CN110219160B

CN110219160B - Automatic braid processing device

Info

Publication number: CN110219160B
Application number: CN201910500688.2A
Authority: CN
Inventors: 谢雄星; 邱惠峰
Original assignee: Nantong Taiying New Material Technology Co ltd
Current assignee: NANTONG TAIYING NEW MATERIAL TECHNOLOGY Co.,Ltd.
Priority date: 2019-06-11
Filing date: 2019-06-11
Publication date: 2020-07-24
Anticipated expiration: 2039-06-11
Also published as: CN110219160A

Abstract

The invention discloses an automatic braid processing device which structurally comprises a placing frame, a workbench, a cutting and pulling integrated device, a guide plate and a base, wherein the placing frame is arranged above the workbench, the workbench is fixedly welded with the base, the base is connected with the placing frame through the workbench, the cutting and pulling integrated device is arranged on the workbench, the guide plate is mutually vertical to the surface of the workbench, and the guide plate is connected with the base, and the automatic braid processing device has the beneficial effects that: utilize outer mechanical force drive center pin to drive the dead lever rotatory, thereby make positive pole magnetic path and negative pole magnetic path clip the meshbelt and rotate a week thereupon, and tailor it, realize the unity of meshbelt internal diameter, through the alternate circular telegram between external force control positive pole magnetic path, No. two positive pole magnetic paths, can make positive pole magnetic path, clip the meshbelt and pull it between No. two positive pole magnetic paths in turn, thereby length when having ensured the continuity production of meshbelt is fixed, the phenomenon that the meshbelt had been cut off when having avoided not pulling the meshbelt to predicted length.

Description

Automatic braid processing device

Technical Field

The invention relates to the field of textile woven belts, in particular to an automatic woven belt processing device.

Background

Since the length and the inner diameter of the sleeve are fixed, the length and the diameter of the braid need to be cut at a fixed length, so as to ensure the length and the diameter of the sleeve to be uniform, and the conventional automatic braid processing device has the following defects:

the existing automatic mesh belt processing device needs to set a pulling mechanism to pull back the mesh belt after the mesh belt is cut off, so that the next section of mesh belt is cut off, and when the two mechanisms work independently, due to accumulation of working time difference, the mesh belt is cut off when the mesh belt is not pulled to the expected length for a long time.

Disclosure of Invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme:

an automatic woven tape processing device structurally comprises a placing frame, a workbench, a cutting and pulling integrated device, a guide plate and a base, wherein the placing frame is arranged above the workbench, the workbench is fixedly welded with the base, the base is connected with the placing frame through the workbench, the cutting and pulling integrated device is installed on the workbench, the guide plate is perpendicular to the surface of the workbench, and the guide plate is connected with the base;

the cutting and material pulling integrated device is composed of a central shaft, a driving roller, a cutting mechanism and a material pulling mechanism, wherein the central shaft is arranged in the center of the driving roller, the driving roller is in mechanical transmission fit with the central shaft, the cutting mechanism is arranged in an inner cavity of the driving roller, the cutting mechanism is in mechanical fit with the material pulling mechanism, the material pulling mechanism is in mechanical welding with the central shaft, and the central shaft is connected with an external mechanical force.

As a further optimization of the invention, the cutting mechanism is composed of a spring, a guide cavity, a cutter and a limiting structure, wherein the spring is arranged in the guide cavity, the guide cavity is arranged in the inner cavity of the driving roller and is connected with the central shaft, the cutter is arranged in the guide cavity, the cutter is matched with the guide cavity, the guide cavity is in a rectangular cavity shape, the limiting structure is mechanically connected with the cutter, the cutter penetrates through the outer wall of the driving roller, one end of the spring is fixedly connected with the central shaft, and the other end of the spring is fixed with the cutter.

As a further optimization of the invention, the material pulling mechanism comprises a clamping structure, a push plate and two fixing rods, wherein the clamping structure is mechanically connected with the fixing rods, the fixing rods are fixedly connected with the central shaft, the clamping structure is arranged at one end of the fixing rod far away from the central shaft, the push plate is mechanically welded with the fixing rods, the push plate is mutually vertical to the fixing rods, and the push plate is movably connected with the limiting structure.

As a further optimization of the invention, the limiting structure is composed of a limiting plate and a fixed plate, the limiting plate is mechanically connected with the fixed plate, one end of the limiting plate, which is connected with the fixed plate, penetrates through and is fixed by a fixed shaft, and a clockwork spring is arranged in the fixed shaft.

As a further optimization of the invention, when the limiting plate and the fixed plate are positioned on the same vertical line, one end of the limiting plate far away from the fixed plate is just connected with one end of the cutter close to the spring.

As a further optimization of the invention, the clamping structure comprises a first positive pole magnetic block, a movable plate, a second positive pole magnetic block and a track, wherein the first positive pole magnetic block and the second positive pole magnetic block are oppositely arranged, the first positive pole magnetic block and the second positive pole magnetic block are respectively arranged on two ends of the movable plate, the center of the movable plate is fixed, the number of the tracks is two, the first positive pole magnetic block and the second positive pole magnetic block are respectively arranged on the two tracks, and the first positive pole magnetic block and the second positive pole magnetic block are mechanically and slidably matched with the tracks.

As a further optimization of the invention, the first positive magnetic block and the second positive magnetic block are arranged on the same side of the transmission roller, and a negative magnetic block with opposite magnetism to the first positive magnetic block and the second positive magnetic block is arranged on the side opposite to the first positive magnetic block and the second positive magnetic block.

As a further optimization of the invention, the fixed rod is mechanically connected with the back surfaces of the first positive magnetic block and the second positive magnetic block, a sliding rod is arranged on the surface perpendicular to the fixed rod, and the sliding rod penetrates through the first positive magnetic block and the second positive magnetic block and is in mechanical sliding fit with the track.

Compared with the prior art, the invention has the following advantages:

the fixing rod is driven to rotate by driving the central shaft through external mechanical force, so that the first positive magnet and the first negative magnet clamp the woven tape and rotate the woven tape for a circle, and the woven tape is cut, and the inner diameters of the woven tapes are uniform; through the alternate electrification between the first positive magnetic block and the second positive magnetic block under the control of external force, the woven belt can be clamped and pulled alternately between the first positive magnetic block and the second positive magnetic block, so that the length of the woven belt is fixed during continuous production, and the phenomenon that the woven belt is cut off when the woven belt is not pulled to the preset length is avoided.

Drawings

Fig. 1 is a schematic structural diagram of an automatic webbing processing apparatus according to the present invention.

Fig. 2 is a cross-sectional view of a cutting and pulling integrated device of an automatic mesh belt processing device according to the present invention.

Fig. 3 is a cross-sectional view of the cutting and pulling integrated device of the automatic mesh belt processing device according to the present invention.

Fig. 4 is a schematic view of a connection relationship between a first positive magnetic block and a second positive magnetic block of the automatic mesh belt processing device according to the present invention.

Fig. 5 is a schematic view of a connection relationship between a limiting plate and a push plate of the automatic webbing processing apparatus according to the present invention.

Fig. 6 is a schematic view of a connection relationship between a limiting plate and a fixing plate of the automatic webbing processing apparatus according to the present invention.

In the drawing, a placing rack-1, a workbench-2, a cutting and pulling integrated device-3, a guide plate-4, a base-5, a central shaft-a, a driving roller-b, a cutting mechanism-c, a pulling mechanism-d, a spring-c 1, a guide cavity-c 2, a cutter-c 3, a limiting structure-c 4, a clamping structure-d 1, a push plate-d 2, a fixed rod-d 3, a limiting plate-e, a fixed plate-f, a first positive magnet-h, a movable plate-i, a second positive magnet-j and a track-k are arranged.

Detailed Description

The preferred embodiments of the present invention will be further described with reference to the following description and accompanying drawings.

Examples

Referring to fig. 1-6, the invention provides an automatic processing device for woven belts, which structurally comprises a placing frame 1, a workbench 2, a cutting and pulling integrated device 3, a guide plate 4 and a base 5, wherein the placing frame 1 is arranged above the workbench 2, the workbench 2 is fixedly welded with the base 5, the base 5 is connected with the placing frame 1 through the workbench 2, the cutting and pulling integrated device 3 is arranged on the workbench 2, the guide plate 4 is perpendicular to the surface of the workbench 2, and the guide plate 4 is connected with the base 5;

the cutting and material pulling integrated device 3 is composed of a central shaft a, a transmission roller b, a cutting mechanism c and a material pulling mechanism d, wherein the central shaft a is arranged in the center of the transmission roller b, the transmission roller b is in mechanical transmission fit with the central shaft a, the cutting mechanism c is arranged in an inner cavity of the transmission roller b, the cutting mechanism c is in mechanical fit with the material pulling mechanism d, the material pulling mechanism d is in mechanical welding with the central shaft a, and the central shaft a is in mechanical connection with an external machine.

The cutting mechanism c comprises a spring c1, a guide cavity c2, a cutter c3 and a limiting structure c4, the spring c1 is installed in the guide cavity c2, the guide cavity c2 is arranged in the inner cavity of the driving roller b and connected with the central shaft a, the cutter c3 is installed in the guide cavity c2, the cutter c3 is matched with the guide cavity c2, the guide cavity c2 is in a rectangular cavity shape, the limiting structure c4 is mechanically connected with the cutter c3, the cutter c3 penetrates through the outer wall of the driving roller b, one end of the spring c1 is fixedly connected with the central shaft a, the other end of the spring c3 is fixed together with the cutter c4, one end of the cutter c3 connected with the spring c1 is connected with the limiting structure c4, and the cutter c3 is controlled by means of the limiting structure c 4.

The material pulling mechanism d comprises a clamping structure d1, a push plate d2 and a fixed rod d3, wherein the clamping structure d1 is mechanically connected with the fixed rod d3, two fixed rods d3 are arranged, the fixed rod d3 is fixedly connected with a central shaft a, the clamping structure d1 is arranged at one end, away from the central shaft a, of the fixed rod d3, the push plate d2 is mechanically welded with the fixed rod d3, the push plate d2 is perpendicular to the fixed rod d3, the push plate d2 is movably connected with a limiting structure c4, and when the push plate d2 rotates along with the fixed rod d3, the limiting structure c4 is pushed to be separated from the cutter c3, so that the cutter 3 is ejected outwards to cut the woven belt.

The limiting structure c4 comprises a limiting plate e and a fixing plate f, the limiting plate e is mechanically connected with the fixing plate f, one end of the limiting plate e, which is connected with the fixing plate f, penetrates through and is fixed through a fixing shaft, a clockwork spring is arranged in the fixing shaft, and the limiting plate e can be pushed by the push plate d2 and rotates around the fixing shaft by the clockwork spring, and then has a reverse acting force to realize reset.

When the limiting plate e and the fixing plate f are positioned on the same vertical line, one end of the limiting plate e, which is far away from the fixing plate f, is just connected with one end of the cutter c3, which is close to the spring c 1.

The clamping structure d1 is composed of a first positive pole magnetic block h, a movable plate i, a second positive pole magnetic block j and rails k, the first positive pole magnetic block h and the second positive pole magnetic block j are oppositely arranged, the first positive pole magnetic block h and the second positive pole magnetic block j are respectively installed on two ends of the movable plate i, the center of the movable plate i is fixed, the number of the rails k is two, the first positive pole magnetic block h and the second positive pole magnetic block j are respectively arranged on the two rails k, the first positive pole magnetic block h and the second positive pole magnetic block j are in mechanical sliding fit with the rails k, the first positive pole magnetic block h and the second positive pole magnetic block j are electrically connected with an external power box, and electricity is alternately conducted between the first positive pole magnetic block h and the second positive pole magnetic block j.

The first positive magnetic block h and the second positive magnetic block j are arranged on the same side of the transmission roller b, the negative magnetic block with opposite magnetism is arranged on the side opposite to the first positive magnetic block h and the second positive magnetic block j, the magnetic blocks attract each other through the difference of magnetism, the magnetism of the magnetic blocks is increased by current, and the woven belt is clamped and pulled to move along with the woven belt.

The fixing rod d3 is mechanically connected with the back surfaces of the first positive magnetic block h and the second positive magnetic block j, a sliding rod is arranged on the surface perpendicular to the fixing rod d3, and the sliding rod penetrates through the first positive magnetic block h and the second positive magnetic block j and is in mechanical sliding fit with the track k.

When the first positive magnetic block h is electrified, the magnetism of the first positive magnetic block h is increased, and at the moment, the second positive magnetic block j is not electrified, so that the attraction force between the first positive magnetic block h and the negative magnetic block is large enough to clamp the woven belt, under the drive of external mechanical force, the central shaft a rotates anticlockwise, and the first positive magnetic block h is driven to rotate along with the central shaft a through the fixing rod d3, so that the woven belt rotates along with the first positive magnetic block h and the negative magnetic block under the pulling action of the first positive magnetic block h and the negative magnetic block, and after the fixing rod d3 rotates for a circle, the fixing rod d3 drives the push plate d2 to move along with the central shaft, so that the push plate d2 rotates and pushes the limit plate e, the limit plate e rotates clockwise around the fixing shaft, at the moment, the limit plate is separated from one end, close to the spring c1, so that the cutter c3 is ejected outwards under the action of the spring c1, the woven, utilize the clockwork spring to make limiting plate e promote by push pedal d2 and after the duplex winding fixed axle is rotatory, have a reverse effort and realize reseing, the power supply of a positive pole magnetic path h stops this moment, change into No. two positive pole magnetic paths j circular telegrams, thereby No. two positive pole magnetic paths j and negative pole magnetic path are cliied the meshbelt and are pulled the meshbelt and move on track k, make the meshbelt pull once more and encircle a week after, cutter c3 cuts off the meshbelt once more, go round and go round again, realize the meshbelt and cut out the pulling material integration, solved because the accumulation of operating time difference, the meshbelt has been cut off when not pulling the meshbelt to predicted length.

The invention solves the problem that the existing automatic mesh belt processing device needs to set a pulling mechanism to pull back the mesh belt after cutting the mesh belt, so as to cut the next section of mesh belt, when the two mechanisms work independently, because of the accumulation of the working time difference, the mesh belt is cut off when the mesh belt is not pulled to the expected length for a long time, the invention utilizes the mutual combination of the components, and utilizes the external mechanical force to drive the central shaft a to drive the fixing rod d3 to rotate, so that the first positive magnetic block h and the negative magnetic block clamp the mesh belt and rotate the same for one circle, and cut the same, thereby realizing the unification of the inner diameters of the mesh belt; through the alternate electrification between the first positive magnetic block h and the second positive magnetic block j under the control of external force, the woven belt can be clamped and pulled alternately between the first positive magnetic block h and the second positive magnetic block j, so that the length of the woven belt is fixed during continuous production, and the phenomenon that the woven belt is cut off when the woven belt is not pulled to the preset length is avoided.

Claims

1. The utility model provides a meshbelt automatic processing device, its structure includes rack (1), workstation (2), cuts out and draws integrative device of material (3), deflector (4), base (5), its characterized in that:

the cutting and pulling integrated device is characterized in that the placing frame (1) is arranged above the workbench (2), the workbench (2) is fixedly welded with the base (5), the base (5) is connected with the placing frame (1) through the workbench (2), the cutting and pulling integrated device (3) is installed on the workbench (2), the guide plate (4) is perpendicular to the table top of the workbench (2), and the guide plate (4) is connected with the base (5);

the cutting and material pulling integrated device (3) is composed of a central shaft (a), a transmission roller (b), a cutting mechanism (c) and a material pulling mechanism (d), wherein the central shaft (a) is arranged in the center of the transmission roller (b), the transmission roller (b) is in mechanical transmission fit with the central shaft (a), the cutting mechanism (c) is arranged in an inner cavity of the transmission roller (b), the cutting mechanism (c) is in mechanical fit with the material pulling mechanism (d), the material pulling mechanism (d) is in mechanical welding with the central shaft (a), and the central shaft (a) is connected with an external mechanical force;

the cutting mechanism (c) is composed of a spring (c1), a guide cavity (c2), a cutter (c3) and a limiting structure (c4), the spring (c1) is installed in the guide cavity (c2), the cutter (c3) is matched with the guide cavity (c2), the limiting structure (c4) is mechanically connected with the cutter (c3), one end of the spring (c1) is fixedly connected with the central shaft (a), and the other end of the spring (c1) is fixed with the cutter (c 3);

draw material mechanism (d) to constitute by clamping structure (d1), push pedal (d2), dead lever (d3), clamping structure (d1) and dead lever (d3) mechanical connection, dead lever (d3) and center pin (a) fixed connection, push pedal (d2) and dead lever (d3) mechanical welding, push pedal (d2) and limit structure (c4) swing joint.

2. An apparatus for automatically processing a web according to claim 1, wherein: the limiting structure (c4) is composed of a limiting plate (e) and a fixing plate (f), the limiting plate (e) is mechanically connected with the fixing plate (f), one end of the limiting plate (e) connected with the fixing plate (f) penetrates through and is fixed through a fixing shaft, and a clockwork spring is arranged in the fixing shaft.

3. An apparatus for automatically processing a web according to claim 2, wherein: when the limiting plate (e) and the fixing plate (f) are positioned on the same vertical line, one end of the limiting plate (e), which is far away from the fixing plate (f), is just connected with one end of the cutter (c3), which is close to the spring (c 1).

4. An apparatus for automatically processing a web according to claim 1, wherein: the clamping structure (d1) is composed of a first positive pole magnetic block (h), a movable plate (i), a second positive pole magnetic block (j) and a track (k), the first positive pole magnetic block (h) and the second positive pole magnetic block (j) are oppositely arranged, the first positive pole magnetic block (h) and the second positive pole magnetic block (j) are respectively installed on two ends of the movable plate (i), and the first positive pole magnetic block (h) and the second positive pole magnetic block (j) are in mechanical sliding fit with the track (k).

5. An apparatus for automatically processing a web according to claim 4, wherein: the first positive magnetic block (h) and the second positive magnetic block (j) are arranged on the same side of the transmission roller (b), and a negative magnetic block with opposite magnetism to the first positive magnetic block (h) and the second positive magnetic block (j) is arranged on the side opposite to the first positive magnetic block (h) and the second positive magnetic block (j).

6. An apparatus for automatically processing a web according to claim 1, wherein: the fixing rod (d3) is mechanically connected with the back surfaces of the first positive magnetic block (h) and the second positive magnetic block (j), a sliding rod is arranged on the surface perpendicular to the fixing rod (d3), and the sliding rod penetrates through the first positive magnetic block (h) and the second positive magnetic block (j) and is mechanically matched with the track (k) in a sliding manner.