CN211522632U - Automatic sock turning machine - Google Patents

Abstract

The utility model relates to the technical field of sock manufacturing, in particular to an automatic sock turning machine, which is used for turning socks and matching the end sewing of the socks and comprises a base, wherein a supporting structure is arranged on the base, a plurality of sock turning components are arranged on the supporting structure in a surrounding way, each sock turning component is provided with a hollow sock turning pipe, one side of each sock turning pipe is correspondingly provided with a sewing mechanism, the other side of each sock turning pipe is provided with a vacuum adsorption switching mechanism, and a sock turning mechanism is also arranged at the position corresponding to the corresponding sock turning pipe; two rolling discs and two stirring discs are arranged on the base at intervals, the stirring discs are arranged on the rotating shaft, and the sock turning assembly rotates around the rotating shaft under the matching of the stirring discs and the rolling discs. Can encircle the socks subassembly that turns over that sets up through a plurality of and realize the multistation operation to this will sew up and turn over the socks and unify, realize sewing up and turn over the automation mechanized operation of socks, and owing to adopted the multistation operation, overall efficiency is higher, turns over socks and sutural linking also better.

Description

Automatic sock turning machine

Technical Field

The utility model relates to a socks manufacturing technical field, in particular to automatic sock turning machine.

Background

The sock is woven by yarn, when the end part of the sock leg is sewed, the sock leg needs to be turned over,

after the sock is manufactured and sewn, the sock is usually in a reverse state; therefore, it is necessary to turn the sock inside and outside before sewing, and turn the sock inside and outside again after sewing so that the seam faces inward.

Turning over the sock is therefore a necessary procedure in sock preparation. Sock turning and sewing are mutually connected steps, and how to unify sock turning and sewing to realize automatic operation is one of the keys for improving production efficiency.

Therefore, in order to increase the overall efficiency of the manufacture of the hosiery, a machine is required which is capable of automatically turning the hosiery and of cooperating with the stitching.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to solve the foretell how to cooperate continuously and sew up the front and back to socks and carry out twice inside and outside upset problem to how realizing a vacuum mechanism and a plurality of work pipe complex problem that are used for the cover to establish socks that this problem related provides a turn over hosiery machine vacuum tube auto-change over device.

The utility model provides a technical scheme that its technical problem adopted is:

an automatic sock turning machine comprises a base, wherein a supporting structure is arranged on the base, a plurality of sock turning assemblies are arranged on the supporting structure in a surrounding mode, the supporting structure is provided with a rotating shaft, and the sock turning assemblies are matched with the supporting structure to rotate around the rotating shaft; the sock turning component is provided with a hollow sock turning pipe, one side of the sock turning pipe is correspondingly provided with a sewing mechanism, the other side of the sock turning pipe is provided with a vacuum adsorption switching mechanism, and a sock turning mechanism is arranged at the position corresponding to the sock turning pipe; two rotating discs are arranged on the base at intervals, the sock turning assembly is movably limited on the two rotating discs, two poking discs are arranged on the base and arranged on the rotating shaft, and the sock turning assembly rotates around the rotating shaft under the matching of the poking discs and the rotating discs.

Preferably, the sock turning assembly further comprises a support member, a sock turning plate, a driving mechanism and a track rod, wherein the two support members are respectively arranged on the rotating disc in a limited mode, the track rod and the sock turning pipe are fixed on the two support members, the sock turning plate is connected with the sock turning pipe in a sliding mode through a sliding member, the driving mechanism is arranged on the track rod, and the driving mechanism drives the sock turning plate to reciprocate along the sock turning pipe in the axial direction.

Preferably, the driving mechanism comprises a driving seat and a driving rod, the driving seat is connected with the sock turning plate through the driving rod, a poking assembly is arranged on the supporting structure and provided with an inclined rod which forms a certain angle with the track rod, the inclined rod is matched with the driving seat, and the driving seat slides to one side of the sock turning plate along the track rod under the matching of the inclined rod.

Preferably, the sock turning tube is correspondingly provided with a restoring spring, and the restoring spring is matched with the driving seat.

Preferably, the sock turning mechanism is provided with a sock turning wheel and a hinged rod, the sock turning wheel is arranged at the tail end of the hinged rod, and the sock turning mechanism is further matched with a driver which is used for driving the hinged rod to rotate and driving the sock turning wheel to change in position.

Preferably, the inner side between the two rotating discs is provided with an annular groove, the base of the support being confined and sliding within the annular groove.

Preferably, the edge of the poking disc is provided with a clamping groove, the clamping groove is matched with the track rod, and the track rod is matched with the poking disc to realize that the sock turning assembly rotates around the rotating shaft.

The utility model has the advantages that: can encircle the socks subassembly that turns over that sets up through a plurality of and realize the multistation operation to this will sew up and turn over the socks and unify, realize sewing up and turn over the automation mechanized operation of socks, and owing to adopted the multistation operation, overall efficiency is higher, turns over socks and sutural linking also better.

Drawings

Fig. 1 shows the overall structure of the present invention.

Fig. 2 is a schematic structural diagram of the sock turning assembly of the present invention.

Fig. 3 is a schematic diagram of a part of the structure of the present invention.

Fig. 4 is a schematic structural diagram of the sock turning mechanism of the present invention.

Fig. 5 is a schematic structural diagram of the rotating disk of the present invention.

Fig. 6 shows a schematic structural diagram of the toggle plate of the present invention.

In the figure: 100 bases, 200 supporting structures, 201 rotating shafts, 202 rotating discs, 203 poking discs, 204 poking assemblies, 205 diagonal rods, 206 annular grooves, 207 clamping grooves, 300 sock turning assemblies, 301 sock turning pipes, 302 guide plates, 303 supporting pieces, 304 sock turning plates, 305 driving mechanisms, 306 track rods, 307 sliding pieces, 308 driving seats, 309 driving rods, 310 restoring springs, 400 sewing mechanisms, 500 vacuum adsorption switching mechanisms, 600 sock turning mechanisms, 601 sock turning wheels, 602 hinged rods and 603 drivers.

Detailed Description

Further refinements will now be made on the basis of the representative embodiment shown in the figures. It should be understood that the following description is not intended to limit the embodiments to one preferred embodiment. On the contrary, it is intended to cover alternatives, modifications, and equivalents as may be included within the spirit and scope of the embodiments as defined by the appended claims.

In the following detailed description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific embodiments in accordance with the embodiments. Although these embodiments are described in sufficient detail to enable those skilled in the art to practice the embodiments, it is to be understood that these examples are not limiting, such that other examples may be used and that corresponding modifications may be made without departing from the spirit and scope of the embodiments.

In particular, with reference to fig. 1-6, an automatic sock turning machine is shown.

Firstly, referring to fig. 1, 2 and 3, the sock turning machine comprises a base 100, a support structure 200 is arranged on the base 100, and a plurality of sock turning assemblies 300, for example 6 or 4, are arranged around the support structure 200 to form a multi-station structure; the sock turning assembly 300 is provided with a hollow sock turning tube 301, one side of the sock turning tube 301 is correspondingly provided with a sewing mechanism 400, the other side of the sock turning tube 301 is provided with a vacuum adsorption switching mechanism 500, and a sock turning mechanism 600 is further arranged at the position corresponding to the sock turning tube 301; the supporting structure 200 is provided with a rotating shaft 201, two rotating discs 202 are arranged on the base 100 at intervals, two poking discs 203 are arranged on the rotating shaft 201, the sock turning assembly 300 is movably limited on the two rotating discs 202, the poking discs 203 poke the sock turning assembly 300 to move on the rotating discs 202, and particularly the sock turning assembly 300 rotates around the rotating shaft 201 under the matching of the poking discs 203 and the rotating discs 202.

In addition to the sock turning tube 301, the sock turning assembly 300 further has a support member 303, a sock turning plate 304, a driving mechanism 305, and a track rod 306, wherein the two support members 303 are respectively and limitedly disposed on the rotating disc 202, the track rod 306 and the sock turning tube 301 are fixed on the two support members 303, the sock turning plate 304 is slidably connected with the sock turning tube 301 through a sliding member 307307, the driving mechanism 305 is disposed on the track rod 306, and the driving mechanism 305 drives the sock turning plate 304 to reciprocate along the axial direction of the sock turning tube 301. The driving mechanism 305 comprises a driving seat 308 and a driving rod 309, the driving seat 308 is connected with the sock turning plate 304 through the driving rod 309, the support structure 200 is provided with a toggle assembly 204, the toggle assembly 204 is provided with a diagonal rod 205 which forms a certain angle with the track rod 306, the diagonal rod 205 is matched with the driving seat 308, and the driving seat 308 slides towards one side of the sock turning plate 304 along the track rod 306 under the matching of the diagonal rod 205. The sock overturning tube 301 is correspondingly provided with a restoring spring 310, and the restoring spring 310 is matched with the driving seat 308. The restoring spring 310 is compressed when the driving seat 308 slides to a certain position, and is restored to the initial position under the cooperation of the spring when the driving seat 308 is separated from the slanting rod 205, or is restored to the initial position with the assistance of a subsequent similar slanting rod 205 structure.

As shown in fig. 5 and 6, the inner side between the two rotating disks 202 is provided with an annular groove 206, and the base portion of the support member 303 is confined in the annular groove 206 and slides within the annular groove 206. The edge of the dial plate 203 is provided with a clamping groove 207, the clamping groove 207 is matched with the track rod 306, and the track rod 306 realizes the rotation of the sock turning assembly 300 around the rotating shaft 201 under the matching of the dial plate 203. The dial plate 203 rotates to drive the track rod 306 to rotate together, and then the whole sock turning assembly 300 is driven to rotate.

As shown in fig. 4, the sock turning mechanism 600 has a sock turning wheel 601 and a hinge rod 602, the sock turning wheel 601 is disposed at the end of the hinge rod 602, and the sock turning mechanism 600 further cooperates with a driver 603 configured to drive the hinge rod 602 to rotate and to change the position of the sock turning wheel 601. The sock turning wheel 601 is driven to rotate by a motor, the sock turning wheel 601 is matched with the sock turning plate 304, after a sock is sleeved on the sock turning plate 304, the sock turning wheel 601 is contacted with the sock turning plate 304 under the action of the driver 603, and the sock turning wheel 601 turns the sock upwards through friction.

The specific matching process is as follows:

first, the sock is manually placed at the opening of the sock turning tube 301 connected to the vacuum suction switching mechanism 500, and the vacuum suction switching mechanism 500 intermittently contacts the other end of the sock turning tube 301 to provide vacuum, and at this time, the sock is sucked into the sock turning tube 301.

Then, the opening of the sock is sleeved on the sock turning tube 301, the vacuum adsorption switching mechanism 500 is separated from the sock turning tube 301, the vacuum suction force is lost, then, the sock turning wheel 601 is in contact with the sock turning plate 304, and the sock is turned on the sock turning plate 304 through friction force. Here, a guide plate 302 is provided on the sock-turning tube 301 in advance, and the guide plate 302 is fixed to the sock-turning tube 301 to guide the sock to be fitted over the sock-turning tube 301.

Then, the rotating shaft 201 drives the poking disc 203 to rotate, and the poking disc 203 drives the sock turning assembly 300 to rotate through the poking track rod 306; the sock turning tube 301 sleeved with the socks is transferred to a sewing station and corresponds to the sewing mechanism 400, at the moment, under the action of the inclined rod 205, the driving seat 308 slides to drive the sock turning plate 304 to push the socks outwards, one end of the socks is pushed to the sewing position of the sewing mechanism 400, and the sewing mechanism 400 sews the socks. In order to facilitate the sock turning plate 304 to push socks, a blocking portion for driving socks is arranged on the sock turning plate 304, and the blocking portion protrudes out of two sides of the sock turning plate 304 to facilitate pushing out.

After the sewing mechanism 400 finishes sewing, the sock turning assembly 300 is rotated and switched away, and then the sock on the sock turning tube 301 is matched with other matching mechanisms, for example, a vacuum suction mechanism connects the other end of the sock turning tube 301, and vacuum suction is applied, so that the sock can be sucked and discharged. No corresponding structure is given here. Here, the present disclosure focuses on the engagement of the sock turnup with the stitching mechanism 400.

In the above-mentioned scheme, the intermittent switching scheme between the vacuum suction switching mechanism 500 and the sock overturning tube 301 is not given, and the scheme does not hinder the implementation of the scheme in the present application, and therefore, the detailed description thereof is not given.

For purposes of explanation, specific nomenclature is used in the above description to provide a thorough understanding of the described embodiments. It will be apparent, however, to one skilled in the art that these specific details are not required in order to practice the embodiments described above. Thus, the foregoing descriptions of specific embodiments described herein are presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the embodiments to the precise form disclosed. It will be apparent to those skilled in the art that certain modifications, combinations, and variations can be made in light of the above teachings.

Claims (7)

1. The utility model provides an automatic sock turning machine which characterized in that: the sock turning device comprises a base, wherein a supporting structure is arranged on the base, a plurality of sock turning assemblies are arranged on the supporting structure in a surrounding mode, the supporting structure is provided with a rotating shaft, and the sock turning assemblies are matched with the supporting structure to rotate around the rotating shaft; the sock turning component is provided with a hollow sock turning pipe, one side of the sock turning pipe is correspondingly provided with a sewing mechanism, the other side of the sock turning pipe is provided with a vacuum adsorption switching mechanism, and a sock turning mechanism is arranged at the position corresponding to the sock turning pipe; two rotating discs are arranged on the base at intervals, the sock turning assembly is movably limited on the two rotating discs, two poking discs are arranged on the base and arranged on the rotating shaft, and the sock turning assembly rotates around the rotating shaft under the matching of the poking discs and the rotating discs.

2. An automatic hosiery overturning machine according to claim 1, characterized in that: the sock turning assembly is further provided with a support piece, a sock turning plate, a driving mechanism and a track rod, the two support pieces are arranged on the rotating disc in a limited mode respectively, the track rod and the sock turning pipe are fixed on the two support pieces, the sock turning plate is connected with the sock turning pipe in a sliding mode through a sliding piece, the driving mechanism is arranged on the track rod, and the driving mechanism drives the sock turning plate to reciprocate along the axial direction of the sock turning pipe.

3. An automatic hosiery overturning machine according to claim 1, characterized in that: actuating mechanism drives the seat and passes through the actuating lever and turn over the socks board including driving seat, actuating lever, drives the seat and is connected, is provided with on the bearing structure and stirs the subassembly, stirs the subassembly and has the down tube that is certain angle with the track pole, and the down tube matches with driving the seat, drives the seat and slides to one side of turning over the socks board along the track pole under the cooperation of down tube.

4. An automatic hosiery overturning machine according to claim 1, characterized in that: the sock turning tube is correspondingly provided with a recovery spring which is matched with the driving seat.

5. An automatic hosiery overturning machine according to claim 1, characterized in that: the sock turning mechanism is provided with a sock turning wheel and a hinged rod, the sock turning wheel is arranged at the tail end of the hinged rod, and the sock turning mechanism is further matched with a driver which is used for driving the hinged rod to rotate and driving the sock turning wheel to change in position.

6. An automatic hosiery overturning machine according to claim 1, characterized in that: an annular groove is arranged on the inner side between the two rotating discs, and the base part of the supporting piece is limited in the annular groove and slides in the annular groove.

7. An automatic hosiery overturning machine according to claim 1, characterized in that: the edge of the poking disc is provided with a clamping groove which is matched with the track rod, and the track rod is matched with the poking disc to realize that the sock turning component rotates around the rotating shaft.

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