KR102027381B1 - Power distribution cable support system - Google Patents

Abstract

The present invention relates to a distribution line pole cable support device capable of stabilizing the connection condition of a distribution line for distribution on a telephone pole and cutting off the transmission of power by disconnecting the distribution line if a limit to the stretchiness of the distribution line is exceeded. To achieve the purpose, the distribution line pole cable support device includes: a first frame placed on one side of a telephone pole; a second frame placed on the other side of the telephone pole; a moving body placed between the first and second frames and supporting first and second distribution lines; a first control unit combined with the moving body to be able to be slid, and elastically supporting the first distribution line to make the first distribution line stretchable; a second control unit combined with the moving body at a distance from the first control unit to be able to be slid, and elastically supporting the second distribution line to make the second distribution line stretchable; a jump line connection unit installed in the moving body and electrically connecting a first jump line branched from the first distribution line and a second jump line branched from the second distribution line; and a jump line separating unit installed in the moving body and separating the first and second jump lines from the jump line connection unit by converting rotational movement into linear movement through gearing with at least one of the first and second control units.

Description

Power distribution cable support device {POWER DISTRIBUTION CABLE SUPPORT SYSTEM}

The present invention relates to a distribution cable support device for a distribution line, more specifically, to stabilize the connection state of the distribution line for power distribution in the telephone pole, and when exceeding the extension limit of the distribution line, can disconnect the power distribution line to interrupt the power transfer. The present invention relates to a distribution cable pole support device.

In general, the distribution lines are installed on the telephone pole so as to be spaced apart from the floor, and are installed so as to be spaced apart by the wire support device to prevent the distribution lines from being energized with each other.

Such a wire support device has been disclosed in Korean Patent Publication No. 10-1161422. Conventional wire support device is provided to secure the fastener to the U-bolt and nut to secure the fastener to the binding portion of the cap and the cap part to be fixed to the telegraph pole to prevent the breakage of the wire A shock absorber comprising a folding bar that is connected to the fastener and the light insulator that absorbs the shock and serves to connect the suspension insulator to the fastener, which is fixed in an X-shape. Provides a wire support device for telegraph poles, but the light arm is bent by the bend to extend the extension fastening to increase the extension of the wire, and at the same time to form a bending bar connection to absorb shocks and to act as a spring spring U ball at opposite reinforcement protrusion and reinforcement protrusion to reinforce the fastening piece and the bent part to prevent breakage of the fastening piece when absorbing the impact of the fastening piece The cap is projected with the reinforcing projection space left between the reinforcing protrusions and the U bolt together with the reinforcing protrusion between the reinforcing protrusions and the reinforcing protrusions and the reinforcing protrusions to further prevent breakage of the fasteners when absorbing the impact of the fastenings. Combination with the negative binding piece is fixed by the fastening of the nut, including the reinforcement protrusion and the protruding wall and the U bolt to further strengthen the prevention of fracture of the fastener when absorbing the shock of the fastener and increase the fastening force of the light arm.

In the conventional wire support device, the fastening piece performs a function of a leaf spring, thereby being able to firmly support the wire while maintaining tension.

However, the conventional wire support device is only built to have the tension of the wire, when the electric wire is disconnected by the electric pole or wind of the telephone pole, the accident that the pedestrian passing by the line is dropped to the floor in the live state, the electric shock occurs There was a problem.

Republic of Korea Patent Publication No. 10-1666933 (Invention name: wire support device for distribution poles, 2016. 10. 17. announcement)

DISCLOSURE OF THE INVENTION An object of the present invention is to solve a conventional problem, and stabilizes the connection state of a distribution line for power distribution in a telephone pole, and in a case where the extension limit of the distribution line is exceeded, the distribution line may disconnect the power distribution line to interrupt power transmission. It is to provide a pole cable support device.

According to a preferred embodiment for achieving the above object of the present invention, the distribution line cable support apparatus according to the present invention includes a first frame disposed on one side of the telephone pole; A second frame disposed on the other side of the telephone pole; A driving housing disposed between the first frame and the second frame and supporting the first distribution line and the second distribution line; A first control unit coupled to the drive housing so as to be slidably movable, the first control unit elastically supporting the first distribution line such that the first distribution line is stretchable and expandable; A second adjusting unit spaced apart from the first adjusting unit so as to be slidably coupled to the driving housing, and elastically supporting the second distribution line so that the second distribution line is stretchable and expandable; A jump line connecting unit provided in the driving enclosure and electrically connecting a first jump line branched from the first distribution line and a second jump line branched from the second distribution line; And a first housing and a second jump line provided from the jump line connecting unit by converting a rotational motion into a linear motion through engagement between at least one of the first control unit and the second control unit. And a jump line separating unit for separating the first control unit, the first control unit being coupled to the driving enclosure so as to be slidably movable in correspondence to the longitudinal direction of the first distribution line, and the first distribution line is coupled to one end thereof. A first rod provided at the other end with a first supporting protrusion; A first elastic member elastically pressing the first support protrusion based on the driving enclosure; And a first adjustment case protruding from the driving enclosure corresponding to the longitudinal direction of the first distribution line, and configured to form a slide movement path of the first support protrusion. The second adjustment unit includes the second adjustment unit. A second rod coupled to the driving housing so as to be slidably movable in a longitudinal direction of a distribution line, one end of which is coupled to the second distribution line, and the other end of which includes a second support protrusion; A second elastic member elastically pressing the second support protrusion based on the driving enclosure; And a second adjusting case protruding from the driving enclosure corresponding to the longitudinal direction of the second distribution line, and forming a slide movement path of the second supporting protrusion. An actuating pinion gear rotatably coupled; A first actuating rack gear meshed with the actuating pinion gear, the first actuating rack gear being spaced apart from the actuating pinion gear and provided on the first rod of the first adjusting unit; A second actuating rack gear meshed with the actuating pinion gear, the second actuating rack gear being spaced apart from the actuating pinion gear and provided on the second rod of the second adjusting unit; A separate pinion gear rotatably coupled to the drive housing so as to rotate together with the actuating pinion gear; A first separation rack gear slidably coupled to the drive housing in engagement with the separation pinion gear; a first support bracket on which the first jump line is supported when the jump line connecting unit and the first jump line are connected; A first separating member including a first terminal detachable part formed through the first support bracket in an open state to communicate with the jump line connecting unit; And a second separating rack gear slidably coupled to the drive housing in engagement with the separating pinion gear, and a second support bracket for supporting the second jump line when the jump line connecting unit and the second jump line are connected. And a second separating member including a second terminal detachable part formed through the second support bracket in an open state to communicate with the jump line connecting unit.
The first actuating rack gear is spaced apart from the center of the actuating pinion gear by the first stretching distance toward the first distribution line in response to the expansion limit of the first distribution line, and is formed as long as the first separation distance. The second actuating rack gear is spaced apart from the center of the actuating pinion gear by the second stretching distance in response to the stretching limit of the second distribution line toward the second distribution line, and then formed as long as the second separation distance.
At this time, within the stretch limit of at least one of the first distribution line and the second distribution line, even if at least one of the first rod and the second rod is slid from the driving enclosure, the first operation is performed on the actuating pinion gear. Since the rack gear and the second actuating rack gear are not engaged, the actuating pinion gear does not rotate.
And the at least one of the first rod and the second rod when the at least one of the first rod and the second rod is deviated or broken, when the at least one of the first rod and the second rod is slid from the driving enclosure. As the at least one of the first actuating rack gear and the second actuating rack gear meshes with the gear, the actuating pinion gear and the separating pinion gear are rotated, and the first separating rack gear and the second separating rack gear are rotated. The first jump line and the second jump line, which are slidably moved from the driving enclosure and supported on the first support bracket and the second support bracket, respectively, are separated from the jump line connecting unit.

Here, the jump line connection unit, the fixed terminal block fixed to the drive housing; A reciprocating terminal block which is installed to face the fixed terminal block and reciprocates from the driving housing toward the fixed terminal block; And a connection elastic member for elastically pressing the reciprocating terminal block toward the fixed terminal block.

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According to the distribution line cable support apparatus according to the present invention, in the telephone pole to stabilize the connection state of the distribution line for the distribution, if the extension limit of the distribution line, the connection of the distribution line can be disconnected to cut off the power transfer.

In addition, the present invention can determine the expansion limit of the distribution line through the jump line separation unit, and can quickly respond to plastic deformation of the distribution line or breakage of the distribution line, at least one of the first distribution line and the second distribution line is beyond the expansion limit In this case, the first jump line and the second jump line are separated at the same time from the jump line connecting unit.

In addition, the present invention facilitates the linkage with the jump line separating unit through the first control unit, it is possible to stably elastically support the first distribution line.

In addition, the present invention facilitates the linkage with the jump line separation unit through the second control unit, it is possible to stably elastically support the second distribution line.

In addition, the present invention allows the first jump line and the second jump line to be electrically connected stably through the jump line connection unit, and can improve the holding force of the first jump line and the second jump line.

1 is an enlarged plan view illustrating a distribution cable pole cable support apparatus according to an embodiment of the present invention.
Figure 2 is a longitudinal sectional view showing a drive box along the line AA in the distribution cable pole cable support apparatus according to an embodiment of the present invention.
3 is a plan view illustrating a first operation state of a jump line separating unit in a distribution cable pole cable supporting apparatus according to an embodiment of the present invention.
4 is a plan view illustrating a second operation state of a jump line separating unit in a distribution cable pole cable supporting apparatus according to an embodiment of the present invention.
5 is a perspective view illustrating a first separation member (a) and a second separation member (b) in a distribution cable pole cable supporting apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a distribution cable pole cable support apparatus according to the present invention. At this time, the present invention is not limited or limited by the embodiment. In addition, in describing the present invention, a detailed description of known functions or configurations may be omitted to clarify the gist of the present invention.

1 to 5, the distribution line cable support apparatus according to an embodiment of the present invention, the first frame 10, the second frame 20, the drive housing 30, the first control unit 40, the second adjusting unit 50, the jump line connecting unit 60, and the jump line separating unit 70 may be included.

The first frame 10 is disposed on one side of the telephone pole. The first frame 10 is formed in a rod shape. A first band portion may be provided in the end region or the central region of the first frame 10 to surround and fix the circumference of the telephone pole. The first band portion may have a semicircular shape corresponding to the telephone pole.

The second frame 20 is disposed on the other side of the telephone pole so as to be substantially parallel to the first frame 10. The second frame 20 is formed in a rod shape. A second band portion may be provided in the end region or the central region of the second frame 20 to surround and fix the circumference of the telephone pole. The second band portion may have a semicircular shape corresponding to the telephone pole.

Then, each of the first band portion and the second band portion wraps around the telephone pole, and both ends thereof can be fixedly overlapped with respect to the telephone pole.

The driving enclosure 30 is disposed between the first frame 10 and the second frame 20. The driving enclosure 30 is coupled to the first frame 10 and the second frame 20.

Distribution line pole cable support apparatus according to an embodiment of the present invention is to support the distribution line in the telephone pole, the distribution line may be disposed two or more spaced apart from each other. In this case, the distribution line may be divided into the first distribution line 11 and the second distribution line 21 based on the telephone pole in order to minimize disconnection due to replacement and tension.

The first distribution line 11 and the second distribution line 21 may be electrically connected to each other by a jump line. The jump line may be divided into a first jump line 13 branched from the first distribution line 11 and a second jump line 23 branched from the second distribution line 21.

Here, an end of the first jump line 13 is provided with a first connection terminal 131 electrically connected to the jump line connection unit 60. The first catching ring 132 supported by the first support bracket 752 by the first separating member 75 of the jump line separating unit 70 at the boundary between the end of the first jump line 13 and the first connecting terminal 131. ) Is formed to protrude.

Similarly, at the end of the second jump line 23, a second connection terminal 231 electrically connected to the jump line connection unit 60 is provided. The second locking ring 232 supported by the second support bracket 762 in the second separating member 76 of the jump line separating unit 70 at the boundary between the end of the second jump line 23 and the second connection terminal 231. ) Is formed to protrude.

Accordingly, two or more driving enclosures 30 may be disposed in a length direction of the first frame 10 or the second frame 20 in correspondence to the number of arrangement of the distribution lines.

The first distribution line 11 and the second distribution line 21 are respectively supported by the driving enclosure 30. In an embodiment of the present invention, the first distribution line 11 and the second distribution line 21 are eccentric in the pinion shaft 711, which is the central region of the driving enclosure 30, as shown in FIG. The origin symmetry may be achieved with respect to the pinion shaft 711, which is a central region of the driving enclosure 30.

A first insulator 12 is provided at an end portion of the first distribution line 11 facing the driving enclosure 30 to electrically insulate the first distribution line 11, the first frame 10, and the driving enclosure 30. Can be. In addition, a second insulator 22 is provided at an end portion of the second distribution line 21 facing the driving enclosure 30 to electrically insulate the second distribution line 21, the second frame 20, and the driving enclosure 30. can do.

When the jump line connecting unit 60 is built into the driving enclosure 30, the driving jumper 30 includes a second jump branch 13 and a second branch line 21 branched from the first distribution line 11. The jump line 23 can be detachably supported.

The first control unit 40 is coupled to the drive housing 30 so as to slide. The first control unit 40 elastically supports the first distribution line 11 so that the first distribution line 11 is stretchable.

The first adjustment unit 40 may include a first rod 41, a first elastic member 43, and a first adjustment case 44.

The first rod 41 is fitted to the drive housing 30 so as to be slidable in correspondence with the longitudinal direction of the first distribution line 11. The first rod 41 allows both sides to protrude from the drive housing 30, respectively.

The first rod 41 is provided with a first operating rack gear 72 to be described later.

One end of the first rod 41 is coupled to the first distribution line 11 via the first insulator 12.

The other end of the first rod 41 is provided with a first support protrusion 42.

The first elastic member 43 elastically presses the first support protrusion 42 based on the driving housing 30. The first elastic member 43 may be formed of a coil spring surrounding the first rod 41.

The first control case 44 is formed to protrude from the drive housing 30 corresponding to the longitudinal direction of the first distribution line (11). The first adjustment case 44 is coupled to at least one of the drive housing 30 and the second frame 20. The first adjustment case 44 is a hollow enclosure, and forms a slide movement path of the first support protrusion 42. The other side of the first rod 41 protruding from the driving housing 30 and the first elastic member 43 are inserted into the first adjustment case 44.

The second control unit 50 is spaced apart from the first control unit 40. The second control unit 50 is coupled to the drive housing 30 to be slidable. The second control unit 50 elastically supports the second distribution line 21 so that the second distribution line 21 is stretchable.

The second adjusting unit 50 may include a second rod 51, a second elastic member 53, and a second adjusting case 54.

The second rod 51 is fitted to the drive housing 30 so as to be slidably movable in correspondence to the longitudinal direction of the second distribution line 21. The second rod 51 allows both sides to protrude from the driving housing 30, respectively.

The second rod 51 is provided with a second operating rack gear 73 to be described later.

The second distribution line 21 is coupled to one end of the second rod 51 via the second insulator 22.

The second support protrusion 52 is provided at the other end of the second rod 51.

The second elastic member 53 elastically presses the second support protrusion 52 based on the driving housing 30. The second elastic member 53 may be formed of a coil spring surrounding the second rod 51.

The second adjustment case 54 is formed to protrude from the drive housing 30 corresponding to the longitudinal direction of the second distribution line 21. The second adjustment case 54 is coupled to at least one of the drive housing 30 and the first frame 10. The second adjustment case 54 is a hollow enclosure, and forms a slide movement path of the second support protrusion 52. The other side of the second rod 51 protruding from the driving housing 30 and the second elastic member 53 are inserted into the second adjustment case 54.

In an embodiment of the present invention, the first rod 41 and the second rod 51 are eccentric in the pinion shaft 711, which is the central region of the driving enclosure 30, as shown in FIG. 1. The origin symmetry may be achieved with respect to the pinion shaft 711, which is a central region of the driving enclosure 30.

The jump line connecting unit 60 is provided in the drive housing 30. The jump line connection unit 60 may be built in the driving enclosure 30. The jump line connecting unit 60 may include a fixed terminal block 61, a reciprocating terminal block 62, and a connecting elastic member 63.

The fixed terminal block 61 is fixed to the drive housing 30. The fixed terminal block 61 is formed long along the longitudinal direction of the first distribution line 11 or the second distribution line 21. The fixed terminal block 61 has a semicircular cross section or an arc cross section.

The reciprocating terminal block 62 is installed to face the fixed terminal block 61. The reciprocating terminal block 62 is capable of reciprocating toward the fixed terminal block 61 in the drive housing (30).

The connection elastic member 63 elastically presses the reciprocating terminal block 62 toward the fixed terminal block 61.

Although not shown, the first connecting terminal 131 and the second connecting terminal 231 are guided between the fixed terminal block 61 and the reciprocating terminal block 62 at both ends of the fixed terminal block 61 and both ends of the reciprocating terminal block 62, respectively. Terminal guide portion may be provided.

Then, the first connecting terminal 131 and the second connecting terminal 231 are inserted between the fixed terminal block 61 and the reciprocating terminal block 62 via the terminal guide, respectively, the connection elastic member 63 is the reciprocating terminal block 62 As the elastic pressure is applied, the adhesion between the fixed terminal block 61 and the reciprocating terminal block 62 and the first connecting terminal 131 and the second connecting terminal 231 are improved.

The jump line separating unit 70 is provided in the drive housing 30. The jump line separating unit 70 converts the rotational motion into a linear motion through the engagement of at least one of the first control unit 40 and the second control unit 50 to the first jump line (from the jump line connecting unit 60). 13) and the second jump line (23).

More specifically, the jump line separating unit 70 is the first control unit 40 and the second control unit (at least one of the first distribution line 11 and the second distribution line 21 when the break out or breaks the stretch limit) ( At least one of the operation 50 is engaged with at least one of the first control unit 40 and the second control unit 50, the first control unit 40 and the second control unit in the engaged state As at least one of the 50 is operated, the jump line separating unit 70 changes the rotational motion into a linear motion to separate the first jump line 13 and the second jump line 23 from the jump line connecting unit 60.

The jump line separating unit 70 includes an actuating pinion gear 71, a first actuating rack gear 72, a second actuating rack gear 73, a separating pinion gear 74, and a first separating member 75. And a second separation member 76.

The actuating pinion gear 71 is rotatably coupled to the drive housing 30. The actuating pinion gear 71 is embedded in the drive enclosure 30 and is disposed between the first rod 41 and the second rod 51 and rotates around the pinion shaft 711 to the drive enclosure 30. Possibly combined.

The first actuating rack gear 72 meshes with the actuating pinion gear 71. The first actuating rack gear 72 is spaced apart from the actuating pinion gear 71 and provided on the first rod 41 of the first regulating unit 40.

The first operating rack gear 72 is spaced apart from the center of the operating pinion gear 71 by the expansion distance a toward the first distribution line 11 in response to the expansion limit of the first distribution line 11, and then separated. It is formed as long as (b).

At this time, the distance from the first support protrusion 42 to the end of the first adjustment case 44 in the first adjustment unit 40 is designed by the sum of the stretching distance a and the separation distance b, the separation distance b The first actuating rack gear 72 formed by) is engaged with the actuating pinion gear 71 and rotates the actuating pinion gear 71 as the first rod 41 slides in response to the separation distance b. Can be.

The second actuating rack gear 73 meshes with the actuating pinion gear 71. The second actuating rack gear 73 is spaced apart from the actuating pinion gear 71 and provided on the second rod 51 of the second regulating unit 50.

The second operating rack gear 73 is spaced apart from the center of the operating pinion gear 71 by the expansion distance a toward the second distribution line 21 in response to the expansion limit of the second distribution line 21, and then the separation distance. It is formed as long as (b).

At this time, the distance from the second support protrusion 52 to the end of the second adjustment case 54 in the second adjustment unit 50 is designed by the sum of the stretch distance (a) and the separation distance (b), separation distance (b) The second actuating rack gear 73 formed by) is engaged with the actuating pinion gear 71 and rotates the actuating pinion gear 71 as the second rod 51 slides in response to the separation distance b. Can be.

Separation pinion gear 74 is rotatably coupled to the drive housing (30). The separate pinion gear 74 is built in the drive housing 30 and is spaced apart from the actuating pinion gear 71 corresponding to the position of the jump wire connecting unit 60, and the drive housing 30 is centered on the pinion shaft 711. It can be rotatably coupled to).

The separate pinion gear 74 is rotated together with the actuating pinion gear 71.

When the jump line connecting unit 60 and the first jump line 13 are connected, the first separating member 75 is supported by the first jump line 13. The first separating member 75 is engaged with the separating pinion gear 74. When at least one of the first actuating rack gear 72 and the second actuating rack gear 73 is engaged with the actuating pinion gear 71 and the separating pinion gear 74 is rotated, the first separating member 75 is a jump line. The first jump line 13 is separated from the connecting unit 60.

The first separating member 75 may include a first separating rack gear 751, a first support bracket 752, and a first terminal detachable part 753.

The first separating rack gear 751 meshes with the separating pinion gear 74. The first separating rack gear 751 is slidably coupled to the driving enclosure 30.

The first support bracket 752 is supported by the first jump line 13 when the jump line connecting unit 60 and the first jump line 13 are connected to each other. The first support bracket 752 is integrally formed with the first separating rack gear 751.

The first terminal detachable portion 753 is formed through the first support bracket 752 in an open state toward the bottom. The first terminal detachable part 753 communicates with the jump line connecting unit 60 so that the first connecting terminal 131 can pass smoothly.

Then, when the separation pinion gear 74 is rotated while at least one of the first operation rack gear 72 and the second operation rack gear 73 is engaged with the operation pinion gear 71, the first separation rack gear 751 ) Is moved and the first support bracket 752 is spaced apart from the jump line connecting unit 60 to separate the first jump line 13 from the jump line connecting unit 60. The first connecting terminal 131 is separated from the first terminal detachable part 753 by the weight of the separated first jump line 13 to completely separate the first jump line 13 from the jump line connecting unit 60. have.

When the jump line connecting unit 60 and the second jump line 23 are connected to the second separating member 76, the second jump line 23 is supported. The second separating member 76 is engaged with the separating pinion gear 74. When at least one of the first actuating rack gear 72 and the second actuating rack gear 73 is engaged with the actuating pinion gear 71 and the separating pinion gear 74 is rotated, the second separating member 76 is a jump line. The second jump line 23 is separated from the connecting unit 60.

The second separating member 76 may include a second separating rack gear 761, a second support bracket 762, and a second terminal detachable part 763.

The second separating rack gear 761 is engaged with the separating pinion gear 74. The second separating rack gear 761 is slidably coupled to the drive housing 30.

The second support bracket 762 is supported by the second jump line 23 when the jump line connecting unit 60 and the second jump line 23 are connected to each other. The second support bracket 762 is integrally formed with the second separation rack gear 761.

The second terminal detachable part 763 is formed through the second support bracket 762 in an open state toward the bottom. The second terminal detachable part 763 communicates with the jump line connecting unit 60 so that the second connecting terminal 231 can pass smoothly.

Then, when the separation pinion gear 74 is rotated while at least one of the first operation rack gear 72 and the second operation rack gear 73 is engaged with the operation pinion gear 71, the second separation rack gear 761 is rotated. ) Slides and the second support bracket 762 is spaced apart from the jump line connecting unit 60 to separate the second jump line 23 from the jump line connecting unit 60. The second connecting terminal 231 is separated from the second terminal detachable part 763 by the weight of the separated second jump line 23 to completely separate the second jump line 23 from the jump line connecting unit 60. have.

In an embodiment of the present invention, the first separation rack gear 751 and the second separation rack gear 761 are pinion shafts 711 which are the central regions of the driving enclosure 30 based on the planar state as shown in FIG. 4. Eccentric symmetry may be achieved with respect to the pinion shaft 711 which is the center region of the driving enclosure 30.

According to the above-mentioned distribution line cable support apparatus of the distribution line, in the telephone pole, the connection state of the distribution line for power distribution is stabilized, and when the extension limit of the distribution line is exceeded, the connection of the distribution line can be released to cut off the power transfer.

In addition, through the jump line separating unit 70, it is possible to check the stretch limit of the distribution line, and to quickly respond to plastic deformation of the distribution line or breakage of the distribution line, and at least any one of the first and second distribution lines 11 and 21. When one is out of the stretch limit, the first jump line 13 and the second jump line 23 are to be separated from the jump line connection unit 60 at the same time.

In addition, it is possible to simplify the linkage with the jump line separating unit 70 through the first control unit 40, and stably elastically support the first distribution line (11).

In addition, it is possible to simplify the linkage with the jump line separating unit 70 through the second adjusting unit 50, and stably elastically support the second distribution line 21.

Further, the first jump line 13 and the second jump line 23 are electrically connected stably through the jump line connection unit 60, and the gripping force of the first jump line 13 and the second jump line 23 may be improved. Can be.

Although the preferred embodiments of the present invention have been described with reference to the drawings as described above, those skilled in the art can variously change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Can be modified or changed.

10: first frame 11: first power distribution line 12: first insulator
13: First jump line 131: First connection terminal 132: First engaging ring
20: second frame 21: second distribution line 22: second insulator
23: second jump line 231: second connection terminal 232: second locking ring
30: drive housing 40: first control unit 41: first rod
42: first support protrusion 43: first elastic member 44: first adjustment case
50: second adjusting unit 51: second rod 52: second support protrusion
53: second elastic member 54: second control case 60: jump wire connection unit
61: fixed terminal block 62: reciprocating terminal block 63: connection elastic member
70: jump line separating unit 71: operating pinion gear 711: pinion shaft
72: first operating rack gear 73: second operating rack gear 74: separate pinion gear
75: first separating member 751: first separating rack gear 752: first support bracket
753: first terminal detachable portion 76: second separating member 761: second separating rack gear
762: second support bracket 763: removable terminal 2
a: stretching distance b: separation distance

Claims (4)

A first frame disposed on one side of the telephone pole;
A second frame disposed on the other side of the telephone pole;
A driving housing disposed between the first frame and the second frame and supporting the first distribution line and the second distribution line;
A first control unit coupled to the drive housing so as to be slidably movable, the first control unit elastically supporting the first distribution line such that the first distribution line is stretchable and expandable;
A second adjusting unit spaced apart from the first adjusting unit so as to be slidably coupled to the driving housing, and elastically supporting the second distribution line so that the second distribution line is stretchable and expandable;
A jump line connecting unit provided in the driving enclosure and electrically connecting a first jump line branched from the first distribution line and a second jump line branched from the second distribution line; And
The first and second jump lines are provided from the jump line connecting unit by converting a rotational motion into a linear motion through engagement between at least one of the first control unit and the second control unit. And a jump line separating unit for separating,
The first control unit,
A first rod coupled to the driving housing so as to be slidably movable in a longitudinal direction of the first distribution line, one end of which is coupled to the first distribution line, and the other end of which includes a first support protrusion;
A first elastic member elastically pressing the first support protrusion based on the driving enclosure; And
And a first adjustment case protruding from the driving enclosure corresponding to the longitudinal direction of the first distribution line and forming a slide movement path of the first support protrusion.
The second control unit,
A second rod fitted to the driving housing so as to be slidably movable in correspondence with a length direction of the second distribution line, one end of which is coupled to the second distribution line, and the other end of which includes a second support protrusion;
A second elastic member elastically pressing the second support protrusion based on the driving enclosure; And
And a second adjustment case protruding from the driving housing corresponding to the length direction of the second distribution line and forming a slide movement path of the second support protrusion.
The jump line separating unit,
An actuating pinion gear rotatably coupled to the drive enclosure;
A first actuating rack gear meshed with the actuating pinion gear, the first actuating rack gear being spaced apart from the actuating pinion gear and provided on the first rod of the first adjusting unit;
A second actuating rack gear meshed with the actuating pinion gear, the second actuating rack gear being spaced apart from the actuating pinion gear and provided on the second rod of the second adjusting unit;
A separate pinion gear rotatably coupled to the drive housing so as to rotate together with the actuating pinion gear;
A first separation rack gear slidably coupled to the drive housing in engagement with the separation pinion gear; a first support bracket on which the first jump line is supported when the jump line connecting unit and the first jump line are connected; A first separating member including a first terminal detachable part formed through the first support bracket in an open state to communicate with the jump line connecting unit; And
A second separation rack gear slidably coupled to the drive housing in engagement with the separation pinion gear; a second support bracket on which the second jump line is supported when the jump line connecting unit and the second jump line are connected; And a second separating member including a second terminal detachable part formed through the second support bracket in an open state to communicate with the jump line connecting unit.
The first actuating rack gear is spaced apart from the center of the actuating pinion gear by the first telescopic distance toward the first power distribution line in response to the expansion limit of the first power distribution line, and is formed as long as the first separation distance.
The second operating rack gear is spaced apart from the center of the operating pinion gear by the second stretching distance toward the second distribution line in response to the expansion limit of the second distribution line, and is formed as long as the second separation distance.
Within the stretch limit of at least one of the first distribution line and the second distribution line, even if at least one of the first rod and the second rod is slid from the driving enclosure, the actuating pinion gear may be connected to the first actuating rack gear. And the second actuating rack gear are not engaged so that the actuating pinion gear does not rotate.
When at least one of the first distribution line and the second distribution line is out of the breaking limit or broken, the actuating pinion gear when at least one of the first rod and the second rod is slid in the drive housing As the at least one of the first actuating rack gear and the second actuating rack gear meshes with each other, the actuating pinion gear and the separating pinion gear are rotated, and the first separating rack gear and the second separating rack gear are connected to each other. And a first jump line and a second jump line, each of which is slidably moved from a driving enclosure and supported on the first support bracket and the second support bracket, respectively, from the jump line connection unit. The method of claim 1,
The jump line connection unit,
A fixed terminal block fixed to the driving enclosure;
A reciprocating terminal block which is installed to face the fixed terminal block and reciprocates from the driving housing toward the fixed terminal block; And
And a connecting elastic member for elastically pressing the reciprocating terminal block toward the fixed terminal block. delete delete

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