JP7495333B2 - Wire Support Device - Google Patents

Description

The present invention relates to an electric wire support device. More specifically, the present invention relates to an electric wire support device that supports an electric wire that is installed between steel towers while applying tension to the electric wire.

Conventionally, as described in Patent Document 1 and the like, a wire support device that supports an electric wire that is strung between steel towers while applying tension to the electric wire has been known that is equipped with an expandable vernier fitting for adjusting the slackness (i.e., the degree of slackness) of the electric wire.
A conventional electric wire support device (81) is provided between each end of a plurality of electric wires (51) and a steel tower (61) as shown in Fig. 14 and Fig. 15. Here, in the example shown in Fig. 14 and Fig. 15, the four electric wires (51) are arranged two above and two below, spaced apart from each other in the horizontal direction X and the vertical direction Z.

In Figures 14 and 15, a compression clamp (52) is fixed to the end of each electric wire (51) in advance at a factory on the ground or the like. A yoke (62) connected to an insulator device is provided on a steel tower (61). The electric wire support device (81) connects the compression clamp (52) of the electric wire (51) to the yoke (62) of the steel tower (61) so that electrical continuity is possible.

The electric wire support device (81) comprises a vernier fitting (82), a pair of first connecting fittings (83) on both sides of the vernier fitting (82), and a number of second connecting fittings (84), which are made of a conductive material, such as an iron-based material or alloy.

The vernier fitting (82) has a pair of long outer plates (82a), an inner plate (82b) slidably inserted into the gap between the pair of outer plates (82a), and a bolt (82c) for fixing the inner plate (82b) to the outer plate (82a). The bolt (82c) fixes the inner plate (82b) to the outer plate (82a) by passing through the through holes formed at different pitches in the outer plate (82a) and the inner plate (82b) at a position where these through holes are connected.

A pair of first connecting fittings (83) are linked to both ends of the vernier fitting (82). Specifically, as shown in Figs. 16 and 17, the first connecting fitting (83) has a U-shaped hook-shaped clevis portion (85). The clevis portion (85) has a link insertion groove (85a) into which a convex link portion (82d) of the mating member (here, the vernier fitting (82)) to which the first connecting fitting (83) is connected can be inserted. The convex link portion (82d) shown in Fig. 16 is provided at the end of the inner plate (82b) of the vernier fitting (82). The clevis portion (85) is linked to the link portion (82d) by a bolt or the like.
The first connecting fitting (83) is also formed with bolt insertion holes (86), (87) into which the bolts (75) for attaching the slack adjustment tool (71) can be inserted at a position spaced from the link insertion groove (85a) of the clevis portion (85). The bolt insertion hole (86) extends vertically (perpendicular to the plane of FIG. 16) and passes through the first connecting fitting (83). The bolt insertion hole (87) extends horizontally (perpendicular to the plane of FIG. 17) and passes through the first connecting fitting (83).

The second connecting fittings (84) connect the first connecting fitting (83) to the yoke (62) of the tower (61) and between the first connecting fitting (83) and the compression clamp (52) of the electric wire (51). Taking into consideration conditions such as the slack of the electric wire or the maximum length of the vernier fitting (82), a plurality of second connecting fittings (84) (three in Figs. 14-15) are provided between the first connecting fitting (83) and the compression clamp (52) of the electric wire (51). As shown in Figs. 16-17, a U-shaped clevis portion is formed at each end on both sides of the axial direction of the second connecting fitting (84). The U-shaped clevis portions on both sides of the second connecting fitting (84) are linked to the convex link portion (62a) of the yoke (62) and the convex link portion (82d) of the first connecting fitting (83).

The slack adjustment tool (71) has a configuration that allows the slack of the electric wire (51) to be adjusted by changing the distance between the pair of first connecting fittings (83). For example, a hydraulic tool is used for the slack adjustment tool (71), and specifically, the tool has a pair of swing arms (72), a support rod (73), and a hydraulic cylinder (74) (see FIG. 15). The pair of swing arms (72) are rotatably supported at both ends of the support rod (73). The tip ends of the pair of swing arms (72) are linked to the first connecting fitting (83) via bolts (75). The ends of the root side (i.e., the side farther from the first connecting fitting (83)) of the pair of swing arms (72) are connected to both ends of a hydraulic cylinder (74). The hydraulic cylinder (74) expands and contracts hydraulically to rotate the pair of swing arms (72) around pins provided at both ends of the support rod (73).

As shown in FIG. 16, the bolt (75) is inserted into the vertically extending bolt insertion hole (86), so that the slack adjustment tool (71) can be attached to the first connecting fitting (83) with the swing arm (72) extending in the horizontal direction X, as shown in FIG. 14. On the other hand, as shown in FIG. 17, the bolt (75) is inserted into the horizontally extending bolt insertion hole (87), so that the slack adjustment tool (71) can be attached to the first connecting fitting (83) with the swing arm (72) extending in the vertical direction Z, as shown in FIG. 15.

When adjusting the slack of the electric wire (51), first remove the bolt (82c) of the vernier fitting (82) to release the connection between the inner plate (82b) and the outer plate (82a), and then rotate the pair of swing arms (72) using the driving force of the hydraulic cylinder (74) of the slack adjustment tool (71) to change the distance between the pair of first connecting fittings (83) connected to the tip end of the pair of swing arms (72) via the bolt (75). This makes it possible to adjust the slack of the electric wire (51) to a predetermined slack. After adjusting the slack, attach the bolt (82c) of the vernier fitting (82) to connect the inner plate (82b) and the outer plate (82a), and the installation work of the electric wire (51) is completed.

In the prefabricated cable construction method, in which electric wires are cut to a specified length in advance in an above-ground factory and then erected between steel towers with compression clamps attached, there is a large variation in the elongation of the electric wires due to the effects of drawing the wires, etc.
On the other hand, since the first connecting fitting (83) has a structure in which the bolt insertion holes (86), (87) are formed at a position away from the link insertion groove (85a), it is difficult to shorten the length of the first connecting fitting (83). This limits the length of the vernier fitting that can be used. As a result, the range of adjustment of the slack of the electric wire (51) by the vernier fitting (82) is limited. This increases the effort required to adjust the slack by adding the second connecting fitting (84), making it difficult to improve workability.

Japanese Patent Application Laid-Open No. 6-169519

The present invention aims to solve the problems of the conventional technology described above by providing a wire support device that can expand the range of adjustment for the slack of the wire using vernier fittings, reduces the effort required to adjust the slack by adding additional connecting fittings, and improves workability.

The electric wire support device according to claim 1 of the present invention is an electric wire support device that supports an electric wire that is installed between steel towers while applying tension to the electric wire, and is equipped with a vernier fitting that is arranged between the end of the electric wire and the steel tower and has a configuration that allows the slack of the electric wire to be adjusted by changing the length in the direction in which the electric wire extends, and a connecting fitting that connects both ends of the vernier fitting to the end of the electric wire and the steel tower, respectively. The connecting fitting has a clevis part with a link insertion groove into which a convex link part provided on the mating member to which the connecting fitting is connected can be inserted, and the clevis part is linked and coupled to the link part so that the link part can rotate about an axis while inserted in the link insertion groove, and a rod-shaped member insertion space is formed at the back side of the link insertion groove in the clevis part, continuous with the link insertion groove, into which a rod-shaped member can be inserted to attach a slack adjustment tool to the connecting fitting.

The electric wire support device according to claim 2 of the present invention relates to the electric wire support device according to claim 1, in which the link portion has a contact portion with the connecting fitting, and when the link portion is inserted into the link insertion groove, the contact portion comes into contact with the connecting fitting, thereby restricting the axial rotation of the link portion relative to the connecting fitting.

The electric wire support device according to claim 3 of the present invention relates to the electric wire support device according to claim 2, in which the link portion is provided at the end of the vernier fitting.

The electric wire support device according to claim 4 of the present invention relates to an electric wire support device according to any one of claims 1 to 3, in which the vernier fitting is a pair of long outer plates arranged at a distance in the plate thickness direction, an inner plate slidably inserted into the gap between the pair of outer plates, and a rod-shaped fixing member for fixing the inner plate to the outer plate, the outer plate has a plurality of first through holes formed at intervals of a predetermined first pitch in the longitudinal direction of the outer plate and a plurality of first display parts formed at positions corresponding to the first through holes on the side edge of the outer plate, the inner plate has a plurality of second through holes formed at intervals of a predetermined second pitch different from the first pitch in the longitudinal direction of the inner plate and a plurality of second display parts formed at positions corresponding to the second through holes on the side edge of the inner plate, and the fixing member fixes the inner plate to the outer plate in a state where it penetrates the first through hole and the second through hole at a position where the first through hole and the second through hole are connected.

The electric wire support device according to claim 5 of the present invention relates to the electric wire support device according to any one of claims 1 to 4, in which the vernier fitting has a mounting hole to which the rod-shaped member can be attached.

According to the electric wire support device of claim 1 of the present invention, in the connecting fittings that connect both ends of the vernier fittings to the end of the electric wire and the steel tower, respectively, a rod-shaped member insertion space is formed at the back side of the link insertion groove of the clevis part of the connecting fitting, continuous with the link insertion groove, into which a rod-shaped member such as a bolt can be inserted to attach a slack adjustment tool to the connecting fitting. By forming the link insertion groove and the rod-shaped member insertion space in the connecting fitting in this way, it is possible to shorten the length of the connecting fitting. Therefore, it is possible to adopt a vernier fitting that is longer than conventional, and as a result, it is possible to expand the range of adjustment of the slack of the electric wire using the vernier fitting. This also reduces the effort required to adjust the slack by adding connecting fittings, improving workability.

According to the electric wire support device according to claim 2 of the present invention, the link portion has a contact portion with the connecting fitting. When the link portion is inserted into the link insertion groove, the contact portion of the link portion comes into contact with the connecting fitting, thereby restricting the axial rotation of the link portion relative to the connecting fitting. This eliminates the need for the worker to support the link portion so that it does not rotate axially relative to the connecting fitting during the slack adjustment work, improving workability.

According to the electric wire support device of claim 3 of the present invention, when the link portion provided at the end of the vernier fitting is inserted into the link insertion groove, the contact portion of the link portion comes into contact with the connecting fitting, and the axial rotation of the link portion and the vernier fitting having it relative to the connecting fitting is restricted. This eliminates the need for the worker to support the vernier fitting so that it does not rotate axially relative to the connecting fitting during the slack adjustment work, improving the workability of adjusting the length of the vernier fitting.

According to the wire support device of the fourth aspect of the present invention, a plurality of first indication portions are formed on the side edge of the outer plate of the vernier fitting at positions corresponding to the plurality of first through holes, while a plurality of second indication portions are formed on the side edge of the inner plate at positions corresponding to the plurality of second through holes.
When the length of the vernier fitting is changed by sliding the inner plate of the vernier fitting between the pair of outer plates to adjust the slack of the electric wire, the pitches of the first through holes formed in the pair of outer plates and the pitches of the second through holes formed in the inner plate are different, so that the position where the first through hole and the second through hole communicate with each other is uniquely determined. The position where the first through hole and the second through hole communicate with each other can be easily confirmed from the outside by finding the position where the first marking portion formed on the side edge of the outer plate and the second marking portion formed on the side edge of the inner plate match. This makes it possible to improve the workability of the work of fixing the inner plate to the outer plate by passing a fixing member such as a bolt through the first through hole and the second through hole that communicate with each other.

According to the electric wire support device of claim 5 of the present invention, the rod-shaped member for attaching the slack adjustment tool can be attached not only to the rod-shaped member insertion space of the connecting fitting, but also to the attachment hole formed in the vernier fitting. Therefore, by increasing the number of positions where the slack adjustment tool can be attached, it is possible to further expand the slack adjustment range.

1 is a plan view showing a state in which an electric wire support device according to a first embodiment of the present invention is arranged between an electric wire and a steel tower. FIG. FIG. 2 is a side view of the electric wire support device, electric wires, and tower of FIG. 2 is an enlarged plan view showing a state in which a bolt for attaching a slack adjustment tool is inserted into a bolt insertion space extending vertically in a first clevis portion of the first connecting fitting in FIG. 1 . FIG. 2 is an enlarged side view showing a state in which a bolt is inserted into a horizontally extending bolt insertion space of a second clevis portion of the first connecting fitting in FIG. 1 . FIG. 10A is an enlarged plan view of the vicinity of a first connecting portion, and FIG. 10B is a cross-sectional explanatory view showing a state in which the contact portion of the link portion and the bolt are in contact over a wide area inside the first connecting portion, in a wire support device according to a second embodiment of the present invention. FIG. 11 is an explanatory cross-sectional view showing a comparative example of the second embodiment, illustrating that the contact area between the link portion and the bolt inside the first connecting portion is small. 10A and 10B are diagrams showing a structure in which a first display portion is formed on a side edge of an outer plate of a vernier fitting in an electric wire support device according to a third embodiment of the present invention, in which (a) is a front view of the outer plate, and (b) is a top view thereof. 13A and 13B are diagrams showing a structure in which a second display portion is formed on a side edge of an inner plate of the vernier fitting in the above-mentioned embodiment 3, in which (a) is a front view of the inner plate, and (b) is a top view thereof. 11A and 11B are diagrams showing a state in which the first through hole and the first indicating portion of the outer plate in the above-mentioned embodiment 3 are aligned with the second through hole and the second indicating portion of the inner plate, where (a) is a top view of the vernier fitting, and (b) is a front view of the vernier fitting. FIG. 10 is a side view showing a structure in which a bolt mounting hole is added to a vernier fitting in an electric wire support device according to a fourth embodiment of the present invention. 13A and 13B are diagrams showing a state in which an electric wire support device according to a seventh embodiment of the present invention is arranged between an electric wire and a steel tower, in which (a) is a plan view and (b) is a side view. 13A and 13B are diagrams showing a state in which an electric wire support device according to an eighth embodiment of the present invention is arranged between an electric wire and a steel tower, where (a) is a plan view and (b) is a side view. 13A and 13B are diagrams showing a state in which an electric wire support device according to a ninth embodiment of the present invention is arranged between an electric wire and a steel tower, where (a) is a plan view and (b) is a side view. FIG. 1 is a plan view showing a state in which a plurality of electric wires are connected to a yoke of a steel tower via a conventional electric wire support device. FIG. 15 is a side view of the wire support device, wires, and yoke of FIG. 14. FIG. 15 is an enlarged plan view of the first connecting fitting and its vicinity shown in FIG. FIG. 16 is an enlarged side view of the first connecting fitting and its vicinity shown in FIG.

Next, an embodiment of the electric wire support device of the present invention will be described in more detail with reference to the drawings.
As shown in Figures 1 and 2, the electric wire support device (1) of this embodiment is a device that supports an electric wire (51) that is laid between steel towers (61) while applying tension to the electric wire (51).

The electric wire support device (1) is provided between each end of a plurality of electric wires (51) and a steel tower (61) in the same manner as the conventional electric wire support device (81) shown in Figs. 14-15. Here, in the embodiment shown in Figs. 1-2, as in the example of Figs. 14-15 above, the four electric wires (51) are arranged two above and two below, spaced apart from each other in the horizontal direction X and the vertical direction Z. A compression clamp (52) is fixed to the end of each electric wire (51) in advance at a factory on the ground or the like. The steel tower (61) is provided with a yoke (62) connected to an insulator device. The electric wire support device (1) electrically connects the compression clamp (52) of the electric wire (51) to the yoke (62) of the steel tower (61).

The electric wire support device (1) comprises a vernier fitting (2), a pair of first connecting fittings (3) on both sides of the vernier fitting (2), and a number of second connecting fittings (4), which are made of conductive materials, such as iron-based materials or alloys.

The vernier fitting (2) is arranged between the end of the electric wire (51) and the steel tower (61), and has a configuration that makes it possible to adjust the slack of the electric wire (51) by changing its length in the direction in which the electric wire (51) extends.
The vernier fitting (2) has basically the same configuration as the vernier fitting (82) shown in Figures 14 to 17 above.
Specifically, as shown in Figures 1 to 4, the vernier fitting (2) is a pair of long outer plates (2a) spaced apart in the plate thickness direction, and includes the pair of outer plates (2a) spaced apart in the plate thickness direction, an inner plate (2b) slidably inserted into the gap between the pair of outer plates (2a), and a bolt (2c) which is a rod-shaped fixing member for fixing the inner plate (2b) to the outer plate (2a). Note that a pin or the like may be used as the rod-shaped fixing member in addition to the bolt (2c).

Each outer plate (2a) has a plurality of first through holes (2e) formed at intervals of a predetermined first pitch (p1) in the longitudinal direction of the outer plate (2a).
On the other hand, a plurality of second through holes (2f) are formed in the inner plate (2b) at intervals of a predetermined second pitch (p2) different from the above-mentioned first pitch (p1) in the longitudinal direction of the inner plate (2b).

The bolt (2c) fixes the inner plate (2b) to the outer plate (2a) in a state where the first through hole (2e) and the second through hole (2f), which are formed at different pitches in the outer plate (2a) and the inner plate (2b), communicate with each other, by passing through these through holes (2e) and (2f).

The first connecting fitting (3) connects both ends of the vernier fitting (2) to the end of the electric wire (51) and the steel tower (61), respectively.
The first connecting fitting (3) has a first clevis portion (11) and a second clevis portion (12) so that it can be connected to a mating member on both axial sides (see FIG. 3). The first clevis portion (11) and the second clevis portion (12) are both U-shaped and hook-shaped portions, and are disposed at positions perpendicular to each other (i.e., shifted by 90 degrees) with respect to the axial direction (i.e., the longitudinal direction) of the first connecting fitting (3).

As shown in Figure 3, the first clevis portion (11) has a link insertion groove (11a) into which a convex link portion (2d) provided on a mating member (here, the inner plate (2b) of the vernier fitting (2)) to which the first connecting fitting (3) is connected can be inserted. The link insertion groove (11a) of the first clevis portion (11) opens in the axial direction (i.e., the longitudinal direction) of the first connecting fitting (3) and extends vertically (perpendicular to the plane of the paper in Figure 3).
The first clevis portion (11) is linked and coupled to the link portion (2d) of the inner plate (2b) so that the link portion (2d) can rotate about its axis while being inserted into the link insertion groove (11a). In other words, a rod-shaped member such as a bolt passes through the link portion (2d) and the first clevis portion (11), so that the link portion (2d) can rotate around the bolt.

A bolt insertion space (11b) is further formed adjacent to the link insertion groove (11a) at the back side of the link insertion groove (11a) in the first clevis portion (11), into which a bolt (75), which is a type of rod-shaped member, can be inserted in order to attach the slack adjustment tool (71) to the first connecting fitting (3). Note that as the rod-shaped member, a rod-shaped body such as a pin may be used in addition to the bolt (75).
The bolt insertion space (11b) of the first clevis portion (11), like the link insertion groove (11a), extends vertically (perpendicular to the plane of the paper in FIG. 3) and penetrates the first connecting fitting (3).

On the other hand, the second clevis portion (12), as shown in Fig. 4, has a link insertion groove (12a) into which a convex link portion (4a) provided on a mating member (here, the second connecting fitting (4)) to which the first connecting fitting (3) is connected can be inserted. The link insertion groove (12a) of the second clevis portion (12) opens in the axial direction (i.e., the longitudinal direction) of the first connecting fitting (3) and extends horizontally (perpendicular to the plane of the paper in Fig. 4).
As with the first clevis portion (11), the second clevis portion (12) is linked and connected to the link portion (4a) of the second connecting fitting (4) so that the link portion (4a) can rotate about its axis while inserted into the link insertion groove (12a).

At the rear side of the link insertion groove (12a) in the second clevis portion (12), similar to the first clevis portion (11), a bolt insertion space (12b) is further formed continuous with the link insertion groove (12a), into which a bolt (75) can be inserted to attach the slack adjustment tool (71) to the first connecting fitting (3).
The bolt insertion space (12b) of the second clevis portion (12), like the link insertion groove (12a), extends horizontally (perpendicular to the plane of the paper in FIG. 4) and penetrates the first connecting fitting (3).

The second connecting fittings (4) connect between the first connecting fitting (3) and the yoke (62) of the steel tower (61), and between the first connecting fitting (3) and the compression clamp (52) of the electric wire (51). As shown in Figs. 1 to 4, the second connecting fitting (4) has a U-shaped clevis portion formed at one end in the axial direction. The convex link portion (62a) of the yoke (62) or the convex link portion (52a) of the compression clamp (52), which is the mating member, is linked to this clevis portion. The other end of the second connecting fitting (4) has a convex link portion (4a). This link portion (4a) is inserted into the link insertion groove (12a) of the second clevis portion (12) of the first connecting fitting (3) described above, and is linked to the second clevis portion (12).

The slack adjustment tool (71) has a configuration that allows the slack of the electric wire (51) to be adjusted by changing the distance between a pair of first connecting fittings (3). As in the above-mentioned Figs. 14 and 15, for example, a hydraulic tool is used for the slack adjustment tool (71), and specifically, the slack adjustment tool (71) has a pair of swing arms (72), a support rod (73), and a hydraulic cylinder (74).

The slack adjustment tool (71) may be a tool of other configurations than a hydraulic tool that adjusts slack using hydraulic pressure. For example, a tool such as a lever block (registered trademark) that has a lever that an operator manually operates to adjust the slack may also be used as the slack adjustment tool.

As shown in FIG. 3, the bolt (75) is inserted into the bolt insertion space (11b) extending vertically at the rear side of the first clevis portion (11), so that the slack adjustment tool (71) can be attached to the first connecting fitting (3) with the swing arm (72) of the slack adjustment tool (71) extending in the horizontal direction X as shown in FIG. 1. Since the link portion (2d) closes the link insertion groove (11a), there is no risk of the bolt (75) inserted into the bolt insertion space (11b) falling out of the first connecting fitting (3) through the link insertion groove (11a).

On the other hand, as shown in FIG. 4, by inserting the bolt (75) into the bolt insertion space (12b) extending horizontally at the rear side of the second clevis portion (12), it is possible to attach the slack adjustment tool (71) to the first connecting fitting (3) with the swing arm (72) extending in the vertical direction Z, as shown in FIG. 2. In this case, too, since the link portion (4a) closes the link insertion groove (12a), there is no risk of the bolt (75) inserted into the bolt insertion space (12b) falling out of the first connecting fitting (3) through the link insertion groove (12a).

The method of adjusting the slack of the electric wire (51) is performed in the same manner as in the conventional method, as shown in Figs. 14 and 15 above. That is, first, the bolt (2c) of the vernier fitting (2) is removed to release the connection between the inner plate (2b) and the outer plate (2a), and then the pair of swing arms (72) is rotated by the driving force of the hydraulic cylinder (74) of the slack adjustment tool (71) to change the distance between the pair of first connecting fittings (3) connected to the tip end of the pair of swing arms (72) via the bolt (75). This makes it possible to adjust the slack of the electric wire (51) to a predetermined slack. After adjusting the slack, the bolt (2c) of the vernier fitting (2) is attached to connect the inner plate (2b) and the outer plate (2a), and the installation work of the electric wire (51) is completed.

As described above, in the electric wire support device (1) according to the first embodiment of the present invention, in the first connecting fitting (3) that connects both ends of the vernier fitting (2) to the end of the electric wire (51) and the steel tower (61), respectively, a bolt insertion space (11b) is formed at the back side of the link insertion groove (11a) of the first clevis part (11) of the first connecting fitting (3), which is continuous with the link insertion groove (11a) and into which a bolt (75) can be inserted to attach the slack adjustment tool (71) to the first connecting fitting (3). By forming the link insertion groove (11a) and the bolt insertion space (11b) in the first connecting fitting (3) in this way, it is possible to shorten the length of the first connecting fitting (3). In addition, a bolt insertion space (12b) is formed on the rear side of the link insertion groove (12a) of the second clevis portion (12), which is continuous with the link insertion groove (12a), and this also makes it possible to shorten the length of the first connecting fitting (3). This makes it possible to use a longer vernier fitting (2) than before, and as a result, it is possible to expand the range of adjustment of the slack of the electric wire (51) using the vernier fitting (2). This also reduces the effort required to adjust the slack by adding more first connecting fittings (3), improving workability.

[Embodiment 2]
In the electric wire support device (1) according to the second embodiment of the present invention, as shown in Fig. 5, a contact portion (2g) with the first connecting fitting (3) is formed on the link portion (2d) at the end of the inner plate (2b) of the vernier fitting (2). Note that other configurations of the electric wire support device (1) are the same as those of the first embodiment, and therefore description thereof will be omitted.

When the contact portion (2g) comes into contact with the first connecting fitting (3), the relative axial rotation of the link portion (2d) with respect to the first connecting fitting (3) around the bolt (13) is restricted.

In the electric wire support device (1) according to the second embodiment, the link portion (2d) has a contact portion (2g) with the first connecting fitting (3). When the link portion (2d) is inserted into the link insertion groove (11a), the contact portion (2g) of the link portion (2d) comes into contact with the first connecting fitting (3), thereby restricting the relative axial rotation of the link portion (2d) with respect to the first connecting fitting (3) about the bolt (13) as the center of rotation. This eliminates the need for the worker to support the link portion (2d) so that it does not rotate axially with respect to the first connecting fitting (3) during the slack adjustment work, improving workability.

In particular, in the second embodiment, the link portion (2d) is provided at the end of the vernier fitting (2) (specifically, at the end of the inner plate (2b)). Therefore, when the link portion (2d) provided at the end of the vernier fitting (2) is inserted into the link insertion groove (11a), the contact portion (2g) of the link portion (2d) comes into contact with the first connecting fitting (3), and the axial rotation of the link portion (2d) and the inner plate (2b) of the vernier fitting (2) having the link portion (2d) about the bolt (13) relative to the first connecting fitting (3) is restricted. This eliminates the need for the worker to support the inner plate (2b) of the vernier fitting (2) so that it does not rotate about its axis relative to the first connecting fitting (3) during the slack adjustment work, improving the workability of adjusting the length of the vernier fitting (2).

Here, as a comparative example of the second embodiment, as shown in FIG. 6, when the link portion (2d) at the end of the vernier fitting (2) has a shape that does not have a contact portion, the arc-shaped outer periphery of the link portion (2d) cannot contact the first connecting fitting (3). Therefore, the link portion (2d) and the vernier fitting (2) having it may rotate on their axis relative to the first connecting fitting (3). Therefore, the worker needs to support the link portion (2d) so that it does not rotate on its axis relative to the first connecting fitting (3) during the slack adjustment work, which makes it difficult to improve workability. Considering these points, it can be understood that the axial rotation of the link portion (2d) and the vernier fitting (2) having it during the slack adjustment work can be effectively restricted by the link portion (2d) having a contact portion (2g) as in the electric wire support device of the second embodiment described above.

In the present invention, the contact portion is not limited to being formed on the link portion (2d) provided at the end of the vernier fitting (2), but may be another link portion capable of contacting the first connecting fitting (3), for example, the contact portion may be the link portion (4a) (see FIG. 4) of the second connecting fitting (4). Even in this case, the axial rotation of the link (4a) can be restricted by the contact portion formed on the link portion (4a) coming into contact with the first connecting fitting (3).
The shape of the contact portion (2g) is not particularly limited, and may be any shape as long as the contact portion (2g) comes into contact with the first connecting fitting (3) such that the axial rotation of the link portion (2d) and the inner plate (2b) of the vernier fitting (2) having the link portion (2d) about the bolt (13) relative to the first connecting fitting (3) is restricted.

[Embodiment 3]
In the electric wire support device according to the third embodiment of the present invention, as shown in FIGS. 9(a) and 9(b), groove-shaped first and second indication portions (2h and 2j) are formed on the outer and inner plates (2a and 2b) of the vernier fitting (2) so that the position where the first through hole (2e) and the second through hole (2f) communicate with each other can be easily confirmed from the outside.

That is, as shown in Figures 7(a) and (b), in addition to the multiple first through holes (2e) formed at intervals of a predetermined first pitch in the longitudinal direction of the outer plate (2a) as described above, the outer plate (2a) has multiple first display portions (2h) formed at positions corresponding to the first through holes (2e) on the side edges of the outer plate (2a).

The first indicia (2h) are grooves formed on the side edges of the outer plate (2a), specifically, on both sides in the width direction of the outer plate (2a) (both the top and bottom in FIG. 7(a)) so as to sandwich the first through hole (2e). Note that the first indicia (2h) may have a shape other than a groove, such as a dot or a triangle, as long as it indicates the position of the first through hole (2e).
Further, on the side edge of the outer plate (2a), a number mark (2i) such as "1" or "2" is formed as a first mark to distinguish each of the first display portions (2h).

On the other hand, as shown in Figures 8(a) and 8(b), in addition to the multiple second through holes (2f) formed at intervals of a predetermined second pitch different from the first pitch in the longitudinal direction of the inner plate (2b) as described above, the inner plate (2b) has multiple second display portions (2j) formed at positions corresponding to the second through holes (2f) on the side edges of the inner plate (2b).

The second indicia (2j), like the above-mentioned first indicia (2h), are grooves formed on the side edges of the inner plate (2b), specifically, on both sides in the width direction of the inner plate (2b) (both the top and bottom in FIG. 8(a)) so as to sandwich the second through hole (2f). Note that the second indicia (2j) may also be in the form of a dot or the like other than a groove, as long as it indicates the position of the second through hole (2f).
Further, a second mark, for example an English letter mark (2k) such as "A" or "B" is formed on the side edge of the inner plate (2b) to distinguish the individual second display portions (2j).

From the combination of the number marks (2i) on the outer plate (2a) and the alphabet marks (2k) on the inner plate (2b), it is possible to easily grasp the adjustment amount for adjusting the slack of the electric wire (for example, -10 mm for the combination of "3" and "D", 10 mm for the combination of "5" and "F").
It is preferable to prepare a conversion table in advance so that the amount of slack adjustment can be more easily understood from the combination of the number mark (2i) and the alphabet mark (2k). For example, the conversion table may be arranged by arranging the number mark (2i) vertically and the alphabet mark (2k) horizontally, and displaying the amount of slack adjustment corresponding to each combination on a matrix composed of the number mark (2i) and the alphabet mark (2k). By looking at such a conversion table, it is possible to easily understand the amount of slack adjustment from the combination of the number mark (2i) and the alphabet mark (2k).
The other configuration of the vernier fitting (2) is the same as that of the first embodiment, so the description will be omitted.

In the electric wire support device (1) according to the third embodiment, a plurality of first indication portions (2h) are formed on the outer plate (2a) of the vernier fitting (2) at positions corresponding to the plurality of first through holes (2e) on its side edge, while a plurality of second indication portions (2j) are formed on the inner plate (2b) at positions corresponding to the plurality of second through holes (2f) on its side edge.
9(a) and (b), when the length of the vernier fitting (2) is changed by sliding the inner plate (2b) of the vernier fitting (2) between the pair of outer plates (2a) in order to adjust the slackness of the electric wire (51), the pitches of the first through holes (2e) formed in the pair of outer plates (2a) and the pitches of the second through holes (2f) formed in the inner plate (2b) are different, so that the position where the first through holes (2e) and the second through holes (2f) communicate with each other is uniquely determined. The position where the first through holes (2e) and the second through holes (2f) communicate with each other can be easily confirmed from the outside by finding the position where the first marking portion (2h) formed on the side edge of the outer plate (2a) and the second marking portion (2j) formed on the side edge of the inner plate (2b) coincide with each other. This makes it possible to improve the workability of fixing the inner plate (2b) to the outer plate (2a) by passing a fixing member such as a bolt (2c) through the first through hole (2e) and the second through hole (2f), which are connected to each other.

[Embodiment 4]
In an electric wire support device according to a fourth embodiment of the present invention shown in Fig. 10, in order to increase the positions for attaching bolts (75), in addition to the above-mentioned first connecting fitting (3), mounting holes (2l) capable of attaching bolts (75) are formed in the vernier fitting (2). A plurality of mounting holes (2l) are formed, for example, in either the outer plate (2a) or the inner plate (2b) of the vernier fitting (2) lined up in the longitudinal direction of the vernier fitting (2).
In the electric wire support device (1) according to the fourth embodiment, the bolt (75) for attaching the slack adjustment tool (71) can be attached not only to the bolt insertion spaces (11b, 12b) of the first connecting fitting (3) but also to the attachment hole (2l) formed in the vernier fitting (2). Therefore, by increasing the number of positions at which the slack adjustment tool (71) can be attached, it is possible to further expand the slack adjustment range.

[Embodiment 5]
In the above-mentioned first embodiment, the first connecting fittings (3) are connected to both ends of the vernier fitting (2), but the present invention is not limited to this. Either of the first connecting fittings (3) at both ends may be combined with the end of the vernier fitting (2). In this case, it is possible to reduce the number of parts of the electric wire support device.

[Embodiment 6]
In the above embodiment 1, the bolt insertion spaces (11b), (12b) are formed contiguous to the rear side of the link insertion grooves (11a), (12a) in the first and second clevis portions (11), (12) of the first connecting fitting (3) at both ends of the vernier fitting (2), but the present invention is not limited to this, and a bolt insertion space may be formed contiguous to the rear side of the link insertion groove in the clevis portion of the second connecting fitting (4). Even in this case, the shortening of the length of the second connecting fitting (4) makes it possible to employ a long vernier fitting (2), and as a result, it becomes possible to expand the range of adjustment of the slackness of the electric wire (51) by the vernier fitting (2).

[Embodiment 7]
In the electric wire support device of embodiment 7 of the present invention shown in Figure 11, in order to increase the number of positions for attaching the bolt (75), in addition to the first connecting fitting (3), a mounting hole (2l) capable of attaching the bolt (75) is formed in the second connecting fitting (4) (see Figure 11 (a)).
In the electric wire support device (1) according to the seventh embodiment, the bolt (75) for attaching the slack adjustment tool (71) can be attached not only to the bolt insertion space (11b, 12b) of the first connecting fitting (3) but also to the attachment hole (2l) formed in the second connecting fitting (4). Therefore, by increasing the number of positions at which the slack adjustment tool (71) can be attached, it is possible to further expand the slack adjustment range.
As shown in Fig. 11(b), when supporting four electric wires, the appropriate slack differs between the upper two electric wires and the lower two electric wires, so the overall length of the electric wire support device supporting the lower two electric wires is usually made longer than the overall length of the upper electric wire support device. Therefore, an extension metal fitting (9) may be provided to increase the overall length of the lower electric wire support device.

[Embodiment 8]
In the electric wire support device of embodiment 8 of the present invention shown in Figure 12, in order to increase the number of positions for attaching the bolt (75), in addition to the first connecting fitting (3), a mounting hole (2l) capable of attaching the bolt (75) is formed in the second connecting fitting (4) (see Figure 12 (a)).
Furthermore, in the electric wire support device (1) of embodiment 8, the first connecting fitting (3) on the steel tower (61) side and the second connecting fitting (4) are spaced apart, and the first connecting fitting (3) is approximately H-shaped when viewed in a plane.
In the electric wire support device (1) according to the eighth embodiment, the bolt (75) for attaching the slack adjustment tool (71) can be attached not only to the bolt insertion space (11b, 12b) of the first connecting fitting (3) but also to the attachment hole (2l) formed in the second connecting fitting (4). Therefore, by increasing the number of positions at which the slack adjustment tool (71) can be attached, it is possible to further expand the slack adjustment range.
As shown in Fig. 12(b), when supporting four electric wires, the appropriate slack differs between the upper two electric wires and the lower two electric wires, so the overall length of the electric wire support device supporting the lower two electric wires is usually made longer than the overall length of the upper electric wire support device. Therefore, an extension metal fitting (9) may be provided to increase the overall length of the lower electric wire support device.

[Embodiment 9]
An electric wire support device (1) according to a ninth embodiment of the present invention shown in FIG. 13 is an electric wire support device for supporting two electric wires.
In the wire support device of embodiment 9, in order to increase the number of positions for attaching the bolts (75), in addition to the first connecting fitting (3), the second connecting fitting (4) has an attachment hole (2l) capable of attaching the bolt (75) (see Figure 13 (a)).
In the electric wire support device (1) according to the ninth embodiment, the bolt (75) for attaching the slack adjustment tool (71) can be attached not only to the bolt insertion space (11b, 12b) of the first connecting fitting (3) but also to the attachment hole (2l) formed in the second connecting fitting (4). Therefore, by increasing the number of positions at which the slack adjustment tool (71) can be attached, it is possible to further expand the slack adjustment range.

The present invention can be widely applied to electric wire support devices that support electric wires that are installed between steel towers while applying tension to the electric wires. With the present invention, the link insertion groove and rod-shaped member insertion space in the connecting fitting are formed continuously, making it possible to shorten the length of the connecting fitting. This makes it possible to employ vernier fittings that are longer than conventional ones, and as a result, it becomes possible to expand the range of adjustment for the slack of the electric wire using the vernier fittings. This also reduces the effort required to adjust the slack by adding connecting fittings, improving workability.

1 Electric wire support device 2 Vernier bracket 2a Outer plate 2b Inner plate 2c Bolt (fixing member)
2d Link portion 2e First through hole 2f Second through hole 2g Contact portion 2h First display portion 2i Number mark 2j Second display portion 2k Alphabetical mark 3 First connecting fitting 4 Second connecting fitting 11 First clevis portion 11a Link insertion portion 11b Bolt insertion portion 12 Second clevis portion 12a Link insertion portion 12b Bolt insertion portion 13 Bolt 51 Electric wire 52 Compression clamp 52a Link portion 61 Steel tower 62 Yoke 62a Link portion 71 Slack adjustment tool 72 Swing arm 73 Support rod 74 Hydraulic cylinder

Claims (5)

A wire support device that supports an electric wire that is installed between steel towers while applying tension to the electric wire,
A vernier fitting is disposed between an end of the electric wire and the steel tower, and has a configuration capable of adjusting the slack of the electric wire by changing a length in a direction in which the electric wire extends;
a connecting fitting for connecting both ends of the vernier fitting to the end of the electric wire and the steel tower, respectively;
Equipped with
The connecting fitting has a clevis portion having a link insertion groove into which a convex link portion provided on a mating member to which the connecting fitting is connected can be inserted,
the clevis portion is linked and coupled to the link portion so that the link portion can rotate axially while being inserted into the link insertion groove,
A rod-shaped member insertion space is formed adjacent to the link insertion groove at the back side of the clevis portion, into which a rod-shaped member can be inserted in order to attach a slack adjustment tool to the connecting fitting.
1. A wire support device comprising: The link portion has a contact portion with the connecting fitting,
When the link portion is inserted into the link insertion groove, the contact portion comes into contact with the connecting fitting, thereby restricting relative axial rotation of the link portion with respect to the connecting fitting.
2. The wire support device according to claim 1. The link portion is provided at an end of the vernier fitting.
3. The wire support device according to claim 2. The vernier fitting is
A pair of long outer plates arranged apart from each other in a plate thickness direction;
an inner plate slidably inserted into a gap between the pair of outer plates;
a rod-shaped fixing member for fixing the inner plate to the outer plate,
The outer plate is
a plurality of first through holes formed at intervals of a predetermined first pitch in the longitudinal direction of the outer plate, and a plurality of first indication portions formed at positions corresponding to the first through holes on a side edge of the outer plate,
The inner plate is
a plurality of second through holes formed in the longitudinal direction of the inner plate at intervals of a second pitch different from the first pitch;
a plurality of second indicia portions formed at positions corresponding to the second through holes on a side edge of the inner plate;
the fixing member fixes the inner plate to the outer plate in a state in which the fixing member penetrates the first through hole and the second through hole at a position where the first through hole and the second through hole are in communication with each other;
The wire support device according to any one of claims 1 to 3. The vernier fitting has a mounting hole formed therein to which the rod-shaped member can be attached.
The wire support device according to any one of claims 1 to 4.