CN107956032B - Double-layer mesh control structure for motor type and motor mountain plate thereof - Google Patents

Abstract

The invention relates to the field of textile machinery equipment, in particular to a motor type double-layer mesh control structure and a motor mountain plate thereof, comprising: the device comprises an upper-layer mesh sliding block, a lower-layer mesh sliding block, a mesh control assembly, a gear connecting rod assembly, a mesh motor assembly, a torsion spring and a fixed support, wherein the mesh motor assembly drives the gear connecting rod assembly to move back and forth through a transmission gear assembly, a bearing assembly on the gear connecting rod assembly respectively drives the upper-layer mesh sliding block and the lower-layer mesh sliding block to move through a mesh control assembly, and one end of the torsion spring respectively props against the outer side of the mesh control assembly. The motor mountain plates can realize the adjustment of a plurality of sections of character codes; the single knitting needle is controllable, which means that the flower-shaped transition zone is narrowed; the two layers of braiding belts are dynamic, so that the flatness of the flowers is enhanced; the knitting cam and the needle turning cam are controlled by a cam motor, so that the knitting cam is stable and reliable; the double-layer mesh motor can realize 9 actions: zero position, left tight hanging, right tight hanging, needle turning, knitting hanging, two-layer knitting, two-layer hanging, left needle pressing and right needle pressing.

Description

Double-layer mesh control structure for motor type and motor mountain plate thereof

Technical field:

the invention relates to the field of textile machinery equipment, in particular to a motor type double-layer mesh control structure and a motor mountain plate thereof.

The background technology is as follows:

the design structure of the bottom plate of the head of the computerized flat knitting machine can enable the knitting needle to complete five basic actions of knitting, eye lifting, needle turning, needle receiving and non-knitting. The movements extending over these five basic movements include half a eye, etc. The half-eye picking action is to perform the knitting action while the knitting needle performs the turning action. In the needle track design of the existing machine head bottom plate, the control mode is relatively simple, only simple patterns can be woven, and a plurality of weaving actions cannot be completed.

Conventional single system and electromagnet products suffer from a number of disadvantages, such as: the station triangle uses electromagnetic control, so that the stability is insufficient, the high-precision knitting action cannot be completed, the control and adjustment are complex, the service life is short, and the like; the old stitch cam adopts a single-layer design, and cannot be used for cloth with larger standard density.

The invention comprises the following steps:

aiming at the defects of the prior art, the motor mountain plate with the advantages of high operation efficiency, high stability and the like is provided, and in order to achieve the purposes, the invention adopts the following technical scheme: a motor type double-layer mesh control structure and a motor mountain plate thereof mainly comprise: the device comprises an upper-layer mesh sliding block, a lower-layer mesh sliding block, a mesh control assembly, a gear connecting rod assembly, a mesh motor assembly, a torsion spring and a fixed support, wherein the mesh motor assembly drives the gear connecting rod assembly to move back and forth through a transmission gear assembly, one mesh motor assembly drives the upper gear connecting rod assembly, the other mesh motor assembly drives the lower gear connecting rod assembly, bearing assemblies on the upper gear connecting rod assembly and the lower gear connecting rod assembly respectively drive the upper-layer mesh sliding block (1) and the lower-layer mesh sliding block (2) to move through the mesh control assembly (3), and one end of the torsion spring respectively props against the outer side of the mesh control assembly.

Specifically, the mesh control assembly mainly comprises an upper mesh control block and a lower mesh control block, a sliding rail is arranged on the inner side of the upper mesh control block, a bearing assembly of an upper gear connecting rod assembly is displaced along the sliding rail, a convex edge surface is arranged on the inner side of the lower mesh control block, the bearing assembly of a lower gear connecting rod assembly is displaced along the convex edge surface, and the upper mesh control block and the lower mesh control block are separately controlled by the upper gear connecting rod assembly and the lower gear connecting rod assembly, so that independent operation of upper-layer and lower-layer mesh sliding blocks is realized.

Specifically, the upper scale control block outside connect in upper strata scale slider, lower scale control block outside connect in lower floor scale slider, upper strata scale slider inboard is equipped with the scale concave surface, lower floor scale slider outside is equipped with the scale lug, when upper strata scale slider and lower floor scale slider are closed each other, the scale lug agrees in the scale concave surface, when equipment high-speed operation, the cooperation between upper strata scale slider and lower floor scale slider is more inseparable, avoids equipment to cause unnecessary damage.

Specifically, the fixed bolster about all be equipped with horizontal line slot position, upper and lower two gear link assembly set up respectively in horizontal line slot position, the mesh motor assembly runs through the round hole on the fixed bolster and through the straight tooth driving medium intermeshing of drive gear subassembly and gear link assembly, gear link assembly makes a round trip the displacement along horizontal line slot position to guarantee the precision and the life of equipment.

Specifically, the mesh motor assembly mainly comprises transmission gear assembly, mesh motor, magnetic sensor and magnetic induction wheel, and transmission gear assembly is connected at mesh motor top, and the magnetic induction wheel is installed in mesh motor bottom, and the magnetic sensor sets up in magnetic induction wheel one side.

Specifically, the gear connecting rod assembly mainly comprises a bearing assembly, a straight-tooth transmission piece and a slat, wherein the bearing assembly is arranged on one side of the slat, and the straight-tooth transmission piece is arranged on the other side of the slat, so that the linear motor can drive the slat to transversely move back and forth through the straight-tooth transmission piece, and the bearing assembly presses the upper-layer linear sliding block and the lower-layer linear sliding block to move.

Specifically, the panel be equipped with a plurality of groups and turn over needle triangle, weave triangle, station triangle and station motor, upper strata degree mesh slider and lower floor degree mesh slider are located and turn over needle triangle both sides, are equipped with symmetrical splayed spout on the panel, upper strata degree mesh slider and lower floor degree mesh slider are along splayed spout round trip displacement.

Specifically, the station motor connect in the pivot, the station motor drives cam module through the pivot and rotates, the cam module below is equipped with the trace, the trace both ends contact each other with the front and back cam of cam module respectively.

Specifically, cam subassembly and degree mesh motor assembly install at the fixed bolster, two degree mesh motor assemblies are located the motor inslot of cam subassembly both sides respectively.

The beneficial effects of the invention are as follows:

1) The double-layer mesh control structure adopts independent control of upper and lower double-layer meshes, an upper-layer mesh sliding block or a lower-layer mesh sliding block is respectively and separately regulated and controlled by two mesh motors, one mesh motor controls the upper-layer mesh sliding block, the other mesh motor controls the lower-layer mesh sliding block, the double-layer mesh adjustable range is greatly improved, compared with the single mesh transmission technology and single-side regulation and control, the upper and lower layers of the double-layer mesh control structure can form 2 runways with different mesh values for the operation of knitting needles, thereby forming the knitting effect with different tightness of the same layer, the double-layer mesh can be knitted in a wider density range, and cloth with different densities can be knitted, thereby meeting different customer demands, the double-layer mesh cam can finish more knitting needle dynamics, and greatly improve the practicability of the cam;

2) The motor mountain plates can realize the adjustment of a plurality of sections of character codes; the single knitting needle is controllable, which means that the flower-shaped transition zone is narrowed; the two layers of braiding belts are dynamic, so that the flatness of the flowers is enhanced; the knitting cam and the needle turning cam are controlled by a cam motor, so that the knitting cam is stable and reliable; the double-layer mesh motor can realize 9 actions: zero position, left tight hanging, right tight hanging, needle turning, knitting hanging, two-layer knitting, two-layer hanging, left needle pressing and right needle pressing.

Description of the drawings:

FIG. 1 is an internal perspective view of a control structure of the present invention;

FIG. 2 is an assembly view of the stitch motor assembly and the gear link assembly of the present invention;

FIG. 3 is a perspective view of the brightness motor assembly of the present invention;

FIG. 4 is a schematic diagram of a dual-level mesh control structure of the present invention;

FIG. 5 is a perspective view of an upper order slider of the present invention;

FIG. 6 is a perspective view of a lower order slider of the present invention;

FIG. 7 is an assembled view of the back of the fixing bracket of the present invention;

FIG. 8 is an assembled view of the back of the motor mountain plate of the present invention;

FIG. 9 is a diagram of the trace of the front of the motor mountain plate of the present invention;

FIG. 10 is an enlarged view of a portion of the trace of the present invention;

fig. 11 to 20 are trace diagrams of the motor mountain plate nonwoven and nine actions of the present invention.

The specific embodiment is as follows:

for a further understanding of the objects, features and functions of the present invention, preferred embodiments are described below in conjunction with the drawings:

fig. 1 to 6 are schematic structural views of a preferred embodiment of the present invention, which is a motor type double-layer mesh control structure, mainly comprising: the upper layer stitch slider 1, lower floor stitch slider 2, stitch control assembly 3, gear connecting rod assembly 4, stitch motor assembly 5, torsional spring 6 and fixed bolster 7, stitch motor assembly 5 pass through drive gear assembly 51 and drive gear connecting rod assembly 4 back and forth displacement, one stitch motor assembly 5 drives gear connecting rod assembly 4, another stitch motor assembly 5 drives lower gear connecting rod assembly 4, the bearing assembly 41 on upper and lower two gear connecting rod assemblies 4 passes through stitch control assembly 3 and drives upper layer stitch slider 1 and lower floor stitch slider 2 displacement respectively, torsional spring 6 one end withstands stitch control assembly 3 outside respectively.

In the above scheme, the mesh control assembly 3 mainly comprises an upper mesh control block 31 and a lower mesh control block 32, a slide rail 311 is arranged at the inner side of the upper mesh control block 31, a bearing assembly 41 of the upper gear connecting rod assembly 4 is displaced along the slide rail 311, a convex edge surface 321 is arranged at the inner side of the lower mesh control block 32, and the bearing assembly 41 of the lower gear connecting rod assembly 4 is displaced along the convex edge surface 321. The outer side of the upper order control block 31 is connected to the upper order sliding block 1, the outer side of the lower order control block 32 is connected to the lower order sliding block 2, the inner side of the upper order sliding block 1 is provided with an order concave surface 11, the outer side of the lower order sliding block 2 is provided with an order convex block 21, and the order convex block 21 and the order concave surface 11 are mutually matched. When the upper-layer stitch slider 1 and the lower-layer stitch slider 2 are mutually closed, the stitch convex block 21 is well fit in the stitch concave surface 11.

According to the scheme, the fixed support 7 is provided with the transverse line groove position 71 up and down, the upper gear connecting rod assembly 4 and the lower gear connecting rod assembly 4 are respectively arranged in the transverse line groove position 71, and the stitch motor assembly 5 penetrates through the round hole 72 on the fixed support 7 and is meshed with the straight tooth transmission piece 42 of the gear connecting rod assembly 4 through the transmission gear assembly 51. The mesh motor assembly 5 mainly comprises a transmission gear assembly 51, a mesh motor 52, a magnetic sensor 53 and a magnetic induction wheel 54, wherein the top of the mesh motor 52 is connected with the transmission gear assembly 51, the magnetic induction wheel 54 is arranged at the bottom of the mesh motor 52, and the magnetic sensor 53 is arranged on one side of the magnetic induction wheel 54. The gear connecting rod assembly 4 mainly comprises a bearing assembly 41, a straight-tooth transmission piece 42 and a slat 43, wherein the bearing assembly 41 is arranged on one side of the slat 43, and the straight-tooth transmission piece 42 is arranged on the other side of the slat 43.

Fig. 7 to 10 show a schematic structural diagram of a preferred embodiment of the present invention, which is a motor mountain board in the above scheme, the panel 8 is provided with a plurality of groups of stitch cams 81, knitting cams 82, station cams 83 and station motors 84, the upper stitch slider 1 and the lower stitch slider 2 are located at two sides of the stitch cams 81, symmetrical splayed sliding grooves are provided on the panel 8, and the upper stitch slider 1 and the lower stitch slider 2 are displaced back and forth along the splayed sliding grooves. The station motor 84 is connected to the rotating shaft 841, the station motor 84 drives the cam assembly 842 to rotate through the rotating shaft 841, a linkage rod 843 is arranged below the cam assembly 842, two ends of the linkage rod 843 are respectively contacted with front and rear cams of the cam assembly 842, and the other sides of two ends of the linkage rod 843 are propped against the needle turning cam 81 and the knitting cam 82. The cam assembly 842 and the stitch motor assembly 5 are mounted on the fixing bracket 7, and the stitch motor assembly 5 is respectively positioned in the motor grooves 73 at two sides of the cam assembly 842.

The double-layer mesh operation process comprises the following steps: the rotation angle and the position of the stitch motor component 5 are controlled by the components such as the magnetic sensor 53, the magnetic sensing wheel 54 and the like, the stitch motor component 5 drives the two bearing components 41 on the ribbon 43 to move back and forth through the transmission gear component 51 and the straight tooth transmission piece 42 at the front end, at this time, the upper bearing component 41 makes the upper bearing component 31 swing by pressing the sliding rail 311 on the inner side of the upper stitch control block 31, and as the upper stitch control block 31 is connected with the upper stitch slide block 1, the upper stitch slide block 1 of the upper stitch control block 31 is pulled to move upwards or downwards along the splayed chute of the panel 8, and similarly, the other stitch motor component 5 makes the lower bearing component 41 press the convex edge surface 321 on the inner side of the lower stitch control block 32, so as to pull the lower stitch slide block 2 to move upwards or downwards along the splayed chute.

The double-layer mesh resetting is realized by using the upper torsion spring 6 and the lower torsion spring 6, and the upper bearing assembly 41 and the lower bearing assembly 41 are driven to reset by reversing the mesh motor assembly 5, so that when the bearing assembly 41 is not pressed to the upper mesh control block 31 and the lower mesh control block 32 any more, the upper torsion spring 6 pushes the upper mesh control block 31 and the lower mesh control block 32 to the designated positions by using self elasticity, and the resetting action of the upper mesh sliding block 1 and the lower mesh sliding block 2 is completed.

While the basic principles and main features of the present invention and advantages of the present invention have been shown and described, it will be understood by those skilled in the art that the present invention is not limited by the foregoing embodiments, which are described in the foregoing description and illustrations only, and are thus applicable to different knitting needles without departing from the spirit and scope of the invention, which is defined by the appended claims and their equivalents.

Claims (4)

1. A motor type double-layer mesh control structure mainly comprises: upper strata stitch slider (1), lower floor stitch slider (2), stitch control assembly (3), gear connecting rod assembly (4), stitch motor assembly (5), torsional spring (6) and fixed bolster (7), its characterized in that: the utility model discloses a mesh motor component (5) drive gear connecting rod component (4) back and forth displacement through transmission gear subassembly (51), one mesh motor component (5) drive gear connecting rod component (4), another mesh motor component (5) drive lower gear connecting rod component (4), bearing component (41) on upper and lower two gear connecting rod components (4) drive upper strata mesh slider (1) and lower floor's mesh slider (2) displacement respectively through mesh control subassembly (3), torsional spring (6) one end withstands mesh control subassembly (3) outside, mesh control subassembly (3) mainly constitute by mesh control piece (31) and lower mesh control piece (32) of going up, mesh control piece (31) inboard is equipped with slide rail (311), the bearing component (41) of last gear connecting rod component (4) are along slide rail (311) displacement, the mesh control piece (32) inboard is equipped with protruding face (321) down, the bearing component (41) of gear connecting rod component (4) are along protruding face (321) displacement down, mesh control piece (31) are connected in mesh control piece (1) outside the mesh of going up and are connected in mesh (1) outside the mesh of layer outside of layer (1), the utility model provides a degree mesh slider (2) outside is equipped with degree mesh lug (21), degree mesh lug (21) and degree mesh concave surface (11) agree with each other, fixed bolster (7) about all be equipped with horizontal line slot position (71), two upper and lower gear link assembly (4) set up respectively in horizontal line slot position (71), degree mesh motor assembly (5) run through round hole (72) on fixed bolster (7) and through the straight tooth driving medium (42) intermeshing of drive gear assembly (51) and gear link assembly (4), degree mesh motor assembly (5) mainly constitute by drive gear assembly (51), degree mesh motor (52), magnetic sensor (53) and magnetic induction wheel (54), degree mesh motor (52) top connection drive gear assembly (51), magnetic induction wheel (54) are installed in degree mesh motor (52) bottom, magnetic sensor (53) set up in magnetic induction wheel (54) one side, its characterized in that: the gear connecting rod assembly (4) mainly comprises a bearing assembly (41), a straight-tooth transmission member (42) and a slat (43), wherein the bearing assembly (41) is arranged on one side of the slat (43), and the straight-tooth transmission member (42) is arranged on the other side of the slat (43).

2. The motor type double-layer mesh control structure according to claim 1, wherein: the panel (8) of motor mountain board is equipped with a plurality of groups and turns over needle triangle (81), weave triangle (82), station triangle (83) and station motor (84), and upper strata degree mesh slider (1) and lower floor's degree mesh slider (2) are located and turn over needle triangle (81) both sides, are equipped with symmetrical splayed spout on panel (8), and upper strata degree mesh slider (1) and lower floor's degree mesh slider (2) are along splayed spout round trip displacement.

3. The motor type double-layer mesh control structure according to claim 2, wherein: the station motor (84) is connected to the rotating shaft (841), the station motor (84) drives the cam assembly (842) to rotate through the rotating shaft (841), a linkage rod (843) is arranged below the cam assembly (842), two ends of the linkage rod (843) are respectively contacted with front and rear cams of the cam assembly (842), and the other sides of two ends of the linkage rod (843) are propped against the needle turning cam (81) and the knitting cam (82).

4. A motor version double-duty control structure according to claim 3, characterized in that: the cam component (842) and the stitch motor component (5) are arranged on the fixed bracket (7), and the stitch motor component (5) is respectively positioned in the motor grooves (73) at two sides of the cam component (842).