CN218932484U - Needle plate of computerized flat knitting machine with knitting needle selection mechanism - Google Patents

Abstract

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism, wherein each mirror knitting needle corresponds to one connecting stitch, a limiting stitch and a limiting piece respectively, the two mirror knitting needles share one selection stitch, and one end of the selection stitch is in clamping connection with the two connecting stitches; the upper part of the connecting stitch is provided with a limiting stitch and a limiting piece, one end of the limiting piece is driven to downwards rotate through the limiting piece fixed by the third steel wire by moving the limiting stitch, the limiting piece downwards presses the connecting stitch, the connecting stitch is separated from the connecting part of the selecting stitch, the connecting stitch is elastic, and when the limiting piece is not stressed, the connecting stitch drives the limiting piece to reset. The advantages are that: through setting up of spacing stitch and locating part, promote spacing stitch and be close to the locating part, make the locating part steadily rotatory along the third steel wire, push down the connection stitch, make corresponding connection stitch and select the stitch separation.

Description

Needle plate of computerized flat knitting machine with knitting needle selection mechanism

Technical Field

The utility model relates to a needle plate of a computerized flat knitting machine with a knitting needle selection mechanism.

Background

The tooth mouth piece installed on doffing mouth in computerized flat knitting machine is whole according to the existing machine type, the distance between the tooth mouth pieces is calculated according to the number of needles, the distance between the tooth mouth pieces is constant, and meanwhile, the design of the knitting needle ring expanding reed height, the needle hook size and the thickness of the ring connecting rod also takes the distance between the tooth mouth pieces as a main reference basis.

How two knitting needles in the needle groove are orderly and accurately discharged under the control of one selection stitch is extremely important; the control structure of the knitting needle combination and knitting needle selection mechanism disclosed in the prior art has the defects of large abrasion of a control cam, large difficulty in machine adjustment, large corresponding operation power consumption, low machine speed, short service life of a needle plate influenced by corresponding stress and the like when controlling and selecting the knitting needle under the operation condition of a machine head, and needs great innovation aiming at the problems, solves the problems and is beneficial to the next step in the flat knitting machine industry.

Disclosure of Invention

The utility model aims to solve the defects in the prior art and provides a needle plate of a computerized flat knitting machine with a knitting needle selection mechanism.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: a needle plate of a computerized flat knitting machine with a knitting needle selection mechanism comprises a needle plate, inserting sheets, mirror knitting needles, connecting pins, selection pins, limit pins and limit pieces, wherein a plurality of inserting sheet grooves are formed in the needle plate at equal intervals, the inserting sheets are arranged in the inserting sheet grooves, needle grooves are formed between every two adjacent inserting sheets, two mirror knitting needles are placed in the needle grooves, each mirror knitting needle corresponds to one connecting pin, each limit pin and each limit piece respectively, the two mirror knitting needles share one selection pin, and one end of each selection pin is in clamping connection with the two connecting pins; the upper part of the connecting stitch is provided with a limiting stitch and a limiting piece, one end of the limiting piece is driven to downwards rotate through the limiting piece fixed by the third steel wire by moving the limiting stitch, the limiting piece downwards presses the connecting stitch, the connecting stitch is separated from the connecting part of the selecting stitch, the connecting stitch is elastic, and when the limiting piece is not stressed, the connecting stitch drives the limiting piece to reset.

Further, a compensation small inserting sheet which corresponds to the selection stitch and avoids the left-right displacement of the selection stitch is arranged at the tail end of the inserting sheet corresponding to the selection stitch; one end of the selecting stitch is a junction of the thickened section corresponding to the two connecting stitches.

Further, the inserting piece at the connecting stitch is provided with an upper extension section, and two parallel limiting stitches and limiting pieces are arranged between the adjacent upper extension sections.

Further, the upper extension section is provided with a first wire hole, a second wire hole, a third wire hole and a fourth wire hole; the first steel wire hole and the second steel wire hole are arranged at the same height in parallel, and the first steel wire hole penetrates through the first steel wire; the second wire hole is internally penetrated through the second steel wire, the third wire hole is internally penetrated through the third steel wire, and the fourth wire hole is internally penetrated through the fourth steel wire; two steel wire grooves for the movement of the limiting stitch are formed in the limiting stitch, and one steel wire groove is penetrated by a first steel wire; the other steel wire groove is penetrated by a second steel wire, the limiting stitch is suspended on the connecting stitch through the first steel wire and the second steel wire, one end of the limiting piece is provided with a fifth steel wire hole, the fifth steel wire hole corresponds to the third steel wire hole and penetrates through the third steel wire to limit, and the limiting piece rotates by taking the third steel wire as an axle center when stressed; the limiting piece is suspended on the connecting pin through a third steel wire; the limiting pin is provided with a strip-shaped bulge close to the end of the limiting piece, the upper end surface of the limiting piece is a downward inclined surface towards the limiting pin, the limiting piece is driven to rotate downwards through the movement and force application of the strip-shaped bulge on the upper end surface of the limiting piece, the fourth steel wire hole is positioned above the inclined surface, and the fourth steel wire penetrates through the fourth steel wire hole and is used for upward warping in the force application process of the limiting strip-shaped bulge.

Further, the fourth wire holes are parallel and parallel, and different fourth wires pass through the fourth wire holes.

Further, the tail end of the connecting stitch is provided with an elastic supporting leg, when the connecting stitch is pressed downwards, the elastic supporting leg is propped against the bottom surface of the needle groove to store force, after the limiting stitch is moved away, the elastic supporting leg is sprung up, so that the limiting piece is reset, and the connecting position of the connecting stitch is clamped with one end of the selecting stitch.

Further, the upper end face of the selection stitch is provided with a plurality of first driving bulges which are used for driving, and the first driving bulges are higher than the upper plane of the inserting sheet.

Further, the upper ends of the two limit pins in the same pin slot are respectively provided with second driving protrusions with staggered positions, the second driving protrusion at the upper end of one limit pin is arranged on the right side, the second driving protrusion at the upper end of the other limit pin is arranged on the left side, and the second driving protrusions are higher than the upper plane of the upper extension section.

Further, a partition plate is arranged between the two limit pins in the same needle groove, and steel wire holes corresponding to the first steel wire hole, the second steel wire hole, the third steel wire hole and the fourth steel wire hole are formed in the partition plate.

Further, a semicircular bulge is arranged below the other end of the limiting piece and is used for propping against the upper end of the connecting pin.

Furthermore, two parallel mirror knitting needles are placed in the needle groove, one mirror knitting needle is provided with a concave surface, and a first inclined plane is arranged at the transition position of the mirror knitting needle plane at the same side of the concave surface.

Furthermore, a sinker positioning groove is correspondingly arranged at the front port of the needle plate groove and is used for controlling the sinker.

The beneficial effects of the utility model are as follows: through the arrangement of the limit stitch and the limit piece, the limit stitch is pushed to be close to the limit piece, so that the limit piece stably rotates along the third steel wire, the connecting stitch is pressed down, the corresponding connecting stitch is separated from the selecting stitch, the control structure can realize accurate and stable needle discharging with smaller stress, the needle discharging rises, and the mirror knitting needle is provided with a first inclined plane to push the position of the sinker to deviate, so that the maximization of the space position is realized; the limiting pin is pushed to reset, and the elastic connecting pin drives the limiting piece to reset, so that the corresponding connecting pin is clamped with the selecting pin.

Drawings

Fig. 1 is a schematic drawing of the needle-out structure of a mirror image knitting needle a.

Fig. 2 is a schematic drawing of the needle-out structure of a mirror image knitting needle two A.

Figure 3 is a schematic drawing of the needle-out structure of a mirror image knitting needle three A.

Figure 4 is a schematic drawing of the needle-out structure of a mirror image needle four a.

Fig. 5 is a schematic drawing of the needle-out structure of another mirror image knitting needle, B.

Fig. 6 is a schematic diagram B of the needle-out structure of another mirror image knitting needle.

Fig. 7 is a schematic drawing of the needle-out structure of another mirror image knitting needle three B.

Fig. 8 is a schematic drawing of the needle-out structure of another mirror image knitting needle, four B.

Fig. 9 is a schematic view of the needle plate structure.

Fig. 10 is an enlarged view of a portion a in fig. 9.

Fig. 11 is a schematic drawing of the needle-out connection of another mirror image needle-C.

Fig. 12 is a schematic view of the needle-out connection of another mirror image needle.

Fig. 13 is a schematic drawing of the needle-out connection of another mirror image needle three C.

Fig. 14 is a schematic drawing of the needle-out connection of another mirror image needle.

Fig. 15 is a schematic view of a connection pin structure.

Fig. 16 is a schematic diagram of a select stitch configuration.

Fig. 17 is a schematic view of a spacing pin structure.

Fig. 18 is a schematic view of another spacing pin structure.

Fig. 19 is a schematic view of a stopper structure.

Fig. 20 is a schematic view of a spacer structure.

Fig. 21 is a schematic illustration of a tab construction.

Fig. 22 is a schematic view of another retainer mounting structure.

Fig. 23 is a schematic view of another retainer mounting structure.

Fig. 24 is a schematic view of another spacer plate configuration.

Fig. 25 is a schematic view of another insert sheet structure.

1 is a needle plate; 11 is an insert slot; 12 is an insert; 121 a sixth wire hole; 13 is a needle slot; 14 is a compensating tab; 15 is a sinker; 16 is a sinker positioning groove; 17 is a jogged groove, 18 is an upper lug, 19 is a small needle plate;

2 is a mirror image knitting needle; 21 is a concave surface, 22 is a sinker relief groove; 23 is a first incline;

3 is a connection pin; 31 are resilient legs; 32 is the junction;

4 is a select stitch; 41 is a first drive protrusion; 42 is a thickened section;

5 is a limit stitch; 51 is a second drive protrusion; 52 is a wire groove; 53 are stripe-shaped projections;

6 is a limiting piece; 61 is a fifth wire hole; 62 is a bevel; 63 are semi-circular protrusions;

7 is an upward extending section; 71 is a first wire hole; 72 is a second wire hole; 73 is a third wire hole; 74 is a fourth wire hole;

8 is a spacer plate;

9 is a front tooth mouth piece mounting plate; reference numeral 91 denotes a front tooth plate mounting plate driving device, and 92 denotes a motor.

Description of the embodiments

The technical solutions according to the embodiments of the present utility model will be clearly and completely described below with reference to fig. 1 to 25 in the embodiments of the present utility model, and it is obvious that the described embodiments are only some embodiments of the present utility model, but not all embodiments.

Embodiment 1 referring to fig. 1-23, a needle plate of a computerized flat knitting machine with a knitting needle selection mechanism comprises a needle plate 1, an inserting piece 12, mirror knitting needles 2, connecting pins 3, selecting pins 4, limiting pins 5 and limiting pieces 6, wherein a plurality of inserting piece grooves 11 are formed in the needle plate 1 at equal intervals, the inserting piece 12 is arranged in the inserting piece grooves, a needle groove 13 is formed between every two adjacent inserting pieces, two mirror knitting needles 2 are placed in each needle groove, each mirror knitting needle 2 corresponds to one connecting pin 3, each limiting pin 5 and each limiting piece 6 respectively, the two mirror knitting needles share one selecting pin 4, and one end of each selecting pin 4 is in clamping connection with the two connecting pins 3; the upper part of the connecting stitch 3 is provided with a limiting stitch 5 and a limiting piece 6, one end of the limiting piece is driven to rotate downwards through the limiting piece fixed by the third steel wire by moving the limiting stitch 5, the limiting piece 6 presses down the connecting stitch 3, the connecting stitch 3 is separated from the connecting part 32 of the selecting stitch 4, the connecting stitch 3 is elastic, and when the limiting piece 6 is not stressed, the connecting stitch 3 drives the limiting piece 6 to reset.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism, two parallel mirror image knitting needles 2 are placed in a needle groove, and a small compensation inserting piece 14 which corresponds to the selection stitch 4 and avoids the left-right displacement of the selection stitch 4 is arranged at the tail end of the inserting piece 12 corresponding to the selection stitch 4; one end of the selecting pin 4 is a junction of the thickened section 42 corresponding to the two connecting pins 3.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism is provided, an upper extension section 7 is arranged on an inserting piece 12 at a connecting stitch, and two parallel limit stitches 5 and limit pieces 6 are arranged between adjacent upper extension sections.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism, wherein a first steel wire hole 71, a second steel wire hole 72, a third steel wire hole 73 and a fourth steel wire hole 74 are arranged on an upper extension section 7; the first wire hole 71 and the second wire hole 72 are arranged at two parallel heights, and the first wire hole 71 penetrates through the first wire; the second wire hole 72 is internally threaded through the second wire, the third wire hole 73 is internally threaded through the third wire, and the fourth wire hole 74 is internally threaded through the fourth wire; the limiting stitch 5 is provided with two steel wire grooves 52 for the limiting stitch to move, and one steel wire groove 52 is penetrated by a first steel wire; the structure of the wire groove 52 is shown in the figure, the other wire groove 52 is penetrated by a second wire, the limiting pin 5 is limited to move back and forth along the wire groove 52, the limiting pin 5 is suspended on the connecting pin 3 through a first wire and a second wire, one end of the limiting piece 6 is provided with a fifth wire hole 61, the fifth wire hole 61 corresponds to the third wire hole 73, the third wire penetrates through the limiting piece, and the limiting piece 6 rotates by taking the third wire as the axis when being stressed; the limiting piece 6 is suspended on the connecting pin 3 through a third steel wire; the end of the limiting pin 5, which is close to the limiting piece 6, is provided with a strip-shaped bulge 53, the upper end surface of the limiting piece 6 is a downward inclined surface 62 facing the limiting pin, the limiting piece 6 is driven to rotate downwards by moving and applying force to the upper end surface of the limiting piece 6 through the strip-shaped bulge 53, a fourth wire hole 74 is positioned above the inclined surface, and a fourth wire penetrates through the fourth wire hole 74 to be used for upwards warping in the force application process of the limiting strip-shaped bulge.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism has a plurality of fourth wire holes 74 which are parallel and side by side and all have different fourth wires passing through.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism is provided with a sixth wire hole 121 for limiting in the advancing direction of a corresponding selection stitch 4, and a sixth steel wire penetrates through the sixth wire hole. The sixth wire hole 121 is in a staggered design.

The needle plate of the computerized flat knitting machine with the knitting needle selection mechanism is characterized in that elastic supporting legs 31 are arranged at the tail ends of the connecting pins 3, when the connecting pins 3 are pressed down under the stress, the elastic supporting legs are propped against the bottom surface of the needle groove to store force, after the limiting pins 5 are removed, the elastic supporting legs are sprung, the limiting pieces 6 are reset, and the connecting positions of the connecting pins 3 are clamped with one ends of the selection pins 4.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism is provided, wherein the upper end face of a selection stitch 4 is provided with a plurality of first driving bulges 41 for driving, and the first driving bulges are higher than the upper plane of an inserting sheet.

The needle plate of the computerized flat knitting machine with the knitting needle selection mechanism is characterized in that the upper ends of two limit pins 5 in the same needle groove are respectively provided with second driving protrusions 51 with staggered positions, the second driving protrusions of the upper end of one limit pin 5 are arranged on the right side, the second driving protrusions of the upper end of the other limit pin 5 are arranged on the left side, and the second driving protrusions are higher than the upper plane of the upper extension section.

The limiting stitch 5 and the limiting piece 6 form a self-locking structure, so that a large amount of pressure is prevented from being applied when the needle plate selects mirror image knitting needles, the service life of the needle plate is prolonged, and the self-locking structure is not easy to automatically loosen.

A spacing plate 8 is arranged between two limit pins 5 in the same needle groove, and steel wire holes corresponding to a first steel wire hole 71, a second steel wire hole 72, a third steel wire hole 73 and a fourth steel wire hole 74 are arranged on the spacing plate 8.

A semicircular bulge 63 is arranged below the other end of the limiting piece 6 and is used for abutting against the upper end of the connecting stitch 3.

The needle plate of the computerized flat knitting machine with the knitting needle selection mechanism pushes the limiting stitch 5 to be close to the limiting piece 6 through the arrangement of the limiting stitch 5 and the limiting piece 6, so that the limiting piece 6 stably rotates along the third steel wire, the connecting stitch 3 is pressed down, the corresponding connecting stitch 3 is separated from the selection stitch 4, and accurate and stable needle outlet is realized; the limiting stitch 5 is pushed to reset, the connecting stitch 3 with elasticity drives the limiting piece 6 to reset, the corresponding connecting stitch 3 is clamped with the selecting stitch 4, and the two mirror knitting needles are sequentially pulled out and retracted.

The front ends of opposite faces of mirror-image knitting needles in two identical needle grooves are provided with inward concave faces 21 to form sinker relief grooves 22.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism is provided, wherein a first inclined plane 23 is transited between the rear end of a concave surface of the front end of the opposite surface of a mirror knitting needle 2 and the mirror knitting needle 2. The first inclined surface can smoothly drive the sinker 15 to move. When one mirror image knitting needle is out, the sinker 15 close to the concave surface is driven to move towards the other mirror image knitting needle through the first inclined surface and moves into the concave surface of the other mirror image knitting needle.

A sinker positioning groove 16 is arranged in the needle groove wall of the front end of the needle plate 1 of the computerized flat knitting machine. The sinker positioning groove 16 can position the sinker 15 to avoid the transitional movement of the sinker 15.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism is characterized in that an embedding groove 17 is formed in the bottom surface of the front end of the needle plate 1, a front tooth mouth piece mounting plate 9 is embedded in the embedding groove 17, a front tooth mouth piece mounting plate driving device 91 is arranged on one side of the needle plate 1, the front tooth mouth piece mounting plate driving device 91 is connected with the front tooth mouth piece mounting plate 9 to enable the front tooth mouth piece mounting plate 9 to move left and right in the embedding groove 17, a front tooth mouth piece assembly arranged on the front tooth mouth piece mounting plate 9 is driven to move left and right, and gaps between a front tooth mouth piece and a ring expanding reed of a mirror image knitting needle are adjusted without interference. The front tooth plate mounting plate driving device 91 is provided with a motor 92 for driving.

The computerized flat knitting machine needle plate with knitting needle selection mechanism, the front part of the inserting piece 12 extends upwards to form an upper lug 18, the upper end of the upper lug is provided with a small needle plate 19, a sinker mounting groove is formed in the small needle plate, a sinker 15 is placed in the sinker mounting groove, the butt part is exposed out of the sinker mounting groove, the yarn pressing part of the sinker 15 extends into the gap of the corresponding tooth mouth assembly, the tooth mouth assembly comprises a rear mounting section tooth mouth piece and a gasket, a gap is formed between one side of the rear mounting section tooth mouth piece and the gasket, a bulge is arranged in the gap, a limit opening of the sinker yarn pressing part is correspondingly matched with the bulge, an attaching piece gasket is arranged on the attaching piece, and a ring expanding reed abdicating groove is formed on the ring expanding reed side of the inserting piece corresponding to the mirror image knitting needle; the lower end of the small needle plate is provided with a groove, and the upper end of the upper lug is clamped in the groove.

The structure is simple, when the front tooth mouth piece generates fine adjustment to enable the mirror knitting needle to rise to the transfer height, the ring expanding reed is prevented from rubbing against the tooth mouth piece, and the operation is more stable; the knitting speed is improved, and the fabric yield is high.

A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism is characterized in that two parallel mirror knitting needles are placed in a needle groove, one side of each mirror knitting needle is provided with a concave surface, and a first inclined surface is arranged at the plane transition position of the mirror knitting needle on the same side of the concave surface.

Any knitting needle is out of a gap formed by two mirror image knitting needles through which the arranged sinker runs, and the sinker is pushed by the first inclined plane to shift left and right.

A needle plate of computerized flat knitting machine with knitting needle selection mechanism is provided, and a sinker positioning groove is correspondingly arranged at the front end opening of the needle plate groove for sinker control.

Embodiment 2 referring to fig. 24 to 25, a needle plate of a computerized flat knitting machine having a knitting needle selection mechanism, wherein the fourth wire hole 74 of the upper extension 7 is elongated as shown in fig. 25, so that abrasion can be reduced to make movement smoother, and the fourth wire hole 74 is internally penetrated by a corresponding elongated fourth wire; the partition plate 8 is provided with wire holes corresponding to the fourth wire holes 74 and is penetrated by the fourth wires corresponding to the long strips.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the inventive concept thereof, can be replaced or changed within the scope of the present utility model.

Claims (12)

1. A needle plate of a computerized flat knitting machine with a knitting needle selection mechanism comprises a needle plate, an inserting piece, mirror knitting needles, connecting pins, selection pins, limit pieces and compensation small inserting pieces; a plurality of inserted sheet grooves are offered to equidistant on the faller, the inserted sheet is installed in the inserted sheet inslot, forms the needle groove between every adjacent inserted sheet, and every needle inslot places mirror image knitting needle and is one piece each, its characterized in that: each mirror image knitting needle corresponds to one connecting stitch, a limiting stitch and a limiting piece respectively, the two mirror image knitting needles share one selecting stitch, one end of the selecting stitch is in clamping connection with the two connecting stitches, and a compensation small inserting piece is arranged beside the tail end of the selecting stitch; the upper part of the connecting stitch is provided with a limiting stitch and a limiting piece, one end of the limiting piece is driven to downwards rotate through the limiting piece fixed by the third steel wire by moving the limiting stitch, the limiting piece downwards presses the connecting stitch, the connecting stitch is separated from the connecting part of the selecting stitch, the connecting stitch is elastic, and when the limiting piece is not stressed, the connecting stitch drives the limiting piece to reset.

2. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: the position of the insertion sheet corresponding to the tail end of the selection stitch is provided with a compensation small insertion sheet corresponding to the selection stitch to avoid the left-right displacement of the selection stitch; one end of the selecting stitch is a junction of the thickened section corresponding to the two connecting stitches.

3. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: the inserted sheet of connection stitch department is equipped with and extends the section, is equipped with two parallel spacing stitch and locating part between the adjacent section that extends.

4. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: the upper extension section is provided with a first wire hole, a second wire hole, a third wire hole and a fourth wire hole; the first steel wire hole and the second steel wire hole are arranged at the same height in parallel, and the first steel wire hole penetrates through the first steel wire; the second wire hole is internally penetrated through the second steel wire, the third wire hole is internally penetrated through the third steel wire, and the fourth wire hole is internally penetrated through the fourth steel wire; two steel wire grooves for the movement of the limiting stitch are formed in the limiting stitch, and one steel wire groove is penetrated by a first steel wire; the other steel wire groove is penetrated by a second steel wire, the limiting stitch is suspended on the connecting stitch through the first steel wire and the second steel wire, one end of the limiting piece is provided with a fifth steel wire hole, the fifth steel wire hole corresponds to the third steel wire hole and penetrates through the third steel wire to limit, and the limiting piece rotates by taking the third steel wire as an axle center when stressed; the limiting piece is suspended on the connecting pin through a third steel wire; the limiting pin is provided with a strip-shaped bulge close to the end of the limiting piece, the upper end surface of the limiting piece is a downward inclined surface towards the limiting pin, the limiting piece is driven to rotate downwards through the movement and force application of the strip-shaped bulge on the upper end surface of the limiting piece, the fourth steel wire hole is positioned above the inclined surface, and the fourth steel wire penetrates through the fourth steel wire hole and is used for upward warping in the force application process of the limiting strip-shaped bulge.

5. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as defined in claim 4, characterized by: the fourth wire holes are parallel and parallel, and different fourth wires pass through the fourth wire holes.

6. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 2, characterized in that: the tail end of the connecting stitch is provided with an elastic support leg, when the connecting stitch is pressed downwards, the elastic support leg is propped against the bottom surface of the needle groove to store force, and after the limiting stitch is moved away, the elastic support leg is sprung up to reset the limiting piece, so that the connecting position of the connecting stitch is clamped with one end of the selecting stitch.

7. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: the upper end face of the selection stitch is provided with a plurality of first driving bulges which are used for driving, and the first driving bulges are higher than the upper plane of the inserting sheet.

8. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: the upper ends of two limit pins in the same needle groove are respectively provided with second driving bulges with staggered positions, the second driving bulge at the upper end of one limit pin is arranged on the right side, the second driving bulge at the upper end of the other limit pin is arranged on the left side, and the second driving bulge is higher than the upper extension section plane.

9. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as defined in claim 8, characterized in that: a spacing plate is arranged between two spacing pins in the same needle groove, and steel wire holes corresponding to the first steel wire hole, the second steel wire hole, the third steel wire hole and the fourth steel wire hole are arranged on the spacing plate.

10. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: the lower part of the other end of the limiting piece is provided with a semicircular bulge which is used for propping against the upper end of the connecting pin.

11. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: two parallel mirror knitting needles are placed in the needle groove, one mirror knitting needle is provided with a concave surface, and a first inclined plane is arranged at the transition position of the mirror knitting needle plane at the same side of the concave surface.

12. A computerized flat knitting machine needle plate with a knitting needle selection mechanism as claimed in claim 1, characterized in that: and a sinker positioning groove is correspondingly arranged at the front port of the needle plate groove and is used for controlling the sinkers.

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