KR101216117B1 - Module for supporting transmioosin line sleeve - Google Patents

Abstract

PURPOSE: A sleeve supporting module for a transmission line is provided to enable a user to individually replace sleeves by restricting the curvature ratio of a supporting module through a restriction block. CONSTITUTION: A plurality of base units is fixed on a flat board according to a length direction of a flat board(210). A plurality of slack prevention blocks is combined with the base unit in order to be located on the flat board. The plurality of the slack prevention blocks prevents the flat board from being drooped. A plurality of restriction blocks combines with the slack prevention block. A finishing means(300) combines with both ends of a sleeve for a transmission line.

Description

Support module of sleeve for transmission line {MODULE FOR SUPPORTING TRANSMIOOSIN LINE SLEEVE}

The present invention relates to a support module for preventing sagging of a sleeve for transmitting lines, that is, a sleeve repeatedly performing bending and unfolding while protecting a transmission line such as a cable or an air hose without generating dust and noise.

Currently, various industrial machines such as semiconductor equipment, clean room equipment, robots, and the like are used for transmission lines such as cables and air hoses for energy supply or signal transmission. In addition, a transmission line veyor is used to safely move the transmission line while protecting it. Transmission line bays are also referred to as cable veyors.

In general, the transmission line bayer includes a plurality of unit blocks arranged in a line and a connection unit for connecting the plurality of unit blocks. The connection unit connects a plurality of unit blocks to bend the transmission line bay.

However, according to the transmission line bay made as described above, friction between unit blocks and friction between unit blocks and transmission lines which are located adjacent to each other in the process of bending and unfolding are repeated. Therefore, according to the transmission line Bayer, noise and dust are generated in the process of bending and unfolding repeatedly. The noise causes the deterioration of the working environment, the dust can cause a malfunction of the industrial machine, there is a need for improvement.

A flexible sleeve is part of this improvement and has a structure as shown in FIGS. 1 and 2. 1 is a side view illustrating a sleeve for a transmission line, and FIG. 2 is a cross-sectional view taken along line AA ′ of FIG. 1.

The sleeve 10 for the transmission line has an end 12 fixed to a fixed part of an industrial machine and an opposite end 14 fixed to a moving part of an industrial machine to perform a reciprocating motion with the moving part. In addition, the sleeve 10 includes an upper member 20 having flexibility and a lower member 40 having flexibility. A portion of the upper member 20 and a portion of the lower member 40 are attached to each other as shown in Figure 2, the receiving space between the portion of the upper member 20 and the portion of the lower member 40 that is not attached The transmission line 16 is inserted into 50.

According to the sleeve 10, dust and noise are hardly generated in the process of repeated bending and unfolding due to the absence of the joint. However, when the length of the sleeve 10 is long and the transmission line 16 is heavy, deflection occurs in the sleeve 10 as shown in FIG. 1 due to the weight of the transmission line 16. Therefore, a support module for preventing sag is inserted into two accommodation spaces located at the outermost of the accommodation spaces 50 of the sleeve 10. Hereinafter, the supporting module according to the prior art will be described with reference to FIGS. 3 and 4. Figure 3 is a side view showing a support module of a sleeve for a transmission line according to the prior art, Figure 4 is a cross-sectional view taken along line BB 'of FIG.

Conventional sleeve support module 60 is a plurality of fixed to the flat plate 62 and the flat plate 62 to be arranged along the longitudinal direction of the flat plate 62, as shown in Figures 3 and 4 The sag prevention block 64 includes. The flat plate 62 extends through the lower end of the deflection prevention block 64, thereby fixing between the flat plate 62 and the deflection prevention block 64.

When the plate 62 is bent, neighboring sag prevention blocks 64 are spaced apart from each other. However, when the flat plate 62 is extended, the sag prevention blocks 64 located adjacent to each other come into contact with each other. Therefore, when the support module 60 is inserted into the receiving space 50 of the sleeve 10 for the transmission line, sagging of the sleeve 10 can be prevented.

However, according to the support module 60, the radius of curvature R of the bent plate 62 is not limited. Therefore, when the support module 60 receives a force in a bent state as shown in FIG. 3, a problem occurs that the bent portion 62a of the portion of the flat plate 62 is bent.

In addition, according to the support module 60, the flat plate 62 extends through the lower end of the deflection prevention block 64, whereby the deflection prevention block 64 is fixed to the flat plate 62. Therefore, there is a problem that it is impossible to replace only some of the plurality of deflection prevention blocks (64).

In addition, if it is not fixed after being inserted into the sleeve 10, the support module 60 may be withdrawn from the receiving space 50 in the reciprocating process of the opposite end of the sleeve (14). Therefore, a means for fixing the support module 60 to the sleeve 10 is required.

The present invention is to solve the conventional problems as described above, the bending can be bent while the radius of curvature is limited, to allow replacement of only some of the deflection prevention block, the sleeve for the transmission line that can be firmly fixed to the sleeve The purpose is to provide a support module of the.

The present invention for achieving the object as described above is a support module of the sleeve for the transmission line which is inserted into some of the plurality of receiving spaces formed in the sleeve for the transmission line having flexibility to prevent the sagging of the sleeve for the transmission line, Flexible plates; A plurality of bases fixed to the plate so as to be aligned along the longitudinal direction of the plate; A plurality of sag prevention blocks coupled to the base to be positioned above the plate and preventing sag of the plate through mutual contact; A plurality of bending degree limiting blocks coupled to the base and the deflection prevention block so as to be positioned below the plate and limiting the degree of bending of the plate through mutual contact; And closure means coupled to both ends of the sleeve for the transmission line to fix the base.

The closing means includes an upper block and a lower block coupled to each other while pressing both ends of the sleeve for the transmission line and the base located in both ends.

Protrusions are provided on the upper and lower surfaces of the base, and both ends of the sleeve for the transmission line are provided with passage holes for passing the protrusions, and the protrusions passing through the passage holes are inserted into the upper block and the lower block. It is provided with an insertion hole.

The closing means includes an upper cover extending from the upper block and a lower cover extending from the lower block, and a transmission including an outermost deflection prevention block and an outermost bending degree restriction block between the upper cover and the lower cover. The site of the line sleeve is located.

A gap is provided between both side lower ends of the upper cover and both side upper ends of the lower cover.

According to the present invention, the radius of curvature of the bent support module may be limited by the bending degree limiting block, and the deflection preventing block and the bending degree limiting block included in the supporting module may be replaced individually.

In addition, according to the present invention, alignment of the deflection prevention block and the bending degree limiting block may be easily performed on the flat plate, and the assembly of the deflection prevention block and the bending degree limiting block may be easily performed.

In addition, according to the present invention, the support module can be firmly fixed to the sleeve by the closing means.

Further, according to the present invention, since the stress acting on the upper block and the lower block of the finishing means is distributed to the upper cover and the lower cover, it is possible to prevent shortening of the life of the finishing means.

In addition, according to the present invention, since the vertical mobility of the sleeve is ensured to some extent between the upper cover and the lower cover, the impact that the sleeve receives from the upper cover and the lower cover can be alleviated.

1 is a side view showing a sleeve for the transmission line.
2 is a sectional view taken along line A-A 'in Fig.
Figure 3 is a side view showing a support module of a sleeve for a transmission line according to the prior art.
4 is a cross-sectional view taken along line BB ′ of FIG. 3.
Figure 5 is a side view showing a sleeve for the transmission line supported by the support module of the sleeve for the transmission line according to the present invention.
6 is a cross-sectional view taken along line CC ′ of FIG. 5.
Figure 7 is a side view showing a support module of the sleeve for the transmission line according to the present invention.
8 is a partially exploded perspective view of the support module shown in FIG. 7.
9 is a partial longitudinal cross-sectional view of the support module shown in FIG. 7.
10 is an exploded perspective view showing the finishing means of the support module shown in FIG.

Hereinafter, preferred embodiments of the support module of the sleeve for the transmission line according to the present invention will be described in detail with reference to the drawings. It is to be understood that the terminology or words used herein are not to be construed in an ordinary sense or a dictionary, and that the inventor can properly define the concept of a term to describe its invention in the best possible way And should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

As shown in FIG. 5, the sleeve 100 for the transmission line supported by the support module 200 according to the present invention has one end fixed to fixing parts of various industrial machines such as semiconductor equipment, clean room equipment, and robots. 102 and an opposite end 104 fixed to the moving part of the industrial machine. The sleeve 100 for the transmission line does not have a joint because it extends continuously from the one end 102 to the other end 104.

As shown in FIG. 6, the transmission line sleeve 100 includes an accommodation space 150 for accommodating a transmission line 106 such as a cable or an air hose. The accommodation space 150 extends along the length direction of the sleeve 100 and is arranged in parallel along the width direction. In addition, the accommodation space 150 is formed by the upper sheet 120 and the lower sheet 140. In this case, the upper sheet 120 and the lower sheet 140 have flexibility to bend and unfold the sleeve 100.

The support module 200 according to the present invention includes a part of the plurality of accommodation spaces 150 formed in the sleeve 100 having the flexibility as described above, for example, in two accommodation spaces 150 located at the outermost portion of FIG. 6. Inserted to prevent sagging of the sleeve 100, a flat plate 210, a plurality of base 230, a plurality of sag prevention block 250, a plurality of bending degree limit block 270, finish And means 300.

The plate 210 is made of stainless steel, and is formed to a thickness sufficient to retain flexibility. The plurality of bases 230 are arranged along the longitudinal direction of the flat plate 210 and are fixed to the flat plate 210 in a manner that allows the flat plate 210 to pass therethrough. In addition, an upper protrusion 232 is provided on an upper surface of the base 230, and a lower protrusion 234 is provided on a lower surface of the base 230.

The deflection prevention block 250 includes a body 252 having a front surface 254 and a rear surface 256. A protrusion 255 is formed on the front surface 254, and an insertion groove 257 having a bottom 257a is formed on the rear surface 256. The protrusion 255 is inserted into an insertion groove provided in the front deflection prevention block located in front of the insertion groove 257, the insertion groove 257 accommodates the projection provided in the rear deflection prevention block located in its rear.

When the flat plate 210 is extended, the front surface 254 is interviewed with the rear surface provided in the front deflection prevention block, the rear surface 256 is interviewed with the front surface provided in the rear deflection prevention block, and the rear low needle The lower surface of the protrusion provided on the front of the prevention block is in contact with the bottom 257a of the insertion groove 257. And sagging of the flat plate 210 is prevented by such interviews.

On the other hand, the body 252 of the deflection prevention block 250 is provided with a hole 258. The upper protrusion 232 of the base 230 is inserted into the hole 258. In addition, left and right side walls 260 protruding downward in the left and right ends of the deflection prevention block 250 body 252 is provided, the locking hole 262 is provided in the left and right side walls 260.

The bending degree limiting block 270 includes a body 272 having a front surface 274 and a back surface 276. The rear surface 276 is formed of an inclined surface that is inclined closer to the front surface 274 as far away from the flat plate 210, and the front surface 274 is closer to the rear surface 276 as far away from the flat plate 210. It consists of a slope inclined to the fork.

Bending degree restriction block 270 The front surface 274 of the body 272 is formed with a projection 275, the rear surface 276 is formed with an insertion groove 277 having a ceiling (277a). At this time, the upper surface 275a of the protrusion 275 is formed as an inclined surface that is inclined away from the flat plate 210 as the farther from the front surface 274. On the other hand, the protrusion 275 is inserted into the insertion groove provided in the front bending degree limit block located in front of the, and the insertion groove 277 is a protrusion provided in the rear bending degree limit block located in the rear of the Accept.

When the plate 210 is bent, the back side 276 of the bending degree limit block 270 body 272 is interviewed with the front surface provided in the rear bending degree limit block, and the bending degree limit block 270 body ( The front surface 274 of 272 is interviewed with the rear surface provided in the front bending degree limit block, the upper surface of the protrusion provided in the front of the rear bending degree limit block is interviewed with the ceiling (277a) of the insertion groove (277). do. And the radius of curvature of the flat plate 210 bent by such interviews is limited.

On the other hand, the body 272 of the bending degree limiting block 270 is provided with a hole 278. The lower protrusion 234 of the base 230 is inserted into the hole 278. In addition, the left and right ends of the bending degree limiting block 270 body 272 are provided with left and right side walls 280 protruding upward, and the left and right side walls 280 are provided with protrusions 282. The protrusion 282 is coupled to the engaging hole 262 provided on the left and right side walls 260 of the deflection prevention block 250, the body 252.

The support module 100 of the sleeve for the transmission line as described above, after fixing the base 230 to the flat plate 210, the deflection prevention block 250 and the bending degree limit block 270 to the base 230 Assembled by bonding. The base 230 is fixed to the flat plate 210 by insert injection or the like. When the deflection prevention block 250 is coupled to the base 230, the upper protrusion 232 of the base 230 is inserted into the hole 258 of the deflection prevention block 250. Then, when the bending degree limiting block 270 is coupled, the lower protrusion 234 of the base 230 is inserted into the hole 278 of the bending degree limiting block 270, and the left and right side walls 280 of the bending degree limiting block 270. Protrusion 282 of the) is coupled to the engaging hole 262 provided on the left and right side walls 260 of the deflection prevention block 250.

As described above, the support module 200 is inserted into the receiving space 150 of the sleeve 100 for the transmission line to prevent sagging and limit the bending of the sleeve 100 for the transmission line. However, if it is not fixed after being inserted into the accommodation space 150, the support module 200 may be withdrawn from the accommodation space 150 during the reciprocating motion of the opposite end 104 of the sleeve. The support module 200 further includes a finishing means (300).

The finishing means 300 is for fixing the base 230 to both ends of the sleeve 100, as shown in Figure 10, the first upper block (310a) and the second upper block (310b) and The first lower block 350a and the second lower block 350b are included.

The first upper block 310a and the second upper block 310b are positioned to interview the outer surface of one end of the sleeve upper sheet 120 and the outer surface of the opposite end, respectively. The first upper block 310a and the second upper block 310b include a plurality of insertion holes 312a and 312b, which are fixed to one end and the opposite end of the flat plate 210 in the insertion holes 312a and 312b. The upper protrusion 232 of the formed bases 230 is inserted. In order to allow the upper protrusion 232 to be inserted into the insertion holes 312a and 312b, the deflection preventing block 250 is not coupled to the bases 230 fixed to one end and the opposite end of the plate 210. The upper sheet 120 of the through hole 122 for passing through the upper protrusion 232 is provided.

The first lower block 350a and the second lower block 350b are positioned to interview one outer surface and the other outer surface of the sleeve lower sheet 140, respectively. The first lower block 350a and the second lower block 350b include a plurality of insertion holes 352a and 352b, which are fixed to one end and the opposite end of the flat plate 210 in the insertion holes 352a and 352b. The lower protrusion 234 of the bases 230 is inserted. In order to allow the lower protrusion 234 to be inserted into the insertion holes 352a and 352b, the bending degree limiting block 270 is not coupled to the bases 230 fixed to one end of the flat plate 210, and the lower portion of the sleeve The seat 140 is provided with a passage hole (not shown) for passing the lower protrusion 234.

The first upper block 310a and the first lower block 350a, and the second upper block 310b and the second lower block 350b are coupled to each other through the bolt 372 and the nut 374. At this time, the bolt 372 is a bolt hole 314a, 314b of the upper block (310a, 310b), the bolt hole 110 of the sleeve 100 and the bolt hole (354a, 354b) of the lower block (350a, 350b) After passing sequentially, it is coupled with the nut 374. The upper blocks 310a and 310b and the lower blocks 350a and 350b coupled to each other press the base 230 positioned at both ends of the sleeve 100 and both ends thereof, so that the base 230 is at both ends of the sleeve 100. Is fixed to.

One end of the first upper block 310a and one end of the first lower block 350a are provided with holes 316a and 356a. The protrusion 25 provided on the front surface 254 of the deflection preventing block 250 positioned at the outermost portion is inserted into the hole 316a of the first upper block 310a, and the hole (1) of the first lower block 350a is inserted. The protrusion 275a provided on the front surface 274 of the bending degree limiting block 270 positioned at the outermost portion 356a is inserted.

In addition, a protrusion 356b is provided at one end of the second upper block 310b and at one end of the second lower block 350b. The projection (not shown) of the second upper block 310b is inserted into the groove 257 provided in the rear surface 256 of another deflection preventing block 250 positioned at the outermost part, and the second lower block 350b is provided. The protrusion 356b is inserted into the groove 277 provided in the rear side 276 of the other bending degree restriction block 270 located at the outermost.

Meanwhile, the finishing means 300 further includes a first upper cover 320a and a second upper cover 320b, a first lower cover 360a, and a second lower cover 360b.

The first upper cover 320a extends along the longitudinal direction of the sleeve 100 from one end of the first upper block 310a toward the second upper block 310b, and the second upper cover 320a is the second upper block. It extends along the longitudinal direction of the sleeve 100 from one end of (310b) toward the first upper block (310a). The first lower cover 360a extends along the length direction of the sleeve 100 from one end of the first lower block 350a toward the second lower block 350b, and the second lower cover 360b extends along the second lower cover. It extends along the longitudinal direction of the sleeve 100 from the block 350b toward the first lower block 350a. Between the first upper cover 320a and the first lower cover 360a, a portion of the sleeve 100 accommodating the outermost deflection prevention block and the bending degree restricting block is positioned, and the second upper cover 320b and the second upper cover 320a are disposed. Between the lower cover 360b is a portion of the sleeve 100 that accommodates the further outermost sag prevention block and the bending degree limit block.

If the finishing means 300 does not have the upper cover (320a, 320b) and the lower cover (360a, 360b), the upper block (310a, 310b) and lower block ( Since stress is concentrated in the 350a and 350b, the life of the finishing means 300 may be shortened. However, if the finishing means 300 is provided with the upper cover (320a, 320b) and the lower cover (360a, 360b), because the stress is distributed to the upper cover (320a, 320b) and the lower cover (360a, 360b) The shortening of the life of 300) can be prevented.

On the other hand, it is preferable that gaps 322a, 362a, 322b, and 362b are provided between both side lower ends of the upper covers 320a and 320b and upper ends of both sides of the lower covers 360a and 360b. In this case, the sleeve 100 is secured to the upper cover 320a, 320b and the lower cover (360a, 360b) to some extent because the vertical mobility of the sleeve 100 is the upper cover (320a, 320b) and the lower cover ( Impacts from 360a and 360b can be mitigated.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Various modifications and variations may be made within the equivalent scope of the claims to be described.

100: sleeve for the transmission line 106: transmission line
150: receiving space 200: support module
210: flat plate 230: base
232: upper protrusion 234: lower protrusion
250: deflection block 254: front
256: back side 258: hole
260: left and right side wall 270: bending degree limit block
274: front side 276: rear side
278: hole 280: left and right walls
300: finishing means 310a, 310b: upper block
312a, 312b: Insertion hole 320a, 320b: Top cover
350a, 350b: Lower block 352a, 352b: Insertion hole
360a, 360b: lower cover 322a, 322b, 362a, 362b: gap

Claims (5)

In the support module of the sleeve for the transmission line is inserted into some of the plurality of receiving spaces formed in the sleeve for the transmission line having flexibility to prevent the sagging of the sleeve for the transmission line,
Flexible plates;
A plurality of bases fixed to the plate so as to be aligned along the longitudinal direction of the plate;
A plurality of sag prevention blocks coupled to the base to be positioned above the plate and preventing sag of the plate through mutual contact;
A plurality of bending degree limiting blocks coupled to the base and the deflection prevention block so as to be positioned below the plate and limiting the degree of bending of the plate through mutual contact; And
And a closing means coupled to both ends of the sleeve for the transmission line to fix the base. The method of claim 1,
The closing means is a support module for a sleeve for a transmission line, characterized in that it comprises an upper block and a lower block coupled to each other while pressing the base and the base located in both ends of the sleeve for the transmission line. The method of claim 2,
Protrusions are provided on the upper and lower surfaces of the base, and both ends of the sleeve for the transmission line are provided with passage holes for passing the protrusions, and the protrusions passing through the passage holes are inserted into the upper block and the lower block. Supporting module of the sleeve for the transmission line, characterized in that the insertion hole is provided for. The method of claim 2,
The closing means includes an upper cover extending from the upper block and a lower cover extending from the lower block, and a transmission including an outermost deflection prevention block and an outermost bending degree restriction block between the upper cover and the lower cover. The support module of the sleeve for the transmission line, characterized in that the portion of the sleeve for the line is located. 5. The method of claim 4,
A support module for a sleeve for a transmission line, characterized in that a gap is provided between both side lower ends of the upper cover and both side upper ends of the lower cover.

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