CN218621320U - Multi-station embroidery machine - Google Patents

Abstract

The utility model relates to a dress processing automation device, and discloses a multi-station embroidery machine, which comprises a plurality of embroidery machine bodies, wherein the embroidery machine bodies are arranged at intervals; the outer border of operation panel is seted up jaggedly, and one side border pin joint of breach has the operation panel, and the face of operation panel is on a parallel with the mesa of operation panel, and the bottom of operation panel is provided with to be connected and turns over under the actuating mechanism of operation panel with the control operation panel, the utility model discloses a multistation embroidery eye machine, many embroidery eye machine bodies can embroider the eye to many dresses simultaneously and handle to promote machining efficiency. Through set up the breach on the operation panel, can let people be close to the equipment main part that is located the intermediate position when overhauing equipment to promote the maintenance convenience. After the maintenance is finished, the board surface of the operating board is enabled to be parallel to the table board of the operating table again through the driving mechanism, so that the operating table can recover the normal function, and the operation is more humanized.

Description

Multi-station embroidery machine

Technical Field

The utility model relates to a dress processing automation equipment especially relates to multistation embroidery eye machine.

Background

An eyelet machine, also known as a buttonhole sewing machine, is mainly used for processing buttonholes in various clothes, is divided into a straight buttonhole sewing machine (straight eyelet machine) and a round eyelet buttonhole sewing machine (eyelet buttonhole sewing machine), and is divided into two types of ending and non-ending, and is a special device which is very important in clothing machinery. A buttonholing machine system generally consists of nine major mechanisms: the automatic noodle cutting device comprises a feeding mechanism, a crochet hook mechanism, a needle rod mechanism, a stretching mechanism, a hook shuttle mechanism, an upper cutter mechanism, a sliding table mechanism, a thread separating mechanism and an automatic noodle cutting device. Each set of mechanism has the characteristics and functions of the mechanism, has relative independence, but is closely matched and coordinated in work. For example, the utility model with the publication number of CN206591253U discloses a similar eye embroidering machine. The traditional eye embroidering machine can only carry out eye embroidering treatment on one piece of clothes at a time, and has low efficiency, so a certain improvement space exists.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to prior art's shortcoming, provide a multistation embroidery eye machine, can embroider the eye to many dresses simultaneously and handle, promote machining efficiency.

In order to solve the technical problem, the utility model discloses a following technical scheme can solve:

a multi-station embroidery machine comprises a plurality of embroidery machine bodies which are arranged at intervals; an operating platform is arranged between the adjacent eye embroidering machine bodies, a notch is formed in the outer edge of the operating platform, an operating plate is pivoted on one side edge of the notch, the surface of the operating plate is parallel to the table surface of the operating platform, and a driving mechanism connected to the operating plate is arranged at the bottom of the operating platform to control the operating plate to turn downwards.

By adopting the scheme, the plurality of eye embroidering machine bodies can simultaneously embroider a plurality of clothes, so that the processing efficiency is improved. In order to ensure that a plurality of clothes can be simultaneously accommodated in the processing station of the eye embroidery machine, the table top of the operating table is arranged to be spacious, so that the outer side edge of the operating table is far away from the processing position of the eye embroidery machine, and troubles are brought to overhaul equipment for people. Through set up the breach on the operation panel, can let people be close to the equipment principal who is located the intermediate position when overhauing equipment to promote the maintenance convenience. After the maintenance is finished, the board surface of the operation board is enabled to be parallel to the table surface of the operation table again through the driving mechanism, so that the normal function of the operation table can be restored, and the operation table is more humanized.

Preferably, the operating panel is pivotally connected to the edge of the notch by a hinge.

By adopting the scheme, the hinge is simple in structure, convenient to install and low in maintenance cost, and the operating plate can be stably turned over at one side edge of the notch.

Preferably, the driving mechanism includes a first driving block, a second driving block, and a driving source; the first driving block is arranged on the lower plate surface of the operating plate, the second driving block is arranged below the operating table, and the driving source is arranged below the operating table to control the first driving block and the second driving block to be close to or far away from each other.

By adopting the scheme, the driving source is controlled to be close to and far away from the first driving block and the second driving block, the state of the operating panel can be effectively converted, and the operating efficiency is improved.

Preferably, the driving source is an air cylinder, a piston rod of the air cylinder is pivoted to the first driving block, and a cylinder barrel of the air cylinder is pivoted to the second driving block.

By adopting the scheme, the cylinder is simple in structure, convenient to install, rapid in action and low in maintenance cost, and the second driving block can be used as the supporting point to push the first driving block away or pull the first driving block close, so that the state of the operating board is changed, and the action is more efficient.

Preferably, a lock mechanism supporting the operation panel is provided at the bottom of the operation table so that the panel surface of the operation panel is parallel to the top surface of the operation table.

By adopting the scheme, when the surface of the operating board is parallel to the table surface of the operating table, the locking mechanism can support the lower board surface of the operating board, so that the stability of the operating board is ensured, and articles can be placed on the operating board conveniently.

Preferably, the locking mechanism includes a lock tongue and a power source, the lock tongue is disposed below the operating table and supported on the lower plate surface of the operating plate, and the power source is connected to the lock tongue to drive the lock tongue to be attached to or away from the lower plate surface of the operating plate along the plate surface direction of the operating plate.

By adopting the scheme, the power source can drive the lock tongue to stretch and translate below the operating platform and the operating board, so that the operating board is locked or unlocked.

Preferably, the power supply is the cylinder, and the cylinder sets up in the bottom of operation panel, and its telescopic link is connected in the spring bolt in order to drive the spring bolt and carry out reciprocal linear motion.

By adopting the scheme, the cylinder is simple in structure, convenient to install, rapid in action and low in maintenance cost, and can efficiently drive the lock tongue to perform reciprocating linear motion so as to lock or unlock the operating panel.

Preferably, the bottom of operation panel is and install the guide block in being close to the breach position, and the guide block runs through to have the guiding hole that supplies the spring bolt to slide and wear to establish.

By adopting the scheme, the guide hole in the guide block can limit the spring bolt, and the spring bolt is prevented from shaking left and right in the telescopic process, so that the stability and the telescopic efficiency of the spring bolt are improved.

The utility model discloses owing to adopted above technical scheme, have apparent technological effect: the plurality of embroidering machine bodies can simultaneously embroider a plurality of clothes, so that the processing efficiency is improved. In order to ensure that a plurality of clothes can be simultaneously accommodated in the processing station of the eye embroidery machine, the table top of the operating table is arranged to be spacious, so that the outer side edge of the operating table is far away from the processing position of the eye embroidery machine, and troubles are brought to overhaul equipment for people. Through set up the breach on the operation panel, can let people be close to the equipment main part that is located the intermediate position when overhauing equipment to promote the maintenance convenience. After the maintenance is finished, the board surface of the operating board is enabled to be parallel to the table board of the operating table again through the driving mechanism, so that the operating table can recover the normal function, and the operation is more humanized.

Drawings

FIG. 1 is a first schematic structural diagram of the present embodiment;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a second schematic structural diagram of the present embodiment;

FIG. 4 is an enlarged view of portion B of FIG. 3;

FIG. 5 is an enlarged view of section C of FIG. 4;

FIG. 6 is a third schematic structural diagram of the present embodiment;

FIG. 7 is an enlarged view of portion D of FIG. 6;

FIG. 8 is a fourth schematic structural diagram of the present embodiment;

FIG. 9 is an enlarged view of section E of FIG. 8;

FIG. 10 is an enlarged view of portion F of FIG. 9;

FIG. 11 is a fifth schematic structural view of the present embodiment;

fig. 12 is an enlarged schematic view of the portion G shown in fig. 11.

The names of the parts indicated by the numerical references in the above figures are as follows: 1. an embroidery machine body; 2. an operation table; 3. a notch; 4. an operation panel; 5. a hinge; 6. a first driving block; 7. a second driving block; 8. a drive source; 9. a piston rod; 11. a latch bolt; 12. a power source; 13. a telescopic rod; 14. a guide block; 15. a guide hole; 16. a first hinge; 17. a second hinge; 18. a mounting frame; 19. a feeding mechanism; 20. a material moving mechanism; 21. an eye embroidering mechanism; 22. a discharging mechanism; 23. positioning pins; 24. a power plant; 25. a positioning mechanism; 26. a discharge hole; 27. pressing a plate; 28. and a pressing mechanism.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

As shown in fig. 1 to 4, the multi-station eye embroidering machine disclosed in this embodiment includes a plurality of eye embroidering machine bodies 1, and the plurality of eye embroidering machine bodies 1 are arranged at intervals. In this embodiment, the eye embroidery machine body 1 preferably has three, so that three pieces of clothes can be simultaneously processed, and the working efficiency is improved. An operation table 2 is arranged between the adjacent eye embroidery machine bodies 1, a notch 3 is arranged at the outer edge of the operation table 2, the notch 3 is preferably rectangular, and the size of the notch 3 is designed to accommodate the transverse width of an adult and is not limited in detail. An operation plate 4 is pivoted to one side edge of the notch 3, in this embodiment, the operation plate 4 is pivoted to the edge of the notch 3 by a hinge 5, and the hinge 5 is preferably fixed below the operation plate 4 and the operation table 2 by a screw (not shown). The operating plate 4 is also rectangular to accommodate the shape of the notch 3. An interval is kept between the edge of the operating plate 4 and the edge of the notch 3, so that the movement of the operating plate 4 in the notch 3 is not easily limited. The surface of the operation panel 4 is parallel to the surface of the operation table 2, and the bottom of the operation table 2 is provided with a driving mechanism connected to the operation panel 4 to control the operation panel 4 to turn down. The driving mechanism comprises a first driving block 6, a second driving block 7 and a driving source 8; the first driving block 6 is provided on the lower plate surface of the operation plate 4, and is fixed to the operation plate 4 by screws (not shown).

The second driving block 7 is provided below the console 2, and is fixed to the console 2 by screws (not shown). The driving source 8 is disposed below the console 2 to control the first driving block 6 to approach or separate from the second driving block 7.

Further, as shown in fig. 6 and 7, the driving source 8 is a cylinder, a piston rod 9 of the cylinder is pivoted to the first driving block 6 through a first hinge 16, and a cylinder barrel of the cylinder is pivoted to the second driving block 7 through a second hinge 17. The bottom of the console 2 is provided with a mounting frame 18, and the second driving block 7 is fixed to the mounting frame 18 by screws (not shown) or welding, so that one end of the driving source 8 close to the second driving block 7 can keep a certain distance from the bottom of the console 2, and the driving source 8 can be flexibly positioned between the driving plate and the console during operation.

Further, as shown in fig. 5, the bottom of the operation table 2 is provided with a locking mechanism supporting the operation plate 4 so that the plate surface of the operation plate 4 is parallel to the top surface of the operation table 2. The locking mechanism includes spring bolt 11 and power supply 12, and spring bolt 11 sets up in the below of operation panel 2 and supports in the lower face of operation panel 4, and power supply 12 connects in spring bolt 11 with the laminating of the face direction of drive spring bolt 11 along operation panel 4 or keep away from the lower face of operation panel 4. In this embodiment, the power source 12 is a cylinder, the cylinder is disposed at the bottom of the operating platform 2, and the telescopic rod 13 is connected to the latch bolt 11 to drive the latch bolt 11 to perform reciprocating linear motion. A guide block 14 is installed at the bottom of the operating platform 2 and at a position close to the notch 3, and the guide block 14 is in a long square block shape and is arranged along the extension direction perpendicular to the bolt 11. Both ends of the guide block 14 are fixed to the bottom of the console 2 by screws (not shown). A guide hole 15 for the bolt 11 to slide through is formed through the side wall of the guide block 14, and the guide hole 15 is square and has a size equal to or slightly larger than the cross-sectional size of the bolt 11. The bolt 11 can be guaranteed to slide smoothly in the guide block 14, and the stability of the bolt 11 during sliding can be guaranteed.

The specific working process is as follows:

when people need to overhaul the eye embroidery machine body 1, the telescopic rod 13 of the power source 12 can be controlled to contract first, so that the bolt 11 is separated from the lower plate surface of the operating plate 4, and the locking of the operating plate 4 is released. The piston rod 9 of the drive source 8 is then controlled to retract to draw the first drive block 6 towards the second drive block 7, thereby driving the operating plate 4 to flip down to open the notch 3. When the gap 3 is completely opened, people can enter the gap 3 to repair the equipment.

After the equipment is repaired, the piston rod 9 of the driving source 8 is controlled to extend outwards to push the first driving block 6 towards the direction far away from the second driving block 7, so that the operating board 4 is driven to turn upwards until the board surface of the operating board 4 is parallel to the table surface of the operating table 2, and the notch 3 can be completely closed. Then, the telescopic rod 13 controlling the power source 12 is pushed outward so that the latch 11 can be translated to the lower plate surface of the operation plate 4 along the guide hole 15 on the guide block 14, thereby locking the operation plate 4 so that the operation plate 4 can be normally used. In this embodiment, the control of the driving source 8 and the power source 12 can be realized by a single chip, a PLC, or an equivalent circuit, which belongs to the common knowledge in the art and is not described herein.

Further, as shown in fig. 8 to 12, each of the eye embroidery machines includes a feeding mechanism 19, a moving mechanism 20, an eye embroidery mechanism 21, and a discharging mechanism 22. The feeding mechanism 19 comprises a positioning pin 23 sliding through the operating table 2, a power device 24 for driving the positioning pin 23 to stretch and retract, and a positioning mechanism 25 for positioning the cloth. The discharging mechanism 22 includes a discharging hole 26 penetrating the operation table 2, a pressing plate 27 adapted to the shape of the discharging hole 26, and a pressing mechanism 28 for driving the pressing plate 27 to press the cloth to the lower side of the operation table 2.

The specific operation process is as follows:

an operator firstly places the cloth on the operation table 2, so that the power device 24 drives the positioning pin 23 to extend out of the table top of the operation table 2 and insert into an embroidery hole of the cloth, and meanwhile, the positioning mechanism 25 compresses the cloth, thereby completing the positioning of the cloth. After the positioning is completed, the feeding mechanism 19 moves the cloth to the area to be processed. Then move material mechanism 20 and shift the cloth that waits to process the region to embroidery eye mechanism 21 below, embroidery eye mechanism 21 moves down and accomplishes the embroidery eye after, move material mechanism 20 and just can shift the cloth to the ejection of compact region for the cloth is located discharge opening 26 top, and last hold-down mechanism 28 drive clamp plate 27 moves down, pushes down the cloth that finishes to the discharge opening 26 below to accomplish the ejection of compact.

The positions of the feeding mechanism 19, the material moving mechanism 20, the eye embroidering mechanism 21 and the discharging mechanism 22 can be adjusted according to actual conditions, so that the occupied space of the single eye embroidering machine body 1 is reduced, and the machine is more humanized.

Claims (8)

1. The utility model provides a multistation embroidery eye machine, includes embroidery eye machine body (1), its characterized in that: a plurality of eye embroidering machine bodies (1) are arranged, and the eye embroidering machine bodies (1) are arranged at intervals; an operation table (2) is arranged between the adjacent eye embroidery machine bodies (1), a notch (3) is formed in the outer edge of the operation table (2), an operation plate (4) is pivoted on one side edge of the notch (3), the surface of the operation plate (4) is parallel to the table top of the operation table (2), and a driving mechanism connected to the operation plate (4) is arranged at the bottom of the operation table (2) to control the operation plate (4) to turn downwards.

2. The multi-station embroidery eye machine of claim 1, wherein: the operating plate (4) is pivoted to the edge of the gap (3) through a hinge (5).

3. The multi-station embroidery eye machine of claim 1, wherein: the driving mechanism comprises a first driving block (6), a second driving block (7) and a driving source (8); the first driving block (6) is arranged on the lower plate surface of the operating plate (4), the second driving block (7) is arranged below the operating table (2), and the driving source (8) is arranged below the operating table (2) so as to control the first driving block (6) and the second driving block (7) to be close to or far away from each other.

4. The multi-station eyelet machine according to claim 3, characterized in that: the driving source (8) is an air cylinder, a piston rod (9) of the air cylinder is pivoted on the first driving block (6), and a cylinder barrel of the air cylinder is pivoted on the second driving block (7).

5. The multi-station eyelet machine according to any one of claims 1 to 4, wherein: the bottom of the operating platform (2) is provided with a locking mechanism which is supported on the operating plate (4) so that the surface of the operating plate (4) is parallel to the surface of the operating platform (2).

6. The multi-station embroidery eye machine of claim 5, wherein: the locking mechanism comprises a lock tongue (11) and a power source (12), the lock tongue (11) is arranged below the operating platform (2) and supported on the lower plate surface of the operating plate (4), and the power source (12) is connected to the lock tongue (11) to drive the lock tongue (11) to be attached to or away from the lower plate surface of the operating plate (4) along the plate surface direction of the operating plate (4).

7. The multi-station embroidery eye machine of claim 6, wherein: the power source (12) is a cylinder which is arranged at the bottom of the operating platform (2), and a telescopic rod (13) of the cylinder is connected with the bolt (11) to drive the bolt (11) to do reciprocating linear motion.

8. The multi-station embroidery eye machine of claim 6, wherein: the bottom of operation panel (2) and in being close to breach (3) position and install guide block (14), guide block (14) run through have supply spring bolt (11) to slide guide hole (15) of wearing to establish.

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