WO2010101329A1

WO2010101329A1 - Cableveyor with reduced noise, dust and body sagging

Info

Publication number: WO2010101329A1
Application number: PCT/KR2009/002578
Authority: WO
Inventors: 심술진
Original assignee: 주식회사 코닥트
Priority date: 2009-03-04
Filing date: 2009-05-15
Publication date: 2010-09-10
Also published as: KR20100099967A; KR101018293B1

Abstract

The present invention relates to a cableveyor that protects a cable connected to a controller and a mobile machine tool for operation of the machine tool as well as enabling the cable to move smoothly according to the movement of the machine tool. More specifically, the invention is a cableveyor with reduced noise and dust, and alleviated body sagging, which was developed to minimize surface friction and remarkably reduce noise and dust generated during the operation of the machine tool by movement of the cableveyor assembled from plural pieces, and also to relieve the sagging of the cableveyor under the weight of the cable.

Description

Cable bare to reduce noise and dust and reduce body sag

The present invention relates to a cable bare to move smoothly along the feed of the machine tool while protecting the cable connected to the controller and the machine for the operation of the machine in a moving machine tool, and more particularly to the movement during use of the machine tool Noise and dust generated by the cable bear combined with a plurality of cables, but minimized the friction surface to minimize the noise and dust. Also, the noise and dust developed to alleviate the phenomenon that the cable bear sags downward due to the cable load. The present invention relates to a cable bear that reduces the weight and sags the body.

In the cable bear used conventionally, the cable bear of various machine tools is used without any abnormality.

However, the conventional cable bear is operating normally when the cable bear is rotated in a curved shape as shown in FIG. 6, but gradually starts to sag from the upper end of the middle part of the cable bear due to the load of the cable placed on the cable bear. The middle part is considerably drooping down, and when the cable bear is operated, noise is generated along with the noise, which affects the life of the cable bear and the movement of the machine tool.

In this case, the cable bear is deflected downward and the cable bears the cable bear. Also, the cable bears the cable barely drawn between the moving parts of the machine tool and the controller due to the deflection of the cable bearing. The pulling force is transmitted, which causes frequent breakdowns, lowering productivity and exposing a lot of problems to the safety of the machine. In addition, the body and the body that make up the cable bearing are so closely bonded to each other that the cable bears. There was a problem that dust is generated during friction along with noise due to mutual friction during operation.

The present invention has been made to solve the above problems, when using the cable bear, the cable bears the corner portion is rotated and the cable moving up and down so that there is no drooping down the cable used in the cable bear safely It is intended to prevent noise and dust by zooming by minimizing contact with each other by allowing tolerances in the areas where friction occurs during movement by combining the body and the body while using it.

In the configuration of the cable bear, the first pin connection piece insertion groove and the second pin connection insertion groove is formed on both sides of the link pin fixing hole penetrating the center portion, and the upper link pin fastening on the upper and lower portions of the link pin fixing hole. There is a groove and a lower link pin fastening groove, the upper end of the first pin connecting piece insertion groove forms a first insertion wing piece with a first blade insert, the first upper curvature locking stone inward on the upper end of the first insertion blade piece. A first top plate was formed to form a bend and a first top curvature projection protrusion curvature guide space, and a first guide insertion piece having a first guide space at a lower end and a first bottom deflection preventing projection bar at a lower end of the first pin connection piece insertion groove. And a second insertion blade piece having a second blade insertion portion at an upper end of the second pin connection insertion groove, and a second upper curvature engaging protrusion rod and a second upper curvature inward on an upper end of the second insertion blade piece. Jam stick A first upper plate was formed to form a rate guide space. A second guide insertion piece having a lower second guide space and a first lower deflection preventing projection bar were formed at a lower end of the second pin connecting piece insertion groove. The upper and lower parts of the fixing hole protrudes complementary protrusions on the upper and lower sides of the link pin fixing hole of the cable bear body, which is composed of the upper fastening rod and the lower fastening rod, and integrally with the pin release preventing piece at the center. The piece combines the connecting piece and the link pin integrally with the fastener. The upper fastening rod and the lower fastening rod are symmetrically coupled with the cable bar body by combining the guide bars made with the fastening grooves on both sides at the bottom.

The present invention can be moved safely from the machine tool on the horizontal line without the sagging or bending of the middle portion of the cable bear even if a load is applied to each cable bearing body, and minimizes the contact portion of the cable bearing body and the cable bearing body during operation Minimized friction part minimizes noise caused by friction and dust generated during friction to minimize the work environment. It is not limited to machine tools and all industrial equipment and various moving facilities that connect cables from controllers to operating machines. If you install and use it in the system, you can use the machine without any trouble because the cable can be safely protected.

1 is a perspective view of the present invention

2 is a perspective view of a cable bearing body of the present invention

Figure 3 is a perspective view of the link pin of the present invention

4 is a perspective view of a guide bar of the present invention;

5 is a front view of a state in which two cable bearers of the present invention are connected;

Figure 6 is a part of the operation state of the corner of the cable bearing of the present invention

7 is a front view of a conventional cable bear

Explanation of Signs of Major Parts of Drawings

1: link pin fixing hole 2: upper link pin fastening groove

3: lower link pin coupling groove 10: first pin connecting piece insertion groove

11: 1st wing insertion part 15, 25: inclined surface

16, 26: horizontal plane 20: second pin connection insertion groove

21: second wing insertion portion 30: the first insertion wing piece

31: first upper curvature projection bar 32: first upper curvature projection bar curvature guide space

33: first top plate 40: first guide insert

41: 1st guide space 42: 1st lower deflection preventing projection bar

50: second insertion wing 51: second upper curvature projection bar

52: curvature guide bar 2nd top curvature projection bar 53: 2nd top plate

60: 2nd guide insertion piece 62: 1st lower anti-sag | interlocking projection bar

70: Link Pin 80: Information Bar

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 of the present invention is a perspective view of the bare body of the present invention combined, Figure 2 is a perspective view of the cable bare body of the present invention, Figure 3 is a perspective view of the link pin of the present invention, Figure 4 is a cable bear body coupled to the left and right Note is a perspective view of the guide bar, Figure 5 is a front view of a state in which the two cable bearer body of the present invention is connected.

According to the present invention, in the configuration of the cable bear, the lower portions of the link pin fixing holes 1 penetrating the center portion are

inclined surfaces

15 and 25 and the upper portions thereof are straight to the

horizontal surfaces

16 and 26. The first pin connecting piece insertion groove 10 and the second pin connecting insertion groove 20 are formed, and the upper and lower link pin fastening groove 2 and the lower link pin fastening groove ( 3) there are,

A first insertion blade piece 30 having a first blade insertion portion 11 is formed at an upper end of the first pin connecting piece insertion groove 10, and a first inward portion is formed at an upper end of the first insertion blade piece 30. A first upper plate 33 was formed by making the upper curvature engaging projection bar 31 and the first upper curvature engaging projection bar curvature guide space 32.

At the lower end of the first pin connecting piece insertion groove 10, a first guide insertion piece 40 having a lower first guide space 41 and a first lower deflection preventing projection bar 42 were formed.

A second insertion blade piece 50 having a second blade insertion portion 21 is formed at an upper end of the second pin connection insertion groove 20, and a second inward portion is formed at an upper end of the second insertion blade piece 50. The second upper plate 53 was formed by forming the upper curvature engaging projection bar 51 and the second upper curvature engaging projection bar curvature guide space 52.

At the bottom of the second pin connecting piece insertion groove 20, a second guide insertion piece 60 having a lower second guide space 61 and a first lower deflection preventing projection bar 62 were formed.

The upper and lower fastening rods 4 and the lower fastening rods 5 are integrally formed at the upper and lower portions of the link pin fixing hole 1 at the center, and the upper fastening rod 4 and the link pin fixing holes 1 at the center. A first insertion blade piece 30, a first top plate 33, and a first guide insertion piece 40 of one side B, based on the center line A of the middle portion of the lower fastening rod 5, The second insertion blade piece 50, the second upper plate 53 and the second guide insertion piece 60 of the other side (C) is composed of a cable bearing body 100 integrally formed in a symmetrical shape.

And in the link pin fixing hole (1) of the cable bear body 100 as described above, by protruding the complementary protrusion pieces (72) (73) on one side up and down, and integral with the pin release prevention piece (71) of the center, The pin release prevention piece (71) is coupled to the connecting piece (74) and the link pin (70) incorporating the fastener (75), and fastened at both sides to the upper fastening rod (4) and the lower fastening rod (5). The guide bar 80, which makes the groove 81, is coupled to the lower end at the upper end thereof, and the cable bear body 100 is symmetrically coupled.

In the present invention as described above, in order to continuously connect the cable bear body (100) repeatedly look at the embodiment of the state of coupling to both sides using the cable bear body 100 of the same shape, first the cable bear body of the same shape It is a structure that combines the other side (C) of one side (B) and the other side of the cable bearing body 100 on the basis of the center line (A) of the cable bear body (100) by combining (100).

In the combination as described above, the first insertion blade piece 30 of one cable bearing body is inserted into the second blade insertion part 21 of the second insertion blade piece 50 of the other cable bearing body and at the same time the first insertion blade piece. The first upper curvature locking projection bar 31 of the upper wing piece 30 is fitted into the second upper curvature locking projection working space 52 of the second upper plate 53 of the other cable bearing body.

At this time, the second upper curvature projection bar 51 of the second upper plate 53 of the other cable bearing body is inserted into the first upper curvature projection bar operating space 32 of the first upper plate 33 of one cable bearing body to move. do.

At the same time, the second guide insertion piece 60 of the other cable bear body is inserted into the first guide space 41 at the bottom of the first pin connecting piece insertion groove 10 of one cable bear body, and at the same time, the first lower deflection preventing projection bar 42 is inserted into the space of the second guide insertion piece 60 of the other cable bearing body, the first lower deflection preventing projection bar 42 of one cable bearing body is the second guide insertion piece of the other cable bearing body ( 60) is inserted into the space.

Insert the pin escape prevention piece 71 of the link pin 70 in the link pin fixing hole (1) formed in the center of the cable bear body 100 in a state in which one side of the cable bearing body and the other side of the cable bearing body are coupled as described above. .

When the link pin 70 is inserted as described above, the upper and lower link pin fastening grooves at the upper and lower link pin fixing holes 1 of the

complementary protrusion pieces

72 and 73 integrated at the upper and lower ends of the pin detachment prevention piece 71 are inserted. (2) and the lower link pin fastening groove (3) of the lower portion, the connecting piece 74 of the link pin 70 is fitted into the second pin connecting piece insertion groove 20, the fastener 75 is the other cable It is coupled to the link pin fixing hole (1) of the bare body is fixed.

When the repetitive coupling is performed in the same manner as described above, when one cable bear is made, the fastening grooves 81 of the guide waves 80 are respectively formed on the upper fastening rods 4 and the lower fastening rods 5 of the cable bear body 100. When combined, the cable bearing body 100 is to be coupled symmetrically to both sides.

When the coupled cable bear is operated as described above, when the coupled cable bear rotates the corner as shown in FIG. 6, the link pin 70 is elastically centered on the link pin fixing hole 1 of the cable bear body 100. Slightly bent by the connection piece 74 of the link pin 70 is bent inclined surface formed in the lower portion of the second pin connecting piece insertion groove 20 of the one side and the first pin connecting piece insertion groove 10 of the other cable bearing body By being bent steadily.

As described above, when the cable bear rotates the corner, the upper portion of the cable bear body 100 has a second upper curvature protrusion bar 51 of one cable bear body in a state in which one cable bear body and the other cable bear body are maximally opened. The first upper curvature locking projection bar 31 of the cable bearer body and the other side are operated in one side of the first upper curvature locking protrusion curvature guide space 32 and the other side of the second upper curvature locking protrusion curvature guide space 52 to maximize as much as possible. By moving, the second upper curvature engaging projection bar 51 of the one side cable bear body and the first upper curvature engaging projection bar 31 of the other cable bearing body are moved in contact with each other.

As described above, the upper portion of the cable bearer body 100 is opened as much as possible, but the lower portion of the second insertion guide piece 60 of the cable bearer body is connected to the lower portion of the cable bearer body 100 to move. The first lower deflection preventing projection bar 42 of the rod 62 and the first guide insertion piece 40 of the other cable bearing body operates in the second guide space 61 and the first guide space 41 to be as close as possible. It is rotated while maintaining the state.

As the cable bear is rotated in this way, the connecting piece 74 of the link pin 70, which is bent at the time of corner rotation, is restored by elasticity to restore the original straight state and the link pin 70 at the same time. The connecting piece 74 is to be in close contact with the upper straight surface in the second pin connecting piece insertion groove 20 of the one side cable bearing body and the first pin connecting piece insertion groove 10 of the other cable bearing body.

As described above, when the cable bearing body 100 moves in a straight line, the upper portion of the cable bearing body 100 is the second upper end of one cable bearing body in a state in which one cable bearing body and the other cable bearing body are in close contact with each other as much as possible. The curvature locking projection bar 51 and the first upper curvature locking projection bar 31 of the other cable bearing body respectively have one side upper curvature projection protrusion curvature guide space 32 and the other second upper curvature projection protrusion curvature guide space 52. The second upper curvature locking projection bar 51 of the one cable bearer body and the first upper curvature locking projection bar 31 of the other cable bearer body are moved away from each other as far as possible.

As described above, the upper portion of the cable bearer body 100 is opened as much as possible, but the lower portion of the second insertion guide piece 60 of the cable bearer body is connected to the lower portion of the cable bearer body 100 to move. The first lower deflection preventing projection bar 42 of the rod 62 and the first guide insertion piece 40 of the other cable bearing body is operated as far as possible by operating in the second guide space 61 and the first guide space 41. When the state is inserted into the second insertion guide piece 60 and the first lower anti-hanging projection bar 42 is to move in a state close to each other.

As described above, the link pin 70 that is inserted into the first pin connection piece insertion groove 10 and the second pin connection insertion groove 20 of the cable bear body 100 in the process of moving the cable mare is the first pin connection piece insertion groove. (10) and the inclined surface of the lower portion of the second pin connecting insertion groove 20 can be stably maintained the rotation angle, the top of the first pin connecting piece insertion groove 10 and the second pin connecting insertion groove (20) By the straight surface of the part is supported horizontally with the link pin 70, even if the cable bears a load by zooming to be able to maintain the horizontal without bending.

As such, the first blade inserting portion 30 and the second insertion blade piece 50 inserted into the first blade inserting portion 11 and the second blade inserting portion 21 in the process of operating the cable bearing body are made of Tolerance is provided at the contact portions of the first blade insertion portion 11 and the second blade insertion portion 21 so that friction does not occur between each other so as to prevent dust generation along with noise caused by friction.

The cable bear, which reduces noise and dust and reduces sagging of the body according to the present embodiment, is not limited to the above-described form and may be variously modified within a range not departing from the technical spirit of the present invention. This will be readily apparent to those skilled in the art.

Claims

In the configuration of the cable bear, the first pin connection piece insertion groove 10 and the second pin connection insertion groove 20 are formed on both sides of the link pin fixing hole 1 penetrating the center portion, and the link pin fixing hole ( 1) the upper and lower parts of the upper link pin fastening groove (2) and the lower link pin fastening groove (3),

A first insertion blade piece 30 having a first blade insertion portion 11 is formed at an upper end of the first pin connecting piece insertion groove 10, and a first inward portion is formed at an upper end of the first insertion blade piece 30. A first upper plate 33 was formed by making the upper curvature engaging projection bar 31 and the first upper curvature engaging projection bar curvature guide space 32.

At the lower end of the first pin connecting piece insertion groove 10, a first guide insertion piece 40 having a lower first guide space 41 and a first lower deflection preventing projection bar 42 were formed.

A second insertion blade piece 50 having a second blade insertion portion 21 is formed at an upper end of the second pin connection insertion groove 20, and a second inward portion is formed at an upper end of the second insertion blade piece 50. The second upper plate 53 was formed by forming the upper curvature engaging projection bar 51 and the second upper curvature engaging projection bar curvature guide space 52.

At the bottom of the second pin connecting piece insertion groove 20, a second guide insertion piece 60 having a lower second guide space 61 and a first lower deflection preventing projection bar 62 were formed.

The upper and lower portions of the link pin fixing hole (1) in the center are complemented to the link pin fixing hole (1) of the cable bear body (100) having the upper fastening rod (4) and the lower fastening rod (5) integrally. The protrusion pieces 72 and 73 are projected to be integrated with the pin release prevention piece 71 in the center, and the connection piece 74 and the fastener 75 are integrally formed with the pin release prevention piece 71. Coupling the link pin 70, the upper fastening rods (4) and the lower fastening rods (5) by combining the guide bar 80 made of the fastening grooves 81 on both sides at the top to the bottom of the cable bear body (100) Cable bear which reduces noise, dust and body sag by combining symmetrically.
The method of claim 1,

In the configuration of the cable bearing body 100, the lower portions of the first pin connecting piece insertion groove 10 and the second pin connecting insertion groove 20 formed on both sides of the link pin fixing hole 1 penetrating the center portion are inclined angles. A cable bare which forms a binary inclined surface (15, 25) and the upper portion is a horizontal plane (16, 26) in a straight line to reduce noise and dust and to sag the body.
The method of claim 1,

The first insertion blade piece 30 and one side of the side (B) on the basis of the center line (A) of the middle of the upper fastening rod (4), the link pin fixing hole (1) and the lower fastening rod (5) The first upper plate 33 and the first guide insertion piece 40 and the second insertion blade piece 50 and the second top plate 53 and the second guide insertion piece 60 of the other side C are mutually Cable bear body that is characterized by consisting of a cable bearing body (100) integrally symmetrical shape to reduce noise and dust and sag of the body.