JP2017060377A - Support structure for power cable intermediate connection box - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a support structure for a power cable intermediate connection box that absorbs extension of power cable and that is able to decrease a difference between left and light axial forces.SOLUTION: A pair of support members 9 are joined to upright metal fittings 5 at a predetermined interval. That is, the support members 9 are fixed to a manhole wall 7. The vicinities of the upper end parts of a pair of suspension plates 11 are connected to each support member 9. The support member 9 and each suspension plate 11 are connected via a shield bearing 13. A connection-box fixing frame 15 is connected to the vicinities of the lower end parts of the suspension plates 11 via the shield bearings 13 and shafts 17. That is, the connection-box fixing frame 15 is suspended from the support member 9 by the suspension plates 11, and the suspension plates 11 are rotatably mounted on the support member 9 and the connection-box fixing frame 15, thereby connecting the support member 9 and the connection-box fixing frame 15.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a support structure for a power cable intermediate connection box, particularly in a manhole.

  Electric power cables laid in underground pipes are connected and used in manholes arranged at a predetermined interval. Such a power cable may extend due to heat generated by energization. For this reason, in a manhole, in order to absorb the extension of an electric power cable, the offset part which bent the electric power cable in S shape is formed (for example, patent documents 1).

  For example, in the case of a CV cable (cross-linked polyethylene insulated cable), an intermediate connection box of the power cable is fixed in the manhole, and the extension of the power cable is absorbed by the above-described change in the curvature of the offset portion. In this way, the thermal stress applied to the power cable can be relaxed by absorbing the extension of the power cable.

  In such a method, the extension of the power cable from the pipe line part is reduced by reinforcing the power cable in the offset part to increase the reaction force, or a spring is provided in the offset part. A method of using the reaction force is proposed (Patent Document 2).

JP 60-106314 A Japanese Patent Laid-Open No. 61-9114

  However, in the absorption of the extension of the power cable by the conventional offset portion, different axial forces may be received from the left and right of the intermediate connection box due to differences in the extension conditions of the left and right power cables. For example, when the lengths of the power cables connected to the left and right of the intermediate connection box are different, or when the shape of the offset portion in the manhole is different, the extension amount of the power cable may be different on the left and right.

  As described above, when the extension amount of the power cable is different between right and left, the intermediate connection box is in a state where an axial force according to the difference in extension amount is applied. That is, a force is applied in the axial direction to the reinforcing insulator of the intermediate connection box.

  In particular, as described above, when the reaction force of the offset portion is increased, the axial force acting on the intermediate connection box increases as the reaction force increases. For this reason, an excessive axial force may be applied to the fixed intermediate junction box.

  For example, in a rubber block type joint box (RBJ: Rubber Block Joint), the inner conductor connecting portion and the outer reinforcing insulator are not fixed in the axial direction, so the reinforcing insulator is fixed. Thus, when an excessive axial force is applied to the conductor connecting portion from one side, there is a possibility that an interface shift between the reinforcing insulator and the conductor occurs. When such an interface shift occurs, it causes a problem in electrical performance.

  However, it is difficult to completely match the shapes of the left and right offset portions of the intermediate connection box on the left and right of the intermediate connection box due to the layout in the manhole. In addition, it is difficult to completely match the extension amount of the power cable on the left and right sides of the intermediate connection box.

  The present invention has been made in view of such problems, and provides a support structure for a power cable intermediate connection box that can absorb the extension of the power cable and reduce the difference in axial force between the left and right. With the goal.

  In order to achieve the above-described object, the present invention provides a support structure for a power cable intermediate connection box, which is fixed to the power cable intermediate connection box, and is connected to both sides of the power cable intermediate connection box. And a moving mechanism capable of moving the fixed base in the axial direction of the power cable when receiving a force from the power cable. .

  The moving mechanism includes a support member fixed to a wall surface, and a suspension plate that is rotatably attached to the support member and the fixed mount, and connects the support member and the fixed mount. The gantry may be suspended from the support member by the suspension plate, and the suspension plate that supports the fixed gantry may be rotatable.

  In this case, it is desirable that the suspension plate is connected to the support member and the fixed mount via a shield bearing.

  The moving mechanism includes a fixing member fixed to a wall surface, and a support member rotatably attached to the fixing member with the fixing member as a fulcrum, and the fixed mount is rotatable with respect to the support member. It may be attached to.

  In this case, it is preferable that the support member is connected to the fixed member and the fixed mount via a shield bearing.

  The power cable intermediate connection box may be a rubber block type connection box.

  According to this invention, since it has a moving mechanism which moves a fixed mount to the axial direction of an electric power cable, a fixed mount can be moved to the position where the force from each electric power cable balances. For this reason, it can prevent that the difference arises in the axial force from the right and left of an intermediate | middle junction box.

  In addition, the fixed base is suspended by the support member, and the suspension plates that support the fixed base are rotated in parallel with each other so that the fixed base can be moved. There is no accumulation of foreign matter on the top, and there is no problem of derailment from the rail.

  At this time, if the suspension plate is connected to the support member and the fixed base via the shield bearing, foreign matter can be prevented from entering the bearing and can be stably operated over a long period of time.

  Moreover, a rail is provided by providing a fixed member on the wall surface, supporting the fixed base by a support member that can rotate with respect to the fixed member, and rotating the respective support members in parallel to each other so that the fixed base can be moved. As compared with the case of using, etc., foreign matter or the like is not deposited on the rail, and problems such as derailment from the rail do not occur.

  At this time, if the support member is connected to the fixed member and the fixed mount via the shield bearing, foreign matters can be prevented from entering the bearing and can be stably operated over a long period of time.

  By doing so, the axial forces on the left and right are averaged, and excessive axial forces can be reduced. Even when a rubber block type junction box is used, the occurrence of interface deviation between the reinforcing insulator and the conductor is prevented. Can be suppressed.

  ADVANTAGE OF THE INVENTION According to this invention, while supporting the extension of an electric power cable, the support structure of the electric power cable intermediate | middle junction box which can make a axial difference of right and left small can be provided.

Schematic which shows the power cable intermediate | middle junction box support structure 1. FIG. The side view of the power cable intermediate junction box support structure 1. FIG. The front view of electric power cable intermediate junction box support structure 1 (sectional view of electric power cable 19). The side view of the power cable intermediate | middle junction box support structure 1 of an operation state. The front view of electric power cable intermediate junction box support structure 1a (sectional view of electric power cable 19). The front view of electric power cable intermediate junction box support structure 1b (sectional view of electric power cable 19). FIG. 7 is a cross-sectional view taken along the line AA in FIG. 6, and is a bottom view of the junction box fixing base 15. The bottom view of the junction box fixed mount 15 in the operation state of the power cable intermediate junction box support structure 1b.

  Hereinafter, the first embodiment will be described with reference to the drawings. 1 is a view showing the entire power cable intermediate connection box support structure 1, FIG. 2 is a side view showing the power cable intermediate connection box support structure 1, and FIG. 3 is a front view of the power cable intermediate connection box support structure 1. It is (sectional drawing of the power cable 19). In practice, a plurality of power cable intermediate connection box support structures 1 are installed inside one manhole, but only one power cable intermediate connection box support structure 1 is shown for simplicity.

  The power cable intermediate connection box support structure 1 is installed in a manhole, for example. Inside the manhole, the power cables 19 led out from the left and right pipelines 4 in the figure are connected. For connection of the power cable 19, the connection box 3 which is an intermediate connection box of the power cable is used.

  The power cables 19 are connected to each other inside the connection box 3. A reinforcing insulator or the like is formed on the outer periphery of the connection portion between the power cables.

  An offset portion where the power cable 19 is bent in an S shape is formed between the pipe line 4 and the connection box 3. The shape of the offset portion is not limited to the illustrated example. Further, the shape of the left and right offset portions of the connection box 3 and the length from the pipe line 4 to the connection box 3 may be the same on the left and right, or may be in different forms.

  For example, the offset portion is not only S-shaped when viewed from the horizontal direction, but can also be S-shaped in plan view, and these can be combined. The shape and size of the offset portion are determined in consideration of the expected extension amount of the power cable 19 and the layout with other configurations.

  On the manhole wall surface 7, a standing object 5 is installed. Although a pair of standing objects 5 are illustrated in FIG. 1, a plurality of standing objects 5 are installed on the manhole wall surface 7 at a predetermined interval. The standing metal 5 is formed in the height direction of the manhole wall surface 7.

  As shown in FIGS. 2 and 3, a pair of support members 9 are joined to the metal stand 5 at a predetermined interval. That is, the support member 9 is fixed to the manhole wall surface 7. Each support member 9 is connected to the vicinity of the upper end portions of the pair of suspension plates 11. The support member 9 and the suspension plate 11 are rotatably connected via a shield bearing 13.

  In the vicinity of the lower end portion of the suspension plate 11, a junction box fixed mount 15 is rotatably connected via a shield bearing 13 and a shaft 17. In other words, the junction box fixed base 15 is suspended from the support member 9 by the suspension plate 11, and the suspension plate 11 is rotatably attached to the support member 9 and the junction box fixed base 15, and is connected to the support member 9. The box fixed mount 15 is connected.

  The connection box 3 is fixed to the connection box fixing base 15. Therefore, the connection box 3 does not move or rotate with respect to the connection box fixed mount 15.

  Next, the operation of the power cable intermediate connection box support structure 1 will be described. When the power cables 19 are energized from the state of FIG. 1, each power cable 19 extends due to heat generation. At this time, when the lengths of the power cables 19 on both sides of the connection box 3 are different, or when the form of the offset portion is different, the extension amount of the power cable 19 may be different on both sides of the connection box 3. is there.

  When the extension amount of the power cable 19 differs between the left and right sides of the connection box 3, a difference in thermal stress caused by the extension amount occurs with respect to the connection box 3. In this case, an axial force corresponding to the difference in thermal stress is applied to the conductor connection portion inside the connection box 3. As a result, there is a possibility that the power cable 19 and the conductor connection portion may cause an interface shift with respect to the outer peripheral reinforcing insulator.

  On the other hand, in the present embodiment, as shown in FIG. 4, the suspension plates 11 are rotated in parallel with each other according to the left and right extension amounts (thermal stress), and the junction box fixed base 15 swings to the left and right. Is possible. Therefore, the junction box fixed mount 15 moves to a position where the forces from the left and right power cables 19 are balanced. As a result, the thermal stress applied to the junction box 3 is uniform on the left and right.

  At this time, the junction box fixed base 15 moves in the axial direction of the power cable 19 (in the direction of arrow X in the figure) while maintaining the horizontal state. That is, when the power cable intermediate connection box support structure 1 receives force from the power cables 19 connected to both sides of the connection box 3, the power cable intermediate connection box support structure 1 The connection box fixed mount 15 moves to a position where the forces of the two are balanced. In addition, the structure that moves the junction box fixed base 15 in the axial direction of the power cable 19 is referred to as a moving mechanism.

  Since the connection box 3 is fixed to the connection box fixed mount 15, when the connection box fixed mount 15 is moved, the connection box 3 is kept horizontal and does not rotate around the axis of the power cable 19. When the connection box 3 is tilted or rotated, an excessive bending force or a kink may occur in the power cable 19 connected to the connection box 3.

  On the other hand, in the power cable intermediate connection box support structure 1 according to the present embodiment, the connection box 3 does not tilt with respect to the axial direction of the power cable 19 and does not rotate. For this reason, generation | occurrence | production of the excessive bending force and kink to the power cable 19 can be prevented.

  Note that the movable range of the junction box fixed mount 15 may be restricted. For example, when the length of the suspension plate 11 is 300 mm, by restricting the rotation range of the shield bearing 13 to ± 30 °, the junction box fixed mount 15 can be restricted to a movable range of about ± 150 mm. . If such a movable range is set, it will be a practical range as a measure for reducing the axial force.

  When the movable range of the connection box fixed mount 15 is restricted, the connection box 3 is set within a range in which the connection box 3 does not interfere with the upper support member 9 in the movable range of the connection box fixed mount 15. By doing in this way, when the junction box fixed mount 15 moves, it can prevent that the support member 9 and the junction box 3 contact.

  As described above, according to the first embodiment, since the connection box 3 can be moved in the axial direction by the moving mechanism, the connection box 3 moves when the axial force from the left and right of the connection box 3 is different. And it can hold | maintain in the position where axial force balances. For this reason, it is possible to prevent the axial force from being applied to the conductor connecting portion inside the connection box 3 due to the unbalance of the axial force from the left and right.

  In particular, even when the connection box 3 is a rubber block type connection box that does not have a mechanism for preventing the displacement between the conductor and the reinforcing insulator, the conductor and the reinforcing insulator are less likely to be displaced. Deterioration of electrical performance due to deviation can be suppressed.

  As described above, the present invention is particularly effective when the connection box 3 is a rubber block type connection box, but can be applied to other types such as a prefabricated joint (PJ). Further, the present invention can be applied not only to a CV cable but also to an OF cable (Oil Filled Cable).

  Moreover, in this embodiment, when the connection box 3 moves to an axial direction, the level of the connection box 3 is maintained. For this reason, generation | occurrence | production of the excessive bending stress, the kink of the power cable 19, etc. with respect to the connection box 3 can be suppressed.

  In particular, when the shield bearing 13 is used, it is possible to prevent dust and the like from entering the bearing, and even when the manhole is submerged, it can be stably operated. For this reason, maintenance is unnecessary and it can function stably over a long period of time.

  Moreover, the power cable intermediate connection box support structure 1 has a simple structure and can reduce the installation space. For this reason, the connection box 3 usually supports three phases on the manhole wall surface 7 in a vertical arrangement. At this time, the distance between the connection boxes is about 450 mm (an example of a 275 kV line). If it is the power cable intermediate junction box support structure 1 of this embodiment, it can be accommodated in the conventional storage space, and it can respond by the conventional manhole design.

  In addition, this embodiment is not restricted to the shape shown in FIGS. For example, as shown in FIG. 5, instead of the rod-like support member 9, a power cable intermediate connection box support structure 1a using a plate-like support member 9a may be used.

  The support member 9a has a substantially trapezoidal shape, and has a wide width on the joining side with the metal stand 5, and becomes narrower as it goes from the manhole wall surface 7 to the front end side. A cutout for avoiding interference with the suspension plate 11 is formed in the support member 9 a, and the suspension plate 11 is connected to the cutout portion via a shield bearing 13. According to the support member 9a, higher rigidity can be ensured.

  Thus, in the present embodiment, the shape and number of each part are not particularly limited, and can be appropriately changed according to the required strength and occasion. For example, a general-purpose bearing may be used instead of the shield bearing 13 as long as dustproof and waterproofing of the manhole can be secured.

  Next, a second embodiment will be described. 6 is a front view of the power cable intermediate connection box support structure 1b (cross-sectional view of the power cable 19), and FIG. 7 is a cross-sectional view taken along line AA of FIG. FIG. In the following description, components having the same functions as those of the first embodiment are denoted by the same reference numerals as in FIGS.

  The power cable intermediate connection box support structure 1b is substantially the same structure as the power cable intermediate connection box support structure 1 and the like, but the method of supporting the connection box fixed mount 15 is different. A fixing member 21 is fixed to the metal fixture 5 on the manhole wall 7. For example, a pair of fixing members 21 are provided at a predetermined interval.

  Support members 23 are attached to the fixing members 21, respectively. The support member 23 and the fixed member 21 are connected to each other via a shield bearing 13 so as to be rotatable. That is, the support member 23 is rotatably attached to the fixed member 21 with the fixed member 21 as a fulcrum.

  A junction box fixed base 15 is rotatably connected to the vicinity of the ends of the pair of support members 23 via a shield bearing 13. That is, the junction box fixing base 15 is supported from below by the support member 9, and the supporting member 23 is rotatably attached to the fixing member 21 and the junction box fixing base 15. 15 is connected.

  Next, the operation of the power cable intermediate connection box support structure 1b will be described. In the present embodiment, as shown in FIG. 8, the pair of support members 23 rotate in parallel with each other in accordance with the left and right extension amounts (thermal stress) of the power cable 19, and the junction box fixed base 15 It can swing. Therefore, the connection box fixed mount 15 moves to the balance position by the force from the left and right power cables 19. As a result, the thermal stress applied to the junction box 3 is uniform on the left and right.

  At this time, the junction box fixed base 15 moves in the axial direction of the power cable 19 (in the direction of arrow X in the figure) while maintaining the horizontal state. That is, when the power cable intermediate connection box support structure 1 receives force from the power cables 19 connected to both sides of the connection box 3, the power cable intermediate connection box support structure 1 The connection box fixed mount 15 moves to a position where the forces of the two are balanced. In addition, the structure that moves the junction box fixed base 15 in the axial direction of the power cable 19 is referred to as a moving mechanism.

  Since the connection box 3 is fixed to the connection box fixed mount 15, when the connection box fixed mount 15 is moved, the connection box 3 is kept horizontal and does not rotate around the axis of the power cable 19. For this reason, generation | occurrence | production of the excessive bending force and kink to the power cable 19 can be prevented.

  As described above, according to the second embodiment, the same effects as those of the first embodiment can be obtained. That is, it is possible to prevent the axial force from being applied to the conductor connecting portion inside the connection box 3 due to the unbalance of the axial force from the left and right.

  Further, the length of the support member 23 can be increased in the same storage space as compared with the power cable intermediate connection box support structure 1 and the like. By making the support member 23 longer, the movement width perpendicular to the axial direction of the power cable 19 can be reduced, which is effective in limiting the movement in the axial direction.

  As described above, the moving mechanism for moving the junction box in the axial direction may not be the one according to the first embodiment or the second embodiment. For example, a rail may be laid in the axial direction of the power cable 19, and the connection box fixed mount 15 may be installed on the rail so as to be movable. Even in this case, the moving mechanism can move the connection box fixed mount 15 in the axial direction of the power cable 19 while maintaining the connection box fixed mount 15 horizontal.

  However, such a method using a rail has a problem of long-term stability, for example, foreign matter accumulates on the rail to prevent the movement of the junction box. Further, as described above, when a bending force is applied to the junction box 3, the junction box fixing base 15 may be derailed from the rail. For this reason, as in this embodiment, without using rails, a suspension support system in which the connection box fixing base 15 is suspended from above, or a system in which the connection box fixing base 15 is supported from below by a support member 23 extending from the side. It is desirable to be.

  As mentioned above, although embodiment of this invention was described referring an accompanying drawing, the technical scope of this invention is not influenced by embodiment mentioned above. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims, and these are naturally within the technical scope of the present invention. It is understood that it belongs.

  For example, although an example in which a pair of suspension plates 11 and support members 23 are provided is shown, the number is not limited as long as a plurality of suspension plates 11 or support members 23 can rotate in parallel with each other.

  In addition, the moving mechanism of the present invention is not limited to the connection box fixed base that moves in the axial direction of the power cable while maintaining the horizontal direction, and the connection box fixed base is inclined or rotated. It may be formed and moved in the axial direction of the power cable.

1, 1a, 1b ......... Power cable intermediate connection box support structure 3 ......... Connection box 4 ......... Pipe line 5 ......... Rigid material 7 ......... Manhole wall surface 9, 9a ......... Support member 11 ... ... Suspension plate 13 ......... Shield bearing 15 ......... Junction box fixing base 17 ......... Shaft 19 ......... Power cable 21 ......... Fixing member 23 ......... Support member

Claims (6)

A support structure for the power cable intermediate connection box,
A fixed mount to which the power cable intermediate connection box is fixed;
A moving mechanism capable of moving the fixed base in the axial direction of the power cable when receiving a force from each of the power cables connected to both sides of the power cable intermediate connection box;
A support structure for a power cable intermediate connection box. The moving mechanism is
A support member fixed to the wall surface;
A suspension plate rotatably attached to the support member and the fixed base, and connecting the support member and the fixed base;
Comprising
The fixed mount is suspended from the support member by the suspension plate,
2. The support structure for a power cable intermediate connection box according to claim 1, wherein the suspension plate that supports the fixed mount is rotatable.   3. The support structure for a power cable intermediate connection box according to claim 2, wherein the suspension plate is connected to the support member and the fixed base via a shield bearing. The moving mechanism is
A fixing member fixed to the wall surface;
Using the fixing member as a fulcrum, a support member rotatably attached to the fixing member;
Comprising
The power cable intermediate connection box support structure according to claim 1, wherein the fixed base is rotatably attached to the support member.   The power cable intermediate connection box support structure according to claim 4, wherein the support member is connected to the fixed member and the fixed mount via a shield bearing.   6. The support structure for a power cable intermediate connection box according to claim 1, wherein the power cable intermediate connection box is a rubber block type connection box.

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