CN108729038B - Template machine and material feeding unit thereof - Google Patents

Abstract

The invention relates to the technical field of garment sewing, in particular to a feeding device of a template machine and the template machine comprising the feeding device. The X-direction feeding mechanism is arranged on the Y-direction feeding mechanism through the connecting frame, and the Y-direction feeding mechanism only needs to be provided with one group, so that the integral structure is simplified, the production and assembly efficiency can be improved, the production cost is saved, meanwhile, the noise generated during the operation of the device can be effectively reduced, the invalid friction torque of the feeding device is reduced, the feeding stability is improved, the transmission load of the Y-direction feeding mechanism is reduced, the fault occurrence rate is reduced, and the high-speed feeding is favorably realized.

Description

Template machine and material feeding unit thereof

Technical Field

The invention relates to the technical field of garment sewing, in particular to a feeding device of a template machine and the template machine comprising the feeding device.

Background

The template machine designs a sewing template according to the process of each part of the clothes, puts the cloth into the sewing template, then puts the sewing template on a working table of the frame, and drives the sewing template to move on the working table along the X direction and the Y direction by a feeding device, thereby completing the sewing process.

As shown in fig. 1, in a feeding device of a conventional template machine, a sewing template is usually fixed on an X-direction feeding mechanism 1, and the sewing template is driven by the X-direction feeding mechanism 1 to move along the X direction; the X-direction feeding mechanism 1 is directly fixed on a synchronous belt of the Y-direction feeding mechanism 2, and the Y-direction feeding mechanism 2 directly drives the X-direction feeding mechanism 1 to move along the Y direction so as to drive the sewing template to move along the Y direction. Wherein, Y is to feeding mechanism 2 by motor 3 through gear 4 drive a pivot 5 and rotate, drives two sets of band pulleys 6 and hold-in range 7 operation simultaneously, is driven X by two sets of hold-in range 7 jointly and is moved to feeding mechanism. A guide rail 8 is arranged on one side of the synchronous belt 7, the X-direction feeding mechanism 1 is connected with the synchronous belt 7 through a synchronous belt clamping plate 9, and the synchronous belt clamping plate 9 is slidably arranged on the guide rail 8. In order to ensure that the synchronous belt 7 does not slip, the synchronous belt 7 of the feeding device is provided with a large tension force, the tension force greatly increases the ineffective friction torque of the whole device, the transmission load of the motor 3 of the Y-direction feeding mechanism is increased, the motor is easy to break down, and the high-speed feeding is not facilitated. Moreover, the feeding device has more scattered parts and lower production and installation efficiency.

Disclosure of Invention

The technical problem to be solved by the invention is to provide the feeding device of the template machine and the template machine comprising the feeding device, which have the advantages of simple structure, small transmission load, contribution to reducing the failure occurrence rate of the device and realizing high-speed feeding, so as to overcome the defects in the prior art.

In order to solve the technical problems, the invention adopts the following technical scheme:

a feeding device of a template machine comprises a Y-direction feeding mechanism, a connecting frame arranged on the Y-direction feeding mechanism and an X-direction feeding mechanism arranged on the connecting frame, wherein the Y-direction feeding mechanism drives the connecting frame to drive the X-direction feeding mechanism to move along the Y direction, and the X-direction feeding mechanism is connected with a sewing template and drives the sewing template to move along the X direction.

Preferably, the feeding device further comprises a guide mechanism, the guide mechanism comprises a guide piece arranged along the Y direction and a sliding assembly arranged on the guide piece in a sliding manner along the Y direction, and the connecting frame and the X-direction feeding mechanism are connected with the sliding assembly.

Preferably, two guiding mechanisms are respectively arranged on two sides of the Y-direction feeding mechanism along the X direction, and two ends of the connecting frame and two ends of the X-direction feeding mechanism are respectively connected with the sliding assemblies of the two guiding mechanisms.

Preferably, the guide piece is a guide shaft, the sliding assembly comprises a bearing arranged on the guide shaft and a connecting plate arranged on the bearing, and the connecting frame and the X-direction feeding mechanism are connected with the connecting plate.

Preferably, the Y-direction feeding mechanism comprises a first Y-direction belt wheel and a second Y-direction belt wheel arranged at intervals along the Y-direction, a Y-direction synchronous belt connected with the first Y-direction belt wheel and the second Y-direction belt wheel, and a Y-direction motor connected with the first Y-direction belt wheel, and the connecting frame is connected with the Y-direction synchronous belt.

Preferably, Y is to feeding mechanism still includes the hollow Y of axial to the aluminium alloy, and first Y is to band pulley and second Y to the band pulley locate respectively on the both ends terminal surface of Y to the aluminium alloy, and Y is to the inside hollow region of Y to the aluminium alloy and another part is located Y to the aluminium alloy outside of wearing to locate in hold-in range part.

Preferably, the X-direction feeding mechanism comprises a first X-direction belt wheel and a second X-direction belt wheel which are arranged at intervals along the X direction, an X-direction synchronous belt connected with the first X-direction belt wheel and the second X-direction belt wheel, and an X-direction motor connected with the first X-direction belt wheel, wherein an X-direction sliding block used for connecting the sewing template is arranged on the X-direction synchronous belt.

Preferably, X is to feeding mechanism still includes the axial cavity X to the aluminium alloy, and first X is to band pulley and second X to the band pulley locate respectively on the both ends terminal surface of X to the aluminium alloy, and X is to the inside hollow region of X to the aluminium alloy and another part is located the X to the aluminium alloy outside of wearing to locate in hold-in range part.

Preferably, the connecting frame is made of aluminum profiles in a splicing mode.

The template machine comprises a rack and a feeding device of the template machine, wherein the feeding device is arranged on the rack.

Compared with the prior art, the invention has the remarkable progress that:

the X is to the feeding mechanism through the link setting on Y is to feeding mechanism, it is realized that Y drives the link and drives X to feeding mechanism and sewing template and move along Y simultaneously to feeding mechanism, therefore, Y only need set up one set of can to feeding mechanism, Y compared with prior art need set up two sets of drive assembly to feeding mechanism and drive X to the feeding mechanism motion, the feeding device of this embodiment has simplified overall structure, can improve production and assembly efficiency, save manufacturing cost, can effectively reduce the noise when the device operates simultaneously, reduce material feeding device's invalid friction torque, improve the stability of pay-off, reduce Y to feeding mechanism's transmission load, thereby reduce the fault incidence, be favorable to realizing the high-speed of pay-off.

Drawings

Fig. 1 is a schematic structural diagram of a feeding device in the prior art.

Fig. 2 is a schematic structural diagram of a feeding device according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a guiding mechanism of a feeding device according to an embodiment of the invention.

Fig. 4 is an exploded schematic view of a Y-direction feeding mechanism of the feeding device according to the embodiment of the present invention.

Fig. 5 is an exploded schematic view of the X-direction feeding mechanism of the feeding device according to the embodiment of the present invention.

In fig. 1:

1. x is to feeding mechanism 2, Y is to feeding mechanism 3, motor

4. Gear 5, shaft 6, belt wheel

7. Synchronous belt 8, guide rail 9 and synchronous belt clamping plate

In fig. 2 to 5:

100. y-direction feeding mechanism 101, first Y-direction belt wheel 102 and second Y-direction belt wheel

103. Y-direction synchronous belt 104, Y-direction motor 105 and Y-direction slider

106. Y is to aluminium alloy 107, first Y to pulley holder 108, second Y to pulley holder

200. Connecting frame 300, X-direction feeding mechanism 301 and first X-direction belt wheel

302. Second X-direction belt wheel 303, X-direction synchronous belt 304 and X-direction motor

305. X is to slider 306, X is to aluminium alloy 307, first X is to band pulley seat

308. Second X-direction pulley seat 400, guide mechanism 410 and guide piece

420. Sliding assembly 421, bearing 422 and first connecting plate

423. Second connecting plate 424, third connecting plate 425, support

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings. These embodiments are merely illustrative of the present invention and are not intended to limit the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

Fig. 2 to 5 show an embodiment of a feeding device of a plate molding machine according to the present invention. It should be noted that the "X direction" and the "Y direction" in this document refer to directions as shown in fig. 2 when the feeding device of the present invention is conventionally disposed on the frame of the plate molding machine.

As shown in fig. 2, the feeding device of the present embodiment includes a Y-direction feeding mechanism 100, a connecting frame 200 disposed on the Y-direction feeding mechanism 100, and an X-direction feeding mechanism 300 disposed on the connecting frame 200. The X-direction feeding mechanism 300 is used for being connected with the sewing template, and the X-direction feeding mechanism 300 drives the sewing template to move along the X direction. The Y-direction feeding mechanism 100 drives the connecting frame 200 to move along the Y direction, and the movement of the connecting frame 200 drives the X-direction feeding mechanism 300 to move along the Y direction together, so that the sewing template is driven to move along the Y direction.

The feeding device of the embodiment, the X-direction feeding mechanism 300 is arranged on the Y-direction feeding mechanism 100 through the connecting frame 200, and the Y-direction feeding mechanism 100 drives the connecting frame 200 to drive the X-direction feeding mechanism 300 and the sewing template to move along the Y direction simultaneously, so that the Y-direction feeding mechanism 100 only needs to be provided with one group, compared with the Y-direction feeding mechanism in the prior art, two groups of transmission assemblies need to be arranged to drive the X-direction feeding mechanism to move.

Further, the feeding device of the embodiment further includes a guiding mechanism 400, the guiding mechanism 400 includes a guiding element 410 disposed along the Y direction and a sliding assembly 420 slidably disposed on the guiding element 410 along the Y direction, and both the connecting frame 200 and the X-direction feeding mechanism 300 are connected to the sliding assembly 420. When the Y-direction feeding mechanism 100 drives the connecting frame 200 to move along the Y-direction, the connecting frame 200 drives the sliding assembly 420 to slide along the Y-direction on the guide 410, and the sliding assembly 420 drives the X-direction feeding mechanism 300 to move along the Y-direction therewith. The guide member 410 and the sliding member 420 of the guide mechanism 400 guide the movement of the X-direction feeding mechanism 300 along the Y-direction, and also assist the X-direction feeding mechanism 300, so as to ensure the stability of the movement of the X-direction feeding mechanism 300 along the Y-direction, and thus ensure the stability and reliability of the operation of the feeding device.

To further enhance the guiding and supporting function of the guiding mechanism 400 on the movement of the X-direction feeding mechanism 300 along the Y-direction, preferably, the embodiment is provided with one guiding mechanism 400 on each side of the Y-direction feeding mechanism 100 along the X-direction. The middle of the connecting frame 200 is connected to the Y-direction feeding mechanism 100, and both ends of the connecting frame 200 are respectively connected to the sliding assemblies 420 of the two guiding mechanisms 400. The two ends of the X-direction feeding mechanism 300 are respectively connected with the sliding assemblies 420 of the two guiding mechanisms 400. Therefore, the two guide mechanisms 400 support the X-direction feeding mechanism 300 together and guide the movement of the X-direction feeding mechanism 300 along the Y direction, so that the stability of the movement of the X-direction feeding mechanism 300 along the Y direction is further improved.

Preferably, as shown in fig. 2 and 3, in the present embodiment, the guide member 410 of the guide mechanism 400 is a guide shaft, and the sliding member 420 includes a bearing 421 and a coupling plate. The bearing 421 is sleeved on the guide shaft, and the bearing 421 in this embodiment is a linear bearing, can move linearly on the guide shaft, and has the advantages of small frictional resistance and low noise. The connecting plate is arranged on the bearing 421 and can move together with the bearing 421 on the guide shaft. The link frame 200 and the X-direction feed mechanism 300 are connected to the link plate so as to be movable together with the link plate. The connection plates in this embodiment include a first connection plate 422, a second connection plate 423, and a third connection plate 424. One end of the first connecting plate 422 is fixedly disposed on the bearing 421, and the other end of the first connecting plate 422 is connected to the connecting frame 200. The second connecting plate 423 has a first bending portion and a second bending portion perpendicular to each other, the first bending portion is fixed on the bearing 421, and the second bending portion is connected to the third connecting plate 424. The third connecting plate 424 is U-shaped, and a space for accommodating the X-direction feeding mechanism 300 is formed between two side edges and a bottom edge of the third connecting plate. In this embodiment, the first bending portion of the second connecting plate 423 is perpendicular to the guide shaft, the second bending portion of the second connecting plate 423 is parallel to the guide shaft and is located above the guide shaft, the bottom edge of the third connecting plate 424 is fastened to the upper surface of the second bending portion of the second connecting plate 423, and the X-direction feeding mechanism 300 is disposed between the two side edges of the third connecting plate 424 and is fastened to the third connecting plate 424.

Preferably, this embodiment also has supports 425 at both ends of the guide shaft, the supports 425 being adapted to couple to the frame of the stencil printer to support the guide mechanism 400 on the frame of the stencil printer.

Further, the link 200 of this embodiment is made by aluminum profile concatenation, has the advantage that processing technology is simple. As shown in fig. 2, in the present embodiment, three aluminum profiles are preferably spliced to form a "U" shaped connecting frame 200, the middle of the bottom edge of the connecting frame is connected to the Y-direction feeding mechanism 100, and the upper ends of the two side edges are respectively connected to the first connecting plates 422 of the sliding assemblies 420. Therefore, the X-direction feeding mechanism 300 and the Y-direction feeding mechanism 100 have a certain spacing distance without interference.

Further, as shown in fig. 2 and 4, the Y-direction feeding mechanism 100 of this embodiment includes a first Y-direction pulley 101 and a second Y-direction pulley 102 that are disposed at intervals along the Y-direction, a Y-direction timing belt 103 that connects the first Y-direction pulley 101 and the second Y-direction pulley 102, and a Y-direction motor 104 that is connected to the first Y-direction pulley 101, and the Y-direction motor 104 drives the first Y-direction pulley 101 to rotate, so as to drive the Y-direction timing belt 103 and the second Y-direction pulley 102 to rotate synchronously with each other. The link 200 is connected to the Y-direction timing belt 103, and the link 200 is driven by the rotation of the Y-direction timing belt 103 to move linearly along the Y-direction. In this embodiment, a Y-direction slider 105 is fixed to the Y-direction timing belt 103, and the link 200 is connected to the Y-direction slider 105.

Preferably, as shown in fig. 4, the Y-direction feeding mechanism 100 of the present embodiment further includes a Y-direction aluminum profile 106 that is hollow in the axial direction, the first Y-direction pulley 101 and the second Y-direction pulley 102 are respectively disposed on both end faces of the Y-direction aluminum profile 106, the Y-direction timing belt 103 is partially inserted into an inner hollow area of the Y-direction aluminum profile 106 and the other part is located outside the Y-direction aluminum profile 106, and the Y-direction slider 105 is disposed on the Y-direction timing belt 103 located outside the Y-direction aluminum profile 106. Therefore, the Y-direction timing belt 103 is partially wrapped and sealed by the Y-direction aluminum profiles 106, and the effect of reducing noise can be achieved. In this embodiment, the first Y-direction pulley 101 is disposed on the first Y-direction pulley seat 107, the second Y-direction pulley 102 is disposed on the second Y-direction pulley seat 108, and the first Y-direction pulley seat 107 and the second Y-direction pulley seat 108 are respectively connected to end faces of two ends of the Y-direction aluminum profile 106.

Further, as shown in fig. 2 and 5, the X-direction feeding mechanism 300 of the present embodiment includes a first X-direction pulley 301 and a second X-direction pulley 302 arranged at an interval along the X-direction, an X-direction timing belt 303 connecting the first X-direction pulley 301 and the second X-direction pulley 302, and an X-direction motor 304 connected to the first X-direction pulley 301, wherein the first X-direction pulley 301 is driven by the X-direction motor 304 to rotate, and the X-direction timing belt 303 and the second X-direction pulley 302 are driven to rotate synchronously therewith. An X-direction sliding block 305 is arranged on the X-direction synchronous belt 303, the X-direction sliding block 305 is connected with the sewing template, and the sewing template is driven to move linearly along the X direction by the rotation of the X-direction synchronous belt 303.

Preferably, as shown in fig. 5, the X-direction feeding mechanism 300 of the present embodiment further includes an X-direction aluminum profile 306 that is hollow in the axial direction, the first X-direction pulley 301 and the second X-direction pulley 302 are respectively disposed on end faces of two ends of the X-direction aluminum profile 306, a part of the X-direction timing belt 303 is disposed in an inner hollow area of the X-direction aluminum profile 306, and another part of the X-direction timing belt 303 is located outside the X-direction aluminum profile 306. The X-direction slider 305 is provided on the partial X-direction timing belt 303 located outside the X-direction aluminum profile 306. Therefore, the X-direction aluminum profile 306 wraps and seals the X-direction synchronous belt 303, and the noise reduction effect can be achieved. In this embodiment, the first X-direction pulley 301 is disposed on the first X-direction pulley holder 307, the second X-direction pulley 302 is disposed on the second X-direction pulley holder 308, and the first X-direction pulley holder 307 and the second X-direction pulley holder 308 are respectively connected to end faces of two ends of the X-direction aluminum profile 306.

Based on the feeding device, the embodiment further provides a template machine, the template machine comprises a rack and the feeding device, and the feeding device is arranged on the rack and used for realizing the movement of the sewing template along the X direction and the Y direction.

In summary, in the feeding device and the template machine including the feeding device of the present embodiment, the X-direction feeding mechanism 300 is disposed on the Y-direction feeding mechanism 100 through the connecting frame 200, so that the Y-direction feeding mechanism 100 drives the connecting frame 200 to drive the X-direction feeding mechanism 300 and the sewing template to move along the Y direction simultaneously, therefore, only one group of Y-direction feeding mechanisms 100 is needed, compared with the Y-direction feeding mechanism in the prior art which needs to be provided with two groups of transmission components to drive the X-direction feeding mechanism to move, the feeding device of the embodiment simplifies the whole structure, can improve the production and assembly efficiency, saves the production cost, meanwhile, the noise of the feeding device during operation can be effectively reduced, the invalid friction torque of the feeding device is reduced, the feeding stability is improved, and the transmission load of the Y-direction feeding mechanism is reduced, so that the fault rate is reduced, and the high-speed feeding is favorably realized. The guide mechanism 400 has a guide function for the movement of the X-direction feeding mechanism 300 along the Y direction, and simultaneously has an auxiliary supporting function for the X-direction feeding mechanism 300, so that the stability of the movement of the X-direction feeding mechanism 300 along the Y direction can be ensured, and the working stability and reliability of the feeding device can be ensured.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and substitutions can be made without departing from the technical principle of the present invention, and these modifications and substitutions should also be regarded as the protection scope of the present invention.

Claims (7)

1. The feeding device of the template machine is characterized by comprising a Y-direction feeding mechanism (100), a connecting frame (200) arranged on the Y-direction feeding mechanism (100) and an X-direction feeding mechanism (300) arranged on the connecting frame (200), wherein the Y-direction feeding mechanism (100) drives the connecting frame (200) to drive the X-direction feeding mechanism (300) to move along the Y direction, and the X-direction feeding mechanism (300) is connected with a sewing template and drives the sewing template to move along the X direction; the feeding mechanism is characterized by further comprising a guide mechanism (400), wherein the guide mechanism (400) comprises a guide piece (410) arranged along the Y direction and a sliding assembly (420) arranged on the guide piece (410) in a sliding mode along the Y direction, and the connecting frame (200) and the X-direction feeding mechanism (300) are connected with the sliding assembly (420); two sides of the Y-direction feeding mechanism (100) along the X direction are respectively provided with one guide mechanism (400), and two ends of the connecting frame (200) and two ends of the X-direction feeding mechanism (300) are respectively connected with sliding components (420) of the two guide mechanisms (400); the connecting frame (200) is made by splicing aluminum profiles, three aluminum profiles are spliced to form a U-shaped connecting frame (200), the middle of the bottom edge of the connecting frame is connected with the Y-shaped feeding mechanism (100), and the upper ends of the two side edges are respectively connected with the sliding assembly (420).

2. The feeding device of the stencil making machine according to claim 1, wherein the guiding member (410) is a guiding shaft, the sliding assembly (420) comprises a bearing (421) provided on the guiding shaft and a connecting plate provided on the bearing (421), and the connecting frame (200) and the X-direction feeding mechanism (300) are connected to the connecting plate.

3. The feeding device of the stencil machine as claimed in claim 1, wherein the Y-direction feeding mechanism (100) includes a first Y-direction pulley (101) and a second Y-direction pulley (102) arranged at an interval in a Y-direction, a Y-direction timing belt (103) connecting the first Y-direction pulley (101) and the second Y-direction pulley (102), and a Y-direction motor (104) connected to the first Y-direction pulley (101), and the link (200) is connected to the Y-direction timing belt (103).

4. The feeding device of the template machine as claimed in claim 3, wherein the Y-direction feeding mechanism (100) further comprises an axially hollow Y-direction aluminum profile (106), the first Y-direction belt pulley (101) and the second Y-direction belt pulley (102) are respectively arranged on end faces of two ends of the Y-direction aluminum profile (106), the Y-direction synchronous belt (103) is partially arranged in an inner hollow area of the Y-direction aluminum profile (106) in a penetrating manner, and the other part of the Y-direction synchronous belt is positioned outside the Y-direction aluminum profile (106).

5. The feeding device of the template machine as claimed in claim 1, wherein the X-direction feeding mechanism (300) comprises a first X-direction belt wheel (301) and a second X-direction belt wheel (302) which are arranged at intervals along the X direction, an X-direction synchronous belt (303) which is connected with the first X-direction belt wheel (301) and the second X-direction belt wheel (302), and an X-direction motor (304) which is connected with the first X-direction belt wheel (301), wherein an X-direction sliding block (305) which is used for connecting the sewing template is arranged on the X-direction synchronous belt (303).

6. The feeding device of the template machine according to claim 5, wherein the X-direction feeding mechanism (300) further comprises an X-direction aluminum profile (306) which is hollow in the axial direction, the first X-direction belt wheel (301) and the second X-direction belt wheel (302) are respectively arranged on end faces of two ends of the X-direction aluminum profile (306), the X-direction synchronous belt (303) is partially arranged in a hollow area inside the X-direction aluminum profile (306) in a penetrating mode, and the other part of the X-direction synchronous belt is positioned outside the X-direction aluminum profile (306).

7. A stencil machine comprising a frame, characterized in that it further comprises a feeding device of the stencil machine as claimed in any of claims 1 to 6, the feeding device being provided on the frame.

Images