阅读说明：本技术 绳带收料装置及方法 (Rope belt receiving device and method ) 是由 张波 曾武 杨青平 程仕德 申显兵 薛矛 于 2020-12-30 设计创作，主要内容包括：本发明涉及一种绳带收料装置及方法。该绳带收料装置包括机座、收卷轴、驱动机构以及移动机构。收卷轴、驱动机构设置在机座上。驱动机构连接于收卷轴,以用于驱动收卷轴转动。移动机构设置在机座的下方。工作时,将待收料绳带的一端卷绕在收卷轴上,然后控制驱动机构驱动收卷轴转动,以使待收料绳带的其余部分逐渐脱离平台并且卷绕在收卷轴上,同时由于待收料绳带的其余部分与平台之间存在粘接力,收卷轴也会受到待收料绳带的反作用力,即待收料绳带对绳带收料装置产生了牵引力,使得移动机构动作,进而使绳带收料装置整体移动,最终使得绳带全部收卷在收卷轴上。本发明能够提高绳带的收料工序的自动化程度,节省人力,提高生产效率。(The invention relates to a rope belt receiving device and method. The rope belt receiving device comprises a machine base, a winding shaft, a driving mechanism and a moving mechanism. The winding shaft and the driving mechanism are arranged on the machine base. The driving mechanism is connected to the winding shaft and used for driving the winding shaft to rotate. The moving mechanism is arranged below the base. During operation, one end of the rope belt to be received is wound on the winding shaft, then the driving mechanism is controlled to drive the winding shaft to rotate, so that the rest part of the rope belt to be received is gradually separated from the platform and wound on the winding shaft, meanwhile, due to the fact that bonding force exists between the rest part of the rope belt to be received and the platform, the winding shaft can also receive the reaction force of the rope belt to be received, namely, the rope belt to be received generates traction force on the rope belt receiving device, the moving mechanism moves, the rope belt receiving device integrally moves, and finally the rope belt is completely wound on the winding shaft. The rope belt receiving device can improve the automation degree of the rope belt receiving process, saves labor and improves production efficiency.)

1. The utility model provides a rope area material collecting device which characterized in that includes:

a machine base;

the winding shaft is arranged on the stand;

the driving mechanism is arranged on the machine base and connected to the winding shaft so as to drive the winding shaft to rotate around the shaft center;

and the moving mechanism is arranged below the base.

2. The rope belt collecting device of claim 1, wherein the winding shaft is a slip shaft.

3. The rope belt collecting device of claim 1, wherein the base comprises a first mounting frame, a second mounting frame and a base, the first mounting frame and the second mounting frame are respectively disposed on the base and are oppositely disposed, one end of the winding shaft is connected to the first mounting frame, the other end of the winding shaft is connected to the second mounting frame, and the moving mechanism is disposed below the base.

4. The cord collecting device of claim 1, further comprising a cord guiding mechanism disposed on the base, the cord guiding mechanism having a cord guiding bar disposed parallel to the winding shaft.

5. The rope belt collecting device according to claim 4, wherein the rope guide is located below the winding shaft in a vertical direction, and the rope guide is located on one side of the winding shaft in a horizontal direction.

6. The rope belt collecting device according to any one of claims 1 to 5, further comprising a partition and a partition mounting member, wherein the partition mounting member is provided on the machine base, the partition is mounted on the partition mounting member, the partition abuts against the winding shaft, and a plate surface of the partition is provided perpendicular to the winding shaft.

7. The rope belt collecting device as claimed in claim 6, wherein the partition mounting member is a rod-shaped structure, both ends of the partition mounting member are respectively connected to the machine base, the partition is provided with mounting holes, and the partition is mounted on the partition mounting member through the mounting holes.

8. The cord collection apparatus of claim 7, wherein said spacer is movably attached to said spacer mounting member, said spacer being movable along said spacer mounting member.

9. The rope belt receiving device as claimed in claim 7 or 8, wherein there are a plurality of said partition plates, and a plurality of said partition plates are arranged at intervals.

10. The rope belt collecting device according to any one of claims 1 to 5, 7 and 8, wherein the moving mechanism comprises a plurality of rollers.

11. The rope belt collecting device according to any one of claims 1 to 5, 7 and 8, further comprising a guiding mechanism, wherein the guiding mechanism comprises a connecting component and a first guiding wheel and a second guiding wheel respectively arranged on the connecting component, the wheel surfaces of the first guiding wheel and the second guiding wheel face each other, the first guiding wheel and the second guiding wheel are used for being respectively arranged on two sides of a guide rail on a screen printing platform, and the connecting component is connected to the base.

12. The cord receiving apparatus of claim 11 wherein said connecting assembly comprises a first connecting member, a second connecting member, a first mounting member and a second mounting member; the first connecting piece and the second connecting piece are respectively connected to the base and oppositely arranged, the first mounting piece is connected to the first connecting piece and the second connecting piece, the first guide wheel is arranged below the first mounting piece, the wheel shaft of the first guide wheel is connected to the first mounting piece, the second mounting piece is connected to the first connecting piece and the second connecting piece, the second mounting piece is oppositely arranged with the first mounting piece, the second guide wheel is arranged below the second mounting piece, and the wheel shaft of the second guide wheel is connected to the second mounting piece.

13. The cord receiving apparatus of claim 12 wherein said connecting assembly further comprises a first spring, a second spring and an abutting member; the second installation part comprises a first swing rod and a second swing rod, the first swing rod is rotatably connected to the first connecting part, the second swing rod is rotatably connected to the second connecting part, two ends of the first spring are respectively connected to the first installation part and the first swing rod, two ends of the second spring are respectively connected to the first installation part and the second swing rod, the second guide wheel is connected below the first swing rod and/or below the second swing rod, the first swing rod and the second swing rod respectively approach the first installation part under the action of the tension of the first spring and the second spring, so that the first guide wheel and the second guide wheel are matched and clamped with the guide rail, and when the first guide wheel and the second guide wheel are matched and clamped with the guide rail, one end of the first swing lever and one end of the second swing lever are close to each other; the opening part is rotatably connected to the first mounting part, when the opening part rotates to a position between the first swing rod and the second swing rod, the first swing rod and the second swing rod are opened through the opening part, so that the first guide wheel and the second guide wheel are far away from each other, and the first swing rod and the second swing rod are respectively abutted against the opening part under the tensile force action of the first spring and the second spring.

14. The rope collection device of claim 13, wherein the abutting member includes a third swing link rotatably connected to the first mounting member and an abutting wheel disposed below the third swing link, the abutting wheel having a wheel axle connected to the third swing link, the abutting wheel abutting the second guide wheel when the abutting member is rotated between the first swing link and the second swing link.

15. A rope belt receiving method using the rope belt receiving apparatus according to any one of claims 1 to 14, comprising the steps of:

placing the rope belt receiving device on a platform adhered with a rope belt to be received;

winding one end of the rope belt to be collected on the winding shaft;

and controlling the driving mechanism to drive the winding shaft to rotate so as to enable the rest part of the rope belt to be received to be gradually separated from the platform and wound on the winding shaft, and meanwhile, due to the fact that bonding force exists between the rest part of the rope belt to be received and the platform, the rope belt to be received generates traction force on the rope belt receiving device, the moving mechanism acts, and the rope belt receiving device integrally moves towards the rest part of the rope belt to be received.

Technical Field

The invention relates to the technical field of rope belt production, in particular to a rope belt receiving device and method.

Background

In the process of producing the silk-screen rope belt, the rope belt to be silk-screen is usually adhered to a silk-screen walking platform, so that a certain adhesive force exists between the rope belt and the silk-screen walking platform to prevent the rope belt from shifting, and then patterns, characters and the like are silk-screen printed on the rope belt to obtain the silk-screen rope belt. After the silk-screen printing process is completed, the silk-screen printing rope belt needs to be received. At present, when receiving materials, the silk-screen rope belt adhered to the silk-screen walking platform needs to be torn off from the silk-screen walking platform from one end to the other end through manpower, and then the silk-screen rope belt is wound into a cake shape on a rope belt winding device. However, the traditional material receiving mode is time-consuming and labor-consuming, and the production efficiency is low.

Disclosure of Invention

Therefore, there is a need for a rope belt receiving device and method to improve the automation degree and production efficiency of rope belt receiving.

One of the purposes of the invention is to provide a rope belt receiving device, which adopts the following scheme:

a rope belt receiving device, comprising:

a machine base;

the winding shaft is arranged on the stand;

the driving mechanism is arranged on the machine base and connected to the winding shaft so as to drive the winding shaft to rotate around the shaft center;

and the moving mechanism is arranged below the base.

In one embodiment, the take-up reel is a slip reel.

In one embodiment, the machine base comprises a first mounting frame, a second mounting frame and a base, the first mounting frame and the second mounting frame are respectively arranged on the base and are oppositely arranged, one end of the winding shaft is connected to the first mounting frame, the other end of the winding shaft is connected to the second mounting frame, and the moving mechanism is arranged below the base.

In one embodiment, the driving mechanism comprises a rotating motor and a belt wheel transmission assembly, and the belt wheel transmission assembly is in transmission connection with the rotating motor and the winding shaft.

In one embodiment, the rope belt receiving device further comprises a rope guiding mechanism, the rope guiding mechanism is arranged on the machine base, the rope guiding mechanism is provided with a rope guiding rod, and the rope guiding rod is arranged in parallel with the winding shaft.

In one embodiment, the rope guide is located below the winding shaft in the vertical direction, and the rope guide is located on one side of the winding shaft in the horizontal direction.

In one embodiment, the rope belt receiving device further comprises a partition and a partition mounting piece, the partition mounting piece is arranged on the base, the partition is mounted on the partition mounting piece and abuts against the winding shaft, and the plate surface of the partition is perpendicular to the winding shaft.

In one embodiment, the partition mounting member is a rod-shaped structure, two ends of the partition mounting member are respectively connected to the base, the partition is provided with a mounting hole, and the partition is mounted on the partition mounting member through the mounting hole.

In one embodiment, the bulkhead is movably coupled to the bulkhead mount, and the bulkhead is movable along the bulkhead mount.

In one embodiment, the partition plate is provided in plurality, and the plurality of partition plates are arranged at intervals.

In one embodiment, the moving mechanism includes a plurality of rollers.

In one of them embodiment, fag end material collecting device still includes guiding mechanism, guiding mechanism includes coupling assembling and sets up respectively first leading wheel and second leading wheel on the coupling assembling, first leading wheel with the wheel face of second leading wheel is in opposite directions, first leading wheel with the second leading wheel is used for setting up the both sides at the guide rail on the silk screen printing walking board respectively, coupling assembling connect in the frame.

In one embodiment, the connection assembly includes a first connector, a second connector, a first mount, and a second mount; the first connecting piece and the second connecting piece are respectively connected to the base and oppositely arranged, the first mounting piece is connected to the first connecting piece and the second connecting piece, the first guide wheel is arranged below the first mounting piece, the wheel shaft of the first guide wheel is connected to the first mounting piece, the second mounting piece is connected to the first connecting piece and the second connecting piece, the second mounting piece is oppositely arranged with the first mounting piece, the second guide wheel is arranged below the second mounting piece, and the wheel shaft of the second guide wheel is connected to the second mounting piece.

In one embodiment, the connection assembly further comprises a first spring, a second spring, and an abutting member; the second installation part comprises a first swing rod and a second swing rod, the first swing rod is rotatably connected to the first connecting part, the second swing rod is rotatably connected to the second connecting part, two ends of the first spring are respectively connected to the first installation part and the first swing rod, two ends of the second spring are respectively connected to the first installation part and the second swing rod, the second guide wheel is connected below the first swing rod and/or below the second swing rod, the first swing rod and the second swing rod respectively approach the first installation part under the action of the tension of the first spring and the second spring, so that the first guide wheel and the second guide wheel are matched and clamped with the guide rail, and when the first guide wheel and the second guide wheel are matched and clamped with the guide rail, one end of the first swing lever and one end of the second swing lever are close to each other; the opening part is rotatably connected to the first mounting part, when the opening part rotates to a position between the first swing rod and the second swing rod, the first swing rod and the second swing rod are opened through the opening part, so that the first guide wheel and the second guide wheel are far away from each other, and the first swing rod and the second swing rod are respectively abutted against the opening part under the tensile force action of the first spring and the second spring.

In one embodiment, the opening-resisting piece comprises a third swinging rod and an opening-resisting wheel, the third swinging rod is rotatably connected to the first mounting piece, the opening-resisting wheel is arranged below the third swinging rod, the wheel shaft of the opening-resisting wheel is connected to the third swinging rod, and when the opening-resisting piece rotates to the position between the first swinging rod and the second swinging rod, the second guide wheel is abutted by the opening-resisting wheel.

The invention also aims to provide a rope belt receiving method, which adopts the following scheme:

a rope belt receiving method using the rope belt receiving device according to any one of the embodiments described above, the rope belt receiving method including the steps of:

placing the rope belt receiving device on a platform adhered with a rope belt to be received;

winding one end of the rope belt to be collected on the winding shaft;

and controlling the driving mechanism to drive the winding shaft to rotate so as to enable the rest part of the rope belt to be received to be gradually separated from the platform and wound on the winding shaft, and meanwhile, due to the fact that bonding force exists between the rest part of the rope belt to be received and the platform, the rope belt to be received generates traction force on the rope belt receiving device, the moving mechanism acts, and the rope belt receiving device integrally moves towards the rest part of the rope belt to be received.

Compared with the prior art, the rope belt receiving device and the rope belt receiving method have the following beneficial effects:

the rope belt receiving device can be applied to the receiving process of the silk-screen rope belt. When the rope belt winding device works, the rope belt receiving device is placed on the platform adhered with the rope belt to be received, one end of the rope belt to be received is wound on the winding shaft, then the driving mechanism is controlled to drive the winding shaft to rotate, so that the rest part of the rope belt to be received is gradually separated from the platform and wound on the winding shaft, meanwhile, due to the fact that bonding force exists between the rest part of the rope belt to be received and the platform, when the winding shaft rotates to pull the rope belt to be received, the winding shaft can also receive the reaction force of the rope belt to be received, namely, the rope belt to be received generates traction force on the rope belt receiving device, the moving mechanism acts, the rope belt receiving device integrally moves towards the rest part of the rope belt to be received, and finally the rope belt is completely wound on the winding shaft. Therefore, the rope belt receiving device can improve the automation degree of the rope belt receiving process, saves labor and improves production efficiency.

Drawings

FIG. 1 is a schematic structural view of a rope belt receiving device according to an embodiment;

FIG. 2 is a schematic view of a rotating mechanism of the rope belt receiving device shown in FIG. 1;

fig. 3 is a schematic structural view of a guide mechanism in the rope belt receiving device shown in fig. 1.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

In the description of the present invention, it is to be understood that the terms "first", "second" and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, a rope belt collecting device 100 according to an embodiment of the present invention includes a base 110, a winding shaft 120, a driving mechanism 130, and a moving mechanism 140.

The take-up reel 120 is disposed on the stand 110. The take-up reel 120 is used for winding the screen printing cord tape.

The driving mechanism 130 is disposed on the base 110. The driving mechanism 130 is connected to the take-up reel 120 for driving the take-up reel 120 to rotate around the axis.

The moving mechanism 140 is disposed below the base 110.

The rope belt receiving device 100 can be applied to a receiving process of a silk-screen rope belt. When the rope belt collecting device works, the rope belt collecting device 100 is placed on a platform adhered with a rope belt to be collected, one end of the rope belt to be collected is wound on the winding shaft 120, then the driving mechanism 130 is controlled to drive the winding shaft 120 to rotate, so that the rest part of the rope belt to be collected is gradually separated from the platform and wound on the winding shaft 120, meanwhile, due to the fact that bonding force exists between the rest part of the rope belt to be collected and the platform, when the winding shaft 120 rotates to pull the rope belt to be collected, the winding shaft 120 can also receive the reaction force of the rope belt to be collected, namely, the rope belt to be collected generates traction force on the rope belt collecting device 100, the moving mechanism 140 acts, the rope belt collecting device 100 integrally moves towards the rest part of the rope belt to be collected, and finally the rope belt is completely wound on the winding shaft 120. Therefore, the rope belt receiving device 100 can improve the automation degree of the rope belt receiving process, save labor and improve production efficiency.

It is understood that the extending direction of the take-up reel 120 is perpendicular to the moving direction of the moving mechanism 140.

In one example, the movement mechanism 140 includes a plurality of rollers. In the material receiving process, the roller rolls under the action of the traction force of the rope belt, so that the material receiving device integrally moves without consuming power on the moving mechanism 140.

As shown in fig. 1, in one example, the base 110 includes a first mounting bracket 111, a second mounting bracket 112, and a base 113. The first and second mounting brackets 111 and 112 are respectively disposed on the base 113 and are opposite to each other. One end of the take-up reel 120 is coupled to the first mounting bracket 111, the other end of the take-up reel 120 is coupled to the second mounting bracket 112, and the moving mechanism 140 is disposed below the base 113. Further, a mechanism such as a regulated power supply 151 and a battery 152 may be provided on the base 113 to increase power for the driving mechanism 130.

In the specific example shown in the figures, the first mount 111 and the second mount 112 are plate-like structures. The first mounting rack 111 and the second mounting rack 112 are arranged in parallel, so that the winding shaft 120 can be conveniently mounted. The base 113 is also a plate-shaped structure, and the first and second mounting brackets 111 and 112 are connected to both ends of the base 113 to form a U-shaped structure with the base 113.

It is understood that in other examples, the first and second mounts 111 and 112 may have other shapes, such as a cylindrical structure, to mount the winding shaft 120.

In one example, the take-up reel 120 is a slip reel. In this example, the winding shaft 120 is a slip shaft, and when a plurality of silk-screen strings are wound simultaneously, the tension of the silk-screen strings can be kept consistent, and the tightness of the silk-screen strings on the winding shaft 120 is consistent, so that the conditions of some silk-screen strings being loosened and some silk-screen strings being tensioned are avoided.

As shown in fig. 2, in one example, the driving mechanism 130 includes a rotating motor 131 and a belt driving assembly 132, and the belt driving assembly 132 is in driving connection with the rotating motor 131 and the winding shaft 120. More specifically, the wheel and belt assembly 132 includes a first driving wheel 1321, a second driving wheel 1322, and a driving belt 1323, the driving belt 1323 being in driving connection with the first driving wheel 1321 and the second driving wheel 1322. The wheel shaft of the first driving wheel 1321 is connected to the rotating motor 131. The axle of the second driving wheel 1322 is connected with the winding shaft 120. It is understood that in other examples, the rotating motor 131 may be connected to the winding shaft 120 through other transmission assemblies or directly.

In the illustrated specific example, the rotation motor 131 is provided on the base 113. The belt drive assembly 132 is disposed on a side of the first mount 111 remote from the second mount 112. An output shaft of the rotating motor 131 passes through the first mounting bracket 111 to be connected to the first driving wheel 1321. In this example, the rotating motor 131 is disposed on the base 113, the rotating motor 131 is connected to the winding shaft 120 through the belt pulley assembly 132, and the belt pulley assembly 132 is disposed on one side of the first mounting rack 111, so that the rope belt receiving device 100 is more compact in structure, occupies a small space, and is convenient to move.

As shown in fig. 2, in one example, the driving mechanism 130 further includes a support bearing 1324, and the support bearing 1324 is disposed on a side of the first mounting bracket 111 away from the second mounting bracket 112. The axle of the second drive wheel 1322 is mounted on a support bearing 1324. Further, the wheel shafts on both sides of the second driving wheel 1322 are respectively erected on the supporting bearings 1324.

In one example, the axle of the second drive wheel 1322 is keyed to the takeup reel 120. For example, the axle of the second driving wheel 1322 has a key-shaped hole at one end thereof, which is in engagement with one end of the takeup reel 120.

As shown in fig. 1, in one example, the rope belt collecting device 100 further includes a rope guide mechanism 160. The cord guide 160 is disposed on the base 110, and the cord guide 160 has a cord guide 161, and the cord guide 161 is disposed in parallel with the winding shaft 120.

More specifically, the cord guide 161 is located below the take-up reel 120 in the vertical direction. The cord guide 161 is located on one side of the takeup reel 120 in the horizontal direction. In this example, the silk-screen rope is wound on the winding shaft 120 after passing around the rope guide 161, and the rope guide 161 supports the silk-screen rope, so that the tension of the silk-screen rope is more uniform.

In one example, the rope guide 160 further includes an adjusting member 162, the two ends of the rope guide 161 are respectively connected with the adjusting member 162, and the adjusting member 162 is rotatably connected with the base. In this way, the rope guide 161 can change its position with the rotation of the adjusting member 162, thereby adjusting the tension of the rope.

As shown, in one example, the cord collection device 100 further includes a bulkhead 170 and a bulkhead mount 180. The diaphragm mount 180 is disposed on the base 110, the diaphragm 170 is mounted on the diaphragm mount 180, and the diaphragm 170 abuts on the take-up shaft 120, and the plate surface of the diaphragm 170 is disposed perpendicular to the take-up shaft 120. In this example, by providing the partition 170, the partition 170 abuts on the take-up shaft 120, and the silk-screen string cannot pass over the partition 170 at the time of take-up, thereby preventing adjacent silk-screen strings from being wound together.

As shown in fig. 1, in one example, the diaphragm mounting member 180 has a rod-shaped structure, both ends of the diaphragm mounting member 180 are respectively coupled to the frame 110, and the diaphragm 170 is provided with mounting holes through which the diaphragm 170 is mounted on the diaphragm mounting member 180. In this example, baffle installed part 180 can play the rope guide effect simultaneously, forms the supporting role to silk screen printing fag end with the cooperation of rope guide rod 161, can make the tension of silk screen printing fag end more even.

In the illustrated specific example, the bulkhead mount 180 is located between the take-up bar and the cord guide bar 161 in the vertical direction, and the bulkhead mount 180 is located between the take-up bar and the cord guide bar 161 in the horizontal direction.

In one example, the diaphragm 170 is movably coupled to the diaphragm mount 180, and the diaphragm 170 is movable along the diaphragm mount 180. That is, the diaphragm 170 and the diaphragm mount 180 are not fixedly coupled, and the interval between the diaphragms 170 can be adjusted. In this example, since the widths of the silk-screen strings on the silk-screen walking stage may be different, the operator may adjust the interval between the partition boards 170 according to the width of the silk-screen strings.

It is understood that the number of the partitions 170 is not limited to only one. As shown, in one example, the number of the partitions 170 is plural, and the partitions 170 are arranged at intervals. In one example, the number of the spacers 170 is 3 to 30. In one example, the number of the partitions 170 is 5 to 20. In some specific examples, the number of baffles 170 is 4, 8, 12, 16, 20, etc.

As shown in fig. 1 and 3, in one example, the string receiving device 100 further includes a guide mechanism 190. The guide mechanism 190 includes a connection assembly and first and second guide wheels 191 and 192 provided on the connection assembly, respectively. The wheel faces of the first guide wheel 191 and the second guide wheel 192 are oppositely arranged. The first guide wheel 191 and the second guide wheel 192 are respectively arranged on two sides of the guide rail on the screen printing walking platform. The connection assembly is connected to the base 110.

Since the loop guide rail is provided on the screen printing platform, in this example, by providing the guide mechanism 190, the guide mechanism 190 cooperates with the loop guide rail to realize the guidance of the rope belt receiving device 100 during the traveling. The guide mechanism 190 is provided with a first guide wheel 191 and a second guide wheel 192 which are respectively arranged on two sides of the guide rail on the screen printing walking platform, so that the first guide wheel 191 and the second guide wheel 192 roll along the guide rail in the advancing process of the rope belt receiving device 100, and friction is reduced.

As shown in fig. 3, in one example, the connection assembly includes a first connector 193, a second connector 194, a first mount 195, and a second mount 196. The first and second connectors 193 and 194 are connected to the base 110 and are disposed opposite to each other. The first mounting member 195 is connected to the first and second connectors 193 and 194, respectively. The first guide wheel 191 is disposed below the first mounting member 195. The axle of the first guide wheel 191 is connected to the first mounting member 195. The second mounting member 196 is connected to the first and second coupling members 193 and 194, respectively. The second mounting member 196 is disposed opposite the first mounting member 195. The second guide wheel 192 is disposed below the second mount 196. The axle of the second guide wheel 192 is connected to a second mounting member 196.

Further, in one example thereof. The connection assembly further includes a first spring 197, a second spring 198, and a standoff 199. The second mounting member 196 includes a first swing lever 1961 and a second swing lever 1962.

The first swing lever 1961 is rotatably connected to the first connecting member 193 to be rotatable about the connecting point.

The second swing lever 1962 is rotatably coupled to the second link 194 so as to rotate about the connection point. Both ends of the first spring 197 are connected to the first mounting part 195 and the first swing lever 1961, respectively. Both ends of the second spring 198 are connected to the first mounting member 195 and the second swing lever 1962, respectively. A second guide wheel 192 is connected to a lower portion of the first swing lever 1961 and/or a lower portion of the second swing lever 1962. The first and second swing levers 1961 and 1962 approach the first mounting member 195 under the tensile force of the first and second springs 197 and 198, respectively. So that the first guide wheel 191 and the second guide wheel 192 engage the clamping rail. When the first guide wheel 191 and the second guide wheel 192 engage the clamping rail. One end of the first swing lever 1961 and one end of the second swing lever 1962 are close to each other. The offset 199 is rotatably connected to the first mounting member 195. When the offset 199 rotates between the first and second swing levers 1961 and 1962, the offset 199 offsets the first and second swing levers 1961 and 1962 so that the first and second guide wheels 191 and 192 move away from each other. The first and second rocking levers 1961 and 1962 abut against the offset 199 by the tensile force of the first and second springs 197 and 198, respectively.

In this way, when the guide mechanism 190 needs to be attached to or detached from the guide rail, the release member 199 can be easily attached to or detached from the guide rail by simply rotating the release member between the first and second rocking levers 1961 and 1962.

Further, in one example, the break-away piece 199 includes a third swing lever 1991 and a break-away wheel 1992. The third oscillating rod 1991 is rotatably connected to the first mounting member 195 to be rotatable about the connecting point. The kick-off wheel 1992 is disposed below the third oscillating rod 1991. The axle of the kick-off wheel 1992 is connected to a third oscillating rod 1991. When the opening member 199 is rotated between the first and second swing levers 1961 and 1962, the opening wheel 1992 opens the second guide wheel 192.

Since the kick-off wheel 1992 and the second guide wheel 192 are rotatable, the second guide wheel 192 can be kicked off more easily and with less effort by providing the kick-off wheel 1992.

In one example, a handle 1993 is disposed on the third oscillating rod 1991 to facilitate the rotational operation of the third oscillating rod 1991.

In one example, two first guide wheels 191 are disposed below the first mounting member 195.

In one example, a second guide wheel 192 is disposed below the first and second swing levers 1961 and 1962, respectively.

In one example, the first connector 193 is provided with a first adjustment hole 1931. The first swinging piece is provided with a first connecting rod. The first connecting rod penetrates the first adjusting hole 1931 to achieve the rotatable connection of the first swing lever 1961 and the first link 193. The second connecting member 194 is provided with a second adjusting hole 1941. The second swinging piece is provided with a second connecting rod. The second connecting rod penetrates the first adjusting hole 1931 to accomplish the rotatable connection of the second swing lever 1962 with the second link 194.

Further, in one example, the first adjustment apertures 1931 can be a plurality and the plurality of first adjustment apertures 1931 can be arranged linearly away from the first mounting member 195 to proximate the first mounting member 195. The second adjustment holes 1941 are provided in a plurality, and the plurality of second adjustment holes 1941 are linearly arranged away from the first mounting member 195 to close to the first mounting member 195. In this manner, the first and second swing levers 1961 and 1962 can be connected according to the width of the guide rail.

It will be appreciated that the guide mechanism 190 may also include guide tracks in applications without guide rails. In one example, the guiding mechanism 190 further comprises a guiding track, which cooperates with the above-mentioned connecting assembly, the first guiding wheel 191 and the second guiding wheel 192 to realize guiding.

Further, the present invention also provides a rope belt receiving method using the rope belt receiving device 100 of any one of the above examples, including the steps of:

placing the rope belt receiving device 100 on a platform adhered with rope belts to be received;

winding one end of the rope belt to be collected on the winding shaft 120;

the driving mechanism 130 is controlled to drive the winding shaft 120 to rotate, so that the rest of the rope to be received gradually separates from the platform and is wound on the winding shaft 120, and meanwhile, due to the bonding force between the rest of the rope to be received and the platform, the rope to be received generates traction force on the rope receiving device 100, so that the moving mechanism 140 acts, and the rope receiving device 100 integrally moves towards the rest of the rope to be received.

The rope belt receiving device 100 and the rope belt receiving method can be applied to the receiving process of silk-screen rope belts. When the rope belt collecting device works, the rope belt collecting device 100 is placed on a platform adhered with a rope belt to be collected, one end of the rope belt to be collected is wound on the winding shaft 120, then the driving mechanism 130 is controlled to drive the winding shaft 120 to rotate, so that the rest part of the rope belt to be collected is gradually separated from the platform and wound on the winding shaft 120, meanwhile, due to the fact that bonding force exists between the rest part of the rope belt to be collected and the platform, when the winding shaft 120 rotates to pull the rope belt to be collected, the winding shaft 120 can also receive the reaction force of the rope belt to be collected, namely, the rope belt to be collected generates traction force on the rope belt collecting device 100, the moving mechanism 140 acts, the rope belt collecting device 100 integrally moves towards the rest part of the rope belt to be collected, and finally the rope belt is completely wound on the winding shaft 120. Therefore, the rope belt receiving device 100 and the rope belt receiving method can improve the automation degree of the rope belt receiving process, save labor and improve production efficiency.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.