsorption positioning device is arranged below the cloth piece deformation adsorption groove, and the patch vacuum adsorption positioning device is used for adsorbing and downwards deforming a region, opposite to the cloth piece deformation adsorption groove, of the cloth piece on the workbench;

as a preferable scheme, the gasket punching conveying device is detachably arranged beside the workbench.

Compared with the prior art, the utility model has obvious advantages and beneficial effects, in particular, the technical scheme shows that the workbench is mainly provided with a group of X-axis continuous guide rails at the rear side, the first press frame feeding device is connected with a first driving seat component for driving the first press frame feeding device to move along the Y-axis, the second press frame feeding device is connected with a second driving seat component for driving the second press frame feeding device to move along the Y-axis, the first driving seat component and the second driving seat component are arranged at intervals left and right and slidably along the X-axis continuous guide rails, the consistency of the feeding directions of the two press frames is good, the secondary sewing processing precision is better controlled, and the structure is more compact, saves space and is easy to install.

In order to more clearly illustrate the structural features and efficacy of the present utility model, the present utility model will be described in detail below with reference to the accompanying drawings and examples.

Drawings

FIG. 1 is a perspective view of a dual head bag applicator of an embodiment of the present utility model;

FIG. 2 is a top view of a dual head bag applicator of an embodiment of the present utility model;

FIG. 3 is another angular perspective view of a dual head bag applicator of an embodiment of the present utility model;

FIG. 4 is a partial structural view of a dual head bag machine of an embodiment of the present utility model;

FIG. 5 is a structural view of a bag vacuum suction positioning device of a double-head bag machine according to an embodiment of the present utility model;

Fig. 6 is a structural view of a pad punching and conveying device of a double-head bag machine according to an embodiment of the present utility model.

The attached drawings are used for identifying and describing: the bag sheet hemming machine comprises a workbench 1, a bag sheet hemming station 2, a first sewing station 3, a second sewing station 4, a hemming device 5, a first sewing device 6, a second sewing device 7, a first frame pressing feeding device 8, a second frame pressing feeding device 9, a gasket punching conveying device 10, an X-axis continuous guide rail 11, a first driving seat assembly 12, a second driving seat assembly 13, a first motor 14, a first synchronous belt 15, a second motor 16, a second synchronous belt 17, a driving seat 18, a Y-axis driving motor 19, a Y-axis synchronous belt 20, a Y-axis guide rail 21, a sliding block 22, a cloth sheet deformation adsorption groove 23, a gasket groove 24, a bag pasting vacuum adsorption positioning device 25, a lifting unit 26, a vacuum suction plate 27, a vacuum adsorption carrier 28, a transverse conveying unit 29, a punching driving unit 30 and a first lifting unit 31.

Detailed Description

Referring to fig. 1 to 6, specific structures of embodiments of the present utility model are shown.

In the description of the present utility model, it should be noted that the azimuth or positional relationship indicated by the terms "upper", "lower", "left", "right", etc. are based on the azimuth or positional relationship shown in the drawings, and are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present utility model.

The double-end bag pasting machine comprises a workbench 1, a bag sheet flanging station 2, a first sewing station 3 and a second sewing station 4 which are sequentially arranged on the workbench 1 along the X-axis direction, and a flanging device 5, a first sewing device 6 and a second sewing device 7 are correspondingly arranged; the device also comprises a first frame pressing feeding device 8 and a second frame pressing feeding device 9; the first frame pressing and feeding device 8 is connected between the edge folding device 5 and the first sewing device 6 to send the bag sheet after edge folding to the first sewing device 6 for first sewing, and the second frame pressing and feeding device 9 is connected between the first sewing device 6 and the second sewing device 7 to send the bag sheet after first sewing to the second sewing device 7 for second sewing. A gasket punching and conveying device 10 is detachably mounted beside the workbench 1. The upper part of the 5-position workbench 1 of the edge folding device is used for folding the bag sheets.

The rear side of the workbench 1 is provided with a group of X axial continuous guide rails 11, the X axial continuous guide rails 11 extend left and right to cover the travel between the bag sheet flanging station 2 and the second sewing station 4, the first pressing frame feeding device 8 is connected with a first driving seat assembly 12 for driving the first pressing frame feeding device 8 to displace along the Y axial direction, the second pressing frame feeding device 9 is connected with a second driving seat assembly 13 for driving the second pressing frame feeding device 9 to displace along the Y axial direction, and the first driving seat assemblies 12 are arranged at left and right intervals and are arranged along the X axial continuous guide rails 11 in a sliding mode.

An X-axis translation driving device is arranged at the rear side of the workbench 1, and drives the first driving seat assembly 12 and the second driving seat assembly 13 to slide along the X-axis continuous guide rail 11. In this embodiment, a first X-axis translation driving device and a second X-axis translation driving device are disposed at the rear side of the workbench 1, the first X-axis translation driving device drives the first driving seat assembly 12 to slide along the X-axis continuous guide rail 11, and the second X-axis translation driving device drives the second driving seat assembly 13 to slide along the X-axis continuous guide rail 11. The first X-axis translational driving device includes a first motor 14 and a first synchronous belt 15 driven by the first motor 14, the first synchronous belt 15X is disposed in an extending manner in an axial direction (left-right direction), and the first driving seat assembly 12 is connected to the first synchronous belt 15 so as to move along with the first synchronous belt 15 in the X-axis direction; the second X-axis translational driving device includes a second motor 16 and a second synchronous belt 17 driven by the second motor 16, the second synchronous belt 17X extends axially (left and right), and the second driving seat assembly 13 is connected to the second synchronous belt 17 to move along with the second synchronous belt 17 along the X-axis direction. Two X-axis continuous guide rails 11 are arranged in a front-back interval mode to form a group, and the first synchronous belt 15 and the second synchronous belt 17 are located between the two X-axis continuous guide rails 11. The first driving seat assembly 12 and the second driving seat assembly 13 comprise a driving seat 18, a Y-axis driving motor 19, a Y-axis synchronous belt 20 and a Y-axis guide rail 21 which are arranged on the driving seat 18; the rear ends of the first pressing frame feeding device 8 and the second pressing frame feeding device 9 are connected with sliding blocks 22; the Y-axis driving motor 19 drives the Y-axis synchronous belt 20, and the slider 22 is slidably disposed on the Y-axis guide rail 21 and connected to the Y-axis synchronous belt 20, so that the slider 22 can be driven to slide along the Y-axis guide rail 21 along with the Y-axis synchronous belt 20 when the Y-axis driving motor 19 works.

As shown in fig. 1 and 5, a cloth piece deformation adsorption groove 23 and a gasket groove 24 are arranged on the workbench 1 corresponding to the lower part of the flanging device 5, a patch pocket vacuum adsorption positioning device 25 is arranged below the cloth piece deformation adsorption groove 23, and the patch pocket vacuum adsorption positioning device 25 is used for adsorbing and downwards deforming a region, facing the cloth piece deformation adsorption groove 23, of the cloth piece on the workbench 1; through being provided with the groove of dodging that link up from top to bottom on sewing machine's workstation 1, utilize elevating unit 26 drive connect in vacuum suction plate 27 with the drive vacuum suction plate in dodge the inslot can reciprocate, make vacuum adsorption face relatively the relative height-adjustable of the top surface of sewing machine workstation 1, and then adjust vacuum suction plate will place in just right of cloth piece on the sewing machine workstation 1 dodge the regional absorption down deflection of groove, so, the subsidence deflection of cloth piece is directly controlled to cloth piece blowing district on sewing machine workstation 1 ingeniously, replaces the mode that adopts complicated mechanism to push the cloth piece to the centre along the horizontal direction to warp in the prior art, and the structure is simpler, can not occupy the space above the workstation 1, and can directly decide the down deflection of cloth piece by elevating unit's lift drive quantity, and the controllability is better.

As shown in fig. 1 and 6, the pad punching and conveying device 10 includes a punch, a vacuum suction carrier plate 28 and a transverse conveying unit 29, wherein the punch is driven by a punching driving unit 30 to move up and down, and the top surface of the vacuum suction carrier plate 28 is a first vacuum suction surface and is arranged below the punch to be used for sucking the pad punched and dropped by the punch; the vacuum adsorption carrier plate 28 is connected with a first lifting unit 31 to control the vacuum adsorption carrier plate 28 to move up and down; the transverse conveying unit 29 drives the first lifting unit 31 and the vacuum adsorption carrier plate 28 to move transversely so as to convey the gasket from the lower part of the punch to the lower part of the gasket groove 24 in a translational manner, and the first lifting unit 31 drives the vacuum adsorption carrier plate 28 to lift up through the gasket groove 24 so as to convey the gasket in place. Through the setting of drift, vacuum absorption carrier plate 28 and horizontal conveying unit 29, when horizontal conveying unit 29 moved vacuum absorption carrier plate 28 to the drift below, directly received the spacer that is punched by the drift and falls down, afterwards, the drift risees, horizontal conveying unit 29 moves vacuum absorption carrier plate 28 to the hem station below, rise vacuum absorption carrier plate 28 with the spacer that sends in place by elevating unit, its simple structure, whole die-cut and conveying action is simplified greatly, be favorable to promoting efficiency, and the structure is compacter, be convenient for install and be applied to on the sewing machine.

The utility model mainly aims at the design that a group of X-axis continuous guide rails 11 are arranged on the rear side of a workbench 1, a first driving seat 18 assembly 12 for driving the first frame pressing and feeding device 8 to move along the Y-axis is connected with the first frame pressing and feeding device 8, a second driving seat 18 assembly 13 for driving the second frame pressing and feeding device 9 to move along the Y-axis is connected with the second driving seat 18 assembly 13, the first driving seat 18 assembly 12 and the second driving seat 18 assembly 13 of the driving seat 18 are arranged at a left-right interval and slidably arranged along the X-axis continuous guide rails 11, and the consistency of the feeding directions of two frames pressing is good, so that the secondary sewing processing precision can be controlled better, and the structure is more compact, saves space and is easy to install.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the technical scope of the present utility model, so any minor modifications, equivalent changes and modifications made to the above embodiments according to the technical principles of the present utility model are still within the scope of the technical solutions of the present utility model.

Claims (9)

1. The utility model provides a double-end pocket machine which characterized in that: the automatic folding machine comprises a workbench, a bag piece folding station, a first sewing station and a second sewing station which are sequentially arranged on the workbench along the X-axis direction, and a folding device, a first sewing device and a second sewing device are correspondingly arranged;

The device also comprises a first frame pressing feeding device and a second frame pressing feeding device; the first frame pressing feeding device is connected between the flanging device and the first sewing device, and the second frame pressing feeding device is connected between the first sewing device and the second sewing device;

The rear side of workstation is provided with a set of X axial continuous guide rail, first frame material feeding unit that presses is connected with and is used for the drive first drive seat subassembly that frame material feeding unit along Y axial displacement presses, second frame material feeding unit that presses is connected with and is used for the drive second drive seat subassembly that frame material feeding unit along Y axial displacement presses, first drive seat subassembly second drive seat subassembly left and right sides interval arrangement just follows X axial continuous guide rail slidable sets up.

2. A dual-head bag machine according to claim 1, wherein: the rear side of the workbench is provided with an X-axis translation driving device, and the X-axis translation driving device drives the first driving seat assembly and the second driving seat assembly to slide along the X-axis continuous guide rail.

3. A dual-head bag machine according to claim 1, wherein: the rear side of the workbench is provided with a first X-axis translation driving device and a second X-axis translation driving device, the first X-axis translation driving device drives the first driving seat component to slide along the X-axis continuous guide rail, and the second X-axis translation driving device drives the second driving seat component to slide along the X-axis continuous guide rail.

4. A dual-head bag machine according to claim 3, wherein: the first X-axis translation driving device comprises a first motor and a first synchronous belt driven by the first motor, and the first driving seat assembly is connected with the first synchronous belt so as to move along the X-axis along with the first synchronous belt;

The second X-axis translation driving device comprises a second motor and a second synchronous belt driven by the second motor, and the second driving seat assembly is connected with the second synchronous belt to move along the X-axis along with the second synchronous belt.

5. The dual-head bag machine of claim 4, wherein: and two X-axis continuous guide rails are arranged at intervals in front of and behind the X-axis continuous guide rails to form a group, and the first synchronous belt and the second synchronous belt are positioned between the two X-axis continuous guide rails.

6. A dual-head bag machine according to claim 1, wherein: the first driving seat assembly and the second driving seat assembly comprise a driving seat, a Y-axis driving motor, a Y-axis synchronous belt and a Y-axis guide rail, wherein the Y-axis driving motor, the Y-axis synchronous belt and the Y-axis guide rail are arranged on the driving seat; the rear ends of the first pressing frame feeding device and the second pressing frame feeding device are connected with sliding blocks; the Y-axis driving motor drives the Y-axis synchronous belt, and the sliding block is arranged on the Y-axis guide rail in a sliding manner and connected with the Y-axis synchronous belt, so that the sliding block can be driven to slide along the Y-axis guide rail along with the Y-axis synchronous belt when the Y-axis driving motor works.

7. A dual-head bag machine according to claim 1, wherein: the gasket punching and conveying device comprises a punch, a vacuum adsorption carrier plate and a transverse conveying unit, wherein the punch is driven by a punching driving unit to move up and down, and the top surface of the vacuum adsorption carrier plate is a first vacuum adsorption surface and is arranged below the punch for adsorbing gaskets punched and fallen by the punch; the vacuum adsorption carrier plate is connected with a first lifting unit to control the vacuum adsorption carrier plate to move up and down; the transverse conveying unit drives the first lifting unit and the vacuum adsorption carrier plate to transversely displace so as to convey the gasket to the position below the gasket groove in a translational mode from the position below the punch head, and the first lifting unit drives the vacuum adsorption carrier plate to lift to pass through the gasket groove so as to convey the gasket in place.

8. A dual-head bag machine according to claim 1, wherein: the cloth piece deformation adsorption groove and the gasket groove are formed in the workbench and correspond to the lower portion of the flanging device, the bag attaching vacuum adsorption positioning device is arranged below the cloth piece deformation adsorption groove and is used for enabling the cloth piece on the workbench to face the cloth piece deformation adsorption groove region to be adsorbed and deformed downwards.

9. The dual-head bag machine of claim 7, wherein: the gasket punching conveying device is detachably arranged beside the workbench.