CN113564796A

CN113564796A - Hosiery machine rotates lift drive mechanism

Info

Publication number: CN113564796A
Application number: CN202110918227.4A
Authority: CN
Inventors: 钱福海; 吴华盛; 陈宁; 单向海
Original assignee: Zhejiang Yuen Technology Group Co ltd
Current assignee: Zhejiang Yuen Technology Group Co ltd
Priority date: 2021-08-11
Filing date: 2021-08-11
Publication date: 2021-10-29
Anticipated expiration: 2041-08-11
Also published as: CN113564796B

Abstract

The invention discloses a hosiery machine rotation lifting transmission mechanism which comprises a base, wherein a guide shaft is installed on the base, a transfer tooth cylinder is sleeved outside the guide shaft, the upper end of the transfer tooth cylinder is connected with a swing arm, a transfer mechanism for driving the transfer tooth cylinder to rotate is arranged on one side of the base, a lifting driving mechanism for controlling the transfer tooth cylinder to lift is arranged above the swing arm, and a sensing device for feeding back the position of the transfer tooth cylinder is arranged on the base. The invention can realize the lifting and rotating control of the grabbing part of the hosiery machine, and the sensing device is arranged to feed back whether the grabbing part is in place, thereby effectively solving the problem of lifting precision; and the lifting driving mechanism and the guide shaft are on the same straight line, so that the defects of guide shaft blocking and unstable work caused by large working load due to the fact that a transmission shaft and the guide shaft of the traditional structure are not on the same straight line are overcome.

Description

Hosiery machine rotates lift drive mechanism

Technical Field

The invention relates to the technical field of knitting mechanical equipment, in particular to a rotational lifting transmission mechanism of a hosiery machine.

Background

In the production process of socks, the hosiery machine during operation will be followed the cylinder and snatched the fashioned socks of weaving and transferred to sewing up on the device of undertoe and sew up, and traditional hosiery machine rotates the unable accurate positioning socks of elevating system and snatchs the height of part, and the lift unstability that traditional socks snatched the part can influence socks snatch the part and snatch socks and to the needle. The transmission shaft and the guide shaft of the traditional hosiery machine rotating and lifting mechanism are not on the same straight line, and when a motor or other actuating mechanisms work, force is applied to the other side of the guide shaft, so that the working load of the motor or other actuating mechanisms is large, the guide shaft is easy to clamp, and the hosiery machine rotating and lifting mechanism is unstable in working.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a hosiery machine rotation lifting transmission mechanism which can be used for quickly and accurately positioning a grabbing part, is accurate in transmission and runs smoothly.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a hosiery machine rotates lift drive mechanism, includes the base, install the guiding axle on the base, the guiding axle overcoat is equipped with and shifts a tooth section of thick bamboo, the upper end of shifting a tooth section of thick bamboo is connected with the swing arm, one side of base is provided with the drive shift tooth section of thick bamboo pivoted transfer mechanism, the top of swing arm is provided with control shift the lift actuating mechanism that a tooth section of thick bamboo goes up and down, be provided with on the base right it carries out the induction system who feeds back to shift tooth section of thick bamboo position.

The sock grabbing mechanism is arranged on the swing arm, the transfer gear cylinder can move up and down along the guide shaft under the action of the lifting driving mechanism, the transfer mechanism on the side controls the transfer gear cylinder to rotate, and the transfer gear cylinder is fixedly connected with the swing arm, so that the position of the grabbing mechanism is positioned; the induction device is arranged on the base, so that the lifting position of the detection and control transfer gear cylinder can be monitored in real time, and whether the detection and control transfer gear cylinder is in place or not can be fed back, and the problem of lifting precision is effectively solved; and the lifting driving mechanism and the guide shaft are on the same straight line, so that the defects of guide shaft blocking and unstable work caused by large working load due to the fact that a transmission shaft and the guide shaft of the traditional structure are not on the same straight line are overcome.

Furthermore, the lifting driving mechanism comprises a screw nut fixed in the guide shaft, a pushing screw rod matched with the screw nut is arranged in the screw nut, a lifting driving motor is installed on the swing arm, and the pushing screw rod is connected with a transmission shaft of the lifting driving motor.

The pushing screw rod is connected with a fixed coupler for a lifting driving motor, the lifting driving motor is fixed on a motor base, and the motor base is fixedly connected with the swing arm. The lifting driving motor can drive the push screw rod to rotate during working, and the screw rod nut is fixed in the guide shaft and can not move up and down, so that the push screw rod is rotated to give axial force to the screw rod nut, and the screw rod nut can not move up and down to give reverse acting force to the push screw rod, so that the push screw rod can move up and down to drive the swing arm to lift.

Further, the guide shaft inner circle is provided with the jump ring groove, and the top is provided with the internal thread, install the jump ring in the jump ring groove, screw-nut installs the jump ring top, the screw-nut top is provided with fixation nut, fixation nut with the internal thread cooperation is fixed. The screw rod nut is pressed on the clamp spring through the structure, so that the clamp spring is fixed and cannot move up and down.

Further, the locking nut is arranged above the fixing nut, so that the fixing nut can be prevented from loosening, and the stability of the structure is improved.

Further, the lower extreme that promotes the lead screw is provided with the anticreep circle, the anticreep circle adopts the staple bolt structure, and the anticreep circle can prevent to promote the lead screw and break away from screw-nut when the overtravel of lead screw time limit, adopts the staple bolt structure, easy to assemble and dismantlement.

Further, the upper end of the transfer gear cylinder is connected with a supporting plate, the swing arm is installed on the supporting plate, and bearings are arranged between the pushing screw rod and the supporting plate and between the pushing screw rod and the swing arm.

The upper end of the pushing screw rod is provided with a thrust ball bearing, the upper end face of the thrust ball bearing is attached to the lower end face below the supporting plate and is attached to a shaft shoulder of the pushing screw rod, the upper end face of the thrust ball bearing is further provided with a deep groove ball bearing, the deep groove ball bearing is sleeved on the pushing screw rod shaft and is clamped in a bearing retainer of the supporting plate, the thrust ball bearing is arranged above the deep groove ball bearing, the thrust ball bearing is sleeved on the pushing screw rod shaft, the lower face of the thrust ball bearing is attached to the upper face of the supporting plate, the supporting plate is clamped between the two thrust ball bearings, a specially-made locking nut is arranged above the thrust ball bearing, a gasket is arranged between the specially-made locking nut and the thrust ball bearing, and the specially-made locking nut presses the thrust ball bearing to be dead. The structure can ensure the stability and smoothness of the operation of the rotation lifting process, and avoid the situations of blocking and the like.

Further, the transfer mechanism comprises a support arranged on one side of the base, a rack meshed with the periphery of the transfer gear cylinder is arranged in the support in a sliding mode, the rack is connected with a sliding block, one end of the support is provided with a rotary driving motor for driving the sliding block to reciprocate, and the rotary driving motor is connected with the sliding block through a screw rod structure.

The periphery of the transfer gear cylinder is provided with a gear surface which is meshed with the rack, the screw rod structure comprises a screw rod arranged on the support, one end of the screw rod is connected with a rotation driving motor, a screw nut is in threaded fit on the screw rod, and the screw nut is fixedly connected with the sliding block. When the rotary driving motor works, the screw rod is driven to rotate, so that the screw rod nut moves along the direction of the screw rod, the sliding block fixed with the screw rod nut is driven to slide in the support, and the rack slides due to the connection of the rack and the sliding block, so that the transfer mechanism can drive the transfer gear barrel to rotate through the back-and-forth movement of the rack.

Further, the connecting plate is installed to the base side, the transfer mechanism is installed on the connecting plate, and the transfer mechanism is installed in the base side through the connecting plate, and the installation is dismantled conveniently.

Furthermore, the induction device comprises a plurality of inductors which are vertically arranged, the transfer gear cylinder is provided with an upper flange and a lower flange, two sides of the base are respectively provided with a stand column and a probe support, the stand column is provided with a zero position limit screw and a zero position inductor which are matched with the lower flange, and the probe support is provided with a half position inductor and a full position inductor which are matched with the upper flange.

The probe bracket is arranged on the connecting plate and is respectively positioned at two sides of the base together with the upright column, and the three detectors respectively correspond to different positions of the transfer gear cylinder. The lower flange at the lower end of the transfer gear cylinder can be sensed by the zero sensor, the upper limit of the transfer gear cylinder is limited and returns to zero after the lower flange is sensed by the zero sensor, the height of the transfer gear cylinder can be controlled by adjusting the zero sensor up and down, a zero limit screw is arranged on the side of the zero sensor, and the transfer gear cylinder can be limited and protected when a lifting driving motor (with an encoder) is out of step. When the hosiery machine works, the hosiery head needs to have two accurate positions for the swing arm of the grabbing mechanism when the hosiery machine grabs the hosiery from the needle cylinder and transfers the hosiery to the position of the stitching head, and the two accurate positions can be accurately positioned by matching the upper flange at the middle part of the transfer tooth cylinder with the half-position sensor and the full-position sensor.

Further, the base adopts the staple bolt structure, lift driving motor adopts and takes encoder motor. The base adopts a hoop structure to lock the guide shaft, so that the structure is stable and the installation and the disassembly are convenient; the adoption takes encoder motor, its rotational speed of available computer control and the number of turns to control its height of snatching the mechanism swing arm, improve the precision of going up and down.

In conclusion, the control device can realize the lifting and rotating control of the grabbing part of the hosiery machine, and the sensing device can be arranged to feed back whether the grabbing part is in place, so that the problem of lifting precision is effectively solved; and the lifting driving mechanism and the guide shaft are on the same straight line, so that the defects of guide shaft blocking and unstable work caused by large working load due to the fact that a transmission shaft and the guide shaft of the traditional structure are not on the same straight line are overcome.

Drawings

FIG. 1 is an exploded view of the overall structure of the present invention;

FIG. 2 is a perspective view of the structure of the present invention;

FIG. 3 is a cross-sectional view of the structure of the present invention;

FIG. 4 is a schematic structural view (inside) of the transfer mechanism of the present invention;

FIG. 5 is a state diagram of the zero configuration of the present invention;

FIG. 6 is a state diagram of a half-bit configuration of the present invention;

FIG. 7 is a state diagram of the all-bit architecture of the present invention.

Description of the labeling: 1. a base; 2. a column; 3. a zero position limit screw; 4. an induction device; 5. a connecting plate; 6. a transfer mechanism; 7. a probe holder; 8. a guide shaft; 9. a clamp spring; 10. a feed screw nut; 11. fixing a nut; 12. locking the nut; 13. preventing the ring from falling off; 14. pushing the screw rod; 15. a thrust ball bearing; 16. a deep groove ball bearing; 17. a gasket; 18. specially manufacturing a locking nut; 19. a null sensor; 20. a coupling; 21. transferring a gear cylinder; 22. a support plate; 23. a half position inductor; 24. a full position inductor; 25. swinging arms; 26. a motor base; 27. rotating the drive motor; 28. a lifting drive motor; 29. an upper flange; 30. a lower flange; 31. A support; 32. a slider; 33. a rack.

Detailed Description

An embodiment of a hosiery machine rotation elevating transmission according to the present invention will be further explained with reference to fig. 1 to 7.

The utility model provides a hosiery machine rotates lift drive mechanism, refers to fig. 1 and 2 structure and shows, including base 1, install guiding axle 8 on the

base

1, 8 outsourcing of guiding axle are equipped with and shift tooth section of thick bamboo 21, the upper end of shifting tooth section of thick bamboo 21 is connected with swing arm 25, one side of base 1 is provided with the drive shift tooth section of thick bamboo 21 pivoted transfer mechanism 6, the top of swing arm 25 is provided with control shift the lift actuating mechanism that tooth section of thick bamboo 21 goes up and down, it is right to be provided with on the base 1 shift tooth section of thick bamboo 21 position and carry out the induction system 4 that feeds back.

The swing arm 25 is provided with a sock grabbing mechanism, the transfer gear cylinder 21 can move up and down along the guide shaft 8 under the action of the lifting driving mechanism, the transfer mechanism 6 on the side controls the transfer gear cylinder 21 to rotate, and the transfer gear cylinder 21 is fixedly connected with the swing arm 25, so that the position positioning of the grabbing mechanism is realized; the induction device 4 is arranged on the base 1, so that the lifting position of the detection and control transfer gear cylinder 21 can be monitored in real time, whether the detection and control transfer gear cylinder is in place or not can be fed back, and the problem of lifting precision is effectively solved; and the lifting driving mechanism and the guide shaft 8 are on the same straight line, so that the defects that the guide shaft 8 is blocked and works unstably due to the fact that a transmission shaft and the guide shaft 8 are not on the same straight line and the working load is large in the traditional structure are overcome.

Preferably, in this embodiment, the lifting driving mechanism includes a lead screw nut 10 fixed in the guide shaft 8, a pushing lead screw 14 matched with the lead screw nut 10 is arranged in the lead screw nut 10, a lifting driving motor 28 is installed on the swing arm 25, and the pushing lead screw 14 is connected with a transmission shaft of the lifting driving motor 28.

As shown in fig. 3, the pushing screw 14 is connected to a lifting driving motor 28 by a fixed coupling 20, the lifting driving motor 28 is fixed to a motor base 26, and the motor base 26 is fixedly connected to the swing arm 25. The lifting driving motor 28 can drive the pushing screw rod 14 to rotate when working, because the screw rod nut 10 is fixed in the guide shaft 8 and can not move up and down, the pushing screw rod 14 can be rotated to give axial force to the screw rod nut 10, and the screw rod nut 10 can not move up and down and can give reverse acting force to the pushing screw rod 14, so that the pushing screw rod 14 can move up and down, and the swing arm 25 can be driven to lift.

This embodiment is preferred, 8 inner circles of guiding axle are provided with jump ring 9 grooves, and the top is provided with the internal thread, jump ring 9 is installed to jump ring 9 inslot, screw-nut 10 is installed jump ring 9 top, screw-nut 10 top is provided with fixation nut 11, fixation nut 11 with the internal thread cooperation is fixed. The feed screw nut 10 is pressed on the clamp spring 9 through the structure, so that the clamp spring is fixed and cannot move up and down.

In this embodiment, the locking nut 12 is preferably disposed above the fixing nut 11, so as to prevent the fixing nut 11 from loosening and improve the structural stability.

In this embodiment, preferably, the lower end of the pushing screw 14 is provided with the anti-drop ring 13, the anti-drop ring 13 adopts a hoop structure, the anti-drop ring 13 can prevent the pushing screw 14 from being separated from the screw nut 10 when the pushing screw 14 exceeds the stroke, and the hoop structure is adopted, so that the installation and the disassembly are convenient.

In this embodiment, preferably, the upper end of the transfer gear cylinder 21 is connected with a support plate 22, the swing arm 25 is mounted on the support plate 22, and bearings are disposed between the push screw 14 and the support plate 22 and the swing arm 25.

The upper end of the pushing screw rod 14 is provided with a thrust ball bearing 15, the upper end face of the thrust ball bearing 15 is attached to the lower end face below the supporting plate 22 and is attached to a shaft shoulder of the pushing screw rod 14, the upper end face of the thrust ball bearing 15 is further provided with a deep groove ball bearing 16, the deep groove ball bearing 16 is sleeved on the pushing screw rod 14, meanwhile, the deep groove ball bearing 16 is clamped in a bearing retainer of the supporting plate 22, the thrust ball bearing 15 is arranged above the deep groove ball bearing 16, the thrust ball bearing 15 is sleeved on the pushing screw rod 14, the lower face of the thrust ball bearing 15 is attached to the supporting plate 22, the supporting plate 22 is clamped between the two thrust ball bearings 15, a specially-made locking nut 18 is arranged above the thrust ball bearing 15, a gasket 17 is arranged between the specially-made locking nut 18 and the thrust ball bearing 15, and the specially-made locking nut 18 presses the thrust ball bearing 15. The structure can ensure the stability and smoothness of the operation of the rotation lifting process, and avoid the situations of blocking and the like.

Preferably, in the present embodiment, the transfer mechanism 6 includes a support 31 installed on one side of the base 1, a rack 33 engaged with the periphery of the transfer gear cylinder 21 is slidably disposed in the support 31, a sliding block 32 is connected to the rack 33, a rotation driving motor 27 for driving the sliding block 32 to reciprocate is disposed at one end of the support 31, and the rotation driving motor 27 and the sliding block 32 are connected through a screw rod structure.

The periphery of the transfer gear cylinder 21 is provided with a gear surface which is meshed with a rack 33, as shown in fig. 4, the screw rod structure comprises a screw rod arranged in a support 31, one end of the screw rod is connected with a rotation driving motor 27, a screw nut is in threaded fit with the screw rod, and the screw nut is fixedly connected with a slide block 32. When the rotation driving motor 27 works, the lead screw is driven to rotate, so that the lead screw nut moves along the direction of the lead screw, the sliding block 32 fixed with the lead screw nut is driven to slide in the support 31, and the rack 33 is connected with the sliding block 32, so that the rack 33 slides, and the transfer mechanism 6 can drive the transfer gear cylinder 21 to rotate through the back-and-forth movement of the rack 33.

In this embodiment, preferably, the side surface of the base 1 is provided with a connecting plate 5, the transfer mechanism 6 is installed on the connecting plate 5, and the transfer mechanism 6 is installed on the side surface of the base 1 through the connecting plate 5, so that the installation and the disassembly are convenient.

Preferably, in this embodiment, the sensing device 4 includes a plurality of sensors arranged up and down, the transfer gear cylinder 21 is provided with an upper flange 29 and a lower flange 30, two sides of the base 1 are respectively provided with the column 2 and the probe bracket 7, the column 2 is provided with the zero position limit screw 3 and the zero position sensor 19 which are matched with the lower flange 30, and the probe bracket 7 is provided with the half position sensor 23 and the full position sensor 24 which are matched with the upper flange 29.

The probe bracket 7 is arranged on the connecting plate 5 and is respectively positioned at two sides of the base 1 together with the upright post 2, and the three detectors respectively correspond to different positions of the transfer gear cylinder 21. The lower flange 30 at the lower end of the transfer gear cylinder 21 is sensed by the zero sensor 19, as shown in fig. 5, after the lower flange is sensed by the zero sensor 19, the upper limit of the transfer gear cylinder 21 is limited and reset to zero, the height of the transfer gear cylinder 21 can be controlled by adjusting the zero sensor 19 up and down, the zero limit screw 3 is arranged on the side of the zero sensor 19, and the transfer gear cylinder 21 can be limited and protected when the lifting drive motor 28 (with an encoder) is out of step. Since the hosiery knitting machine is operated to transfer the hosiery from the needle cylinder to the toe-stitching position, the toe-stitching position requires two precise positions of the swing arm 25 of the gripping mechanism, which are precisely positioned by the upper flange 29 of the middle of the transfer cylinder 21 in cooperation with the half position sensor 23 and the full position sensor 24, as shown in fig. 6 and 7.

In this embodiment, the base 1 preferably adopts a hoop structure, and the lifting driving motor 28 adopts a belt encoder motor. The base 1 adopts a hoop structure to lock the guide shaft 8, so that the structure is stable and the installation and the disassembly are convenient; the motor with the encoder is adopted, and the rotating speed and the number of rotating turns of the motor can be controlled by a computer, so that the height of the swing arm 25 of the grabbing mechanism is controlled, and the lifting precision is improved.

The working principle is as follows: the upper end of the transfer gear cylinder 21 is connected to the support plate 22 and moves together with the support plate, the upper part of the support plate is connected with the swing arm, the swing arm 25 is provided with a sock grabbing mechanism, and the transfer mechanism 6 drives the rack 32 to move through a screw rod structure, so that the transfer gear cylinder 21 meshed with the transfer gear cylinder rotates to drive the sock grabbing mechanism to swing left and right; a motor base is arranged on the swing arm 25, a lifting driving motor 28 is arranged on the motor base 26, and the lifting driving motor 28 drives the transfer gear cylinder 21 to move up and down along the guide shaft 8 by controlling the push screw rod 14, so that the swing arm 25 of the grabbing mechanism moves up and down; a plurality of inductors can carry out accurate feedback to the position of transferring tooth section of thick bamboo 21, improves the lift precision.

The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention, and are considered to be within the scope of the invention.

Claims

1. The utility model provides a hosiery machine rotates lift drive mechanism which characterized in that: the induction type gear shifting device comprises a base, install the guiding axle on the base, the guiding axle overcoat is equipped with and shifts a tooth section of thick bamboo, the upper end of shifting a tooth section of thick bamboo is connected with the swing arm, one side of base is provided with the drive shift a tooth section of thick bamboo pivoted transfer mechanism, the top of swing arm is provided with control shift the lift actuating mechanism that a tooth section of thick bamboo goes up and down, it is right to be provided with on the base shift the induction system that tooth section of thick bamboo position carries out the feedback.

2. Hosiery machine rotation-lifting transmission according to claim 1, characterized in that: the lifting driving mechanism comprises a lead screw nut fixed in the guide shaft, a pushing lead screw matched with the lead screw nut is arranged in the lead screw nut, a lifting driving motor is installed on the swing arm, and the pushing lead screw is connected with a transmission shaft of the lifting driving motor.

3. Hosiery machine rotation-lifting transmission according to claim 2, characterized in that: the guide shaft inner circle is provided with the jump ring groove, and the top is provided with the internal thread, install the jump ring in the jump ring groove, screw-nut installs the jump ring top, the screw-nut top is provided with fixation nut, fixation nut with the internal thread cooperation is fixed.

4. Hosiery machine rotation-lifting transmission according to claim 3, characterized in that: and a locking nut is arranged above the fixing nut.

5. Hosiery machine rotation-lifting transmission according to claim 2, characterized in that: the lower extreme of promotion lead screw is provided with anticreep circle, anticreep circle adopts the staple bolt structure.

6. Hosiery machine rotation-lifting transmission according to claim 2, characterized in that: the upper end of the transfer gear cylinder is connected with a supporting plate, the swing arm is installed on the supporting plate, and bearings are arranged between the pushing screw rod and the supporting plate and between the pushing screw rod and the swing arm.

7. Hosiery machine rotation-lifting transmission according to claim 1, characterized in that: the transfer mechanism comprises a support arranged on one side of the base, a rack meshed with the periphery of the transfer gear cylinder is arranged in the support in a sliding mode, the rack is connected with a sliding block, one end of the support is provided with a rotary driving motor for driving the sliding block to reciprocate, and the rotary driving motor is connected with the sliding block through a screw rod structure.

8. Hosiery machine rotation-lifting transmission according to claim 7, characterized in that: the side surface of the base is provided with a connecting plate, and the transfer mechanism is arranged on the connecting plate.

9. Hosiery machine rotation-lifting transmission according to claim 1, characterized in that: the induction device comprises a plurality of inductors which are vertically arranged, the transfer gear cylinder is provided with an upper flange and a lower flange, two sides of the base are respectively provided with a stand column and a probe support, the stand column is provided with a zero position limit screw and a zero position inductor which are matched with the lower flange, and the probe support is provided with a half position inductor and a full position inductor which are matched with the upper flange.

10. Hosiery machine rotation-lifting transmission according to claim 1, characterized in that: the base adopts the staple bolt structure, lift driving motor adopts and takes encoder motor.