CN212191757U - Automatic non-woven fabric cutting device - Google Patents

Abstract

The utility model discloses a non-woven fabrics technical field's a non-woven fabrics automatic cutout device, include: a drive base assembly; the two first transmission assemblies are arranged at the tops of the front end and the rear end of the right side of the transmission base assembly in tandem; a lateral movement frame assembly mounted on top of the drive base assembly; a second drive assembly mounted atop a front surface of the transverse carriage assembly; a longitudinal moving frame mounted on top of the transverse moving frame assembly; the third transmission assembly is arranged on the right side of the top of the longitudinal moving frame; laser mounting bracket, the laser mounting bracket is installed the right side of longitudinal movement frame, the utility model discloses can go on just to the non-woven fabrics through laser, can effectually carry out accurate cutting to the non-woven fabrics, guarantee non-woven fabrics cutting size's standard nature, and can reduce the raise dust.

Description

Automatic non-woven fabric cutting device

Technical Field

The utility model relates to a non-woven fabrics technical field specifically is a non-woven fabrics automatic cutout device.

Background

Nonwoven fabrics, also known as nonwovens, are composed of oriented or random fibers. It is called a cloth because of its appearance and certain properties. The non-woven fabric has the characteristics of moisture resistance, air permeability, flexibility, light weight, no combustion supporting, easy decomposition, no toxicity or irritation, rich color, low price, recycling and the like. For example, the polypropylene (pp material) granules are mostly adopted as raw materials and are produced by a continuous one-step method of high-temperature melting, spinning, laying a line and hot-pressing coiling.

In the process of using the non-woven fabric, the non-woven fabric is cut into small pieces according to different specific purposes, namely, the non-woven fabric which is rolled into a large roll is cut into small non-woven fabric pieces. At present, the common method is to measure the length of the non-woven fabric to be cut, put a straight ruler on the non-woven fabric, and cut the required small non-woven fabric along the straight ruler by a cutter.

The precision of the existing non-woven fabric cutting mode is not high, the standard of the non-woven fabric cutting size cannot be effectively guaranteed, the existing non-woven fabric cutting mode easily causes dust raising, and the working environment is seriously affected.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a non-woven fabrics automatic cutting device to the current non-woven fabrics cutting mode precision that proposes in solving above-mentioned background is not high, can't effectively ensure non-woven fabrics cutting dimension's standard nature, and current non-woven fabrics cutting mode causes the raise dust easily, seriously influences operational environment's problem.

In order to achieve the above object, the utility model provides a following technical scheme: an automatic nonwoven fabric dividing apparatus comprising:

a drive base assembly;

the two first transmission assemblies are arranged on the tops of the front end and the rear end of the right side of the transmission base assembly in tandem;

a lateral movement frame assembly mounted on top of the drive base assembly;

a second drive assembly mounted atop a front surface of the transverse carriage assembly;

a longitudinal moving frame mounted on top of the transverse moving frame assembly;

the third transmission assembly is arranged on the right side of the top of the longitudinal moving frame;

the laser mounting rack is installed on the right side of the longitudinal moving rack.

Preferably, the transmission base assembly comprises:

a base;

the two first sliding grooves are arranged at the tops of the front end and the rear end of the right side of the base in tandem;

the conveying belt is installed in the top groove of the base.

Preferably, the first transmission assembly comprises:

a first motor;

and the first lead screw is installed on a left output shaft of the first motor through spline connection.

Preferably, the traverse frame assembly includes:

a transverse moving frame body;

the second sliding groove is formed in the top of the front surface of the transverse moving frame body;

the two first sliding blocks are arranged at the front end and the rear end of the bottom of the transverse moving frame body in tandem;

two first screw holes, two the first screw hole one-to-one sets up two the right side middle-end of first slider, first screw hole runs through the left side of first slider.

Preferably, the second transmission assembly comprises:

a second motor;

and the second lead screw is installed on a left output shaft of the second motor through spline connection.

Preferably, the longitudinal moving frame includes:

a longitudinal moving frame body;

the second sliding block is arranged on the top of the bottom groove of the longitudinal moving frame body, and the longitudinal moving frame body is provided with a second sliding block;

the second threaded hole is formed in the front surface of the second sliding block and penetrates through the rear surface of the second sliding block;

and the third sliding groove is formed in the right side of the top of the longitudinal moving frame body.

Preferably, the third transmission assembly comprises:

a third motor;

and the third screw rod is installed on the bottom output shaft of the third motor through spline connection.

Preferably, the laser mount includes:

the laser mounting rack comprises a laser mounting rack body, wherein a laser emitting head is arranged in a right groove of the laser mounting rack body;

the third slider sets up the left side middle-end of laser mounting bracket body, the third screw hole has been seted up at the top of third slider, the screw hole runs through the bottom of third slider.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model can cut the non-woven fabric by laser, can effectively and accurately cut the non-woven fabric, ensures the standard property of the cutting size of the non-woven fabric, can reduce dust, drives a first screw rod to rotate by a first motor, drives a first slide block to move left and right by screw transmission, drives a transverse moving frame body to move left and right by the first slide block, drives a second screw rod to rotate by a second motor, drives a second slide block to move back and forth by screw transmission, drives a longitudinal moving frame to move back and forth by the second slide block, is provided with a laser emission head in a groove at the right side of the laser mounting frame body, carries out laser cutting on the non-woven fabric by the laser emission head, can effectively improve the cutting accuracy of the non-woven fabric, can reduce the dust generated during cutting due to the high-temperature cutting of the laser, drives a third screw rod to rotate by a third motor, drive the laser installation frame body through the third slider and reciprocate to this height of adjusting the laser emission head, the convenience is cut the non-woven fabrics, can carry out not unidimensional cutting to the non-woven fabrics through the relative position that transverse movement put up the body and vertically move the frame and adjust the laser emission head, drives the walking of transverse movement frame body and vertically move the frame through the motor, can pinpoint, improves the cutting accuracy of non-woven fabrics.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the transmission base assembly of the present invention;

fig. 3 is a schematic structural view of the first transmission assembly of the present invention;

FIG. 4 is a schematic structural view of the lateral moving frame assembly of the present invention;

fig. 5 is a schematic structural view of a second transmission assembly of the present invention;

FIG. 6 is a schematic view of the structure of the vertical moving frame of the present invention;

fig. 7 is a schematic structural view of a third transmission assembly of the present invention;

fig. 8 is the structural schematic diagram of the vertical moving rack of the present invention.

In the figure: 100 drive base subassembly, 110 base, 120 first spout, 130 conveyer belt, 200 first drive subassembly, 210 first motor, 220 first lead screw, 300 lateral shifting frame subassembly, 310 lateral shifting frame body, 320 second spout, 330 first slider, 340 first screw hole, 400 second drive subassembly, 410 second motor, 420 second lead screw, 500 longitudinal shifting frame, 510 longitudinal shifting frame body, 520 second slider, 530 second screw hole, 540 third spout, 600 third drive subassembly, 610 third motor, 620 third lead screw, 700 laser mounting bracket, 710 laser mounting bracket body, 720 third slider.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a non-woven fabrics automatic cutting device can cut the non-woven fabrics through laser, can effectually carry out accurate cutting to the non-woven fabrics, ensures the standard nature of non-woven fabrics cutting size, and can reduce the raise dust, please refer to figure 1, include: the laser installation device comprises a transmission base assembly 100, a first transmission assembly 200, a transverse moving frame assembly 300, a second transmission assembly 400, a longitudinal moving frame 500, a third transmission assembly 600 and a laser installation frame 700;

referring to fig. 1-2, the transmission base assembly 100 includes:

a base 110;

the two first sliding chutes 120 are arranged at the top of the front end and the rear end of the right side of the base 110 in tandem;

the conveyor belt 130 is arranged in the top groove of the base 110, and the conveyor belt 130 is used for conveying the non-woven fabric;

referring to fig. 1-3, two first transmission assemblies 200 are mounted in tandem on the top of the front and rear ends of the right side of the transmission base assembly 100, and the first transmission assemblies 200 include:

the two first motors 210 are arranged at the front end and the rear end of the top of the right side of the base 110 in tandem, and the two first motors 210 correspond to the two first sliding grooves 120 one by one;

the two first lead screws 220 are connected through splines and are correspondingly arranged on left output shafts of the two first motors 210 one by one, and the two first lead screws 220 are correspondingly arranged on the inner sides of the two first sliding grooves 120 one by one;

referring to fig. 1-4, the transverse moving frame assembly 300 is mounted on the top of the transmission base assembly 100, and the transverse moving frame assembly 300 includes:

the bottom of the lateral movement frame body 310 contacts the top of the base 110;

the second sliding chute 320 is formed on the top of the front surface of the transverse moving frame body 310;

the two first sliding blocks 330 are arranged at the front end and the rear end of the bottom of the transverse moving frame body 310 in tandem, the first sliding blocks 330 are matched with the first sliding grooves 120, the first sliding blocks 330 are inserted into the inner sides of the first sliding grooves 120, and the transverse moving frame body 310 is arranged at the top of the base 110 through the matching use of the first sliding blocks 330 and the first sliding grooves 120;

the two first threaded holes 340 are correspondingly arranged at the middle ends of the right sides of the two first sliding blocks 330 one by one, the first threaded holes 340 penetrate through the left sides of the first sliding blocks 330, the first threaded holes 340 are matched with the first lead screws 220, the first lead screws 220 are connected with the first sliding blocks 330 through threaded connection, the first lead screws 220 are driven to rotate through the first motor 210, the first sliding blocks 330 are driven to move left and right through lead screw transmission, and the transverse moving frame body 310 is driven to move left and right through the first sliding blocks 330;

referring to fig. 1, 4 and 5, a second driving assembly 400 is installed on the top of the front surface of the traverse frame assembly 300, the second driving assembly 400 including:

the second motor 410 is installed on the top of the front surface of the transverse moving frame body 310, and the second motor 410 corresponds to the second sliding chute 320;

the second lead screw 420 is mounted on the left output shaft of the second motor 410 through spline connection, and the second lead screw 420 is mounted on the inner side of the second chute 320;

referring to fig. 1 and 4-6, the longitudinal moving frame 500 is mounted on the top of the transverse moving frame assembly 300, and the longitudinal moving frame 500 includes:

the longitudinal moving frame body 510 is clamped at the top of the transverse moving frame body 310;

the second slider 520 is arranged on the top of the groove at the bottom of the longitudinal moving frame body 510, the longitudinal moving frame body 510 is arranged on the top of the groove at the bottom of the longitudinal moving frame body 510, the second slider 520 is matched with the second sliding groove 320, the second slider 520 is arranged on the inner side of the second sliding groove 320, and the longitudinal moving frame body 510 is arranged on the top of the transverse moving frame body 310 through the matching use of the second slider 520 and the second sliding groove 320;

the second threaded hole 530 is formed in the front surface of the second slider 520, the second threaded hole 530 penetrates through the rear surface of the second slider 520, the second threaded hole 530 is matched with the second lead screw 420, the second lead screw 420 is connected with the second slider 520 through threaded connection, the second lead screw 420 is driven to rotate through the second motor 410, the second slider 520 is driven to move back and forth through lead screw transmission, and the longitudinal moving frame body 510 is driven to move back and forth through the second slider 520;

the third sliding chute 540 is arranged at the right side of the top of the longitudinal moving frame body 510;

referring to fig. 1, 6 and 7, a third driving assembly 600 is installed at the top right side of the longitudinal moving frame 500, and the third driving assembly 600 includes:

the third motor 610 is installed at the right side of the top of the longitudinal moving frame body 510, and the third motor 610 corresponds to the third sliding chute 540;

the third lead screw 620 is connected and installed on the output shaft at the bottom of the third motor 610 through a spline, and the third lead screw 620 is installed on the inner side of the third chute 540;

referring to fig. 1 and 6 to 8, a laser mount 700 is installed at a right side of the longitudinal moving frame 500, and the laser mount 700 includes:

the laser emission head is arranged in the groove on the right side of the laser mounting frame body 710, and the non-woven fabric is subjected to laser cutting through the laser emission head, so that the cutting accuracy of the non-woven fabric can be effectively improved, and raised dust generated during cutting can be reduced due to high-temperature cutting of laser;

the third slider 720 is arranged at the left middle end of the laser mounting rack body 710, a third threaded hole is formed in the top of the third slider 720, the third threaded hole penetrates through the bottom of the third slider 720, the third slider 720 is matched with the third sliding chute 540, the third slider 720 is arranged on the inner side of the third sliding chute 540, the third threaded hole is matched with the third lead screw 620, the third lead screw 620 is connected with the third slider 720 through threaded connection, the third lead screw 620 is driven to rotate through the third motor 610, the third slider 720 is driven to move up and down through the lead screw tradition, the laser mounting rack body 710 is driven to move up and down through the third slider 720, so that the height of the laser emitting head is adjusted, the non-woven fabric is conveniently cut, the non-woven fabric can be cut in different sizes by adjusting the relative position of the laser emitting head through the transverse moving rack body 310 and the longitudinal moving rack body 510, the transverse moving rack body 310 and the longitudinal moving rack body 510, can pinpoint, improve the cutting accuracy of non-woven fabrics.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (8)

1. The utility model provides a non-woven fabrics automatic separation device which characterized in that: the method comprises the following steps:

a drive base assembly (100);

the two first transmission assemblies (200) are arranged at the tops of the front end and the rear end of the right side of the transmission base assembly (100) in tandem;

a lateral moving frame assembly (300), the lateral moving frame assembly (300) being mounted on top of the drive base assembly (100);

a second drive assembly (400), the second drive assembly (400) mounted atop a front surface of the transverse carriage assembly (300);

a longitudinal moving frame (500), the longitudinal moving frame (500) being mounted on top of the transverse moving frame assembly (300);

a third transmission assembly (600), wherein the third transmission assembly (600) is installed at the top right side of the longitudinal moving frame (500);

a laser mount (700), the laser mount (700) being mounted on a right side of the longitudinal moving frame (500).

2. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the drive base assembly (100) comprises:

a base (110);

the two first sliding chutes (120) are arranged at the tops of the front end and the rear end of the right side of the base (110) in tandem;

a conveyor belt (130), the conveyor belt (130) mounted within a top recess of the base (110).

3. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the first transmission assembly (200) comprises:

a first motor (210);

the first lead screw (220) is mounted on a left output shaft of the first motor (210) through spline connection, and the first lead screw (220) is mounted on the left output shaft of the first motor (210).

4. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the lateral movement frame assembly (300) comprises:

a lateral movement rack body (310);

the second sliding chute (320) is formed in the top of the front surface of the transverse moving frame body (310);

the two first sliding blocks (330) are arranged at the front end and the rear end of the bottom of the transverse moving frame body (310) in tandem;

the two first threaded holes (340) are correspondingly formed in the right middle ends of the two first sliding blocks (330), and the first threaded holes (340) penetrate through the left sides of the first sliding blocks (330).

5. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the second transmission assembly (400) comprises:

a second motor (410);

and the second lead screw (420) is mounted on the left output shaft of the second motor (410) through spline connection, and the second lead screw (420) is connected with the left output shaft of the second motor through a spline.

6. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the longitudinal moving frame (500) includes:

a longitudinal moving rack body (510);

the second sliding block (520) is arranged at the top of the bottom groove of the longitudinal moving frame body (510) on the longitudinal moving frame body (510), and the second sliding block (520) is arranged at the top of the bottom groove of the longitudinal moving frame body (510);

a second threaded hole (530), wherein the second threaded hole (530) is formed in the front surface of the second slider (520), and the second threaded hole (530) penetrates through the rear surface of the second slider (520);

the third sliding chute (540), the third sliding chute (540) is set on the right side of the top of the longitudinal moving frame body (510).

7. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the third transmission assembly (600) comprises:

a third motor (610);

and the third lead screw (620) is mounted on a bottom output shaft of the third motor (610) through spline connection, and the third lead screw (620) is connected with the bottom output shaft of the third motor (610) through a spline.

8. The automatic nonwoven fabric dividing apparatus according to claim 1, wherein: the laser mount (700) includes:

the laser mounting rack comprises a laser mounting rack body (710), wherein a laser emitting head is arranged in a right groove of the laser mounting rack body (710);

the third sliding block (720) is arranged at the middle end of the left side of the laser mounting frame body (710), a third threaded hole is formed in the top of the third sliding block (720), and the threaded hole penetrates through the bottom of the third sliding block (720).

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