CN212771653U

CN212771653U - Composite fabric edge cutting device

Info

Publication number: CN212771653U
Application number: CN202021321258.9U
Authority: CN
Inventors: 鲁林; 朱唱唱
Original assignee: Shanghai Xinfanglian Automobile Interior Co ltd
Current assignee: Shanghai Xinfanglian Automobile Interior Co ltd
Priority date: 2020-07-07
Filing date: 2020-07-07
Publication date: 2021-03-23
Anticipated expiration: 2030-07-07

Abstract

The embodiment of the utility model provides a side cut device is related to, in particular to compound surface fabric side cut device, include: the cutting table, a first trolley and a second trolley are arranged in the cutting table accommodating area, the first trolley and the second trolley are oppositely arranged along the length direction of the table plate and can slide towards the opposite directions; the device also includes: first, the second cuts the mechanism, and first mechanism of cutting includes: the first driving assembly is arranged in the first trolley, and the first driving assembly and the first cutter are arranged on the bedplate; the second cuts the mechanism and includes: the second driving assembly is arranged in the second trolley, and the second driving assembly and the second cutter are arranged on the bedplate. Compared with the prior art, the cutting device has the advantages of simple structure and convenience in maintenance, and the cutting efficiency of the fabric is improved.

Description

Composite fabric edge cutting device

Technical Field

The embodiment of the utility model provides a side cut device is related to, in particular to compound surface fabric side cut device.

Background

The composite fabric is made by bonding two or more different fabrics together through a special process, and after the finished product is made, redundant fabrics or non-woven fabrics are often arranged on two sides of the finished product of the composite fabric, so that redundant burrs must be cut off to meet the requirements of customers. The existing edge cutting device is a professional edge cutting machine generally, so that the cost is high, the structure is complex, and the edge cutting device can only cut one side of a product at one time generally, so that the edge cutting efficiency is undoubtedly influenced.

SUMMERY OF THE UTILITY MODEL

An embodiment of the utility model aims at providing a compound surface fabric side cut device, simple structure not only, it is convenient to maintain, can once cut the both sides of compound surface fabric simultaneously moreover, has improved the efficiency that cuts.

In order to achieve the above object, an embodiment of the utility model designs a compound surface fabric side cut device, include:

a cutting table; the cutting table is internally provided with an accommodating area, the bottom of the accommodating area is a table plate, the bottom of the accommodating area is a bottom plate, and the table plate is provided with a top sliding groove along the length direction;

the first trolley and the second trolley are arranged in the accommodating area and are oppositely arranged along the length direction of the bedplate; the first trolley and the second trolley are slidable towards the opposite direction;

first mechanism of cutting includes: the first driving assembly is connected with the first transmission assembly, and the first transmission assembly is also connected with the first cutter and is used for driving the first cutter to rotate under the driving action of the first driving assembly;

the second cuts the mechanism, includes: the second driving assembly is arranged in the second trolley, and the second driving assembly and the second cutter are arranged on the bedplate, are connected with the second driving assembly, and are also connected with the second cutter and used for driving the second cutter to rotate under the driving action of the second driving assembly.

Compared with the prior art, the edge cutting device has simple structure, a containing area is arranged in a cutting table of the edge cutting device, a first trolley and a second trolley are arranged in the containing area, the edge cutting device also comprises a first cutting mechanism and a second cutting mechanism, a first driving component of the first cutting mechanism is arranged in the first trolley, a first driving component and a first cutter of the first cutting mechanism are arranged on a bedplate of the cutting table, a second driving component of the second cutting mechanism is arranged in the second trolley, a second driving component and a second cutter of the second cutting mechanism are arranged on the bedplate of the cutting table, so that the first cutting mechanism and the second cutting mechanism can move relative to each other under the action of the first trolley and the second trolley, the cutting requirements of fabrics with different widths can be met, and the opposite sides of the fabrics can be simultaneously cut by the first cutting mechanism and the second cutting mechanism, the efficiency of cutting has been improved.

Additionally, the first transmission assembly includes:

a first gear box slidably disposed on the platen;

the first driven gear is rotatably arranged in the first gear box;

the first linkage shaft is partially inserted into the first gear box and is coaxially connected with the first driven gear;

the first cutter shaft is partially inserted into the first gear box and is arranged in parallel with the first linkage shaft;

the first driving belt wheel is coaxially connected with the first linkage shaft;

a first driven pulley coaxially connected with the first tool shaft;

the first belt is respectively connected with the first driving belt wheel and the first driven belt wheel;

the first cutter is sleeved on the first cutter shaft;

the first drive assembly includes: the driving device comprises a first motor and a first driving gear, wherein the first driving gear is coaxially and fixedly connected with a main shaft of the first motor; the first driving gear is meshed with the first driven gear.

Additionally, the second transmission assembly includes:

a second gearbox slidably disposed on the platen;

a second driven gear rotatably provided in the second gear box;

a second coupling shaft partially inserted into the second gear box and coaxially connected to the second driven gear;

a second tool shaft partially inserted into the second gear box and arranged in parallel with the second link shaft;

the second driving belt wheel is coaxially connected with the second linkage shaft;

the second driven belt wheel is coaxially connected with the second cutter shaft;

the second belt is respectively connected with the second driving belt wheel and the second driven belt wheel;

the second cutter is sleeved on the second cutter shaft;

the second drive assembly includes: the second motor and a second driving gear are coaxially and fixedly connected with a main shaft of the second motor; the second driving gear is meshed with the second driven gear.

In addition, the first cart includes: the pulley device comprises a first vehicle body with a first accommodating cavity and a first pulley arranged at the bottom of the first vehicle body;

the second cart includes: the second trolley comprises a second trolley body with a second accommodating cavity and a second pulley arranged at the bottom of the second trolley body;

the first driving assembly is arranged in the first accommodating cavity, and the second driving assembly is arranged in the second accommodating cavity.

In addition, a linear track in sliding fit with the first pulley and the second pulley is arranged on the bottom plate.

In addition, the first cutter and the second cutter are both circular cutters.

In addition, compound surface fabric side cut device still includes: the first manual pushing mechanism and the second manual pushing mechanism;

the first manual pushing mechanism is connected with the first trolley and used for pushing the first trolley to move linearly relative to the second trolley;

the second manual pushing mechanism is connected with the second trolley and used for pushing the second trolley to perform linear motion relative to the first trolley.

In addition, the bottom plate is provided with a bottom sliding chute along the length direction; the first manual thrust mechanism and the second manual thrust mechanism are oppositely arranged along the length direction of the bottom plate;

the first manual pushing mechanism includes: the first handle, the first handle bracket, the first ball screw and the first sliding block;

the first handle, the first handle support and the first ball screw are all arranged outside the cutting table, the first handle support is fixedly connected with the bottom plate, the first ball screw penetrates through the first handle support along the length direction of the bottom plate and is rotatably connected with the first handle support, the first handle and the first ball screw are coaxially fixed and are used for driving the first ball screw to rotate, the first sliding block is partially embedded into the accommodating area through the bottom sliding groove and is fixedly connected with the first trolley, and the other part of the first sliding block is connected with a ball shaft sleeve of the first ball screw;

the second manual thrust mechanism includes: the second handle, the second handle bracket, the second ball screw and the second sliding block;

the second handle, the second handle support and the second ball screw are all arranged outside the cutting table, the second handle support is fixedly connected with the bottom plate, the second ball screw penetrates through the second handle support along the length direction of the bottom plate and is rotatably connected with the second handle support, the second handle and the second ball screw are coaxially fixed and are used for driving the second ball screw to rotate, the second sliding block is partially embedded into the containing area through the bottom sliding groove and is fixedly connected with the second trolley, and part of the second sliding block is connected with a ball shaft sleeve of the second ball screw.

Drawings

Fig. 1 is a schematic structural view of a composite fabric edge cutting device according to a first embodiment of the present invention;

FIG. 2 is a top view of FIG. 1 with the platen removed;

FIG. 3 is a side view of FIG. 1;

fig. 4 is a schematic structural view of a first cutting mechanism according to a first embodiment of the present invention;

fig. 5 is a schematic structural view of a second cutting mechanism according to the first embodiment of the present invention;

fig. 6 is a schematic plan view of a platen according to a first embodiment of the present invention;

fig. 7 is a schematic view of a connection structure between the first manual pushing mechanism and the second manual pushing mechanism and the first trolley and the second trolley respectively according to the first embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the following will explain in detail each embodiment of the present invention with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that in various embodiments of the invention, numerous technical details are set forth in order to provide a better understanding of the present application. However, the technical solutions claimed in the claims of the present application can be implemented without these technical details and with various changes and modifications based on the following embodiments.

The utility model discloses a second embodiment relates to a compound surface fabric side cut device, as shown in fig. 1 to 3, include: the cutting device comprises a cutting table 1, a first trolley 2, a second trolley 3, a first cutting mechanism 4 and a second cutting mechanism 5.

As shown in fig. 1, the inside of the cutting table 1 is an accommodating area 11, the top of the accommodating area 11 is a table plate 12, the bottom of the accommodating area 11 is a bottom plate 13, and, in combination with fig. 6, the table plate 12 is provided with a top chute 14 along the length direction.

Next, as shown in fig. 1, the first cart 2 and the second cart 3 are both disposed in the accommodating area 11, and the first cart 2 and the second cart 3 are disposed opposite to each other along the length direction of the bedplate 12, so that the first cart 2 and the second cart 3 can slide toward the opposite direction to each other.

Further, as shown in fig. 1 and 2, the first cutting mechanism 4 includes: the first driving component 41 is arranged in the first trolley 2, and the first driving component 42 and the first cutting knife 43 are arranged on the bedplate, the first driving component 41 is connected with the first driving component 42, and the first driving component 42 is further connected with the first cutting knife 43 and used for driving the first cutting knife 43 to rotate under the driving action of the first driving component 41. And correspondingly, the second cutting mechanism 5 includes: the second driving component 51 is arranged in the second trolley 3, and the second transmission component 52 and the second cutter 53 are arranged on the bedplate 12, the second driving component 51 is connected with the second transmission component 52, and the second transmission component 52 is further connected with the second cutter 53 and used for driving the second cutter 53 to rotate under the driving action of the second driving component 51. In addition, the first cutting blade 43 and the second cutting blade 53 in the present embodiment are both circular blades.

As can be seen from the above, the edge cutting device of the present embodiment is not only simple in structure, but also has a containing area 11 in the cutting table 1 of the edge cutting device, and a first cart 2 and a second cart 3 are arranged in the containing area 11, and the edge cutting device further includes a first cutting mechanism 4 and a second cutting mechanism 5, and the first driving component 41 of the first cutting mechanism 4 is arranged in the first cart 2, and the first driving component 42 and the first cutter 43 of the first cutting mechanism 4 are arranged on the platen 12 of the cutting table 1, and in addition, the second driving component 51 of the second cutting mechanism 5 is arranged in the second cart 3, and the second driving component 52 and the second cutter 53 of the second cutting mechanism 5 are arranged on the platen 12 of the cutting table 1, so that the first cutting mechanism 4 and the second cutting mechanism 5 can move relative to each other under the action of the first cart 2 and the second cart 3, thereby satisfy the demand that cuts of different breadth surface fabrics to can cut simultaneously the relative both sides of surface fabric through first mechanism 4 and the second mechanism 5 of cutting, improve the efficiency of cutting.

Specifically, in the present embodiment, as shown in fig. 4, the first transmission assembly 42 includes: a first gear box 421 slidably disposed on the bedplate 12, a first driven gear 422 rotatably disposed in the first gear box 421, a first interlocking shaft 423, a first tool shaft 424, a first driving pulley 425, a first driven pulley 426, and a first belt 427.

As shown in fig. 4, a part of each of the first coupling shaft 423 and the first tool shaft 424 is inserted into the first gear box 421, and the first coupling shaft 423 is coaxially connected to the first driven gear 422 and is parallel to the first tool shaft 424. In addition, a first driving pulley 425 is sleeved on the first linkage shaft 423 and coaxially connected with the first linkage shaft 423, meanwhile, a first driven pulley 426 and a first cutter 43 are sleeved on the first cutter shaft 424 and coaxially connected with the first cutter shaft 424, and a first belt 427 is respectively connected with the first driving pulley 425 and the first driven pulley 426. In addition, in the present embodiment, as shown in fig. 4, the first drive unit 41 includes: the first motor 411, and a first driving gear 412 coaxially and fixedly connected to a main shaft of the first motor 411, wherein the first driving gear 412 is engaged with the first driven gear 422. In practical applications, the first motor 411 may drive the first linkage shaft 423 to rotate through engagement between the first driving gear 412 and the first driven gear 422, and the first driving pulley 425 and the first driven pulley 426 drive the first cutter shaft 424 to rotate while the first linkage shaft 423 rotates.

Similarly, as shown in connection with fig. 5, the corresponding second transmission assembly 52 includes: a second gear box 521 slidably provided on the platen 12, a second driven gear 522 rotatably provided in the second gear box 521, a second link shaft 523, a second tool shaft 524, a second driving pulley 525, a second driven pulley 526, and a second belt 527.

As shown in fig. 5, both the second coupling shaft 523 and the second tool shaft 524 are partially inserted into the second gear box 521, and the second coupling shaft 523 is coaxially connected to the second driven gear 522 and is parallel to the second tool shaft 524. The second driving pulley 525 is sleeved on the second coupling shaft 523 and coaxially connected to the second coupling shaft 523, and the second driven pulley 526 and the second cutter 53 are sleeved on the second cutter shaft 524 and coaxially connected to the second cutter shaft 524, and the second belt 527 is respectively connected to the second driving pulley 525 and the second driven pulley 526. In addition, in the present embodiment, as shown in fig. 3, the second drive unit 51 includes: the second motor 511 and a second driving gear 512 coaxially and fixedly connected with the main shaft of the second motor 511, wherein the second driving gear 512 is engaged with the second driven gear 522. In practical applications, the second motor 511 can drive the second linkage shaft 523 to rotate through the engagement between the second driving gear 512 and the second driven gear 522, and the second linkage shaft 523 rotates while the second driving pulley 525 and the second driven pulley 526 drive the second cutter shaft 524 to rotate.

In addition, in order to achieve the sliding of the first carriage 2 and the second carriage 3 within the housing zone 11, as shown in fig. 1 and 2, the first carriage 2 comprises: a first body 22 having a first receiving chamber 21, a first pulley 23 disposed at a bottom of the first body 22. And the second trolley 3 comprises: a second body 32 having a second receiving chamber 31, and a second pulley 33 provided at the bottom of the second body 32. The first driving element 41 is disposed in the first receiving cavity 21, and the second driving element 51 is disposed in the second receiving cavity 31.

Meanwhile, as shown in fig. 2, the bottom plate 13 is further provided with a linear rail 6 in sliding fit with the first pulley 23 and the second pulley 33. The first trolley 2 and the second trolley 3 can slide to realize guiding through the linear track 6, so that the sliding performance of the first trolley 2 and the second trolley 3 is further improved.

In addition, in order to adjust the sliding distance between the first pulley 23 and the second pulley 33 in the accommodating area 11, as shown in fig. 7, the composite fabric edge cutting device of the present embodiment further includes: a first manual thrust mechanism 7 and a second manual thrust mechanism 8. The first manual pushing mechanism 7 is connected to the first carriage 2 and configured to push the first carriage 2 to move linearly in a direction opposite to the second carriage 3. Correspondingly, the second manual pushing mechanism 8 is connected with the second trolley 3 and used for pushing the second trolley 3 to move linearly relative to the direction of the first trolley 2.

Specifically, in the present embodiment, as shown in fig. 7, the bottom plate 13 of the cutting table 1 is provided with a bottom chute (not shown) along the longitudinal direction, and the first manual pushing mechanism 7 and the second manual pushing mechanism 8 are provided to face each other along the longitudinal direction of the bottom plate 13. And the first manual thrust mechanism 7 includes: a first handle 71, a first handle bracket 72, a first ball screw 73, and a first slider 74. As shown in fig. 1 and 7, a first handle 71, a first handle bracket 72 and a first ball screw 73 are all disposed outside the cutting table 1, the first handle bracket 72 is fixedly connected with the bottom plate 13, the first ball screw 73 penetrates through the first handle bracket 72 along the length direction of the bottom plate 13 and is rotatably connected with the first handle bracket 72, the first handle 71 and the first ball screw 73 are coaxially fixed, the first handle 71 can be used for driving the first ball screw to rotate, in addition, a first slider 74 is partially embedded into the accommodating area 11 through a bottom sliding groove and is fixedly connected with the first car body 22 of the first car 2, and meanwhile, another part of the first slider 74 is connected with a ball shaft sleeve 731 of the first ball screw 73. In practical application, a worker can drive the first ball screw 73 to rotate through the first handle 71, and while the first ball screw 73 rotates, the first slider 74 can drive the first vehicle body 22 to move transversely along the length direction of the first ball screw 73 by means of the threaded connection relationship between the screw 732 and the ball shaft sleeve 731 in the first ball screw 73, so that the adjustment of the moving distance of the first vehicle 2 is realized.

As shown in fig. 1 and 7, the second manual thrust mechanism 8 includes: a second handle 81, a second handle bracket 82, a second ball screw 83, and a second slider 84. As shown in fig. 6 and 7, the second handle 81, the second handle bracket 82 and the second ball screw 83 are all disposed outside the cutting table 1, the second handle bracket 82 is fixedly connected with the bottom plate 13, the second ball screw 83 penetrates through the second handle bracket 82 along the length direction of the bottom plate 13 and is rotatably connected with the second handle bracket 82, the second handle 81 and the second ball screw 83 are coaxially fixed, the second handle 81 can be used for driving the second ball screw to rotate, in addition, a part of the second slider 84 is embedded into the accommodating area 11 through the bottom sliding groove and is fixedly connected with the second car body 32 of the second car 3, and another part of the second slider 84 is connected with the ball bushing 831 of the second ball screw 83. In practical application, a worker can drive the second ball screw 83 to rotate through the second handle 81, and while the second ball screw 83 rotates, the second slider 84 can drive the second vehicle body 32 to move transversely along the length direction of the second ball screw 83 by means of the threaded connection relationship between the screw 832 and the ball sleeve 831 in the second ball screw 83, so as to adjust the moving distance of the second cart 3.

In addition, in the present embodiment, in order to realize the rotational connection between the first ball screw 73 and the first handle bracket 72 and the rotational connection between the second ball screw 83 and the second handle bracket 82, a first bearing sleeve (not shown) may be provided between the first ball screw 73 and the first handle bracket 72, an inner ring of the first bearing sleeve is coaxially fixed with the first ball screw 73, and an outer ring of the first bearing sleeve is fixed with the first handle bracket 72, so that the first ball screw 73 can be fixed in a limited position without affecting the rotation of the first ball screw 73.

Similarly, a second bearing sleeve (not marked in the figure) can be arranged between the second ball screw 83 and the second handle bracket 82, the inner ring of the second bearing sleeve and the second ball screw 83 are coaxially fixed, and the outer ring of the second bearing sleeve and the second handle bracket 82 are fixed, so that the second ball screw 83 can be limited and fixed, and the rotation of the second ball screw 83 can not be influenced.

In addition, it is worth mentioning that, in order to position the first cart 2, as shown in fig. 7, a plurality of first positioning holes 711 are distributed on the first handle 71 around the axial direction of the first ball screw 73, meanwhile, a pin hole 721 is formed on the first handle bracket 72 around the axial direction of the first ball screw 73, and after the first cart 2 is moved to a proper position, one of the first positioning holes 711 on the first handle 71 and the pin hole 721 on the first handle bracket 72 are coaxial, and at this time, a positioning pin (not shown in the figure) can be inserted into the pin hole 721 from the first positioning hole 711, so as to lock the first handle 71, and fix the first cart 2 at the current position.

Similarly, in order to position the second cart 3, as shown in fig. 7, a plurality of second positioning holes 811 are distributed around the axis direction of the second ball screw 83 in the second handle 81, and the second handle bracket 82 is provided with a pin hole 821 around the axis direction of the second ball screw 83, and when the second cart 82 is moved to a proper position, one of the second positioning holes 811 on the second handle 81 and the pin hole 821 on the second handle bracket 82 are coaxial, and at this time, a positioning pin (not shown) can be inserted into the pin hole 821 from the second positioning hole 811 by means of a positioning pin (not shown), so as to lock the second handle 81, and fix the second cart 3 at the current position.

It will be understood by those skilled in the art that the foregoing embodiments are specific examples of the invention, and that various changes in form and details may be made therein without departing from the spirit and scope of the invention in its practical application.

Claims

1. The utility model provides a compound surface fabric side cut device which characterized in that includes:

a cutting table; the cutting table is internally provided with an accommodating area, the top of the accommodating area is a table plate, the bottom of the accommodating area is a bottom plate, and the table plate is provided with a top sliding groove along the length direction;

2. The composite fabric trim apparatus of claim 1 wherein the first transmission assembly comprises:

a first gear box slidably disposed on the platen;

the first driven gear is rotatably arranged in the first gear box;

a first driven pulley coaxially connected with the first tool shaft;

the first cutter is sleeved on the first cutter shaft;

3. The composite fabric trim apparatus of claim 1 wherein the second drive assembly comprises:

a second gearbox slidably disposed on the platen;

a second driven gear rotatably provided in the second gear box;

the second cutter is sleeved on the second cutter shaft;

4. The composite fabric trim apparatus of claim 1 wherein the first cart comprises: the pulley device comprises a first vehicle body with a first accommodating cavity and a first pulley arranged at the bottom of the first vehicle body;

5. The composite fabric trimming apparatus according to claim 4, wherein the base plate is provided with a linear rail in sliding engagement with the first and second pulleys.

6. The composite fabric trimming apparatus according to claim 1, wherein the first cutter and the second cutter are circular cutters.

7. The composite fabric edge slitting device according to any one of claims 1 to 6, further comprising: the first manual pushing mechanism and the second manual pushing mechanism;

8. The composite fabric trimming device according to claim 7, wherein the bottom plate is provided with a bottom chute along the length direction; the first manual thrust mechanism and the second manual thrust mechanism are oppositely arranged along the length direction of the bottom plate;