CN112276570B - Intelligent informatization production system of large circular knitting machine center group - Google Patents

Abstract

The invention provides an intelligent informatization production system of a large circular knitting machine center group, which comprises a triangle processing device for processing an annular triangle blank into a convex annular triangle. According to the invention, the annular triangle blank is processed at one time, and then the annular triangles with the processed bulges are cut into the individual triangular blocks one by one, so that the efficiency of processing the triangular blocks is improved, and the matching connection between two adjacent triangular blocks arranged on the triangular base is facilitated.

Description

Intelligent informatization production system of large circular knitting machine center group

Technical Field

The invention relates to the technical field of machining of a large circular knitting machine center group, in particular to an intelligent informatization production system of the large circular knitting machine center group.

Background

Circular knitting machine, known as circular weft knitting machine. The circular knitting machine has the advantages of multiple knitting systems, high rotating speed, high yield, quick pattern change, good fabric quality, few working procedures and strong product adaptability, so the circular knitting machine is developed quickly, the central group of the circular knitting machine is the heart of the circular knitting machine and mainly comprises a needle cylinder, a knitting needle, a triangle, a triangular seat and other parts, and the triangular seat is fixed on a fixed part of the central group and is used for driving the triangle on the triangular seat to move up and down.

The triangle is also called as "shan jiao" or "Ling jiao". According to different requirements of knitting varieties of circular knitting machines, the knitting needles and the sinkers are controlled to do reciprocating motion in the needle cylinder grooves. The cam is provided with five types of stitch cam (full stitch cam), tuck cam (half stitch cam), floating cam (plain stitch cam), anti-string cam (fat cam) and pin cam (proofing cam).

The knitting needles slide on the tracks above the cams to complete the work from the yarn to the fabric. Therefore, the requirement for matching the connection part between the triangles is high.

The processing to the triangle block among the prior art is usually to processing single triangle block, lays a plurality of triangle blocks of processing alone on the cam seat again, forms the lopped triangle, because the machining efficiency of single triangle block of processing is lower, and the triangle block of a plurality of processing alone also difficult assurance adjacent triangle's cooperation relation on the connection cooperation.

Accordingly, the present inventors have made extensive studies to solve the above problems and have made the present invention.

Disclosure of Invention

The invention aims to provide an intelligent informatization production system of a large circular knitting machine center group, which aims to solve the problems that the processing efficiency of a single processed triangular block is low and the matching relation of adjacent triangles is difficult to grasp on the connection and matching of a plurality of singly processed triangular blocks in the background technology.

In order to achieve the purpose, the invention adopts the following technical scheme:

an intelligent informatization production system of a large circular knitting machine center group comprises a triangle processing device which processes an annular triangle blank into a convex annular triangle.

Further, triangle processingequipment is including carrying out the first positioner who fixes a position to annular triangle blank and the first cutting device who cuts the triangle blank after the location.

Further, the first cutting device comprises a rotary cutting part for cutting the surface of the triangular blank.

Further, the rotary cutting component comprises a rotary cutting gun for rotary cutting the surface of the triangular blank.

Further, the rotary cutting gun comprises a rotary cutting head which performs rotary cutting on the surface of the triangular blank to form a protrusion.

Further, the rotary cutting component also comprises a cutting rotation driving device for driving the rotary cutting gun to rotate; the output end of the cutting rotation driving device is connected with the rotary cutting gun.

Further, the first cutting device further comprises a movement driving device for driving the rotary cutting component to move along a preset track.

Further, the movement driving device comprises a manipulator for driving the rotary cutting component to move along a preset track; the output end of the manipulator is connected with the rotary cutting component.

Further, the first positioning device comprises a first positioning component for positioning the triangular blank.

Further, the first positioning part comprises a plurality of positioning seats for positioning the triangular blank.

Further, the positioning seat includes the supporting part that supports the triangle blank and carries out the top that supports to the lateral wall of triangle blank.

Furthermore, the supporting part is provided with a guiding part for guiding the triangular blank to slide in.

Further, the introduction portion includes an introduction slope provided gradually inclined downward from the upper surface of the support portion toward the direction of the inner end surface.

Furthermore, a plurality of the positioning seats surround the triangular blank and are arranged at equal intervals.

Further, the first positioning device further comprises a guiding device for guiding the plurality of positioning seats to gradually move inwards to position the triangular blank.

Further, the guiding device comprises a guiding part for guiding the plurality of positioning seats to gradually move inwards to position the triangular blank.

Furthermore, a plurality of sliding grooves corresponding to the positioning seats one by one are formed on the upper surface of the guiding part; the positioning seat is connected in the sliding groove in a sliding mode.

Furthermore, a first clamping block extends outwards from one side of the positioning seat, and a second clamping block extends outwards from the other side of the positioning seat; a first clamping groove matched with the first clamping block is formed in one side of the sliding groove, and a second clamping groove matched with the second clamping block is formed in the other side of the sliding groove; the first clamping block and the second clamping block of the positioning seat are respectively in sliding connection with the first clamping groove and the second clamping groove.

Furthermore, the first positioning device further comprises a jacking driving device for driving the plurality of positioning seats to slide in the sliding grooves and jack up the triangular blanks.

Furthermore, the jacking driving device comprises a plurality of jacking air cylinders which correspond to the positioning seats one by one; the output end of the jacking cylinder is connected with the positioning seat.

Further, the cutting mechanism is used for cutting the annular triangle with the protrusions into a plurality of triangular blocks.

Further, the dicing mechanism includes a dicing device that cuts the annular triangle one by one into a plurality of triangle pieces.

Further, the dicing apparatus includes a laser cutting apparatus that cuts the annular triangle into a plurality of triangle pieces.

Further, the laser cutting device comprises a laser cutting component for cutting the surface of the annular triangle.

Further, the laser cutting component comprises a laser cutting gun for cutting the annular triangle.

Further, the laser cutting device also comprises a power driving device for driving the laser cutting component to move along a preset track.

Further, the power driving device comprises a first power cylinder for driving the laser cutting gun to move left and right and a second power cylinder for driving the laser cutting gun to move up and down; the output end of the first power cylinder is connected with the laser cutting component, and the output end of the second power cylinder is connected with the first power cylinder.

Further, the dicing mechanism further comprises a second positioning device for positioning the annular triangle before cutting.

Further, the second positioning device comprises a second positioning member carrying an annular triangle.

Further, the second positioning part includes a plurality of positioning blocks supporting the circular triangle.

Further, the locating piece is including the bearing part that bears the weight of annular triangle and the joint in the joint portion of annular triangle inside wall.

Further, a cutting space for downward cutting of the laser cutting gun is formed between the adjacent positioning blocks.

Furthermore, a plurality of locating pieces encircle annular triangle equidistant setting.

Further, the dicing mechanism further comprises a triangle rotation driving device for driving the annular triangle to rotate.

Further, the triangular rotation driving device comprises a first gear, a second gear and a rotating motor for driving the second gear to rotate; the positioning blocks are arranged on the upper surface of the first gear, the first gear is meshed with the second gear, and the output end of the rotating motor is connected with the second gear.

Further, the gear transmission device further comprises a support table for supporting the first gear and the second gear.

After the structure is adopted, the intelligent informatization production system of the large circular knitting machine center group has at least the following beneficial effects:

the annular triangle blank is processed into the bulge for the sliding of the knitting needle at one time through the triangle processing device, and then the annular triangle processed with the bulge is cut into the individual triangle blocks one by one, so that the processing efficiency is improved, and when the triangle blocks are arranged on the triangle base to form the looped triangle, the triangle blocks are all cut off from the same annular triangle, so that the cutting surfaces of the triangle blocks and the adjacent triangle blocks are more easily matched and connected together; according to the invention, the annular triangle blank is processed at one time, and then the annular triangles with the processed bulges are cut into the individual triangular blocks one by one, so that the efficiency of processing the triangular blocks is improved, and the matching connection between two adjacent triangular blocks arranged on the triangular base is facilitated.

Drawings

FIG. 1 is a schematic perspective view of an intelligent informatization production system of a large circular knitting machine center group according to the invention;

FIG. 2 is a schematic perspective view of a triangular processing device of an intelligent informatization production system of a large circular knitting machine center group according to the present invention;

fig. 3 is a schematic perspective view of a positioning seat of an intelligent informatization production system of a large circular knitting machine center group according to the invention;

FIG. 4 is a schematic perspective view of a dicing mechanism of an intelligent informatization production system of a large circular knitting machine center group according to the present invention;

FIG. 5 is a schematic perspective view of a dicing apparatus of an intelligent informatization production system of a large circular knitting machine center group according to the present invention;

fig. 6 is a schematic perspective view of a second positioning device of an intelligent informatization production system of a large circular knitting machine center group according to the present invention.

In the figure: 1-a first positioning device, 2-a first cutting device, 21-a rotary cutting member, 211-a rotary cutting gun, 2111-a rotary cutting head, 212-a cutting rotary drive, 22-a mobile drive, 11-a first positioning member, 111-a positioning seat, 1111-a support, 1112-a coping, 1113-an introduction portion, 12-a guide, 121-a guide, 1211-a sliding groove, 1114-a first snap-in block, 1115-a second snap-in block, 1212-a first snap-in groove, 1213-a second snap-in groove, 3-a cutting block device, 31-a laser cutting device, 311-a laser cutting member, 3111-a laser cutting gun, 312-a power drive, 3121-a first power cylinder, 3122-a second power cylinder, 4-a second positioning device, 41-a second positioning component, 411-a positioning block, 4111-a bearing part, 4112-a clamping part, 5-a triangular rotation driving device, 51-a first gear, 52-a second gear, 53-a rotation motor and 6-a supporting table.

Detailed Description

In order to further explain the technical solution of the present invention, the following detailed description is given by way of specific examples.

As shown in fig. 1 to 6, the intelligent informatization production system of a large circular knitting machine center group of the invention comprises a triangle processing device which processes an annular triangle blank into an annular triangle with a protrusion.

Therefore, the annular triangle blank is processed with the bulge for the sliding of the knitting needle at one time through the triangle processing device, and the annular triangle processed with the bulge is cut into the individual triangle blocks one by one, so that the processing efficiency is improved, and when the triangle blocks are placed on the triangle base to form the looped triangle, the triangle blocks are all cut off from the same annular triangle, so that the cutting surfaces of the triangle blocks and the adjacent triangle blocks are more easily matched and connected together; according to the invention, the annular triangle blank is processed at one time, and then the annular triangles with the processed bulges are cut into the individual triangular blocks one by one, so that the efficiency of processing the triangular blocks is improved, and the matching connection between two adjacent triangular blocks arranged on the triangular base is facilitated.

Preferably, the triangle processing device comprises a first positioning device 1 for positioning the annular triangle blank and a first cutting device 2 for cutting the positioned triangle blank. The annular triangular blank is positioned through the first positioning device 1, and the closed-loop track protrusions for sliding of the knitting needles are gradually machined on the inner side wall of the annular triangular blank through the first cutting device 2 after positioning.

Preferably, the first cutting device 2 comprises a rotary cutting member 21 that cuts the surface of the triangular blank. A closed loop track bulge for the sliding of a knitting needle is gradually processed on the inner side wall of the annular triangle blank by rotating the cutting part 21.

Preferably, the rotary cutting means 21 comprise a rotary cutting torch 211 for rotary cutting of the surface of the triangular blank. And a closed-loop track bulge for sliding of a knitting needle is gradually machined on the inner side wall of the annular triangular blank by the rotary cutting gun 211.

Preferably, the rotary cutting gun 211 includes a rotary cutting head 2111 for rotary cutting the surface of the triangular blank to form a protrusion. A closed loop track bulge for a knitting needle to slide is gradually machined on the inner side wall of the annular triangle blank through rotating the cutting head 2111.

Preferably, the rotary cutting part 21 further comprises a cutting rotary driving means 212 for driving the rotary cutting torch 211 to rotate; the output of the cutting rotary drive 212 is coupled to the rotary cutting torch 211. The rotary cutting gun 211 is driven to rotate at a high speed by the cutting and rotating driving device 212, and track protrusions for sliding of knitting needles are gradually machined on the inner side wall; in particular, the cutting rotary drive 212 is motor driven.

Preferably, the first cutting device 2 further comprises movement driving means 22 for driving the rotary cutting member 21 along a predetermined trajectory. The rotary cutting component 21 is driven by the movable driving device 22 to cut the inner side wall of the annular triangular blank to a certain depth, and then the annular triangular blank is gradually cut into a closed-loop track bulge by surrounding the inner side wall of the annular triangular blank.

Preferably, the movement driving means 22 comprise a robot arm which drives the rotary cutting member 21 to move along a predetermined trajectory; the output of the robot is connected to a rotary cutting unit 21. After the inner side wall of the annular triangular blank is cut to a certain depth by the mechanical arm driving rotary cutting component 21, the closed-loop track bulge is gradually cut around the inner side wall of the annular triangular blank.

Preferably, in order to facilitate the machining of the annular triangular blank by the rotary cutting member 21, the first positioning device 1 comprises a first positioning member 11 for positioning the triangular blank.

Preferably, in order to facilitate the rotary cutting member 21 to machine the annular triangular blank, the first positioning member 11 includes a plurality of positioning seats 111 for positioning the triangular blank.

Preferably, the positioning seat 111 includes a supporting portion 1111 for supporting the triangular blank, and an abutting portion 1112 for abutting against an outer side wall of the triangular blank. Put annular triangle blank on the supporting part 1111 of a plurality of positioning seats 111, support top 1112 and prevent annular triangle blank displacement, be favorable to improving the accuracy of machining efficiency and processing.

Preferably, in order to make the positioning of the annular triangular blank smoother, the supporting portion 1111 is provided with a guiding portion 1113 for guiding the triangular blank to slide in.

Preferably, in order to make the annular triangular blank smoother in positioning, the introduction portion 1113 includes a introduction slope provided gradually inclined downward from the upper surface of the support portion 1111 toward the direction of the inner end surface.

Preferably, in order to improve the positioning effect, the positioning seats 111 are arranged around the triangular blank at equal intervals.

Preferably, in order to make the positioning more accurate, the first positioning device 1 further comprises a guiding device 12 for guiding the plurality of positioning bases 111 to gradually move inwards to position the triangular blank.

Preferably, in order to make the positioning more accurate, the guiding device 12 includes a guiding portion 121 for guiding the plurality of positioning bases 111 to gradually move inward to position the triangular blank.

Preferably, a plurality of sliding grooves 1211 corresponding to the positioning seats 111 one by one are formed on the upper surface of the guide part 121; the positioning seat 111 is slidably connected in the sliding groove 1211. Each positioning seat 111 slides in the corresponding sliding groove 1211, and the positioning seat 111 is guided by the sliding groove 1211, so that the positioning accuracy of the annular triangular blank by the positioning seat 111 is higher.

Preferably, in order to prevent the annular triangular blank from displacing up and down when the positioning seat 111 vibrates during machining, a first clamping block 1114 extends outwards from one side of the positioning seat 111, and a second clamping block 1115 extends outwards from the other side of the positioning seat 111; a first clamping groove 1212 matched with the first clamping block 1114 is arranged at one side of the sliding groove 1211, and a second clamping groove 1213 matched with the second clamping block 1115 is arranged at the other side of the sliding groove 1211; the first clamping block 1114 and the second clamping block 1115 of the positioning seat 111 are slidably connected with the first clamping groove 1212 and the second clamping groove 1213, respectively.

Preferably, the first positioning device 1 further comprises a tightening driving device for driving the plurality of positioning seats 111 to slide in the sliding groove 1211 to tighten the triangular blank. The annular triangular blank is positioned by tightly pushing the driving device to drive the positioning seat 111, and the annular triangular blank is loosened by the driving positioning seat 111 after the annular triangular blank is machined.

Preferably, the jacking driving device includes a plurality of jacking cylinders corresponding to the positioning seats 111 one by one; the output end of the jacking cylinder is connected with the positioning seat 111. The positioning seat 111 is driven to move simultaneously through a plurality of jacking cylinders, and the annular triangular blank is positioned.

Preferably, the cutting mechanism is used for cutting the annular triangle with the protrusions into a plurality of triangular blocks.

Preferably, the dicing mechanism includes a dicing device 3 that cuts the annular triangle one by one into a plurality of triangle pieces. The ring triangle is cut into the triangle block monomer by the block cutting device 3, which is convenient for use.

Preferably, the dicing apparatus 3 includes a laser cutting apparatus 31 that cuts the annular triangle into a plurality of triangular blocks. The laser cutting device 31 is extremely fast, efficient and cost-saving, and meanwhile damage to the workpiece and damage to the workpiece precision are avoided.

Preferably, in order to improve the cutting efficiency, the laser cutting device 31 includes a laser cutting part 311 that cuts the surface of the circular triangle.

Preferably, in order to improve cutting efficiency, the laser cutting part 311 includes a laser cutting gun 3111 cutting the circular triangle.

Preferably, the laser cutting device 31 further comprises a power driving device 312 for driving the laser cutting component 311 to move along a predetermined track. The power driving device 312 drives the laser cutting component 311 to move, and the annular triangle is completely cut.

Preferably, the power driving means 312 includes a first power cylinder 3121 driving the laser cutting gun 3111 to move left and right, and a second power cylinder 3122 driving the laser cutting gun 3111 to move up and down; the output end of the first power cylinder 3121 is connected to the laser cutting unit 311, and the output end of the second power cylinder 3122 is connected to the first power cylinder 3121. The circular triangle is completely cut by controlling the laser cutting gun 3111 to move up and down and left and right.

Preferably, in order to facilitate the cutting of the annular triangle by the laser cutting device 31, the dicing mechanism further comprises a second positioning device 4 for positioning the annular triangle before cutting.

Preferably, the second positioning means 4 comprise a second positioning member 41 carrying an annular triangle. The annular triangle is subjected to positioning processing by the second positioning means 41.

Preferably, the second positioning member 41 includes a plurality of positioning blocks 411 supporting the circular triangle. The positioning processing is performed on the annular triangle by the positioning block 411.

Preferably, the positioning block 411 includes a bearing portion 4111 for bearing the annular triangle, and a clamping portion 4112 clamped to an inner sidewall of the annular triangle. Put the annular triangle on the portion 4111 that bears, joint portion 4112 joint prevents the displacement of annular triangle on the inside wall.

Preferably, in order to avoid interference between the positioning blocks 411 during operation of the laser cutting gun 3111, a cutting space is formed between adjacent positioning blocks 411 for cutting downward by the laser cutting gun 3111.

Preferably, in order to make the positioning block 411 have a better positioning effect on the annular triangle, the positioning blocks 411 are arranged around the annular triangle at equal intervals.

Preferably, the dicing mechanism further includes a triangular rotation driving device 5 that drives the annular triangle to rotate. The circular triangle is driven by the rotation driving device to rotate by the same angle after being cut by the laser cutting device 31, and the circular triangle is cut into the identical triangle block single bodies.

Preferably, the triangular rotation driving means 5 includes a first gear 51, a second gear 52, and a rotation motor 53 driving the second gear 52 to rotate; the positioning blocks 411 are arranged on the upper surface of the first gear 51, the first gear 51 is engaged with the second gear 52, and the output end of the rotating motor 53 is connected with the second gear 52. The second gear 52 is driven to rotate by the rotating motor 53, the second gear 52 is meshed with the first gear 51, so that the first gear 51 rotates, the first gear 51 drives the positioning block 411 to rotate, and the annular triangle on the positioning block 411 rotates simultaneously.

Preferably, in order to make the overall structure more stable and reliable, a support table 6 is further included for supporting the first gear 51 and the second gear 52. Specifically, the first gear and the second gear are arranged on the support platform and are in rotating connection with the support platform.

Preferably, the knitting needle is provided with a groove matched with the track bulge, and the knitting needle is in sliding connection with the track bulge through the groove.

The product form of the present invention is not limited to the embodiments and examples shown in the present application, and any suitable changes or modifications of the similar ideas should be made without departing from the patent scope of the present invention.

Claims (24)

1. The utility model provides a big circular knitting machine center group intelligent informationization production system which characterized in that: the method comprises the steps of processing an annular triangle blank into a triangular processing device with a raised annular triangle; the triangular processing device comprises a first positioning device for positioning the annular triangular blank, a first cutting device for cutting the positioned triangular blank and a block cutting mechanism for cutting the annular triangular blank which is processed into a plurality of triangular blocks;

the first positioning device comprises a first positioning part for positioning the triangular blank, the first positioning part comprises a plurality of positioning seats for positioning the triangular blank, each positioning seat comprises a supporting part for supporting the triangular blank and an abutting part for abutting against the outer side wall of the triangular blank, a guide-in part for guiding the triangular blank to slide in is arranged on the supporting part, and the guide-in part comprises a guide-in inclined plane which is gradually inclined downwards from the upper surface of the supporting part to the direction of the inner end surface; the positioning seats are arranged around the triangular blank at equal intervals;

the first positioning device further comprises a guiding device for guiding the positioning seats to gradually move inwards to position the triangular blank, the guiding device comprises a guiding part for guiding the positioning seats to gradually move inwards to position the triangular blank, and a plurality of sliding grooves corresponding to the positioning seats one by one are formed in the upper surface of the guiding part; the positioning seat is connected in the sliding groove in a sliding manner;

a first clamping block extends outwards from one side of the positioning seat, and a second clamping block extends outwards from the other side of the positioning seat; a first clamping groove matched with the first clamping block is formed in one side of the sliding groove, and a second clamping groove matched with the second clamping block is formed in the other side of the sliding groove; the first clamping block and the second clamping block of the positioning seat are respectively in sliding connection with the first clamping groove and the second clamping groove.

2. The intelligent informatization production system of large circular knitting machine center group of claim 1, characterized in that: the first cutting device comprises a rotary cutting part for cutting the surface of the triangular blank.

3. The intelligent informatization production system of large circular knitting machine center group according to claim 2, characterized in that: the rotary cutting component comprises a rotary cutting gun for performing rotary cutting on the surface of the triangular blank.

4. The intelligent informatization production system of large circular knitting machine center group of claim 3, characterized in that: the rotary cutting gun comprises a rotary cutting head which carries out rotary cutting on the surface of the triangular blank to form a protrusion.

5. The intelligent informatization production system of large circular knitting machine center group of claim 4, characterized in that: the rotary cutting component also comprises a cutting rotary driving device for driving the rotary cutting gun to rotate; the output end of the cutting rotation driving device is connected with the rotary cutting gun.

6. The intelligent informatization production system of large circular knitting machine center group of claim 5, characterized in that: the first cutting device further comprises a movement driving device for driving the rotary cutting member to move along a predetermined track.

7. The intelligent informatization production system of large circular knitting machine center group of claim 6, characterized in that: the movement driving device comprises a mechanical arm for driving the rotary cutting component to move along a preset track; the output end of the manipulator is connected with the rotary cutting component.

8. The intelligent informatization production system of large circular knitting machine center group of claim 7, characterized in that: the first positioning device further comprises a jacking driving device for driving the plurality of positioning seats to slide in the sliding grooves to jack the triangular blanks tightly.

9. The intelligent informatization production system of large circular knitting machine center group of claim 8, characterized in that: the jacking driving device comprises a plurality of jacking air cylinders which correspond to the positioning seats one by one; the output end of the jacking cylinder is connected with the positioning seat.

10. The intelligent informatization production system of large circular knitting machine center group of claim 9, characterized in that: the dicing mechanism comprises a dicing device which cuts the annular triangle into a plurality of triangle blocks one by one.

11. The intelligent informatization production system of large circular knitting machine center group of claim 10, characterized in that: the dicing device comprises a laser cutting device which cuts the annular triangle into a plurality of triangular blocks arranged along the axis of the annular triangle.

12. The intelligent informatization production system of large circular knitting machine center group of claim 11, characterized in that: the laser cutting device comprises a laser cutting component for cutting the surface of the annular triangle.

13. The intelligent informatization production system of large circular knitting machine center group of claim 12, characterized in that: the laser cutting component comprises a laser cutting gun for cutting the annular triangle.

14. The intelligent informatization production system of large circular knitting machine center group of claim 13, characterized in that: the laser cutting device also comprises a power driving device for driving the laser cutting component to move along a preset track.

15. The intelligent informatization production system of large circular knitting machine center group of claim 14, characterized in that: the power driving device comprises a first power cylinder for driving the laser cutting gun to move left and right and a second power cylinder for driving the laser cutting gun to move up and down; the output end of the first power cylinder is connected with the laser cutting component, and the output end of the second power cylinder is connected with the first power cylinder.

16. The intelligent informatization production system of large circular knitting machine center group of claim 15, characterized in that: the dicing mechanism further comprises a second positioning device for positioning the annular triangle before cutting.

17. The intelligent informatization production system of large circular knitting machine center group of claim 16, characterized in that: the second positioning means comprises a second positioning member carrying an annular triangle.

18. The intelligent informatization production system of large circular knitting machine center group of claim 17, characterized in that: the second positioning part includes a plurality of positioning blocks supporting the circular triangle.

19. The intelligent informatization production system of large circular knitting machine center group of claim 18, characterized in that: the locating piece is including the bearing part that bears annular triangle and the joint portion of joint in annular triangle inside wall.

20. The intelligent informatization production system of large circular knitting machine center group of claim 19, characterized in that: and a cutting space for downward cutting of the laser cutting gun is formed between the adjacent positioning blocks.

21. The intelligent informatization production system of large circular knitting machine center group of claim 20, characterized in that: a plurality of locating pieces encircle annular triangle equidistant setting.

22. The intelligent informatization production system of large circular knitting machine center group of claim 21, characterized in that: the dicing mechanism further comprises a triangle rotation driving device for driving the annular triangle to rotate.

23. The intelligent informatization production system of large circular knitting machine center group of claim 22, characterized in that: the triangular rotation driving device comprises a first gear, a second gear and a rotating motor for driving the second gear to rotate; the positioning blocks are arranged on the upper surface of the first gear, the first gear is meshed with the second gear, and the output end of the rotating motor is connected with the second gear.

24. The intelligent informatization production system of large circular knitting machine center group of claim 23, characterized in that: the gear transmission mechanism further comprises a supporting table for supporting the first gear and the second gear.

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