CN110731577A

CN110731577A - Auxiliary shoelace binding clamp

Info

Publication number: CN110731577A
Application number: CN201911220768.9A
Authority: CN
Inventors: 许凯
Original assignee: Zhongshan Zhi Jie Shoes Technology Services Ltd
Current assignee: Zhongshan Zhi Jie Shoes Technology Services Ltd
Priority date: 2019-12-03
Filing date: 2019-12-03
Publication date: 2020-01-31

Abstract

The invention discloses auxiliary shoelace tying clamps, which comprise a bracket, two oppositely arranged clamping parts arranged on the bracket, and at least 0 horizontal moving units with locking functions, wherein when 2 are arranged on the 1 horizontal moving unit, 3 clamping parts are arranged on the bracket through 4 horizontal moving units, when two horizontal moving units are arranged, each clamping part is arranged on the bracket through horizontal moving units, the horizontal moving unit can drive the clamping part arranged on the second clamping part to move towards or away from the side where the other clamping parts are arranged in the horizontal plane along the horizontal axis, therefore, the shoes can be clamped between the two clamping parts through the horizontal moving unit to drive the clamping part to move, an operator can not shake the shoes in the shoelace tying process, the shoelace quality is guaranteed, the shoelace can be tied by both hands, the shoelace tying efficiency is high, meanwhile, the shoes can be fixed by hands without fatigue of the body except the shoelace, and the shoelace is not easy to generate.

Description

Auxiliary shoelace binding clamp

Technical Field

The invention relates to a shoemaking tool, in particular to auxiliary shoelace tying clamps.

Background

When an operator ties the shoelace on the shoe, the shoelace is put on the shoe or tied on the shoe, generally requires two hands to lift the shoe, which causes the shoe to swing and leads to the reduction of shoelace tying efficiency or the reduction of shoelace tying quality, and at this time, if the operator needs to vacate hands to fix the shoe, the shoelace tying efficiency is reduced, and if the shoe is fixed by other body parts except the hands of the operator, the operator is easy to fatigue.

Disclosure of Invention

In order to solve the problems of reduced shoelace tying efficiency or reduced quality of shoelaces due to the swinging of shoes during shoelace tying, reduced shoelace tying efficiency due to the fact that an operator needs to vacate hands to fix the shoes, and fatigue easily caused by the fact that the operator fixes the shoes through other body parts except the hands, auxiliary shoelace tying clamps are provided according to aspects of the present invention.

The auxiliary shoelace tying clamp comprises a bracket, two clamping parts arranged on the bracket, wherein the two clamping parts are oppositely arranged and made of non-hard materials, and at least horizontal moving units with locking functions, when 1 of 0 horizontal moving units are arranged, 2 clamping parts are arranged on the bracket through 3 horizontal moving units, when 4 horizontal moving units are arranged, each clamping part is independently arranged on the bracket through horizontal moving units, and an horizontal moving unit is arranged to drive the clamping part arranged on the clamping part to reciprocate in a horizontal plane along a horizontal axis, so that the clamping part arranged on the clamping part can move towards the side where another clamping parts are arranged or move towards the side away from another clamping parts.

Therefore, before tying the shoelace on the shoe, an operator can firstly sleeve the shoe tree in the shoe, then the shoe on which the shoelace is to be tied and provided with the shoe tree is placed on the support between the two clamping parts, then the clamping parts arranged on the clamping parts are driven by the horizontal moving unit to move towards the side where the other clamping parts are located in the horizontal plane along the horizontal axis so as to clamp the shoe with the shoelace between the two clamping parts, at the moment, the operator can tie the shoelace on the shoe clamped between the two clamping parts, as the shoe is clamped between the two clamping parts, the shoe cannot shake in the shoelace tying process, the quality of the shoelace is guaranteed, the operator can simultaneously use two hands for shoelace tying, the tying efficiency is high, the operator does not need to fix the shoe by other body parts except hands, fatigue is not easy to generate, or the horizontal moving unit drives the clamping parts arranged on the clamping parts to move towards the side where the other clamping parts are located in the horizontal axis so as to replace the shoelace from the shoe with the clamping parts to be loosened.

the auxiliary shoelace tying clamp further comprises an inclined supporting unit arranged on the bracket, wherein the inclined supporting unit is arranged between the two clamping parts, and the included angle between the top surface of the inclined supporting unit and the horizontal plane is 5-60 degrees, therefore, a shoe to be tied with a shoelace can be placed on the top surface of the inclined supporting unit arranged on the bracket, so that when the shoe to be tied with the shoelace is placed on the top surface of the inclined supporting unit, the top surface of the shoe is inclined, an operator can tie the shoelace on the shoe without bending down, the operation burden of the operator is reduced, and the shoelace tying efficiency is improved by steps.

in some embodiments, the top surface of the inclined supporting unit is parallel to the th horizontal axis, so that when the shoe to be tied is placed on the top surface of the inclined supporting unit and the clamping part is moved by the th horizontal moving unit, the inclined supporting unit does not obstruct the movement of the th horizontal moving unit and/or the clamping part, so as to ensure that the clamping part can stably clamp the shoe to be tied.

In , the auxiliary shoelace tying jig further comprises a second horizontal moving unit having a th locking structure, wherein the inclined support unit is disposed on the bracket through the second horizontal moving unit, the second horizontal moving unit is configured to drive the inclined support unit to reciprocate along a second horizontal axis in a horizontal plane, and the second horizontal axis is not parallel to the th horizontal axis, so that the inclined support unit and the shoelace to be tied can be driven by the second horizontal moving unit to reciprocate along the second horizontal axis in the horizontal plane to adjust the clamping position of the clamping portion to clamp shoes with different heights.

In , the second horizontal axis is perpendicular to the horizontal axis, so that the distance that the second horizontal moving unit moves the inclined supporting unit along the second horizontal axis in the horizontal plane is equivalent to the difference between the horizontal distances before and after the distance adjustment between the clamping part and the inclined supporting unit, so as to make the distance adjustment between the clamping part and the inclined supporting unit faster.

In embodiments, the lower end of the top surface of the inclined support unit is provided with a support portion for supporting the side portion of the shoe, whereby when the shoe to be laced is placed on the top surface of the inclined support unit, support can be given to the shoe by the support portion to prevent the shoe from sliding off the top surface of the inclined support unit.

In , the top surface of the inclined supporting unit is provided with at least two sets of mounting structures distributed along the direction vertical to the horizontal axis, the supporting parts are arranged on the inclined supporting unit through the mounting structures, and the mounting structures are arranged to enable the supporting parts to be mounted at different positions of the top surface along the direction vertical to the horizontal axis in the plane of the top surface.

In embodiments, the two horizontal moving units are symmetrically distributed on both sides of the inclined supporting unit, and the horizontal moving unit is an air cylinder driving the clamping part to move along the horizontal axis, therefore, when the shoes placed on the inclined supporting unit need to be clamped by the horizontal moving unit driving the clamping part, the air cylinder can be turned on by a switch, and the operation is convenient and fast.

In embodiments, the auxiliary shoelace tying jig further comprises two vertical moving units having a second locking structure, each of the clamping portions is separately provided on the st horizontal moving unit through vertical moving units or wherein the clamping portions are provided on the horizontal moving unit through vertical moving units, the other clamping portions are provided on the bracket through the other vertical moving units, and the vertical moving units are configured to drive the clamping portions to reciprocate along a vertical axis.

Therefore, the clamping parts can be driven to move along the vertical axis direction through the vertical moving unit, so that the position of the clamping parts in the vertical direction can be adjusted, the height of the shoes clamped between the two clamping parts can be adjusted, and the shoes with different heights can be adapted.

In embodiments, the clamping portion is detachably mounted on the vertical moving unit, whereby the clamping portion having a different shape can be replaced according to the shoe of a different model to enable the shoe to be clamped by the clamping portion.

Drawings

FIG. 1 is a schematic structural view of an auxiliary shoelace tying jig in accordance with an embodiment of the present invention;

FIG. 2 is a structural view of the auxiliary shoelace tying jig of FIG. 1 from another view point ;

FIG. 3 is a structural view, from a further perspective , of the auxiliary shoelace tying holder shown in FIG. 1;

FIG. 4 is a schematic sectional view taken along A-A of the auxiliary shoelace tying jig of FIG. 3;

FIG. 5 is a schematic sectional view taken along line B-B of the auxiliary shoelace tying jig of FIG. 3;

FIG. 6 is a structural view, again at , of the auxiliary shoelace tying jig of FIG. 1;

FIG. 7 is a schematic sectional view of the auxiliary shoelace tying jig of FIG. 6, taken along the line C-C;

FIG. 8 is a structural view illustrating a disassembled state of the auxiliary shoelace tying jig in the exemplary embodiments;

FIG. 9 is a schematic structural diagram of an embodiment of , namely a horizontal slider and a vertical guide rail.

Detailed Description

The present invention is further described in detail below with reference to the attached figures.

Fig. 1 to 9 schematically show embodiments of an auxiliary shoelace tying jig in accordance with the present invention.

Referring to fig. 1 to 6 and 8, the auxiliary shoelace tying jig comprises a bracket 20, two clamping portions 30 and a horizontal moving unit 40, wherein the two clamping portions 30 are provided on the bracket 20, the two clamping portions 30 are oppositely arranged on the bracket 20, the clamping portions 30 are made of non-hard materials, the th horizontal moving unit 40 is provided with at least and has a locking function, when the th horizontal moving unit 40 is provided with , the th clamping portion 30 is provided on the bracket 20 through the 4 horizontal moving unit 40, when the th horizontal moving unit 40 is provided with two, each clamping portion 30 is provided on the bracket 20 through the th horizontal moving unit 40 alone, the th horizontal moving unit 40 is provided to bring the clamping portion 30 provided thereon to reciprocate (move in the direction X shown in fig. 1) in a horizontal plane along the horizontal axis 400 relative to the bracket 20 so that the clamping portion 30 provided thereon can move towards the other clamping portion 30 on the 8536 or towards the other clamping portion 8945 on the 8584 horizontal axis 400 side of the clamping portion 84.

When using the auxiliary shoelace tying jig, an operator may first put the last in the shoe before tying the shoelace to the shoe, then put the shoe on which the last is put to be tied on the bracket 20 between the two clamping portions 30, and then move the clamping portion 30 provided thereon in the horizontal plane along the horizontal axis 400 toward the side where the other clamping portions 30 are located by the horizontal moving unit 40 to clamp the shoe to be tied between the two clamping portions 30, in which case the operator may tie the shoelace to the shoe clamped between the two clamping portions 30, since the shoe is clamped between the two clamping portions 30, the operator does not shake the shoe during shoelace tying, the quality of tying is ensured, and the operator may use both hands simultaneously for tying, the shoelace tying efficiency is high, and the operator does not need to fix the shoe by the body parts other than the hands, fatigue is not easily generated, or the operator may move the clamping portion 30 provided thereon in the horizontal plane along the 2 horizontal axis 3875 to change the shoelace from the clamping portion 64 to the shoe to be tied to the shoe in the horizontal plane.

In this embodiment, referring to fig. 4 and 8, the th horizontal moving unit 40 includes an th horizontal moving unit 40 including an air cylinder 43 and a th horizontal guiding rail 41 and a th horizontal sliding block 42 fitted to each other, wherein the th horizontal guiding rail 41 is formed, machined or connected to the support 20, the th horizontal guiding rail 41 extends along the 400 direction of the th horizontal axis in the horizontal plane, the cylinder body of the air cylinder 43 is mounted on the support 20, the piston rod of the air cylinder 43 is connected to the th horizontal sliding block 42, and the clamping portion 30 provided on the th horizontal moving unit 40 is provided on the th horizontal sliding block 42.

The piston rod of the air cylinder 43 drives the th horizontal sliding block 42 and the clamping part 30 arranged on the th horizontal sliding block 42 to move towards the lifting clamping parts 30 along the th horizontal axis 400, when the two clamping parts 30 clamp the shoe to be tied with shoelaces, which is placed on the bracket 20 and located between the two clamping parts 30, the air pressure of the air cylinder 43 realizes the locking function of the th horizontal moving unit 40, so that the two clamping parts 30 can clamp the shoe to be tied with shoelaces, which is located between the two clamping parts 30.

In , the cylinder can be controlled by a knee top switch, which can be disposed at the bottom of the support 20 or at the bottom of the table on which the support 20 is placed, so that the operator can press the switch through the knee to turn on and off the cylinder, and the knee top switch can be a press switch (not shown) commonly used in the art.

In referring to fig. 2 and 4, cylinder 43 is mounted to bracket 20 by mounting bracket 21, mounting bracket 21 is integrally formed, machined or otherwise attached to bracket 20, and of mounting bracket 21 is integrally formed, machined or otherwise provided with through holes or threaded holes such that screws may be inserted through the through holes in the body of cylinder 43 and the through holes and threaded holes in mounting bracket 21 to mount cylinder 43 to bracket 21.

In , referring to fig. 4, a baffle 44 is disposed above the horizontal rail 41 of the horizontal sliding block 42 to prevent foreign matters from falling on the horizontal rail 41, so that the horizontal sliding block 42 cannot move smoothly on the horizontal rail 41.

In embodiments, the baffle 44 and the horizontal sliding block 42 are connected in a manner shown in fig. 8, a -th through groove 441 matched with the cross section of the -th horizontal sliding block 42 is integrally formed or machined on the baffle 44, and the baffle 44 is sleeved on the -th horizontal sliding block 42 through the -th through groove 441, so that the baffle 44 and the -th horizontal sliding block 42 are quickly mounted.

In order to prevent the th horizontal sliding block 42 from sliding off the th horizontal rail 41 when reciprocating along the th horizontal rail 41, referring to fig. 8 and 9, two opposite sides of the th horizontal sliding block 42 are formed or machined with slots 420, and the slots 420 are engaged with the th horizontal rail 41.

In , to facilitate the installation of the horizontal rail 41 and the horizontal slider 42, as shown in fig. 8 and 9, the horizontal slider 42 includes a mounting block 421 and a second mounting block 422 detachably connected to each other, so that a slot 420 is formed on the horizontal slider 42 after the mounting block 421 and the second mounting block 422 are connected.

In , side of the two sides of the slot 420 is located above the th horizontal rail 41, and side is located below the th horizontal rail 41.

In another embodiment of the th horizontal moving unit 40, the difference from the th horizontal moving unit 40 of this embodiment is that the th horizontal moving unit 40 is not provided with the air cylinder 43, and the th horizontal moving unit 40 has a locking function by machining a guide rail for communicating the th horizontal guide rail 41 with the outside on the th horizontal slider 42.

In , a screw hole on the horizontal slider 42 is formed on the side of the horizontal rail 41 surrounding the card slot 420 or on the side of the horizontal rail 41 surrounding the card slot 420, so that the horizontal slider 42 is locked on the horizontal rail 41 by abutting a screw on the horizontal rail 41 (not shown in the figure).

In the present embodiment, as shown with reference to fig. 1, 5, 6 and 8, the auxiliary shoelace tying jig further comprises an inclined support unit 50 provided on the bracket 20; the inclined supporting unit 50 is disposed between the two clamping portions, and an angle between a top surface 500 of the inclined supporting unit 50 and a horizontal plane ranges from 5 to 60 °.

From this, the shoes of waiting to tie up the shoelace can be placed on the top surface 500 of the inclined support unit 50 established on support 20 to when making the shoes of waiting to tie up the shoelace place on the top surface 500 of inclined support unit 50, the top surface 500 of shoes inclines, and operating personnel need not to bow just can tie up the shoelace on the shoes, alleviates operating personnel's operation burden, and step improves the efficiency of tying up the shoelace.

In embodiments, referring to fig. 1, 5 and 8, the inclined supporting unit 50 can be realized by the angle plate 53 with an included angle of 5-60 degrees, which is simple in structure and convenient to install.

In embodiments, referring to fig. 1, 3 and 6, the intersection line of the top surface 500 of the inclined supporting unit 50 and the horizontal plane is parallel to the horizontal axis 400. therefore, when the shoe to be tied with a string is placed on the top surface 500 of the inclined supporting unit 50 and the clamping part 30 is moved by the horizontal moving unit 40, the inclined supporting unit 50 does not obstruct the movement of the horizontal moving unit 40 and/or the clamping part 30, so as to ensure that the clamping part 30 can stably clamp the shoe to be tied with a string.

In embodiments, referring to FIGS. 1, 5 and 8, the auxiliary shoelace tying jig further comprises a second horizontal moving unit 60 having a th locking structure 61, the inclined supporting unit 50 is provided on the bracket 20 by the second horizontal moving unit 60, the second horizontal moving unit 60 is configured to drive the inclined supporting unit 50 to reciprocate in a horizontal plane (moving in the Y direction as shown in FIG. 1) along a second horizontal axis 600, and the second horizontal axis 600 is not parallel to the th horizontal axis 400.

Therefore, the second horizontal moving unit 60 can drive the inclined supporting unit 50 and the shoe to be tied with the shoelace to reciprocate along the second horizontal axis 600 in the horizontal plane, so as to adjust the position of the clamping part 30 for clamping the shoe, thereby clamping the shoes with different heights.

in some embodiments, referring to fig. 1 and 8, the second horizontal axis 600 is perpendicular to the horizontal axis 400. therefore, the distance that the second horizontal moving unit 60 moves the inclined supporting unit 50 along the second horizontal axis 600 in the horizontal plane is equivalent to the difference between the horizontal distances before and after the distance adjustment between the clamping part 30 and the inclined supporting unit 50, so as to make the distance adjustment between the clamping part 30 and the inclined supporting unit 50 faster.

In the present embodiment, referring to fig. 1, 5 and 8, the second horizontal moving unit 60 having the th locking structure 61 includes a second through slot 612 integrally formed or machined on the angle plate 53 by th screws 613, , a th screw hole 611 machined on the bracket 20, the second through slot 612 being first arranged along the second level, a th screw 613 being fitted into the second through slot 612 and the th screw hole 611, and a th screw 613 passing through the second through slot 612 and being threadedly connected with the th screw hole 611.

When the screw 613 of the is loosened, the angle plate 53 can move along the second through groove 612 relative to the bracket 20, and when the screw 613 of the is tightened, the angle plate 53 is locked on the bracket 20.

In other embodiments, the second horizontal moving unit 60 can also be implemented as a slide block structure with mutually adaptive guide rails, the guide rails are installed on the bracket 20 and are arranged along the second horizontal axis 600, the angle plate 53 is installed on the slide block, a screw hole for communicating the guide rail with the outside is processed on the slide block, a screw is connected on the screw hole, and when the screw is screwed on the guide rail, the slide block can be locked on the guide rail (not shown in the figure).

In the present embodiment, regardless of whether the auxiliary shoelace tying jig is provided with the second horizontal moving unit 60, in order to give better support to the shoes placed on the inclined supporting unit 50, as shown with reference to FIGS. 1 to 3, 5, 6 and 8, the end of the top surface 500 of the inclined supporting unit 50, which is lower in height, is provided with a support part 51 for supporting the side part of the shoes, whereby, when the shoes to be shoelace tied are placed on the top surface 500 of the inclined supporting unit 50, support can be given to the shoes by the support part 51, preventing the shoes from slipping off the top surface 500 of the inclined supporting unit 50.

In embodiments, referring to fig. 1, 3, 4, 6 and 8, the top surface 500 of the inclined support unit 50 is provided with at least two sets of mounting structures 52 distributed in a direction perpendicular to the horizontal axis 400, the support 51 is provided on the inclined support unit 50 through the mounting structures 52, and the mounting structures 52 are arranged to enable the support 51 to be mounted at different positions on the top surface 500 in a direction perpendicular to the horizontal axis 400 in the plane of the top surface 500, thereby allowing the mounting positions of the support 51 on the mounting structures 52 to be adapted to different sizes of shoes to be clamped.

In , the mounting structure 52 is a body-formed or machined counter bore 521 on the top surface 500, the counter bores 521 are provided with multiple groups and distributed along the direction perpendicular to the horizontal axis 400 in the plane of the top surface 500, the body-formed, machined or connected with the mounting column 511 matched with the counter bore 521 on the supporting portion 51, and the mounting column 511 is installed in the different counter bores 521, namely, the position adjustment of the supporting portion 51 is realized.

In , more than two mounting posts 511 are provided on support 51, and each set of counter-bored holes 521 includes two mounting holes for mounting two mounting posts 511 on support 51, so as to ensure that support 51 is stably mounted in counter-bored holes 521.

To facilitate the processing of the th counterbore 521, referring to fig. 5 and 8, the angle plate 53 is detachably connected with a mounting plate 54, the mounting plate 54 is of a flat plate structure, so that the body of the mounting plate 54 is formed or processed with the th counterbore 521, and at this time, the top surface 500 of the inclined supporting unit 50 is the upper surface of the mounting plate 54.

In embodiments, referring to fig. 2, 4 and 8, two horizontal moving units 40 are symmetrically distributed on both sides of the inclined supporting unit 50, the horizontal moving unit 40 is a cylinder 43 for driving the clamping portion 30 to move along the horizontal axis 400, the sides of the piston rods of the two cylinders 43 are oppositely arranged, so that the two cylinders 43 can simultaneously drive the clamping portion 30 arranged on the piston rod to move relatively or back to back, therefore, when the clamping portion 30 is required to be driven by the horizontal moving unit 40 to clamp the shoe placed on the inclined supporting unit 50, the cylinder 43 can be opened by a switch, and the operation is convenient and fast.

Whether the auxiliary shoelace holder is provided with the second horizontal moving unit 60 or not, in order to hold different heights of the shoe, as shown in fig. 1 to 4 and 5 to 8, the auxiliary shoelace holder further comprises two vertical moving units 70 having the second locking structures 71, each of the clamping portions 30 is separately provided on the th horizontal moving unit 40 through vertical moving units 70, or wherein the clamping portions 30 are provided on the th horizontal moving unit 40 through vertical moving units 70 and the other clamping portions 30 are provided on the bracket 20 through the other vertical moving units 70, and the vertical moving units 70 are provided to bring the clamping portions 30 into reciprocal movement along the vertical axis 700 (movement in the Z direction as shown in fig. 1).

Thus, the clamping portion 30 can be driven by the vertical moving unit 70 to move along the vertical axis 700 to adjust the position of the clamping portion 30 in the vertical direction, so as to adjust the height of the shoe clamped between the two clamping portions 30 to adapt to shoes with different heights.

In embodiments of the vertical moving unit 70 referring to fig. 1, 2, 4, 6 and 8, the vertical moving unit 70 includes a vertical guide rail 72 and a vertical slider 73 fitted to each other, the vertical guide rail 72 is disposed along a vertical axis 700, the clamp 30 is mounted on the vertical slider 73, and the vertical guide rail 72 is disposed on the -th horizontal moving unit 40.

In , the vertical rail 72 is mounted on the horizontal slider 42, or the vertical rail 72 is mounted directly on the support 20. the second locking structure 71 comprises a through slot integrally formed or machined on the vertical slider 73 and adapted to the vertical rail 72, and a threaded hole machined on the vertical slider 73 and communicating the through slot with the outside, the threaded hole being adapted with a screw, the vertical slider 73 being movable along the vertical rail 72 relative to the vertical rail 72 when the screw is loosened, and the vertical slider 73 being locked to the vertical rail 72 when the screw is tightened (not shown in the figure).

In other embodiments of the vertical displacement unit 70, referring to fig. 1, 2, 4, 6 and 8, the difference from the first embodiments is that the vertical slider 73 includes a third mounting block 731 and a fourth mounting block 732 that are detachably connected, the through slot machined in the vertical slider 73 to fit the vertical guide rail 72 is a third through slot 7311 that is integrally formed or machined in the third mounting block 731, and the depth of the third through slot 7311 is smaller than the thickness of the vertical slider 73.

In , the third mounting block 731 and the fourth mounting block 732 are connected by screws, two through holes are integrally formed or machined on the third mounting block 731, the two through holes are located on two sides of the third through groove 7311, a second screw hole 713 corresponding to the through hole 711 of the fourth mounting block 732 is machined on the fourth mounting block 732, a second screw 712 passes through the through hole 711 of the third mounting block and is connected with the second screw hole 713 to connect the third mounting block 731 with the fourth mounting block 732, and when the third mounting block 731 is connected with the fourth mounting block 732, the vertical guide 72 is located between the third mounting block 731 and the fourth mounting block 732.

When the second screw 712 is tightened, the vertical rail 72 is clamped between the third mounting block 731 and the fourth mounting block 732 to form the second locking structure 71 which moves vertically, and when the second screw 712 is loosened, the vertical slider 73 can move along the vertical axis 700 relative to the vertical rail 72.

In embodiments, with continued reference to FIGS. 1 to 4, and FIGS. 5 to 8, the clamping part 30 is detachably mounted on the vertical moving unit 70, the stand 20, or the horizontal moving unit 40, whereby the clamping part 30 having a different shape can be replaced according to different models of shoes to be able to clamp the shoes by the clamping part 30.

In , the clamp 30 is detachably connected to the horizontal slider 42, the bracket 20 or the vertical slider 73. the detachable connection can be a common screw connection or a snap connection.

In , the repeated connection may be accomplished by a hook and loop fastener 74.

In , the male and female surfaces of the hook and loop fastener 74 are mounted on the horizontal slider 42, the bracket 20 or the vertical slider 73, and is mounted on the clip 30.

In embodiments, the bracket 20, the mounting bracket 21, the horizontal rail 41, the horizontal sliding block 42, the inclined supporting unit 50, the second horizontal moving unit 60, and the vertical moving unit 70 are made of metal material to improve the lifespan of the auxiliary shoelace tying jig.

In the embodiments, a material such as stainless steel or aluminum alloy may be used.

, the non-rigid material may be rubber, plastic, or the like, or may be a sponge block, foam board, or the like.

In , the non-rigid material may be made of an organic material, such as woven or bonded organic fibers, to provide a lower stiffness of the grip portion 30, such as EVA (ethylene vinyl acetate) to avoid pinching the last when the grip portion 30 grips the last.

It will be apparent to those skilled in the art that many changes and modifications can be made without departing from the inventive concept herein, which is intended to be limited only to .

Claims

1. Supplementary shoelace anchor clamps of tying up, its characterized in that includes:

a support;

the clamping parts are arranged on the bracket and are arranged oppositely, and the clamping parts are made of non-hard materials;

and at least No. horizontal moving units having a locking function,

when horizontal moving units are provided for the th horizontal moving unit, horizontal moving units are provided for the grippers on the support through the th horizontal moving unit;

when the th horizontal moving units are provided in two, each clamping part is separately provided on the bracket through th horizontal moving units;

the horizontal moving unit is arranged to drive the clamping part arranged on the horizontal moving unit to reciprocate in the horizontal plane along the horizontal axis, so that the clamping part arranged on the horizontal moving unit can move towards the side where another clamping parts (30) are located or move towards the side where another clamping parts are located.

2. The auxiliary shoelace tying jig of claim 1, further comprising an inclined support unit provided on the bracket;

the inclined supporting unit is arranged between the two clamping parts, and the included angle between the top surface of the inclined supporting unit and the horizontal plane ranges from 5 degrees to 60 degrees.

3. The auxiliary tying lace holder of claim 2, wherein an intersection of the top surface of the inclined support unit with the horizontal plane is parallel to the th horizontal axis.

4. The auxiliary shoelace tying jig as claimed in claim 3, further comprising a second horizontal moving unit having a th locking structure;

the inclined supporting unit is arranged on the bracket through the second horizontal moving unit;

the second horizontal moving unit is arranged to drive the inclined supporting unit to reciprocate in a horizontal plane along the second horizontal axis;

the second horizontal axis is non-parallel to the th horizontal axis.

5. The auxiliary lacing fixture of claim 4, wherein the second horizontal axis is perpendicular to the th horizontal axis.

6. The auxiliary shoelace tying jig of claim 3, wherein the end of the lower height of the top surface of the inclined support unit is provided with a support part for supporting the side of the shoe.

7. The auxiliary shoelace tying jig of claim 6, wherein the inclined support unit is provided at a top surface thereof with a mounting structure;

the supporting part is arranged on the inclined supporting unit through the mounting structure;

the mounting structure is arranged to enable the support portion to be mounted at different positions on the top surface in a direction perpendicular to the horizontal axis in the plane of the top surface.

8. The auxiliary shoelace tying jig of claim 6, wherein the two th horizontal moving units are symmetrically arranged at both sides of the inclined supporting unit;

the th horizontal moving unit is a cylinder driving the clamp to move along the th horizontal axis.

9. The auxiliary tying lace holder of any one of claims 1 to 8 further comprising two vertical moving units having the second locking structure;

each clamping part is arranged on horizontal moving units through vertical moving units or

Wherein clamps are provided on the th horizontal moving unit through vertical moving units, and another clamps are provided on the stand through another vertical moving units;

the vertical moving unit is arranged to drive the clamping part to reciprocate along a vertical axis.

10. The auxiliary shoelace tying jig of claim 9, wherein the clamping portion is detachably mounted on the vertical moving unit.