CN209941215U - Six-station computerized flat knitting machine bottom plate device - Google Patents

Abstract

The utility model relates to a six-station computerized flat knitting machine bottom plate device, a needle-turning cam and a knitting cam are arranged at one end of a motor output shaft, and a sensing disc, a needle-receiving cam left-needle-raising cam right, a needle-receiving cam right-needle-raising cam left and a needle-lifting cam are arranged at the other end of the motor output shaft; the sensor is arranged on one side of the sensing disc; six station grooves are uniformly distributed on the sensing disc, and when any one station groove in the six station grooves is opposite to the sensor, the five cams, namely the needle turning cam, the knitting cam, the needle receiving cam left-needle raising cam right, the needle receiving cam right-needle raising cam left and the needle lifting cam, control the corresponding cam to work right. In the utility model, five cams control corresponding cams to work, so that the bottom plate of the single-system flat knitting machine has simple structure and realizes the function of six stations; and the non-woven stations are added, and when the whole row is not woven, the needle selector is not needed to select the needle, so that the loss of the needle selector is reduced.

Description

Six-station computerized flat knitting machine bottom plate device

Technical Field

The utility model relates to a computerized flat knitting machine technical field, specifically say, relate to a six station computerized flat knitting machine bottom plate devices.

Background

Currently, a cam device on a bottom plate of a single-system computerized flat knitting machine generally has five stations: the needle turning, knitting, right needle receiving, stitch lifting and left needle receiving are free of non-knitting stations, when the whole row is required to be non-knitted, the needle selector is required to be used for selecting the needle and pressing the needle into the needle plate, and the needle selector is consumed by the method, so that the cam device on the bottom plate of the existing single-system computerized flat knitting machine is required to be improved and optimized.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the above-mentioned not enough that exists among the prior art, and provide a structural design is reasonable, have the computerized flat knitting machine bottom plate device of six stations.

The utility model provides a technical scheme that above-mentioned problem adopted is: the utility model provides a six station computerized flat knitting machine bottom plate devices, includes the triangle bottom plate, the front activity of triangle bottom plate is provided with the needle turning triangle, weaves triangle, rise cam left side, connects a needle triangle right side, rise cam right side, lift a needle triangle left side and lift a needle triangle right side, and the back of triangle bottom plate is provided with triangle cam transmission, its characterized in that: the cam transmission device comprises a motor, a sensing disc, a sensor, a needle-turning cam, a knitting cam, a needle-receiving cam left-needle-raising cam right, a needle-receiving cam right-needle-raising cam left and a needle-lifting cam; the sensing disc, the needle receiving triangle left-needle raising triangle right cam, the needle receiving triangle right-needle raising triangle left cam and the needle lifting triangle cam are arranged at the other end of the motor output shaft; the sensor is arranged on one side of the sensing disc; six station grooves are uniformly distributed on the sensing disc clockwise along the circumferential direction and are respectively a needle turning station groove, a knitting station groove, a non-knitting station groove, a right needle receiving station groove, a mesh hanging station groove and a left needle receiving station groove; when any one of the six station grooves is over against the sensor, the needle transferring cam, the knitting cam, the needle receiving cam left-needle raising cam right cam, the needle receiving cam right-needle raising cam left cam and the needle lifting cam are driven by the motor to control the needle transferring cam, the knitting cam, the needle raising cam left, the needle receiving cam right, the needle raising cam right, the needle lifting cam left and the needle lifting cam right to work.

Preferably, the needle lifting cam of the utility model is provided with a notch which is aligned with the unwoven station groove; the needle-turning cam is provided with three equal-height convex blocks which are respectively aligned with the needle-turning station groove, the non-weaving station groove and the mesh hanging station groove; the knitting cam is provided with two lugs with the height equal to that of the lug on the needle-turning cam, and the two lugs are respectively aligned with the non-knitting station slot and the mesh hanging station slot; the left needle-withdrawing cam is provided with two lugs with the height equal to that of the lug on the needle-turning cam, and the two lugs are respectively aligned with the non-knitting station groove and the left needle-connecting station groove; the needle connecting triangle right-needle raising triangle left cam is provided with two lugs with the height equal to that of the lug on the needle transferring triangle cam, and the two lugs are respectively aligned with the non-knitting station groove and the right needle connecting station groove.

Preferably, the lifting shaft is installed on the back of the needle transferring triangle, the knitting triangle, the needle raising triangle left side, the needle receiving triangle left side, the needle transferring triangle right side and the needle raising triangle right side, the pushing block is installed on the lifting shaft, and the needle transferring cam, the knitting cam, the needle receiving triangle left-needle raising triangle right cam and the needle receiving triangle right-needle raising triangle left cam push the block through driving and then control the work of each triangle.

Preferably, lift the needle triangle left side and lift and connect through stick up lever mechanism between the needle triangle right side.

In the utility model, when the needle-turning station groove is just opposite to the sensor, the needle-turning cam sinks into the cam bottom plate under the action of the needle-turning cam, the knitting cam, the needle-raising cam left side, the needle-receiving cam right side and the needle-raising cam right side are all in working positions, the needle-raising cam left side and the needle-raising cam right side raise the needle, and the needle-turning action is carried out at the moment; when the knitting station groove is over against the sensor, the needle turning cam, the knitting cam, the left needle raising cam, the left needle receiving cam, the right needle receiving cam and the right needle raising cam are all in working positions, the left needle raising cam and the right needle raising cam carry out needle raising, and knitting is carried out at the moment; when the non-knitting station groove is over against the sensor, the needle turning cam, the knitting cam, the left needle raising cam, the left needle receiving cam, the right needle receiving cam and the right needle raising cam are not in working positions, the cam bottom plate is sunk, the left needle raising cam and the right needle raising cam do not raise needles, and at the moment, the whole line is not knitted; when the right needle receiving station groove is over against the sensor, the left needle transferring cam, the knitting cam, the left needle raising cam and the right needle transferring cam are all in working positions, the left needle transferring cam and the right needle raising cam sink into the cam bottom plate, the left needle raising cam and the right needle raising cam lift needles, and then right needle transferring is carried out; when the eye lifting station groove is over against the sensor, the left needle lifting triangle, the left needle receiving triangle, the right needle receiving triangle and the right needle lifting triangle are all in working positions, the needle turning triangle and the knitting triangle are sunk into the triangle bottom plate, the left needle lifting triangle and the right needle lifting triangle lift needles, and eye lifting action is carried out at the moment; when the left needle receiving station groove is over against the sensor, the needle turning cam, the knitting cam, the left needle receiving cam and the right needle raising cam are all in working positions, the left needle raising cam and the right needle receiving cam sink into the cam bottom plate, the left needle raising cam and the right needle raising cam raise needles, and then left needle receiving action is carried out.

Compared with the prior art, the utility model, have following advantage and effect: the five cams control the needle turning cam, the knitting cam, the left needle raising cam, the left needle receiving cam, the right needle raising cam, the left needle raising cam and the right needle raising cam to work, so that the bottom plate of the single-system flat knitting machine is simple in structure, and the six-station function is realized; the non-woven stations are added, when the whole row is not woven, the needle selector is not needed to select the needle, and the loss of the needle selector is reduced.

Drawings

In order to illustrate the embodiments of the present invention or the solutions in the prior art more clearly, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic front view structure diagram of an embodiment of the present invention.

Fig. 2 is a left side view structure diagram of the embodiment of the present invention.

Fig. 3 is a schematic structural diagram of the connection between the first connecting rod and the second connecting rod and other components in the embodiment of the present invention.

Fig. 4 is a schematic diagram of a position relationship between the tilting rod mechanism and the needle raising cam when raising the needle in the embodiment of the present invention.

Fig. 5 is a schematic diagram of a position relationship between the tilting rod mechanism and the needle raising cam when the needle is not raised in the embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a sensing plate and a station groove thereon according to an embodiment of the present invention.

Fig. 7 is a schematic structural view of the needle raising cam in the embodiment of the present invention.

Fig. 8 is a schematic structural diagram of the stitch cam in the embodiment of the present invention.

Fig. 9 is a schematic structural diagram of a triangular cam for knitting in the embodiment of the present invention.

Fig. 10 is a schematic structural view of the left needle-raising cam of the needle-receiving cam in the embodiment of the present invention.

Fig. 11 is a schematic structural view of the needle receiving cam right-needle raising cam in the embodiment of the present invention.

Fig. 12 is a schematic structural diagram of the position relationship of the cams when the needle-flipping station slot is right opposite to the sensor in the embodiment of the present invention.

Fig. 13 is a schematic diagram of the position relationship structure of each cam when the weaving station slot is right opposite to the sensor in the embodiment of the present invention.

Fig. 14 is a schematic diagram showing a positional relationship between cams when the unwoven station groove faces the sensor according to the embodiment of the present invention.

Fig. 15 is a schematic view of the position relationship structure of each cam when the right needle connecting station slot is right opposite to the sensor in the embodiment of the present invention.

Fig. 16 is a schematic view of the position relationship structure of each cam when the eye hanging station slot is over against the sensor in the embodiment of the present invention.

Fig. 17 is a schematic view of the position relationship structure of each cam when the left needle receiving station groove is right opposite to the sensor in the embodiment of the present invention.

Fig. 18 is a schematic diagram of a needle passing track when the needle is turned over in the embodiment of the present invention.

Fig. 19 is a schematic diagram of a needle passing track in knitting in the embodiment of the present invention.

Fig. 20 is a schematic diagram of the needle travel track during non-weaving in the embodiment of the present invention.

Fig. 21 is a schematic diagram of a needle moving track in the case of right-hand joining according to an embodiment of the present invention.

Fig. 22 is a schematic diagram of the needle moving track in the embodiment of the present invention.

Fig. 23 is a schematic diagram of a needle moving track in the case of left-hand joining according to the embodiment of the present invention.

Description of reference numerals: a triangular bottom plate 1; a needle turning triangle 2; weaving a triangle 3; a needle raising triangle left 4; the left side of the needle connecting triangle 5; the right connecting needle triangle 6; a needle raising triangle right 7; the left side of the needle lifting triangle 8; the needle lifting triangle right 9; a motor 10; a sensing disk 12; a sensor 11; a stitch cam 13; a knitting cam 14; a needle connecting triangle left-needle raising triangle right cam 15; a needle receiving triangle right-needle raising triangle left cam 16; a needle raising cam 17; a recess 171; a knitting cam elevating shaft 18; knitting a triangular pushing block 19; a needle-turning triangular lifting shaft 20; a needle-turning triangular pushing block 21; a stitch cam link block 22; a needle raising cam left lifting shaft 23; a needle connecting triangle left lifting shaft 24; a second push block 25; a first connecting rod 26; a second connecting rod 27; a first pusher block 28; a needle connecting triangle right lifting shaft 29; a needle raising cam right lifting shaft 30; a seesaw lever mechanism 31; a needle overturning station groove a; weaving a station groove b; a non-weaving station groove c; a right needle connecting station groove d; a mesh hanging station groove e; a left needle connecting station groove f.

Detailed Description

The present invention will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present invention and are not intended to limit the present invention.

Examples are given.

See fig. 1-23.

The embodiment is a six-station computerized flat knitting machine bottom plate device, which comprises a triangular bottom plate 1, wherein a needle turning cam 2, a knitting cam 3, a needle raising cam left 4, a needle receiving cam left 5, a needle receiving cam right 6, a needle raising cam right 7, a needle lifting cam left 8 and a needle lifting cam right 9 are movably arranged on the front surface of the triangular bottom plate 1, and a triangular cam transmission device is arranged on the back surface of the triangular bottom plate 1.

The cam transmission device comprises a motor 10, a sensing disc 12, a sensor 11, a needle-turning cam 13, a knitting cam 14, a needle-receiving cam left-needle-raising cam right cam 15, a needle-receiving cam right-needle-raising cam left cam 16 and a needle-lifting cam 17. The needle transferring cam 13 and the knitting cam 14 are installed at one end of the output shaft of the motor 10, and the sensing plate 12, the needle receiving cam left-needle raising cam right 15, the needle receiving cam right-needle raising cam left 16 and the needle raising cam 17 are installed at the other end of the output shaft of the motor 10. The sensor 11 is arranged on one side of the sensing disc 12; six station grooves, namely a needle turning station groove a, a knitting station groove b, a non-knitting station groove c, a right needle receiving station groove d, a mesh hanging station groove e and a left needle receiving station groove f, are uniformly distributed on the sensing disc 12 clockwise along the circumferential direction. When any one of the six station grooves is over against the sensor 11, the five cams, namely the needle transferring cam 13, the knitting cam 14, the needle receiving cam left-needle raising cam right 15, the needle receiving cam right-needle raising cam left 16 and the needle lifting cam 17, control the needle transferring cam 2, the knitting cam 3, the needle raising cam left 4, the needle receiving cam left 5, the needle receiving cam right 6, the needle raising cam right 7, the needle lifting cam left 8 and the needle lifting cam right 9 to work under the driving of the motor 10.

In this embodiment, the needle raising cam 17 has a notch 171, and the notch 11 is aligned with the non-knitting station groove c. The stitch cam 13 has three equal-height projections which are respectively aligned with the stitch station groove a, the unwoven station groove c and the stitch station groove e. The knitting cam 14 has two projections having the same height as the height of the projection on the stitch cam 13, which are aligned with the non-knitting station groove c and the stitch station groove e, respectively. The stitch cam left-raising cam right 15 has two projections having the same height as the projection on the stitch cam 13, which are aligned with the non-knitting station groove c and the left stitch cam groove f, respectively. The stitch cam right-raising cam left cam 16 has two projections having the same height as the projection on the stitch cam 13, which are aligned with the non-knitting station groove c and the right stitch cam groove d, respectively.

In this embodiment, the lifting shafts are installed on the back of the stitch cam 2, the knitting cam 3, the needle raising cam left 4, the needle receiving cam left 5, the needle receiving cam right 6, and the needle raising cam right 7, the pushing blocks are installed on the lifting shafts, and the stitch cam 13, the knitting cam 14, the needle receiving cam left-needle raising cam right 15, and the needle receiving cam right-needle raising cam left 16 control the operation of each cam by driving the pushing blocks. Referring to fig. 2, a stitch cam lifting shaft 20 is arranged on the back of the stitch cam 2, the stitch cam 2 and the stitch cam lifting shaft 20 are connected together through a stitch cam link block 22, a stitch cam pushing block 21 is arranged on the stitch cam lifting shaft 20, and a stitch cam 13 drives the stitch cam pushing block 21; a knitting cam lifting shaft 18 is fixed on the back of the knitting cam 3, a knitting cam pushing block 19 is installed on the knitting cam lifting shaft 18, and the knitting cam 14 drives the knitting cam pushing block 19. Referring to fig. 3, a needle raising cam left lifting shaft 23 is fixed on the back of a needle raising cam left 4, a needle receiving cam right lifting shaft 29 is fixed on the back of a needle receiving cam right 6, the top of the needle raising cam left lifting shaft 23 is connected with the top of the needle receiving cam right lifting shaft 29 through a connecting rod 26, a pushing block 28 is installed on the needle receiving cam right lifting shaft 29, and the needle receiving cam right-needle raising cam 16 drives the pushing block 28 to further drive the needle receiving cam right 6 to be linked with the needle raising cam left 4; the back of the left needle receiving triangle 5 is fixed with a left needle receiving triangle lifting shaft 24, the back of the right needle raising triangle 7 is fixed with a right needle raising triangle lifting shaft 30, the top of the left needle receiving triangle lifting shaft 24 is connected with the top of the right needle raising triangle lifting shaft 30 through a second connecting rod 27, a second pushing block 25 is installed on the left needle receiving triangle lifting shaft 24, and the left needle receiving triangle-right needle raising triangle cam 15 drives the second pushing block 25 to further drive the left needle receiving triangle 5 to be linked with the right needle raising triangle 7.

In this embodiment, the left needle raising cam 8 and the right needle raising cam 9 are connected by the tilting lever mechanism 31, and the needle raising cam 17 drives the tilting lever mechanism 31 to perform needle raising and needle non-raising actions, as shown in fig. 4 and 5, fig. 4 is a schematic diagram of a positional relationship between the tilting lever mechanism 31 and the needle raising cam 17 when raising a needle, fig. 5 is a schematic diagram of a positional relationship between the tilting lever mechanism 31 and the needle raising cam 17 when not knitting, that is, when not raising a needle, and as for a specific structural principle of the tilting lever mechanism 31, reference may be made to the prior art.

In this embodiment, when the needle-turning station groove a is over against the sensor 11, the needle-turning cam 2 sinks into the cam base plate 1 under the action of the needle-turning cam 13, the knitting cam 3, the needle-raising cam left 4, the needle-joining cam left 5, the needle-joining cam right 6, and the needle-raising cam right 7 are all in the working position, the needle-raising cam left 8 and the needle-raising cam right 9 raise the needle, at this time, the needle-turning action is performed, and the needle-moving trajectory is as shown in fig. 18.

In this embodiment, when the knitting station groove b faces the sensor 11, the needle changing cam 2, the knitting cam 3, the needle raising cam left 4, the needle receiving cam left 5, the needle receiving cam right 6, and the needle raising cam right 7 are all in the working positions, and the needle raising cam left 8 and the needle raising cam right 9 raise the needle, and at this time, knitting operation is performed, and the needle running path is as shown in fig. 19.

In this embodiment, when the non-knitting station groove c faces the sensor 11, the stitch transferring cam 2, the knitting cam 3, the needle raising cam left 4, the needle receiving cam left 5, the needle receiving cam right 6, and the needle raising cam right 7 are not in working positions, the cam base plate 1 is sunk, the needle raising cam left 8 and the needle raising cam right 9 do not raise the needle, at this time, the knitting is not performed in the whole line, and the needle moving trajectory is as shown in fig. 20.

In this embodiment, when the right stitch receiving station groove d is over against the sensor 11, the stitch transferring cam 2, the knitting cam 3, the needle raising cam left 4, the stitch receiving cam right 6 and all are in working positions, the stitch receiving cam left 5 and the needle raising cam right 7 sink into the cam bottom plate 1, the needle raising cam left 8 and the needle raising cam right 9 raise the needle, at this time, the right stitch receiving operation is performed, and the needle moving trajectory is as shown in fig. 21.

In this embodiment, when the stitch station groove e is over against the sensor 11, the left needle raising cam 4, the left needle receiving cam 5, the right needle receiving cam 6, and the right needle raising cam 7 are all in the working positions, the needle transferring cam 2 and the knitting cam 3 sink into the cam base plate 1, the left needle raising cam 8 and the right needle raising cam 9 raise the needle, and at this time, a stitch operation is performed, and a needle passing trajectory is as shown in fig. 22.

In this embodiment, when the left needle receiving station groove f is over against the sensor 11, the needle transferring cam 2, the knitting cam 3, the needle receiving cam left 5, and the needle raising cam right 7 are all in the working positions, the needle raising cam left 4 and the needle receiving cam right 6 sink into the cam base plate 1, the needle raising cam left 8 and the needle raising cam right 9 raise the needle, at this time, the left needle receiving operation is performed, and the needle moving trajectory is as shown in fig. 23.

In addition, it should be noted that the specific embodiments described in the present specification may be different in the components, the shapes of the components, the names of the components, and the like, and the above description is only an example of the structure of the present invention. All the equivalent changes or simple changes made according to the structure, characteristics and principle of the patent idea of the utility model are included in the protection scope of the patent of the utility model. Various modifications, additions and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.

Claims (4)

1. The utility model provides a six station computerized flat knitting machine bottom plate devices, includes the triangle bottom plate, the front activity of triangle bottom plate is provided with the needle turning triangle, weaves triangle, rise cam left side, connects a needle triangle right side, rise cam right side, lift a needle triangle left side and lift a needle triangle right side, and the back of triangle bottom plate is provided with triangle cam transmission, its characterized in that: the cam transmission device comprises a motor, a sensing disc, a sensor, a needle-turning cam, a knitting cam, a needle-receiving cam left-needle-raising cam right, a needle-receiving cam right-needle-raising cam left and a needle-lifting cam; the sensing disc, the needle receiving triangle left-needle raising triangle right cam, the needle receiving triangle right-needle raising triangle left cam and the needle lifting triangle cam are arranged at the other end of the motor output shaft; the sensor is arranged on one side of the sensing disc; six station grooves are uniformly distributed on the sensing disc clockwise along the circumferential direction and are respectively a needle turning station groove, a knitting station groove, a non-knitting station groove, a right needle receiving station groove, a mesh hanging station groove and a left needle receiving station groove; when any one of the six station grooves is over against the sensor, the needle transferring cam, the knitting cam, the needle receiving cam left-needle raising cam right cam, the needle receiving cam right-needle raising cam left cam and the needle lifting cam are driven by the motor to control the needle transferring cam, the knitting cam, the needle raising cam left, the needle receiving cam right, the needle raising cam right, the needle lifting cam left and the needle lifting cam right to work.

2. The six-station computerized flat knitting machine bottom plate device of claim 1, characterized in that: the needle lifting cam is provided with a notch which is aligned with the non-weaving station groove; the needle-turning cam is provided with three equal-height convex blocks which are respectively aligned with the needle-turning station groove, the non-weaving station groove and the mesh hanging station groove; the knitting cam is provided with two lugs with the height equal to that of the lug on the needle-turning cam, and the two lugs are respectively aligned with the non-knitting station slot and the mesh hanging station slot; the left needle-withdrawing cam is provided with two lugs with the height equal to that of the lug on the needle-turning cam, and the two lugs are respectively aligned with the non-knitting station groove and the left needle-connecting station groove; the needle connecting triangle right-needle raising triangle left cam is provided with two lugs with the height equal to that of the lug on the needle transferring triangle cam, and the two lugs are respectively aligned with the non-knitting station groove and the right needle connecting station groove.

3. The six-station computerized flat knitting machine bottom plate device of claim 1, characterized in that: the back of the needle transferring triangle, the knitting triangle, the left needle raising triangle, the left needle receiving triangle, the right needle receiving triangle and the right needle raising triangle are all provided with lifting shafts, the lifting shafts are provided with pushing blocks, and the needle transferring triangle cam, the knitting triangle cam, the left needle raising triangle right cam and the right needle raising triangle left cam are used for controlling the work of the cams by driving the pushing blocks.

4. The six-station computerized flat knitting machine bottom plate device of claim 1, characterized in that: the left needle lifting triangle and the right needle lifting triangle are connected through a tilting rod mechanism.

Images