CN216237612U - Collar transporting equipment - Google Patents

Abstract

The utility model provides a collar transporting device, which comprises: the machine table is provided with a material placing area for placing the collar cut pieces; the auxiliary collar transporting device is arranged on the machine table and comprises a first arch-position cushion block and a second arch-position cushion block, the first arch-position cushion block is used for extending into one end of the two superposed collar cut pieces to form an arch position, and the second arch-position cushion block is used for extending into the other end of the two superposed collar cut pieces to form an arch position; the pressing device is arranged on the machine table and provided with a pressing die assembly, and the pressing die assembly is located above the material placing area and can stretch out and draw back to press the collar cutting pieces. According to the collar transporting device, the two arch position cushion blocks in the auxiliary collar transporting device can form arch positions at the two ends of the collar cut pieces, the cut piece arch positions do not need to be manually placed, the collar flying prevention effect can be achieved, collar transporting operation is simplified, collar transporting work efficiency is improved, and manual labor intensity is reduced.

Description

Collar transporting equipment

Technical Field

The utility model relates to the technical field of textile machinery, in particular to a collar conveying device.

Background

In the production process of the woven shirt, a collar transporting procedure is required. Two superimposed panels are sewn together to form the basic shape of a collar, known as a carrier collar. The flying collar prevention effect means that the two cut pieces before collar transportation have size difference, then the two sides of the two cut pieces need to be aligned during sewing, and the size difference part forms an arch position in the middle of the cut pieces after sewing is completed.

In the traditional collar transporting equipment, the two cut pieces need to be manually placed out in advance, then the two cut pieces are pressed by matching with a pressing device, and then sewing operation is carried out. The process of manually placing the cut piece arch position wastes time, and has troublesome operation and higher labor intensity. In addition, the pressing device in the traditional transportation and collection equipment cannot conveniently adjust the pressing angle, and the work efficiency of transportation and collection is seriously affected.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a fortune to lead equipment to need artifical manual putting cut-parts to encircle the position to traditional fortune to lead equipment, and the troublesome poeration is time-consuming, and artifical intensity of labour is big problem.

In order to solve the above problems, the present invention provides a collaring apparatus comprising:

the machine table is provided with a material placing area for placing the collar cutting pieces;

the auxiliary collar transporting device is arranged on the machine table and comprises a first arch-position cushion block and a second arch-position cushion block, the first arch-position cushion block is used for extending into one end of the two superposed collar cut pieces to form an arch position, and the second arch-position cushion block is used for extending into the other end of the two superposed collar cut pieces to form an arch position; and

the pressing device is arranged on the machine table and provided with a pressing die assembly, and the pressing die assembly is located above the material placing area and can stretch out and draw back to press the collar cutting pieces.

In some of these embodiments, the supplemental recited device comprises:

a base plate;

the first telescopic driving mechanism is arranged on the bottom plate;

the first arch position cushion block is connected with the output end of the first telescopic driving mechanism;

the second telescopic driving mechanism is arranged on the bottom plate and is arranged in parallel with the first telescopic driving mechanism; and

and the second arch position cushion block is connected with the output end of the second telescopic driving mechanism.

In some of these embodiments, the supplemental exercise device further comprises:

the first transverse guide rail is arranged on the bottom plate, and the first telescopic driving mechanism and the second telescopic driving mechanism are slidably arranged on the first transverse guide rail.

In some of these embodiments, the auxiliary collar device further comprises a slip drive mechanism, the slip drive mechanism comprising:

the mounting seat is arranged on the bottom plate;

the first telescopic driving mechanism and the second telescopic driving mechanism are both arranged on the sliding driving screw rod in a sliding way; and

and the output end of the sliding driving motor is connected with the sliding driving screw rod so as to drive the sliding driving screw rod to rotate.

In some of these embodiments, the slip drive screw comprises:

a first screw section on which the first telescopic drive mechanism is slidably mounted;

and the second screw rod section is connected with the first screw rod section, the second telescopic driving mechanism can be slidably arranged on the second screw rod section, and the spiral direction of the threads of the second screw rod section is opposite to that of the threads of the first screw rod section.

In some embodiments, the first arch cushion block is movably mounted at the output end of the first telescopic driving mechanism, and the mounting height of the first arch cushion block is adjustable; and/or

The second arch position cushion block is movably arranged at the output end of the second telescopic driving mechanism, and the installation height of the second arch position cushion block is adjustable.

In some of these embodiments, the pressing device comprises:

the base is arranged above the machine table;

the fixed pressing die is arranged on the base; and

the movable pressing dies are arranged on the base and are respectively positioned on two sides of the fixed pressing die, a first pressing die seat is arranged in each movable pressing die, a movable pressing block is hinged to the first pressing die seat, and the movable pressing block can horizontally rotate relative to the first pressing die seat to adjust the pressing angle of the movable pressing block.

In some of these embodiments, the movable die comprises:

the first die holder;

one end of the movable pressing block is hinged to the first pressing die seat;

one end of the connecting piece is hinged with the movable pressing block;

and the output end of the pressing block rotation driving mechanism is connected with the other end of the connecting piece so as to drive the connecting piece to move and further drive the movable pressing block to rotate around a hinge joint with the first pressing die holder.

In some embodiments, a linear guide rail is mounted on the first die holder, a first sliding block is slidably disposed on the linear guide rail, and the connecting piece is fixed on the first sliding block; the movable pressing block is provided with a kidney-shaped groove, and the hinged joint of the connecting piece and the movable pressing block is positioned in the kidney-shaped groove and can slide along the kidney-shaped groove.

In some embodiments, the movable pressing die further comprises a first vertical guide rail and a first die-starting driving mechanism, wherein a second sliding block is slidably mounted on the first vertical guide rail, the first pressing die holder is fixed on the second sliding block, and the second sliding block is connected with the output end of the first die-starting driving mechanism.

In some embodiments, a second transverse guide rail is mounted on the base, a third slider is slidably mounted on the second transverse guide rail, the movable die is mounted on the third slider, and a movable die sliding driving mechanism for driving the third slider to slide along the second transverse guide rail is further arranged on the base.

In some of these embodiments, the movable die slide drive mechanism comprises:

the two ends of the movable pressing die sliding screw rod are rotatably arranged on the base;

the connecting plate is slidably arranged on the movable pressing die sliding screw rod and is connected with the third sliding block;

and the output end of the movable pressing die slippage driving motor is connected with the movable pressing die slippage screw rod so as to drive the movable pressing die slippage screw rod to rotate.

In some embodiments, the movable die sliding screw comprises a third screw rod section and a fourth screw rod section which are connected with each other, the spiral directions of the threads on the third screw rod section and the fourth screw rod section are opposite, and the movable dies on two sides of the fixed die are respectively connected with the third screw rod section and the fourth screw rod section through a connecting plate.

In some of these embodiments, the stationary die comprises:

a second die holder;

the fixed pressing block is arranged on the second pressing die holder;

a second vertical guide rail;

the fourth sliding block is slidably arranged on the second vertical guide rail, and the second die holder is fixedly arranged on the fourth sliding block;

and the output end of the second stripping driving mechanism is connected with the fourth sliding block so as to drive the fourth sliding block to slide along the second vertical guide rail.

Compared with the prior art, the utility model has the following beneficial effects:

according to the collar transporting equipment, the auxiliary collar transporting device is arranged on the machine table, the auxiliary collar transporting device is provided with the first arch-position cushion block and the second arch-position cushion block, the first arch-position cushion block and the second arch-position cushion block can extend into a space between two superposed collar cut pieces, and two arch positions are formed at two ends of the collar cut pieces; in the collar transporting process of the shirt, two arch position cushion blocks in the auxiliary collar transporting device can extend out, two arch positions are formed at two ends of a collar cutting piece, the cutting piece arch positions do not need to be manually placed and released, the collar flying preventing effect can be achieved, collar transporting operation is simplified, collar transporting work efficiency is improved, and manual labor intensity is reduced.

In addition, the collar transporting equipment can conveniently adjust the material pressing angle through the movable pressing dies in the material pressing device, and can quickly adjust the distance between the two movable pressing dies to adapt to collar cutting pieces of different styles, so that the money transferring efficiency and the production efficiency of the collar transporting equipment are improved.

Drawings

Fig. 1 is a schematic structural view of a collar transporting apparatus according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an auxiliary collar transport device in the collar transport apparatus according to an embodiment of the present invention.

Fig. 3 is a schematic structural view of a pressing device in the neckline apparatus according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a movable die in the neckline apparatus according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a fixed die in the neckline apparatus according to an embodiment of the present invention.

Description of reference numerals:

10. a machine platform; 11. a material placing area;

20. an auxiliary collar conveying device; 21. a base plate; 22. a first telescopic driving mechanism; 23. a first arch positioning cushion block; 24. a second telescopic driving mechanism; 25. a second arch position cushion block; 26. a first transverse guide rail; 27. a slip drive mechanism; 271. a mounting seat; 272. a sliding driving screw rod; 273. a slip drive motor; 272a, a first screw rod segment; 272b, a second screw rod segment;

30. a pressing device; 31. a base; 32. fixing the pressing die; 33. a movable pressing die; 311. a second transverse guide rail; 312. a third slider; 313. a movable pressing die slides a screw rod; 314. a connecting plate; 315. the movable pressing die slides to drive the motor; 313a, a third screw rod section; 313b, a fourth screw rod section; 321. a second die holder; 322. fixing a pressing block; 323. a second vertical guide rail; 324. a fourth slider; 325. a second stripping drive mechanism; 331. a first die holder; 332. a movable pressing block; 333. a connecting member; 334. a press block rotation driving mechanism; 335. a first vertical guide rail; 336. a second slider; 337. a first mold-starting drive mechanism; 3311. a linear guide rail; 3312. a first slider; 3321. a kidney-shaped groove.

Detailed Description

The present invention will be described in detail with reference to the following embodiments in order to make the aforementioned objects, features and advantages of the utility model more comprehensible. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

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 utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. 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, an embodiment of the present invention provides a collar transporting apparatus, which includes a machine station 10, an auxiliary collar transporting device 20, and a pressing device 30. Wherein, a material placing area 11 for placing a collar cutting piece (not shown in the figure) is arranged on the machine table 10; the auxiliary collar transporting device 20 is arranged on the machine table 10, the auxiliary collar transporting device 20 comprises a first arching cushion block 23 and a second arching cushion block 25, the first arching cushion block 23 is used for extending into one end of two superposed collar cut pieces to form an arching position, and the second arching cushion block 25 is used for extending into the other end of the two superposed collar cut pieces to form an arching position; the pressing device 30 is disposed on the machine table 10, and the pressing device 30 has a pressing module therein, which is located above the material placing area 11 and can be extended and retracted to press the cut-parts of the collar.

In the collar transporting equipment, the auxiliary collar transporting device 20 is arranged on the machine table 10, the auxiliary collar transporting device 20 is internally provided with the first arch-position cushion block 23 and the second arch-position cushion block 25, the first arch-position cushion block 23 and the second arch-position cushion block 25 can extend into the space between two superposed collar cut pieces, and two arch positions are formed at two ends of the collar cut pieces; in the process of transporting the collar of the shirt, a first arch position cushion block 23 and a second arch position cushion block 25 in the auxiliary collar transporting device 20 can extend out, and an arch position is formed between two cut pieces; then, the cut pieces are pressed by the pressing device 30, and then the sewing operation is performed. This supplementary fortune is led device 20 need not artifical manual putting out cut-parts and encircles the position when carrying out the fortune neck, plays and prevents flying to lead the effect, has simplified fortune neck operation, has improved fortune neck work efficiency to artifical intensity of labour has been reduced.

Referring to fig. 2, in one embodiment, the auxiliary collar transporting device 20 includes a bottom plate 21, a first telescopic driving mechanism 22, a first arch pad 23, a second telescopic driving mechanism 24, and a second arch pad 25. Wherein, the bottom plate 21 is arranged at one side of the material placing area 11 of the machine table 10; the first telescopic driving mechanism 22 is arranged on the bottom plate 21; the first arch position cushion block 23 is connected with the output end of the first telescopic driving mechanism 22; a second telescopic driving mechanism 24 is also arranged on the bottom plate 21, and the second telescopic driving mechanism 24 and the first telescopic driving mechanism 22 are arranged in parallel; the second arch position cushion block 25 is connected with the output end of the second telescopic driving mechanism 24.

In the collar transporting process of the shirt, the first arch position cushion block 23 and the second arch position cushion block 25 can be respectively driven to extend out through the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24, so that the first arch position cushion block 23 extends into two cut pieces at one end of a collar of the shirt (the collar of the shirt comprises two ends which are respectively positioned at the left side and the right side of a neckline) to form an arch position, the second arch position cushion block 25 extends into the space between the two cut pieces at the other end of the collar of the shirt to form the arch position, thus forming an arch position at the two ends of the collar of the shirt respectively, aligning the two sides of the two cut pieces, and facilitating sewing operation; after the sewing is finished, the first arch cushion block 23 and the second arch cushion block 25 are respectively driven to retract by the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24.

It will be appreciated that since the ends of the shirt collar are juxtaposed, the first and second crown blocks 23, 25 should also be juxtaposed with the first and second crown blocks 23, 25 oriented in the same direction so that the first and second crown blocks 23, 25 can correspond to the ends of the shirt collar.

In the actual production process, due to shirts of different styles or different sizes, the distance between the two ends of the collar may be different; therefore, it is often necessary to adapt the distance between the first and second bump blocks 23, 25 in the auxiliary collar device 20. In order to solve the above problem, in one embodiment of the present invention, the auxiliary collar device 20 further includes a first cross rail 26, the first cross rail 26 is disposed on the bottom plate 21, and the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 are slidably disposed on the first cross rail 26.

By arranging the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 on the first transverse guide rail 26 in a sliding manner, when carrying out collar operation on shirts of different styles or sizes, the distance between the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24, namely the distance between the first arch position cushion block 23 and the second arch position cushion block 25, can be conveniently adjusted according to the distance between the two ends of the collar, so as to adapt to the collar operation requirements of shirts of different styles or sizes.

It can be understood that when the distance between the two ends of the collar is larger, the first telescopic driving mechanism 22 and/or the second telescopic driving mechanism 24 can slide along the first transverse guide rail 26, so as to increase the distance between the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24, and further increase the distance between the first arch cushion block 23 and the second arch cushion block 25; when the distance between the two ends of the collar is smaller, the first telescopic driving mechanism 22 and/or the second telescopic driving mechanism 24 can also slide along the first transverse guide rail 26, so that the distance between the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 is reduced, and further the distance between the first arch cushion block 23 and the second arch cushion block 25 is reduced. In addition, when the placing position of the collar cut piece on the collar transporting equipment is changed, the positions of the first arching cushion block 23 and the second arching cushion block 25 relative to the cut piece can be adjusted through the first transverse guide rail 26, so that the first arching cushion block 23 and the second arching cushion block 25 are respectively aligned with the two ends of the collar.

It should be noted that the first telescopic driving mechanism 20 and the second telescopic driving mechanism 40 are slidably disposed on the first transverse rail 26, specifically, two sliders may be slidably disposed on the first transverse rail 26, and the first telescopic driving mechanism 20 and the second telescopic driving mechanism 40 are respectively mounted on the corresponding sliders.

In one embodiment of the present invention, the auxiliary collar device 20 further comprises a sliding driving mechanism 27, and the sliding driving mechanism 27 is connected to the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 for driving the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 to slide along the first transverse rail 26. Specifically, the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 can be respectively driven to slide along the first transverse guide rail 26 by the sliding driving mechanism 27, so that the manual adjusting process is replaced, and the manual labor intensity is reduced.

In the present embodiment, the sliding driving mechanism 27 specifically includes a mounting seat 271, a sliding driving screw 272, and a sliding driving motor 273. Wherein, the mounting seat 271 is fixedly mounted on the bottom plate 21; both ends of the sliding driving screw 272 are rotatably mounted on the mounting base 271, and the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 are slidably mounted on the sliding driving screw 272; the output end of the sliding driving motor 273 is connected to the sliding driving screw 272, and is used for driving the sliding driving screw 272 to rotate, so as to drive the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 to move along the sliding driving screw 272 and the first transverse guide rail 26, and adjust the distance between the first arch cushion block 23 and the second arch cushion block 25.

Specifically, the output end of the sliding driving motor 273 may be connected to the sliding driving screw 272 through a belt wheel transmission mechanism or a sprocket transmission mechanism.

Further, in the present embodiment, the sliding driving screw 272 is a bidirectional screw including a first screw segment 272a and a second screw segment 272 b. Wherein the first screw section 272a is connected to the second screw section 272b, the first telescopic driving mechanism 22 is slidably mounted on the first screw section 272a, the second telescopic driving mechanism 24 is slidably mounted on the second screw section 272b, and the second screw section 272b is opposite to the spiral direction of the first screw section 272 a.

By adopting the above-mentioned bidirectional screw rod as the sliding driving screw rod 272, and slidably mounting the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 on the first screw rod section 272a and the second screw rod section 272b, respectively, the first screw rod section 272a and the second screw rod section 272b can be driven to rotate simultaneously by the sliding driving motor 273; because the sliding driving screw 272 is a bidirectional screw, the screw direction of the second screw segment 272b is opposite to that of the first screw segment 272a, and the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 move in opposite directions, the distance between the first arch cushion block 23 and the second arch cushion block 25 can be conveniently adjusted.

It can be understood that when the distance between the first arch cushion block 23 and the second arch cushion block 25 needs to be adjusted, the distance between the first arch cushion block 23 and the second arch cushion block 25 can be reduced only by driving the sliding driving screw 272 to rotate through the sliding driving motor 273, so that the first arch cushion block 23 and the second arch cushion block 25 move in opposite directions; when the distance between the first arch position cushion block 23 and the second arch position cushion block 25 needs to be enlarged, the sliding driving screw 272 is driven to rotate only by the sliding driving motor 273, so that the first arch position cushion block 23 and the second arch position cushion block 25 move reversely, and the operation is very convenient.

Specifically, a nut is disposed on the first telescopic driving mechanism 22, the nut is sleeved on the first screw rod segment 272a and is connected with the first screw rod segment 272a in a threaded fit manner, the nut and the first screw rod segment 272a form a screw nut pair, and the nut and the first telescopic driving mechanism 22 are driven to move linearly along the first screw rod segment 272a by the rotation of the first screw rod segment 272 a. Similarly, a nut is also disposed on the second telescopic driving mechanism 24, the nut is sleeved on the second screw rod segment 272b and is connected with the second screw rod segment 272b in a threaded fit manner, the nut and the second screw rod segment 272b form a screw nut pair, and the nut and the second telescopic driving mechanism 24 are driven to move linearly along the second screw rod segment 272b together through the rotation of the second screw rod segment 272 b.

In one embodiment, the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 are both air cylinders, and the first arch pad 23 and the second arch pad 25 are respectively mounted on piston rods of the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24. The first arch position cushion block 23 and the second arch position cushion block 25 can be driven to extend or retract through the extension and retraction of the piston rods of the air cylinders. In addition, the first telescopic drive mechanism 22 and the second telescopic drive mechanism 24 may be configured by other drive mechanisms such as a hydraulic cylinder.

In one embodiment of the present invention, the first arching pad 23 of the auxiliary collar transport device 20 is movably mounted at the output end of the first telescopic driving mechanism 22, and the mounting height of the first arching pad 23 is adjustable; similarly, a second arch position cushion block 25 is movably arranged at the output end of the second telescopic driving mechanism 24, and the installation height of the second arch position cushion block 25 is adjustable. Thus, by adjusting the installation heights of the first and second arch spacers 23 and 25, the heights of the first and second arch spacers 23 and 25 can better correspond to the heights of the two ends of the collar of the shirt.

Specifically, in this embodiment, a first kidney-shaped mounting hole (not shown) is vertically formed in the first arch pad 23, the first arch pad 23 is connected to the output end of the first telescopic driving mechanism 22 through a connecting bolt inserted into the first kidney-shaped mounting hole, and the first arch pad 23 is fixedly mounted at the output end of the first telescopic driving mechanism 22 through a nut. When the installation height of the first arch position cushion block 23 needs to be adjusted, the nut is loosened firstly, so that the connecting bolt moves up and down in the first kidney-shaped installation hole to a proper position, and then the nut is screwed for fixing.

Similarly, a second kidney-shaped mounting hole (not shown) is vertically formed in the second arch position cushion block 25, the second arch position cushion block 25 is connected to the output end of the second telescopic driving mechanism 24 through a connecting bolt inserted into the second kidney-shaped mounting hole, and the second arch position cushion block 25 is fixedly mounted at the output end of the second telescopic driving mechanism 24 through a nut. When the mounting height of the second arch position cushion block 25 needs to be adjusted, the nut is loosened firstly to enable the connecting bolt to move up and down to a proper position in the second kidney-shaped mounting hole, and then the nut is screwed to fix the connecting bolt.

It should be noted that, in addition to the height adjustment method of providing the kidney-shaped mounting holes in the vertical direction on the first arch spacer 23 and the second arch spacer 25, the specific structure of the height adjustment may also adopt other similar forms. For example, a plurality of mounting holes may be formed in the first arch spacer 23 and the second arch spacer 25 at intervals in the vertical direction, and the mounting heights of the first arch spacer 23 and the second arch spacer 25 may be adjusted by inserting the connecting bolts into the mounting holes having different heights, respectively; it is also possible to provide a mounting plate at the output of the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24, and to provide a waist-shaped mounting hole or a plurality of mounting holes at intervals on the mounting plate in the vertical direction, i.e. to provide the height adjustment structure on the mounting plate on one side of the telescopic driving mechanism.

In one embodiment, the first arching pad 23 and the second arching pad 25 are both L-shaped, and include a vertical plate and a horizontal plate connected to each other, wherein the vertical plate is connected to the output ends of the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24, and the horizontal plate is used for extending into the space between the two cut pieces to form an arching. The waist-shaped mounting hole is arranged on the vertical plate.

It should be noted that the horizontal plate may be in various shapes such as rectangle, trapezoid, triangle, etc., and specifically, the length, width and specific shape of the horizontal plate in the first arch pad 23 and the second arch pad 25 may be selected according to actual needs. In addition, the first arching cushion block 23 and the second arching cushion block 25 may not adopt the L-shaped structure, and only need to be connected with the output ends of the first telescopic driving mechanism 22 and the second telescopic driving mechanism 24 and extend into the space between the two cut pieces to form the arching position.

Referring to fig. 3, in one embodiment, the pressing device 30 includes a base 31, a fixed die 32 and two movable dies 33. Wherein, the base 31 is disposed above the machine 10; the fixed die 32 is fixedly mounted on the base 31; the movable pressing dies 33 are movably mounted on the base 31, the two movable pressing dies 33 are respectively located on two sides of the fixed pressing die 32, a first pressing die holder 331 is arranged in the movable pressing dies 33, a movable pressing block 332 is hinged to the first pressing die holder 331, and the movable pressing block 332 can horizontally rotate relative to the first pressing die holder 331 to adjust a pressing angle of the movable pressing block 332. The fixed die 32 and the movable die 33 together constitute a die assembly.

In the pressing device 30 of the present invention, the movable pressing dies 33 are mounted on both sides of the fixed pressing die 32, and the pressing angles on both sides of the pressing device 30 can be conveniently adjusted by the movable pressing dies 33 on both sides. The pressing angle of the movable pressing blocks 332 in the movable pressing dies 33 on the two sides is adjusted, so that the pressing device 30 can well adapt to the pressing requirements of different styles of shirt collars and different parts of the collars, the operation is convenient, the time and the labor are saved, and the money transfer and the production efficiency can be effectively improved.

Referring to fig. 4, in one embodiment, the movable die 33 includes a first die holder 331, a movable press block 332, a connecting member 333, and a press block rotation driving mechanism 334. Wherein, one end of the movable pressing block 332 is hinged on the first pressing die holder 331, and the other end is a free end; one end of the connecting piece 333 is hinged with the movable pressing block 332; the output end of the pressing block rotation driving mechanism 334 is connected to the other end of the connecting piece 333, and is used for driving the connecting piece 333 to move, so as to drive the movable pressing block 332 to rotate around the hinge point between the movable pressing block 332 and the first pressing die holder 331.

The movable pressing die 33 is provided with a movable pressing block 332 by hinging the movable pressing block 332 on the first pressing die holder 331, a pressing block rotation driving mechanism 334 is arranged, the output end of the pressing block rotation driving mechanism 334 is connected with the movable pressing block 332 by a connecting piece 333, and the connecting piece 333 is hinged with the movable pressing block 332; when the movable pressing die 33 is used, the pressing block rotation driving mechanism 334 can drive the connecting piece 333 to move, so as to drive the movable pressing block 332 to rotate around the hinged point of the movable pressing block and the first pressing die holder 331, and further adjust the pressing angle of the movable pressing block 332. This activity moulding-die 33 can conveniently adjust the pressure material angle of activity briquetting 332 to the material requirement of the pressure of adaptation different style clothes need not artifical manual regulation pressure material mould, and convenient operation has improved money transfer efficiency and production efficiency.

In one embodiment, the first die holder 331 has a linear guide 3311 mounted thereon, the linear guide 3311 is disposed along a horizontal direction, the linear guide 3311 has a first slide block 3312 slidably disposed thereon, and the connecting member 333 is fixedly mounted on the first slide block 3312. In the process that the press block rotation driving mechanism 334 drives the connecting piece 333 to move, the first slide block 3312 transversely slides along the linear guide 3311, and the rotation direction of the movable press block 332 can be limited by the linear guide 3311 and the first slide block 3312, so that the movable press block 332 swings in the horizontal direction, and the rotation levelness of the movable press block 332 and the stability of the movable press die 33 in adjusting the pressing angle are improved.

Further, in a specific example, the movable pressing block 332 is further provided with a kidney-shaped groove 3321, and the hinged connection of the connecting member 333 and the movable pressing block 332 is located in the kidney-shaped groove 3321 and can slide along the kidney-shaped groove 3321. Since the connecting member 333 moves horizontally under the constraint of the linear guide 3311 and the first slider 3312, by providing a slot 3321 on the movable pressing member 332 and slidably and hingedly mounting the connecting member 333 in the slot 3321, when the connecting member 333 moves horizontally, the hinge point between the connecting member 333 and the movable pressing member 332 can move back and forth in the slot 3321, so that the connecting member 333 drives the movable pressing member 332 to rotate more flexibly.

Further, in one specific example, a bearing is mounted on the first die holder 331, and the movable pressing block 332 is hingedly mounted on the first die holder 331 through the bearing. Thus, the movable pressing block 332 can rotate more smoothly relative to the first pressing base 331.

In one embodiment, the first die holder 331 is a sandwich structure, and the connecting member 333 is disposed in the sandwich gap of the first die holder 331. With the arrangement, in the process of horizontal movement of the connecting piece 333, the interlayer of the first die holder 331 can play a certain auxiliary guiding role for the connecting piece 333, so that the stability of the movable die 33 in adjusting the pressing angle of the movable pressing block 332 is further improved.

Specifically, the briquette turning driving mechanism 334 may adopt an existing driving structure such as a linear motor, an air cylinder, a hydraulic cylinder, or the like. Preferably, a linear motor is adopted, so that the digital control of the material pressing angle adjustment of the movable pressing block 332 is more conveniently realized.

In one embodiment of the present invention, the movable die 33 further includes a first vertical guide 335, a second slide 336, and a first die-driving mechanism 337. The second sliding block 336 is slidably mounted on the first vertical guide rail 335, and the first die holder 331 is fixedly mounted on the second sliding block 336; the output end of the first mold starting driving mechanism 337 is connected with the second slider 336; a first mold starter drive 337 is fixedly attached to the first vertical rail 335.

Through setting up foretell first vertical guide 335, second slider 336 and first die-casting actuating mechanism 337, when needs use this movable mould 33 to press the cut-parts, drive second slider 336 through first die-casting actuating mechanism 337 and move down along first vertical guide 335, and then drive first die holder 331 and the whole downstream of movable briquetting 332, push down the cut-parts through movable briquetting 332. When the movable pressing block 332 needs to be lifted after pressing is finished, the first stripping driving mechanism 337 drives the second sliding block 336 to move upwards along the first vertical guide rail 335, so as to drive the first pressing die holder 331 and the movable pressing block 332 to integrally move upwards, and the pressing operation is finished.

Specifically, in the present embodiment, the first mold opening driving mechanism 337 is a cylinder. In addition, a conventional driving mechanism such as a hydraulic cylinder or a motor may be used as the first mold-starting driving mechanism 337.

In one embodiment of the present invention, a second cross rail 311 is mounted on the base 31, a third slider 312 is slidably mounted on the second cross rail 311, and a first die driving mechanism 337 in the movable die 33 is fixedly mounted on the third slider 312. In this way, by horizontally moving the third slider 312 along the second cross rail 311, the movable die 33 can be horizontally moved as a whole along the second cross rail 311, thereby adjusting the distance of the movable die 33 with respect to the fixed die 32. The horizontal positions of the two movable pressing dies 33 are adjusted, and the distance between the two movable pressing dies 33 positioned at the two sides of the pressing device 30 is adjusted, so that the pressing device 30 can meet the pressing requirements of shirt collars of different styles.

Specifically, when the distance between the two ends of the collar of the shirt is large (the collar of the shirt is wide), the movable pressing die 33 can move outwards along the second transverse guide rail 311, that is, the distance between the two movable pressing dies 33 on the two sides of the pressing device 30 can be increased; when the distance between the two ends of the collar of the shirt is small (the collar of the shirt is narrow), the movable dies 33 can move inwards along the second transverse guide rails 311, and the distance between the two movable dies 33 on the two sides of the pressing device 30 can be reduced.

Further, in order to more conveniently adjust the horizontal positions of the two movable dies 33, in one embodiment of the present invention, the pressing device 30 further includes a movable die slide driving mechanism including a movable die slide screw 313, a connecting plate 314, and a movable die slide driving motor 315. Wherein, two ends of the movable pressing die sliding screw rod 313 are rotatably arranged on the base 31; the connecting plate 314 is slidably mounted on the movable die sliding screw rod 313, and the connecting plate 314 is fixedly connected with the third slide block 312 on the second transverse guide rail 311; the output end of the movable die sliding driving motor 315 is connected to the movable die sliding screw rod 313, and is used for driving the movable die sliding screw rod 313 to rotate, so as to drive the connecting plate 314 to make linear motion along the movable die sliding screw rod 313, and further drive the third sliding block 312 and the integral movable die 33 to move horizontally.

By adopting the above-described movable die slide driving mechanism, the movable die 33 can be easily driven to move on the base 31 in the horizontal direction, and the horizontal position of the movable die 33 and the interval between the two movable dies 33 can be easily adjusted.

It should be noted that the connecting plate 314 is slidably mounted on the movable die sliding lead screw 313, specifically, a nut is disposed on the connecting plate 314, the nut is sleeved on the movable die sliding lead screw 313 and is in threaded fit connection with the movable die sliding lead screw 313, and the nut and the movable die sliding lead screw 313 together form a lead screw-nut pair. The two ends of the movable die sliding screw 313 are rotatably mounted on the base 31, specifically, two rotating supports are mounted on the base 31, and the two ends of the movable die sliding screw 313 are rotatably mounted on the rotating supports.

Further, in one specific example, the movable die slide screw 313 includes a third screw segment 313a and a fourth screw segment 313b connected to each other. The spiral directions of the threads on the third screw rod section 313a and the fourth screw rod section 313b are opposite, so that a bidirectional screw rod is formed; the movable dies 33 on both sides of the fixed die 32 are connected to the third and fourth wire rod sections 313a and 313b, respectively, via a connecting plate 314. Specifically, the movable die 33 located on the left side of the fixed die 32 is connected to the third screw segment 313a via a connecting plate 314, and the movable die 33 located on the right side of the fixed die 32 is connected to the fourth screw segment 313b via a connecting plate 314.

A bidirectional screw is formed by adopting the third screw section 313a and the fourth screw section 313b, and two movable dies 33 are respectively arranged on the third screw section 313a and the fourth screw section 313 b; the third screw rod section 313a and the fourth screw rod section 313b are driven to rotate together by the movable pressing die slippage driving motor 315, so that the two movable pressing dies 33 can be driven to move along opposite directions, and the distance between the two movable pressing dies 33 can be conveniently adjusted, so that the pressing device 30 can adapt to shirt collars of different styles.

Specifically, when the distance between the two movable dies 33 needs to be increased, the third screw rod section 313a and the fourth screw rod section 313b are driven to rotate only by the movable die slippage driving motor 315, so that the two movable dies 33 move in opposite directions; when the distance between the two movable dies 33 needs to be reduced, the movable die slippage driving motor 315 is only needed to drive the third screw rod section 313a and the fourth screw rod section 313b to rotate reversely, so that the two movable dies 33 move towards each other.

It can be understood that the movable die slide driving motor 315 in the movable die slide driving mechanism can be connected with the movable die slide screw 313 for transmission through the existing transmission modes such as a chain wheel transmission mechanism, a belt wheel transmission mechanism and the like. The connection position of the transmission mechanism and the movable die sliding screw rod 313 is preferably arranged at the middle position of the movable die sliding screw rod 313, namely the connection position of the third screw rod section 313a and the fourth screw rod section 313 b.

Referring to fig. 5, in one embodiment, the fixed die 32 specifically includes a second die holder 321, a fixed pressing block 322, a second vertical guide rail 323, a fourth sliding block 324, and a second stripping driving mechanism 325. Wherein, the fixed pressing block 322 is fixedly installed at the front end of the second die holder 321; a fourth sliding block 324 is slidably mounted on the second vertical guide rail 323, and the second die holder 321 is fixedly mounted on the fourth sliding block 324; the second stripping driving mechanism 325 is installed on the base 31, and an output end of the second stripping driving mechanism 325 is connected to the fourth slider 324 for driving the fourth slider 324 to slide along the second vertical guide 323.

Through the arrangement of the second vertical guide rail 323, the fourth slider 324 and the second drawing driving mechanism 325, when the fixed pressing die 32 is required to press the cut piece, the fourth slider 324 is driven by the second drawing driving mechanism 325 to move downwards along the second vertical guide rail 323, so that the second pressing die holder 321 and the fixed pressing block 322 are driven to move downwards integrally, and the cut piece is pressed by the fixed pressing block 322. When the fixed pressing block 322 needs to be lifted after pressing is finished, the second drawing driving mechanism 325 drives the fourth slider 324 to move upwards along the second vertical guide rail 323, so as to drive the second pressing die holder 321 and the fixed pressing block 322 to move upwards integrally, and the pressing action of the fixed pressing die 32 is finished.

Specifically, in the present embodiment, the second drawing drive mechanism 325 is a cylinder. In addition, a conventional driving mechanism such as a hydraulic cylinder or a motor may be used as the second drawing driving mechanism 325. In the present embodiment, the pressing device 30 includes three fixed dies 32 as described above, the three fixed dies 32 are arranged side by side in sequence, and two movable dies 33 are arranged on both sides of the three fixed dies 32.

Specifically, a perforated plate is arranged in the material placing area 11, and a plurality of vent holes are formed in the perforated plate; an air suction device (not shown) is disposed in the machine 10, and the air suction device is a suction fan or a suction blower. The auxiliary collar device 20 is arranged at one side of the material placing area 11, and the material pressing device 30 is arranged above the material placing area 11.

When the collar conveying equipment is used, the shirt collar cut pieces are placed on the perforated plate of the material placing area 11, and the air suction device is started to suck air, so that the cut pieces below the shirt collar can be more effectively adsorbed (attached) in the material placing area 11, and the condition that the cut pieces below are out of shape or deformed in the sewing process is avoided; extending the first arch position cushion block 23 and the second arch position cushion block 25 to be above two ends of the lower cut piece, covering the upper cut piece, and forming arch positions at two ends of the two cut pieces through the first arch position cushion block 23 and the second arch position cushion block 25; then, the upper cut pieces are pressed through a fixed pressing die 32 and a movable pressing die 33 in a pressing device 30, and then sewing operation can be carried out; when the pressing angle of the movable pressing die 33 needs to be adjusted, the pressing block rotation driving mechanism 334 and the connecting piece 333 drive the movable pressing block 332 to rotate around the hinge point between the movable pressing block 332 and the first pressing die holder 331, so that the angle of the movable pressing block 332 can be conveniently changed, and the pressing angle of the movable pressing die 33 can be adjusted; when the collar cut pieces (change) of different styles need to be replaced, the two movable pressing dies 33 on the two sides of the pressing device 30 are driven by the movable pressing die sliding driving motor 315 to transversely move along the second transverse guide rail 311, and the distance between the two movable pressing dies 33 is changed.

In general, the collar transporting equipment can form an arch position between two collar cut pieces through the first arch position cushion block 22 and the second arch position cushion block 23 in the auxiliary collar transporting device 20, the arch positions of the cut pieces do not need to be manually placed, the collar flying prevention effect can be achieved, collar transporting operation is simplified, collar transporting work efficiency is improved, and manual labor intensity is reduced; the pressing angle can be conveniently adjusted through the movable pressing dies 33 in the pressing device 30, and the distance between the two movable pressing dies 33 can be quickly adjusted to adapt to collar cut pieces of different styles, so that the money transferring efficiency and the production efficiency of the collar transporting equipment are improved.

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 utility model. 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 patent of the present invention should be subject to the appended claims, and the description and the drawings can be used for explaining the contents of the claims.

Claims (14)

1. A collar transporting apparatus, comprising:

the machine table is provided with a material placing area for placing the collar cutting pieces;

the auxiliary collar transporting device is arranged on the machine table and comprises a first arch-position cushion block and a second arch-position cushion block, the first arch-position cushion block is used for extending into one end of the two superposed collar cut pieces to form an arch position, and the second arch-position cushion block is used for extending into the other end of the two superposed collar cut pieces to form an arch position; and

the pressing device is arranged on the machine table and provided with a pressing die assembly, and the pressing die assembly is located above the material placing area and can stretch out and draw back to press the collar cutting pieces.

2. The collaring apparatus, as set forth in claim 1, wherein said secondary collaring device comprises:

a base plate;

the first telescopic driving mechanism is arranged on the bottom plate;

the first arch position cushion block is connected with the output end of the first telescopic driving mechanism;

the second telescopic driving mechanism is arranged on the bottom plate and is arranged in parallel with the first telescopic driving mechanism; and

and the second arch position cushion block is connected with the output end of the second telescopic driving mechanism.

3. The collaring apparatus of claim 2, wherein said secondary collaring device further comprises:

the first transverse guide rail is arranged on the bottom plate, and the first telescopic driving mechanism and the second telescopic driving mechanism are slidably arranged on the first transverse guide rail.

4. The collaring apparatus of claim 3, wherein said secondary collaring device further comprises a slip drive mechanism, said slip drive mechanism comprising:

the mounting seat is arranged on the bottom plate;

the first telescopic driving mechanism and the second telescopic driving mechanism are both arranged on the sliding driving screw rod in a sliding way; and

and the output end of the sliding driving motor is connected with the sliding driving screw rod so as to drive the sliding driving screw rod to rotate.

5. The collaring device of claim 4, wherein said slip drive screw comprises:

a first screw section on which the first telescopic drive mechanism is slidably mounted;

and the second screw rod section is connected with the first screw rod section, the second telescopic driving mechanism can be slidably arranged on the second screw rod section, and the spiral direction of the threads of the second screw rod section is opposite to that of the threads of the first screw rod section.

6. The apparatus of claim 2, wherein the first block is movably mounted to the output end of the first telescoping drive mechanism, the first block being adjustable in mounting height; and/or

The second arch position cushion block is movably arranged at the output end of the second telescopic driving mechanism, and the installation height of the second arch position cushion block is adjustable.

7. The neck apparatus of any one of claims 1 to 6, wherein the pressing device comprises:

the base is arranged above the machine table;

the fixed pressing die is arranged on the base; and

the movable pressing dies are arranged on the base and are respectively positioned on two sides of the fixed pressing die, a first pressing die seat is arranged in each movable pressing die, a movable pressing block is hinged to the first pressing die seat, and the movable pressing block can horizontally rotate relative to the first pressing die seat to adjust the pressing angle of the movable pressing block.

8. The collar apparatus of claim 7, wherein said movable die comprises:

the first die holder;

one end of the movable pressing block is hinged to the first pressing die base;

one end of the connecting piece is hinged with the movable pressing block;

and the output end of the pressing block rotation driving mechanism is connected with the other end of the connecting piece so as to drive the connecting piece to move and further drive the movable pressing block to rotate around a hinge joint with the first pressing die holder.

9. The apparatus as claimed in claim 8, wherein a linear guide is mounted on the first die holder, a first slide block is slidably disposed on the linear guide, and the connecting member is fixed to the first slide block; the movable pressing block is provided with a kidney-shaped groove, and the hinged joint of the connecting piece and the movable pressing block is positioned in the kidney-shaped groove and can slide along the kidney-shaped groove.

10. The apparatus of claim 8, wherein the movable die further comprises a first vertical rail and a first die-lifting drive mechanism, the first vertical rail slidably mounts a second slide, the first die holder is fixed to the second slide, and the second slide is connected to an output of the first die-lifting drive mechanism.

11. The apparatus as claimed in claim 7, wherein a second cross rail is mounted on the base, a third slide block is slidably mounted on the second cross rail, the movable die is mounted on the third slide block, and a movable die slide driving mechanism for driving the third slide block to slide along the second cross rail is further provided on the base.

12. The apparatus of claim 11, wherein the movable die slide drive mechanism comprises:

the two ends of the movable pressing die sliding screw rod are rotatably arranged on the base;

the connecting plate is slidably arranged on the movable pressing die sliding screw rod and is connected with the third sliding block;

and the output end of the movable pressing die slippage driving motor is connected with the movable pressing die slippage screw rod so as to drive the movable pressing die slippage screw rod to rotate.

13. The collar apparatus of claim 12 wherein said movable die slide screw comprises a third screw segment and a fourth screw segment connected to each other, said third screw segment and said fourth screw segment having opposite helical directions of threads, said movable dies on both sides of said fixed die being connected to said third screw segment and said fourth screw segment, respectively, through a said connecting plate.

14. The collar apparatus of any one of claims 7 to 13, wherein the stationary die comprises:

a second die holder;

the fixed pressing block is arranged on the second pressing die holder;

a second vertical guide rail;

the fourth sliding block is slidably arranged on the second vertical guide rail, and the second die holder is fixedly arranged on the fourth sliding block;

and the output end of the second stripping driving mechanism is connected with the fourth sliding block so as to drive the fourth sliding block to slide along the second vertical guide rail.

Images