CN111088599A

CN111088599A - Round rope belt machine

Info

Publication number: CN111088599A
Application number: CN201811243887.1A
Authority: CN
Inventors: 曾文彬
Original assignee: Kyang Yhe Delicate Machine Co ltd
Current assignee: Kyang Yhe Delicate Machine Co ltd
Priority date: 2018-10-24
Filing date: 2018-10-24
Publication date: 2020-05-01
Anticipated expiration: 2038-10-24
Also published as: CN111088599B

Abstract

The invention relates to a circular rope belt machine, which comprises a weaving assembly and a transmission assembly which are connected with each other, wherein the transmission assembly comprises a transmission base, a first driving column and two second driving columns, the first driving column and the second driving column are arranged in the transmission base, the second driving columns are arranged on two opposite sides of the first driving column along a transmission direction, a plurality of first ring groove groups are arranged on the first driving column, each first ring groove group comprises at least one first ring groove, the second driving column is provided with a plurality of second ring groove groups, the positions and the numbers of the second ring groove groups correspond to those of the first ring groove groups, and each second ring groove group also comprises at least one second ring groove.

Description

Round rope belt machine

Technical Field

The invention relates to a ribbon loom, in particular to a knitting machine table of a round rope ribbon.

Background

The round rope belt is a multipurpose rope, and can be used in different fields such as binding rope, shoelace or bracelet, and the like, and the method for manufacturing the round rope belt in the prior art is manufactured in the following two ways.

The first is to weave by a Machine of a horse-runner (weaving Machine) in which a plurality of bundles of yarns are simultaneously connected to a central weaving area and are twisted with each other, and there are several disadvantages in using the horse-runner.

Firstly, the horse walking machine is too large, so that the horse walking machine occupies more areas in a factory building; secondly, the weaving method of the horse walker cannot be changed according to the needs of the user, in other words, if the user wants to produce the round rope belts with different weaving methods, the horse walker capable of producing the weaving method is required to be provided, so that the control of the machine cost is also unfavorable.

In view of the limitations of the horse walker in use, users have developed a ribbon loom for weaving flat ribbons, which can be used to weave flat ribbons, or to weave round ribbon by switching some elements, and to switch different weaving modes on the same machine by using a machine improved from the flat ribbon loom.

However, in the prior art, the circular ribbon loom formed by improving the ribbon loom of the flat ribbon, because of the structural difference that the flat ribbon is flat and the circular ribbon is cylindrical, the following problems occur: after weaving, the plain-weave ribbon is tightly wound on the plurality of rollers, and is gradually rolled to move towards the outlet by the driving of the rollers, so that the plain-weave ribbon machine at the rear can continuously weave a new plain-weave ribbon without being incapable of processing due to the blockage of the plain-weave ribbon at the outlet.

However, if the roller device of the flat webbing machine is used as the transmission mechanism of the round cord belt, since the cross section of the round webbing is circular rather than flat, the round cord belt is easily flattened by the rollers after being squeezed by a plurality of adjacent rollers, and the structure of the round cord belt is damaged.

Referring to fig. 9, in order to improve the disadvantage, in the prior art, in the circular rope belt machine 90 improved by the flat ribbon loom, in order to achieve sufficient pulling force, the transmission mechanism 91 is improved by pulling out the processed circular rope belt 92 by means of the weight 93, so as to replace the problem of extruding the shape of the circular rope belt by roller driving, but the transmission mechanism 91 adopting the weight 93 is very large, so that the improvement causes the problem of occupying much space due to the oversize machine platform as in the case of a horse walking machine.

On the other hand, another problem of the transmission mechanism 91 for hanging the heavy object 93 used in the prior art during the manufacturing process is that when the rope belt 92 is wrong in processing due to yarn insertion and the like during the manufacturing process, the product inspection end of the user is located behind the transmission mechanism 91, in other words, when the user inspects a section of the rope belt 92 with a processing error, the rope belt machine 90 actually further processes a whole distance from the front section of the transmission mechanism 91 to the product inspection end, in other words, the long distance between the inspection end and the processing completion end causes the rope belt 92 to waste more processing raw materials of the user when the processing error occurs.

In summary, the two machines for manufacturing the circular rope belts in the prior art have the defects.

Disclosure of Invention

In view of the defects and shortcomings of the prior art, the invention provides a circular rope belt machine, which can pull out a circular rope belt without extruding and deforming the circular rope belt by improving the way of pulling the belt body of the flat ribbon loom, and simultaneously reduce the volume occupied by a machine table.

To achieve the above object, the present invention provides a circular rope belt machine, which comprises

A knitting assembly including

A braided base;

a plurality of heald frames which are arranged in parallel with each other and are arranged on the weaving base so as to be capable of moving up and down relative to the weaving base;

a transmission component connected with the knitting component and comprising

The opposite two ends of the transmission base along a transmission direction are respectively an inlet end and an outlet end, and the weaving base of the weaving assembly is arranged at the inlet end of the transmission base;

the first driving column is rotatably arranged in the transmission base, a plurality of first ring groove groups are further arranged on the first driving column, the first ring groove groups are arranged at intervals along the extending direction of the first driving column, each first ring groove group comprises at least one first ring groove, and each first ring groove is annularly and concavely arranged on the first driving column;

two second driving columns rotatably disposed in the transmission base, wherein the two second driving columns are respectively located at two opposite sides of the first driving column along the transmission direction, each second driving column is further provided with a plurality of second circular groove sets, the number and position of the second circular groove sets respectively correspond to the number and position of the first circular groove sets of the first driving column, each second circular groove set comprises at least one second circular groove, and each second circular groove is disposed around the second driving column.

The flat webbing loom has the advantages that the structure of the flat webbing loom is improved, the first driving column and the second driving column through which the round cord belt passes on the transmission assembly are respectively provided with the first circular groove group and the second circular groove group, and the round cord belt can be accommodated in the corresponding circular grooves when passing through the first driving column and the second driving column through the circular groove groups; in other words, even if the distances between the active columns are relatively close, the round rope belt can be accommodated in the corresponding annular groove to keep a certain space, so that the shape of the round rope belt is maintained and is not flattened by the active columns; on the other hand, the structure of the invention is almost the same as that of the flat ribbon loom, so the volume of the invention is not greatly increased as the improvement of the prior art, and the invention is more effective in the utilization of space; in addition, through the invention with smaller volume, when a user checks whether the processed round rope belt has processing errors, the distance between the checking end and the processing end is smaller than the distance of a machine table utilizing the flat ribbon loom in the prior art, so that when the user checks the errors of the round rope belt in the processing process, the quantity of the round rope belt with processing errors can be effectively reduced.

Further, in the circular rope belt machine, the first driving column further includes a plurality of collars, the collars are disposed on the first driving column at intervals along an extending direction of the first driving column, each collar protrudes a plurality of friction walls, and the friction walls are disposed around each other at intervals; the first ring groove sets up respectively on the lantern ring to each this at least first ring groove is set up by setting up in the same this first initiative post the outer wall surface of friction wall is concave.

In a further aspect, the driving assembly further includes an inlet roller disposed in the driving base and disposed between the first driving pillar and the inlet end along the driving direction, and the inlet roller is higher than the first driving pillar, the inlet roller is provided with a plurality of inlet ring groove sets corresponding to the first ring groove set on the first driving pillar, each inlet ring groove set includes at least one inlet ring groove, and each inlet ring groove is recessed around the inlet roller.

Further, in the above circular rope belt machine, each of the at least one first ring groove of each first ring groove group is a semicircular groove; each second annular groove of each second annular groove group is a semicircular groove.

Further, in the above circular rope belt machine, each of the at least one first ring groove of each first ring groove group is a semicircular groove; each second annular groove of each second annular groove group is a semicircular groove; each of the at least one inlet ring groove of each inlet ring groove group is a semicircular groove.

Further, in the above circular rope belt machine, the number of the at least one first ring groove of each first ring groove group is two, and the width of one first ring groove is greater than the width of the other first ring groove; the number of the at least one second ring groove of each second ring groove group is two, and the width of one second ring groove is larger than that of the other second ring groove.

Further, in the above circular rope belt machine, the number of the at least one first ring groove of each first ring groove group is two, and the width of one first ring groove is greater than the width of the other first ring groove; the number of the at least one second ring groove of each second ring groove group is two, and the width of one second ring groove is larger than that of the other second ring groove; the number of the at least one inlet ring groove of each inlet ring groove group is two, and the width of one inlet ring groove is larger than that of the other inlet ring groove.

Further, in the above-mentioned circular rope belt machine, the transmission assembly further includes two exit roller sets, the two exit roller sets are respectively disposed on two opposite sides of the second driving column closer to the exit end along the transmission direction, each exit roller set includes a plurality of exit rollers, and the number and the position of the exit rollers respectively correspond to the number and the position of the first circular groove set on the first driving column.

Further, in the above circular rope belt machine, each heald frame of the weaving assembly is further provided with a plurality of heald sheets, the heald sheets can horizontally move relative to the heald frame, and each heald sheet is formed with a circular hole.

Further, the circular rope belt machine further includes a plurality of circular rope receiving seats on the weaving base, the circular rope receiving seats are disposed at the end of the weaving base adjacent to the transmission base, the number and the positions of the circular rope receiving seats correspond to the number and the positions of the first circular groove set of the first driving post, a circular rope receiving hole is further formed through each circular rope receiving seat, and the circular rope receiving hole is a circular hole.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a top view of the transmission assembly of the present invention.

Fig. 3 is a cross-sectional side view of the transmission assembly of the present invention.

Fig. 4 is an enlarged perspective view of the transmission assembly of the present invention.

FIG. 5 is a cross-sectional side view of a circular cord wrapped around the drive assembly of the present invention.

Fig. 6 is another use state diagram of fig. 5.

Figure 7 is an exploded view of a portion of the components of the heald frame of the weaving assembly according to the invention.

Figure 8 is an enlarged view of a portion of the round cord receptacle of the braiding assembly of the present invention.

Figure 9 is a side view of a prior art circular leash machine modified with a flat leash machine.

Detailed Description

The technical means adopted by the invention to achieve the preset purpose are further described below by combining the accompanying drawings and the preferred embodiments of the invention.

Referring to fig. 1 and 3, the circular rope belt machine of the present invention includes a knitting element 10 and a transmission element 20, two opposite ends of the transmission element 20 along a transmission direction L are respectively an inlet end 201 and an outlet end 202, and the knitting element 10 is disposed at the inlet end 201 of the transmission element 20.

Referring to fig. 1 and 7, more precisely, the weaving assembly 10 includes a weaving base 11, a plurality of heald frames 12, a plurality of heald blades 13 and a plurality of round rope receiving seats 14.

The heald frames 12 are arranged side by side and can be vertically moved relative to the weaving base 11 on the weaving base 11, each heald frame 12 is further provided with a plurality of heald sheets 13, each heald sheet 13 can be horizontally moved relative to the heald frame 12, and each heald sheet 13 is formed with a round hole 131. the structure of the weaving assembly 10 is substantially the same as that of a flat weaving machine in the prior art, so the description is not repeated herein, but the round hole 131 on each heald sheet 13 is particularly provided with a hole for matching with the cylindrical round rope belt 92, and through the round hole 131, when the weaving assembly 10 weaves the round rope belt 92, the round rope belt 92 can be matched with the shape of the round rope belt 92, but the hole on the heald sheet 13 is not limited by the round hole 131, and can be provided with holes with other shapes.

Referring to fig. 8, the round rope receiving seats 14 are disposed on the weaving base 11 at intervals and adjacent to the end of the transmission assembly 20, and a round rope receiving hole 141 is formed through each round rope receiving seat 14, the round rope receiving hole 141 is a circular hole, the round rope receiving hole 141 is used as a supporting seat for the round rope belt 92 to enter the transmission assembly 20, and the round rope receiving hole 141 is circular in shape and the round rope belt 92, so that the stability of the woven round rope belt 92 when moving towards the transmission assembly 20 can be improved.

Referring to fig. 2, 3 and 4, the driving assembly 20 includes a driving base 21, a first driving pillar 22, two second driving pillars 23, an inlet roller 24 and two outlet roller sets 25, which are detailed as follows.

The opposite ends of the transmission base 21 along the transmission direction L are the inlet end 201 and the outlet end 202, and the braiding base 11 is disposed at the inlet end 201 of the transmission base 21 along the transmission direction L.

The first driving column 22 is rotatably disposed in the transmission base 21, and more precisely, in the embodiment, the extending direction of the first driving column 22 is perpendicular to the transmission direction L, but it is not limited thereto.

The first driving column 22 is provided with a plurality of collars 221, a plurality of friction walls 222 and a plurality of first groove sets 223, the collars 221 are disposed on the first driving column 22 at intervals along the extending direction of the first driving column 22, each collar 221 is formed with a plurality of the friction walls 222, the friction walls 222 are disposed around the corresponding collar 221, and more precisely, the friction walls 222 on the same collar 221 are disposed around the collar 221 along the transmission direction L.

The first circular groove sets 223 are formed on the first driving column 22 at intervals along the extending direction of the first driving column 22, more precisely, the first circular groove sets 223 are formed on the friction wall 222 of the collar 221 respectively, and each first circular groove set 223 includes at least one first circular groove 224, in this embodiment, the number of the first circular grooves 224 on each first circular groove set 223 is two, and the two first circular grooves 224 are arranged on the collar 221 parallel to the transmission direction L and at intervals, but the number of the first circular grooves 224 of each first circular groove set 223 is not limited to two.

Referring to fig. 8, on the other hand, the number and the positions of the round rope holders 14 of the weaving assembly correspond to the number and the positions of the first looping groove sets 223, respectively, so as to move in cooperation with the round rope belt 92.

Referring to fig. 2 and fig. 3, in another aspect, in the present embodiment, in the two first ring grooves 224 of each first ring groove set 223, the width of one first ring groove 224 is greater than that of the other first ring groove 224, but the width between the first ring grooves 224 can also be adjusted according to the requirement of the user; in the embodiment, each first ring groove 224 is a semicircular groove, and the semicircular structure can be adapted to the cylindrical shape of the rope belt 92, but the shape of each first ring groove 224 is not limited to the semicircular shape.

In this embodiment, since the first ring grooves 224 are formed by the outer wall surfaces of the corresponding friction walls 222 being recessed toward the collar 221, each first ring groove 224 is actually formed by a plurality of segment-shaped annular grooves, and the segment-shaped annular grooves can increase the friction force when the first driving column 22 is wound around the driving rope belt 92, thereby increasing the stability of the driving rope belt 92 according to the present invention.

In the present embodiment, the number of the first active pillars 22 is one, but it is not limited to one, and in other embodiments, a plurality of first active pillars 22 may be included.

Referring to fig. 3, the two second driving pillars 23 are rotatably disposed in the transmission base 21, and the two second driving pillars 23 are respectively located at two opposite sides of the first driving pillar 22 along the transmission direction L, and in this embodiment, the heights of the two second driving pillars 23 are both lower than the first driving pillar 22, but the relative heights of the

driving pillars

22 and 23 are not limited thereto, and can be adjusted according to the requirements of the user.

As further shown in fig. 2, each second active pillar 23 further includes a plurality of second annular groove sets 231, the number and the position of the second circular groove sets 231 correspond to the number and the position of the first circular groove sets 223 of the first driving column, respectively, in other words, in this embodiment, the second annular groove sets 231 are also disposed at intervals along the extending direction of the second active pillars 23, each second ring groove set 231 comprises two second ring grooves 232, each second ring groove 232 is annularly and concavely arranged on the second driving column 23, however, the number of the second annular grooves 232 of each second annular groove group 231 is not limited to two, and, in the present embodiment, one of the two second ring grooves 232 has a width larger than that of the other second ring groove 232, and the two second ring grooves 232 are semicircular groove bodies, however, as with the first groove set 223, the shape and number of the second grooves 232 of the second groove set 231 are not limited to the above.

The inlet roller 24 is disposed in the transmission base 21 and disposed between the first driving post 22 and the inlet end 201 along the transmission direction L, and more precisely, the height of the inlet roller 24 is higher than that of the first driving post 22. in this embodiment, the inlet roller 24 is a driven post, that is, the inlet roller 24 does not rotate by itself, but rotates by relying on the rotation of other posts or the movement of the rope 92 wound thereon, but not limited thereto, and the inlet roller 24 may also be a self-rotating post.

A plurality of inlet ring groove sets 241 are arranged on the inlet roller 24, the number and the positions of the inlet ring groove sets 241 respectively correspond to the number and the positions of the first ring groove sets 223 of the first driving column, in other words, in this embodiment, each inlet ring groove set 241 is also arranged at intervals along the extending direction of the inlet roller 24, and each inlet ring groove set 241 includes two inlet ring grooves 242, each inlet ring groove 242 is arranged around the inlet roller 24 in a recessed manner, but the number of the inlet ring grooves 242 of each inlet ring groove set 241 is not limited to two; meanwhile, in the present embodiment, the width of one of the inlet ring grooves 242 is greater than that of the other inlet ring groove 242, and the inlet ring grooves 242 are semicircular grooves, but as with the first ring groove set 223, the shape and number of the inlet ring grooves 242 of the inlet ring groove set 241 are not limited thereto.

Referring to fig. 2, the two exit roller sets 25 are respectively disposed on two opposite sides of the second driving column 23 closer to the exit end 202 along the transmission direction L, and in this embodiment, the height of the exit roller set 25 closer to the exit end 202 is higher than the height of the exit roller set 25 farther from the exit end 202, but the relative heights are not limited to the foregoing.

As further shown in fig. 3 and fig. 4, each of the outlet roller sets 25 includes a plurality of outlet rollers 251, the number and the position of the outlet rollers 251 respectively correspond to the number and the position of the first circular groove set 223 on the first driving column 22, in this embodiment, each of the outlet rollers 251 is concavely formed with an outlet circular groove 252, but the number of the outlet circular grooves 252 on each of the outlet rollers 251 is not limited to one.

The following are aspects of the invention and advantages thereof.

Referring to fig. 5 and 6, the present invention is a structure for pulling out the braided circular rope 92 from the braiding assembly 10, wherein the circular rope 92 is continuously wound between the first driving column 22, the second driving column 23 and the inlet roller 24 after entering the transmission assembly 20 from the braiding assembly 10 through the inlet end 201 through the first driving column 22, the second driving column 23 and the inlet roller 24, so as to generate a certain degree of friction and achieve the pulling purpose.

The invention has the following advantages:

referring to fig. 5 and 6, firstly, when the columns rotate to drive the circular rope 92 wound thereon from the inlet end 201 to the outlet end 202, the circular rope 92 is wound between the columns and is bent continuously, so that the circular rope 92 is not easy to fall off due to looseness, and the circular rope 92 can be stably pulled out toward the outlet end 202; in other words, the braiding unit 10 at the outlet end 202 of the transmission unit 20 can continuously and automatically braid a new circular rope 92 by pulling the transmission unit 20 according to the present invention, and the user can also change the winding manner of the circular rope 92 according to his/her needs, and fig. 5 and 6 show two different winding manners respectively, and the tightening degree of the circular rope 92 wound on the cylinder is different according to the winding manner.

More precisely, when the present invention is used, the first driving column 22, the second driving column 23, the inlet roller 24 and the outlet roller set 25 are spaced from each other along the transmission direction L and are disposed in a vertically staggered manner, so that after the circular rope 92 enters the transmission assembly 20, the circular rope 92 can be wound on different columns or rollers to achieve multiple bending, and the bending provides a certain degree of friction, so that when the first driving column 22 and the second driving column 23 rotate strongly, the circular rope 92 can still be wound on the columns and rollers stably.

Referring to fig. 2 and 4, the friction walls 222 disposed on the ring 221 are for strengthening the friction force of the first driving post 22 when pulling the circular rope 92, and more precisely, since each first ring groove 224 is the outer wall surface of the formed friction wall, each first ring groove 224 is actually a segment-shaped, discontinuous ring groove body, and this discontinuity provides a larger friction force for the circular rope 92 attached above the groove body, so that the circular rope 92 can be more firmly attached to the first driving post 22 when winding.

Thirdly, the ring grooves (such as the first ring groove 224 and the second ring groove 232) are formed in the cylinders and the rollers, and the semicircular ring groove structures not only provide a containing space for the circular rope belt 92 to be wound, so that the circular rope belt 92 cannot be pressed by the cylinders which are too close to each other to deform the cylindrical shape of the circular rope belt 92.

Referring to fig. 2, fig. 3 and fig. 4, in the fourth embodiment, two ring grooves (e.g., the first ring groove 224, the second ring groove 232 and the inlet ring groove 242) are respectively formed in each ring groove set, and the two ring grooves have different sizes, so that the user can conveniently switch the circular ropes 92 with different sizes, in other words, the user can set the two ring grooves to two sizes that are most commonly used, so that when the user wants to switch to manufacture the circular ropes 92 with one size, the circular ropes can be conveniently used on the same set of transmission assemblies 20 of the same machine, thereby improving the manufacturing efficiency.

Referring to fig. 1, fifth, the present invention improves a general webbing loom for making a flat webbing into a machine for making a circular webbing, and simultaneously maintains the volume of a transmission assembly in the flat webbing loom, so that the present invention has a small overall machine volume, and can effectively utilize the space of a factory building for a user, and thus, the present invention is also efficient in terms of space usage.

Referring to fig. 1 and 3, sixth, the small-sized present invention not only can effectively utilize space distribution, but also can reduce the amount of the circular rope 92 lost due to the processing error when the user checks the processing error of the circular rope 92 at the outlet 202 and stops the machine from running because the distance between the inlet 201 and the outlet 202 of the transmission assembly 20 is short when the circular rope 92 has a weaving error due to yarn insertion or other reasons during the processing of the weaving assembly 10, in other words, the present invention can increase the error detection rate during the processing of the circular rope 92.

Although the present invention has been described with reference to the preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but is intended to cover various modifications, equivalents and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims

1. A circular rope belt machine is characterized by comprising

A knitting assembly including

A braided base;

a transmission component connected with the knitting component and comprising

2. The circular rope belt machine of claim 1, wherein the first driving column further comprises a plurality of rings, the rings are disposed on the first driving column at intervals along the extending direction of the first driving column, each ring has a plurality of friction walls protruding therefrom, and the friction walls are disposed at intervals around each other;

the first ring groove sets up respectively on the lantern ring to each this at least first ring groove is set up by setting up in the same this first initiative post the outer wall surface of friction wall is concave.

3. The circular rope belt machine of claim 1 or 2, wherein the transmission assembly further comprises an inlet roller disposed in the transmission base and disposed between the first driving pillar and the inlet end along the transmission direction, the inlet roller has a height higher than that of the first driving pillar, the inlet roller is provided with a plurality of inlet ring groove sets corresponding to the first ring groove set on the first driving pillar, and each inlet ring groove set comprises at least one inlet ring groove, and each inlet ring groove is recessed around the inlet roller.

4. The circular rope belt machine of claim 1 or 2, characterized in that:

each first ring groove of each first ring groove group is a semicircular groove;

each second annular groove of each second annular groove group is a semicircular groove.

5. The circular rope belt machine of claim 3, characterized in that:

each second annular groove of each second annular groove group is a semicircular groove;

each of the at least one inlet ring groove of each inlet ring groove group is a semicircular groove.

6. The circular rope belt machine of claim 1 or 2, characterized in that:

the number of the at least one first ring groove of each first ring groove group is two, and the width of one first ring groove is larger than that of the other first ring groove;

the number of the at least one second ring groove of each second ring groove group is two, and the width of one second ring groove is larger than that of the other second ring groove.

7. The circular rope belt machine of claim 5, characterized in that:

the number of the at least one second ring groove of each second ring groove group is two, and the width of one second ring groove is larger than that of the other second ring groove;

the number of the at least one inlet ring groove of each inlet ring groove group is two, and the width of one inlet ring groove is larger than that of the other inlet ring groove.

8. The circular rope belt machine of claim 1 or 2, wherein the transmission assembly further includes two exit roller sets respectively disposed at opposite sides of the second driving column closer to the exit end along the transmission direction, each exit roller set includes a plurality of exit rollers, and the number and positions of the exit rollers respectively correspond to the number and positions of the first circular groove sets on the first driving column.

9. The circular rope belt machine according to claim 1 or 2, wherein a plurality of heald pieces are further provided on each heald frame of the weaving assembly, the heald pieces being capable of moving horizontally with respect to the heald frame, and a circular hole is formed on each heald piece.

10. The machine as claimed in claim 1 or 2, wherein the weaving base further comprises a plurality of rope receiving seats, the rope receiving seats are disposed at the end of the weaving base adjacent to the transmission base, the number and the position of the rope receiving seats respectively correspond to the number and the position of the first circular groove set of the first driving post, and each rope receiving seat further has a rope receiving hole formed therethrough, the rope receiving hole being a circular hole.