KR101581015B1 - Supporting bar for adjusting tension of distribution line - Google Patents

Abstract

The present invention relates to a device for adjusting tension according to a change in the length of a distribution line. The device prevents the transmission of impact to an insulator or each connection part even if the distribution line vibrates, buffers and adjusts tension which changes when the distribution line is contracted or expanded according to a temperature change, and extends the lifespan of each part. A supporting unit for fixing the distribution line by the medium of an anchor rotates horizontally according to a state change such as the expansion and contraction of the distribution line, and buffers the same. Thereby, tension applied to the distribution line and tension applied to the anchor can be minimized. Also, the expansion of the distribution line due to high temperature can be prevented. A buffering unit for the fixing unit alleviates impact to prevent damage to an insulator.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tension control device for a tension control device,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus for controlling tension in accordance with a change in length of a working transmission line among processing transmission techniques, and more particularly, And more particularly, to a tension control device for improving the tension of a working transmission line so that the lifetime of each part can be prolonged by fully buffering and controlling the tension which is changed when the working transmission line is expanded and contracted according to the change.

Generally, the transmission tower is equipped with a cradle or a cantilever for fixing the transmission line. The cradle is fixed to the transmission tower and fixedly supports the transmission line through the bracket and the connection rod.

Here, the brass bars are generally formed in a square pipe shape and are generally fixed in the horizontal direction on the front and rear surfaces of the transmission tower.

On the other hand, the machined transmission line is fixed to the transmission tower spaced from the ground, and the electricity to be transmitted to the consumer is transferred.

Therefore, the processed transmission line is made of a metal material having an excellent conduction efficiency and being economical, in particular, copper.

However, the metal material applied to the transmission line is expanded due to expansion due to thermal expansion due to a large change in expansion and shrinkage depending on the temperature, and in winter, it is tightened by shrinkage due to cold.

Accordingly, when the temperature is increased and the working transmission line is inflated, there is a problem that the working transmission line is stretched close to the ground surface, which may pose a threat to the passing vehicle or passerby, and the appearance is also not good.

In addition, when the temperature is lowered and the working transmission line is shrunk, the tension received by the working transmission line becomes large, and it is possible to overload the insulator for fixing the transmission line. Of course, the flock shortens the lifespan of the insulator, and its own length is gradually increased by repetition of expansion and contraction of the overhead transmission line, thereby shortening the service life of the transmission line.

As a conventional technique for improving this, Korean Patent Registration No. 10-0940122 (Jan. 26, 2010) entitled "Wand for fixing special high voltage distribution lines" has been disclosed.

The prior art patent has a limitation in that frictional resistance is not taken into consideration when the rotary shaft is rotatably inserted into the lower portion of the power transmission tower, so that it can not respond sensitively to a change in tension, and the fixed body is rotatably supported The risk of insulator damage is predicted by increasing the amount of impulse applied to the insulator by collision during mutual contact due to the tension change.

Korea Patent Registration No. 10-0940122 (2010.01.26.) "Wand for fixing special high voltage distribution line"

SUMMARY OF THE INVENTION It is an object of the present invention to improve the connection structure of a rotary shaft fixed to a lower portion of a transmission tower so as to be able to respond quickly to a change in tension and to reduce the collision performance between the stationary body and the first and second supports The present invention has been made to solve the above-mentioned problems occurring in the prior art.

In order to achieve the above-mentioned object, the present invention provides a rolling bearing device comprising: a ball-type rotary shaft (210) which is elastically pressed against one-directional rotation to generate a rotational force and inserted into a hollow transmission tower; The first and second rotating shafts 221 and 222 are spaced apart from each other on a flat upper surface. The first and second rotating shafts 221 and 222 are spaced apart from each other. A rotor 220 having a pair of linear rails 223 arranged side by side between the first and second rotary shafts 221 and 222; A gear type main roll 231 for engaging with a gear type inner engaging surface 122 of a transmission tower having a tubular shape and a gear type subroller 232 which is vertically disposed and coaxially fixed to the main roll 231 An anchor 200 having a pair of first and second pulleys 230 and 240 rotatably fixed to first and second rotary shafts 221 and 222 and an anchor 200 rotatably fixed in a horizontal direction, (11) is fixed to one side of one end only via one side end (10), the other end is inserted into an opening groove (121) formed in the transmission tower and is fixed in a movable rod shape along the longitudinal direction; Shaped engaging surface 310 engaging with the sub-roll 232 and a rail groove 301 movably engaged with the rail 223; A pair of first and second pulleys 230 and 240 are arranged side by side; A stopper 320 and a guide 330 formed in a longitudinal direction so that the stopper 320 can be movably engaged are formed on the side surfaces facing each other, A pair of fixing pieces 340 spaced apart from each other on one side of the one end of the transmission line 11 to which the transmission line 11 is fixed; A fixing body 350 in which a nut hole 351 is formed at the center and two insulators 10 are fixed at upper and lower ends; (300, 300 ') having threads formed thereon and having a screw (360) through which the nut (351) penetrates and both ends of which are rotatably fixed to the fixing piece (340) The bottom cap 212 is formed in a cylindrical shape having an open top and a bearing is formed at the center of the bottom of the bottom of the transmission tower 210, A housing 212a is formed integrally with the inner circumferential surface of the lower cap 212. The inner circumferential surface of the lower cap 212 is recessed from the upper end by a predetermined depth of an elastic piece fitting groove 212b, A bearing BA is inserted and fixed to the bearing housing 212a and a lower end portion of a body shaft 214a protruding from the center of the lower end surface of the shaft body 214 is inserted and fixed to the bearing BA, The stem main body 214 is rotatable about the body axis 214a And an elastic piece 214b is inserted and fixed in an outer peripheral surface of the body shaft 214a in a radial direction and the elastic piece 214b is fitted into the elastic piece fitting groove 212b, A rectangular fitting shaft 214c which is fitted to the lower end surface of the rotor 220 is formed at the center of the upper surface of the shaft 214, A frictional stopper 322 is fixed to the top and bottom surfaces of the stopper 320 so as to be in contact with the upper and lower surfaces of the guide 330. The frictional stopper 322 is fixed to the upper surface of the stopper 320 A fixed frame F integrally fixed to the base frame BF and bent at both ends to form a U-shaped recessed portion, a fixed frame F formed integrally with the fixed frame F, A cover frame CF having a dome shape and covering the upper portion of the fixed frame F while holding the ball BL from outside so as to prevent the ball BL from falling out, The tension control device according to any one of claims 1 to 5,

According to the present invention, since the supporter for fixing the transmission line via the anchor is rotated horizontally in accordance with the change of the state of the transmission line such as expansion and contraction, it is possible to minimize the tension applied to the transmission line and the tension applied to the anchor, Is stretched and prevented from being stretched due to the high temperature.

Further, since the present invention includes the fixed body buffer means, the effect of preventing the insulator breakage can be obtained by mitigating the impact.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view explaining a state of a wrought iron according to the present invention,
2 is a view showing a rotation of a support according to the present invention,
And
3 is a view showing an improved structure of the elastic type rotary shaft and the first and second support members according to the present invention.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

1 and 2, the tension control apparatus according to the present invention includes a barb, which is composed of a lower portion 110 of a transmission tower, a central portion 120 of a transmission tower, and an upper portion 130 of a transmission tower, And an anchor 200 fixed to a hollow of the transmission tower and a first and a second supports (not shown) fixed to the transmission tower by fixing the transmission line 11 via the insulator 10 300, and 300 '.

In this case, the transmission tower has a hollow for anchoring the anchor 200 and the first and second supports 300 and 300 '. Particularly, the first and second supports 300 and 300' The opening groove 121 is formed.

Here, the transmission tower according to the present invention may be a conventional concrete material, and the central part of the transmission tower 120 may be made of a synthetic resin material to form a hollow.

The anchor 200 is a means for movably fixing the first and second supports 300 and 300 'and includes an elastic type rotary shaft 210 mounted on the lower portion 110 of the transmission tower, And a first and a second pulleys 230 and 240 installed on the upper surface of the rotor 220 so as to be spaced apart from each other.

In particular, when the rotor 220 receives an external force and horizontally rotates in one direction, the resilient rotating shaft 210 supports the resilient rotor 220 to return to its original position. The resilient rotating shaft 210 may be a spring, a torsion spring, An elastic body such as a spring is incorporated to generate a rotational force for rotating the rotor 220.

More specifically, as shown in FIG. 3 (a), the resilient rotary shaft 210 includes a lower cap 212 that is threadedly engaged with the lower portion of the transmission tower 110.

In this case, the lower cap 212 is formed in a cylindrical shape having an open top, and a bearing housing 212a is integrally formed at the center of the inner bottom surface.

That is, the bearing housing 212a protrudes in the form of a boss.

The inner circumferential surface of the lower cap 212 is recessed with a predetermined depth of the elastic piece fitting groove 212b from the upper end.

At this time, the elastic piece fitting grooves 212b are formed symmetrically in the radial direction.

A bearing BA is inserted and fixed to the bearing housing 212a and a lower end portion of a body shaft 214a protruding from the center of the lower end surface of the shaft body 214 is inserted and fixed to the bearing BA.

Accordingly, the stem main body 214 is configured to be rotatable around the body axis 214a.

In addition, an elastic piece 214b is inserted and fixed on the outer circumferential surface of the body shaft 214a, passing through the upper side of the body except for the portion to be fitted to the bearing BA, in the radial direction.

In addition, the elastic piece 214b is fitted into the elastic piece fitting groove 212b.

Therefore, when the stem main body 214 rotates, the elastic pieces 214b are twisted because they are engaged with the elastic piece fitting grooves 212b at their both ends, so that elastic return force is obtained. When the external force is eliminated, (214).

At this time, the external force for rotating the stem main body 214 is a change in tension due to contraction and expansion of the working transmission line. However, since the tensile force change is not large enough to rotate the stem main body 214 by 360 degrees but takes place within a very small angle, the function of the elastic piece 214b is sufficient.

The resilient piece 214b is configured to rotate at a maximum allowable range of 15 degrees so that the resilient piece 214b can be released from the resilient piece fitting groove 212b or can be operated without being separated. When the elastic piece 214b rotates beyond an allowable rotation range of 15 degrees, a locking protrusion (not shown in detail) is formed at the end of the elastic piece 214b, and an end portion opened in the elastic piece fitting groove 212b The elastic piece 214b may be separated from the elastic piece fitting groove 212b or may not be separated from the elastic piece fitting groove 212b.

The shaft body 214 is formed at the center of the upper end surface with a fitting shaft 214c fitted to the lower end surface of the rotor 220.

Here, the fitting shaft 214c should be deformed into a square shape, preferably a quadrangle shape as shown in FIG. 3 (a), because the shaft body 214 must receive rotational force, not the cylindrical shape described with reference to FIG. It is a modification of the invention.

When assembled in this manner, the elastic force of the elastic type rotary shaft 210 is elastically corresponding to the tension of the transmission line 11, so that the transmission line 11 can be maintained in a tight state without sagging.

In addition, the rotor 220 has a flat upper surface so that the first and second supporters 300 and 300 'horizontally arranged are stable without tilting, and the first and second rotary shafts 300 and 300', which are spaced apart from each other, 221, and 222 are protruded.

In addition, a pair of rails 223 guiding the linear movement of the first and second supports 300 and 300 'so as to be constantly guided can be installed between the pair of first and second rotary shafts 221 and 222 do.

The first and second pulleys 230 and 240 are fixed to the first and second rotating shafts 221 and 222 and rotate together with the main roll 231 and the sub roll 232, Gears are formed on the circumferential surfaces of the main roll 231 and the sub roll 231 so that the engaging surfaces 310 formed on the side surfaces of the supporting tables 300 and 300 ' Respectively.

The main roll 231 and the sub roll 231 are driven in the form of a planetary gear in the inner diameter of the transmission tower 120 so that the first and second pulleys 230, 300 'and the central tower 120 of the transmission tower.

The details of this will be explained together with the description of the contents of the first and second supports 300 and 300 '.

The first and second supports 300 and 300 'are connected to one end of the transmission line 11 through the insulator 10 in one direction and the other end is connected to the opening groove 121 of the transmission tower middle 120 And the engaging surface 310 is engaged with the sub rolls 232 of the first and second pulleys 230 and 240, respectively.

At this time, the engaging surface 310 is formed concavely along the longitudinal direction of the first and second supports 300 and 300 ', and the first and second pulleys 230 and 240 correspond to the engaging surface A boundary groove 233 is formed in which a protruding portion along the periphery of the protrusion 310 is engaged. Here, the boundary groove 233 may be a boundary between the main roll 231 and the sub-roll 232.

In other words, although the sub-roll 232 is drawn relatively large with respect to the engaging surface 310, the sub-roll 232 may have a vertical width of the engaging surface 310 to be engaged with the engaging surface 310, So that it can be fitted to the concave portion.

As a result, the first and second supports 300 and 300 'and the first and second pulleys 230 and 240 are closely meshed with each other and accurately interlocked without detaching.

The first and second supports 300 and 300 'are movably disposed between the first and second sheaves 230 and 240 spaced apart from each other. The first and second supports 300 and 300' The side surfaces facing each other are brought into close contact with each other so that the first and second supports 300 and 300 'have a function of fixing each other to each other.

In order to prevent this, the stoppers 320 are provided on the opposite sides of the first and second supports 300 and 300 'to prevent friction between the first and second supports 300 and 300' And a stopper 320 is formed on a side surface of the first support 300. The stopper 320 is engaged with a side of the second support 300 ' 330 are formed so that the horizontal movement of the first and second supports 300 and 300 'is precisely guided without departing from each other. In this state, on the upper surface and the lower surface of the stopper 320, And a frictional contact portion 322 contacting the lower surface thereof is fixed.

In this case, the frictional stopper 322 includes a base frame BF bolted to the top and bottom surfaces of the stopper 320, a base frame BF fixed integrally with the base frame BF, A fixed frame F having a recessed shape and a ball BL seated at both ends of the fixed frame F and a fixing frame F fixed to the fixation frame F while gripping the ball BL from the outside, And a cover frame (CF) covering and sealing the upper portion and having a dome shape.

The upper and lower surfaces of the guide 330 are respectively connected to the outer surface of the cover frame CF.

Therefore, when the stopper 320 moves, the cover frame CF is received by the guide 330 because it is grounded. As the ball BL, which is easy to move, rotates, it can move while minimizing friction.

3 (c), coil springs SP are coupled to each other on the upper surfaces of the first and second supports 300 and 300 'to provide an elastic return force for returning the coil springs SP when they are twisted It is possible to maximize the elastic return force together with the elastic piece 214b described above, thereby securing the original activity of the operation.

The tension adjusting device according to the present invention further includes a fixing body 350 arranged in a longitudinal direction so as to connect a plurality of transmission lines 11 to only one side of one end of the first and second supports 300 and 300 ' , And the fixture 350 is fixed to be movable along the first and second supports 300 and 300 '.

A pair of protrusions 340 protruding from one side of the first and second supporters 300 and 300 'are formed to face each other, 360 to be rotatable in parallel to the longitudinal direction of the first and second supports 300 and 300 '. The fixing body 350 is formed with a nut hole 351 through which the screw 360 is inserted so that the fixing body 350 can move along the rotation direction of the screw 360, 300, and 300 '.

Of course, one side of the fixing body 350 is in contact with the first and second supports 300 and 300 ', and thus moves along the screw 360 without rotating due to the rotation of the screw 360.

Accordingly, the manager can adjust the fixing position of the power transmission line 11 in accordance with the length and length of the first and second supports 300 and 300 '.

Meanwhile, the fixture 350 arranged in the longitudinal direction can fix the two insulators 10 on both the upper and lower ends so as to be horizontally rotatable, thereby connecting the plurality of transmission lines 11 at a time.

The operation of the present invention according to the above-described configuration will be described.

As shown in FIGS. 2 (a) and 2 (b), the first and second support rods 300 and 300 'are disposed such that their side surfaces are interlocked with each other between the first and second pulleys 230 and 240, And the sub rolls 232 of the two pulleys 230 and 240 are engaged with each other via gears.

Of course, the stopper 320 protruding from the side of the first support 300 may be engaged with the guide 330 formed on the side of the second support 300 'so that the movement range of the first and second supports 300 and 300' Does not deviate from the length of the guide (330).

The first and second supporters 300 and 300 'mounted on the upper surface of the rotor 220 can be moved in a manner such that the rail grooves 301 formed on the bottom surface thereof are movable with respect to the rails 223 formed on the upper surface of the rotor 220 So that the first and second supports 300 and 300 'can be precisely moved without derailment.

On the other hand, the main roll 231, which rotates coaxially with the sub-roll 232, is engaged with the inner engaging surface 122 formed on the supporting center portion 120 via a gear.

Subsequently, when the power transmission line 11 expands due to the high temperature, the tension of the first and second support rods 300 and 300 'is weakened as the power transmission line 11 is slackened. As described above, the tension is lower than the elastic force exerted by the elastic rotary shaft 210, so that the elastic rotary shaft 210 rotates the rotor 220.

When the rotor 220 rotates, the first and second sheaves 230 and 240 installed on the upper surface of the rotor 220 also move along the rotor 220. At this time, The main roll 231 of the power transmission tower 240 rotates while meshing with the inner engagement surface 122 of the transmission tower middle portion 120.

Of course, the direction of rotation will be opposite to the direction of rotation of the rotor 220.

On the other hand, the rotation of the main roll 231 rotates the sub roll 232 rotating coaxially with the main roll 231 in the same direction.

At this time, since the sub roll 232 is engaged with the engaging surface 310 of the first and second supports 300 and 300 ', the first and second supports 300 and 300' Thereby moving horizontally along the longitudinal direction.

The transmission line 11, which is expanded and stretched through the interlocking operation, prevents the first and second supports 300 and 300 'from rotating while pulling the first and second supports 300 and 300'.

The first and second supports 300 and 300 'prevent the transmission line 11 from being drawn or approaching the transmission tower while being drawn from the transmission tower even when the first and second support tables 300 and 300' rotate around the transmission tower. Prevent the possibility of safety accidents.

Since the insulator 10 is fixed to be wired in a predetermined direction regardless of the rotation of the first and second supports 300 and 300 ', the insulator 10 is fixed to the first and second supports 300 and 300' , 300 'in a horizontal direction.

110: Transmission tower lower part 120: Central part of transmission tower
130: Transmission tower upper part 200: Anchor
300: first support

Claims (1)

An elastomeric rotary shaft (210) which is elastically pressed against the one-directional rotation to generate a rotational force and inserted into a hollow transmission tower; The first and second rotating shafts 221 and 222 are spaced apart from each other on a flat upper surface. The first and second rotating shafts 221 and 222 are spaced apart from each other. A rotor 220 having a pair of linear rails 223 arranged side by side between the first and second rotary shafts 221 and 222; A gear type main roll 231 for engaging with a gear type inner engaging surface 122 of a transmission tower having a tubular shape and a gear type subroller 232 which is vertically disposed and coaxially fixed to the main roll 231 An anchor 200 having a pair of first and second pulleys 230 and 240 rotatably fixed to first and second rotary shafts 221 and 222 and an anchor 200 rotatably fixed in a horizontal direction, (11) is fixed to one side of one end only via one side end (10), the other end is inserted into an opening groove (121) formed in the transmission tower and is fixed in a movable rod shape along the longitudinal direction; Shaped engaging surface 310 engaging with the sub-roll 232 and a rail groove 301 movably engaged with the rail 223; A pair of first and second pulleys 230 and 240 are arranged side by side; A stopper 320 and a guide 330 formed in a longitudinal direction so that the stopper 320 can be movably engaged are formed on the side surfaces facing each other, A pair of fixing pieces 340 spaced apart from each other on one side of the one end of the transmission line 11 to which the transmission line 11 is fixed; A fixing body 350 in which a nut hole 351 is formed at the center and two insulators 10 are fixed at upper and lower ends; (300, 300 ') having threads formed therein and a screw (360) through which the nut (351) penetrates and both ends of which are rotatably fixed to the fixing piece (340)
The lower end cap 212 is screwed to the upper end of the transmission tower 110 while the upper end of the lower end cap 212 is cylindrical. A bearing housing 212a integrally protrudes and an inner circumferential surface of the lower cap 212 is formed with a predetermined depth of an elastic piece fitting groove 212b so as to be recessed from an upper end thereof and the elastic piece fitting groove 212b is symmetrical in a radial direction A bearing BA is inserted and fixed to the bearing housing 212a and a lower end portion of a body shaft 214a protruding from the center of the lower end face of the axial body 214 is inserted and fixed in the bearing BA The stem body 214 is rotatably mounted on the body shaft 214a. The elastic body 214b is inserted and fixed in the outer peripheral surface of the body shaft 214a in a radial direction, The piece (214b) is fitted into the elastic piece fitting groove (212b) And a rectangular fitting shaft 214c is formed at the center of the upper surface of the axial main body 214 so as to be fitted to the lower end surface of the rotor 220,
A frictional stopper 322 is fixed to the top and bottom surfaces of the stopper 320 so as to be in contact with the upper and lower surfaces of the guide 330. The frictional stopper 322 is fixed to the upper surface of the stopper 320 A fixed frame F which is integrally fixed to the base frame BF and which has both ends bent upwardly and formed with a bent surface to form a U-shaped recessed portion, a fixed frame F A cover frame CF having a dome-like shape and covering the upper portion of the fixed frame F while holding the ball BL from the outside so as to prevent the ball BL from falling out,
Wherein an upper surface and a lower surface of the guide (330) are grounded to an outer surface of the cover frame (CF), respectively.

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