JP2012151950A - Cable disconnection prevention device, and method for preventing cable disconnection using the cable disconnection prevention device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure prevention of occurrence of a cable disconnection event by securing extra length of cable allowing the cable to move smoothly even if strong tensile force by an earthquake acts on the cable rapidly.SOLUTION: A disconnection prevention device for a cable K is comprised of a guide rail 1 with predetermined length and fixed at the upper part of the facility and a plurality of traveling bodies 2 moving along the guide rail. Each traveling body comprises a suspension rod 3 extended downward and the cable is attached to the lower end of the suspension rod. In addition, the guide rail is comprised of a rectangular top plate, a vertical piece, and a horizontal piece. The plurality of traveling bodies moving along the guide rail is comprised of a progress part 7 arranged inside the guide rail and the progress part comprises multiple wheels 8 on both sides thereof and placed on both horizontal pieces constituting the guide rail.

Description

  For example, the present invention is a case where a strong tensile force is suddenly applied to cables installed in various facilities such as a power plant and a substation due to uneven settlement of the ground during an earthquake. However, by using the cable disconnection prevention device and the cable disconnection prevention device that prevent the occurrence of a situation where the cable is disconnected by allowing the cable to move smoothly and securing the extra length of the cable. The present invention relates to a cable disconnection prevention method.

  Various cables K are laid in various facilities such as a power plant and a substation. For example, as shown in FIG. 12, the cable K is used in the tunnel A of the facility where the transformer is installed in the power plant, or in the communication tunnel B connected to the tunnel A. Is laid.

  For example, as shown in FIG. 13, the cable K is laid in the facility sinuses A and B via the cleat 100 installed in the facility sinuses A and B.

  At this time, the cable K is fixedly attached to the cleat 100 such that the circumferential surface of the cable K is strongly sandwiched between the cleats 100 having the divided structure.

  Therefore, the cable K is in a state where the cable K cannot move in the cleat 100 portion.

  In addition, for example, as shown in Patent Document 1, when changing the snake laying of the power cable provided with the cleat along the reference line of the waveform to the straight laying in the root axis direction, at the end portion of the snake laying, the reference A guide cleat with a bell mouth that is supported by sliding near a point on the line, followed by a guide cleat that leads to the top of the waveform along a snake arc, and a fixed cleat at the top of the waveform, from the top of the waveform There exists a power cable laying method in which a straight line is laid in the route axis direction.

  In addition, as shown in Patent Document 2, when laying a power cable in a pipeline, a ring spacer is attached on the outer periphery of the cable at a substantially constant interval, and after laying, the cable is fixed in one human hole. However, there is a method for laying an electric power cable in a pipeline in which a cable is forcibly meandered by applying a compressive force to the cable in the axial direction from the other manhole, and then an intermediate connection box is assembled in the manhole.

  Further, as shown in Patent Document 3, a plurality of fixed cleats arranged at predetermined intervals along the longitudinal direction of the installed cable and fixing and supporting the cable, and the cable is installed between the fixed cleats. There is a cable line including an elastic member that presses and biases in a direction substantially orthogonal to the direction.

JP 56-56113 A JP-A-2-41609 JP-A-6-133424

  However, in the conventional cable K laying method as shown in FIGS. 12 and 13, the cable K is strongly sandwiched by the cleat 100 having the divided structure and cannot move in the cleat 100 portion. The following evils are occurring.

  In other words, when there is an earthquake that is a phenomenon in which the ground fluctuates due to a sudden change that naturally occurs in the crust or mantle and the elastic waves of the crust generated thereby, the ground is unequal in the area where the cable K is laid. When subsidence occurs, a strong tensile force may abruptly act on the cable K installed in the sinuses A and B of the facility.

  Specifically, as shown in FIG. 14, the ground is unevenly subsidized in the area where the cable K is laid due to the earthquake, and the path A and the path B are forcibly moved up and down. May be inconsistent. At this time, a strong pulling force in a predetermined direction is abruptly applied to the cable K, and as shown in FIG. 14, the cable K is fixedly laid through the cleat 100 in the sinus A and the sinus B. There is a possibility that the cable K will be cut at the joint portion between the sinus A and the sinus B that are forcedly moved in the vertical direction and are in a step difference.

  For example, a facility in which a transformer is installed in a power plant is firmly constructed, and its path A is very strong. On the other hand, the connecting cavernous B, etc. connected to the cavernous road A may not be constructed as firmly as the cavernous road A, and in the area where the cable K is laid due to the earthquake If uneven ground subsidence occurs, the joint portion between the sinus A and the sinus B will be stepped, and a strong pulling force may abruptly act on the cable K in a fixed state.

  In addition, the power cable laying method disclosed in Patent Document 1 is provided with a special jig when changing the snake laying of the power cable to the straight laying, so that the bending of the power cable can be moderated and the heat of the power cable can be reduced. It effectively absorbs the contraction, but it is effective when the ground is unevenly subsidized in the area where the power cable is laid due to an earthquake and a strong pulling force is applied to the power cable suddenly. It doesn't work.

  In addition, the power cable laying method shown in Patent Document 2 also includes thermal stress caused by seasonal temperature fluctuations and power cable load current fluctuations, sliding force due to inclined grounding common to underground cables, or axles. Considering the unbalanced axial force of the installation tension when force due to the wave riding phenomenon due to vibration is applied to the cable conductor, uneven ground subsidence occurs in the area where the power cable is installed due to the earthquake. It does not function effectively when a strong tensile force acts on the power cable suddenly.

  Furthermore, the cable line shown in Patent Document 3 also considers that the power cable generates heat and contracts due to the increase or decrease in the amount of power transmitted through the cable. Due to the uneven settlement of the ground, a strong tensile force is exerted on the power cable. It does not function effectively when acting suddenly.

  Therefore, the present invention was created in view of the existing circumstances as described above, and the ground is unevenly subsidized in the area where the cable is laid due to the earthquake, and the strong pulling force on the cable is generated. Even if the cable suddenly acts, the cable can be moved smoothly and the cable length is secured to prevent the cable from breaking. It is an object of the present invention to provide a cable disconnection prevention method using the apparatus and the cable disconnection prevention device.

  The cable disconnection prevention device according to the present invention includes a guide rail having a predetermined length fixed above a facility and a plurality of traveling bodies that move along the guide rail. The traveling body is directed downward. The above-described problems have been solved by providing an extended hanging rod and attaching a cable to the lower end of the hanging rod.

  The guide rail has a rectangular top plate having a predetermined length, a hanging piece extending downward from both sides in the longitudinal direction of the top plate, and an inward extending from the lower part of both hanging pieces. The plurality of traveling bodies that move along the guide rail are constituted by advancing portions disposed inside the guide rail, and the advancing portions include a plurality of wheels on both sides thereof. Moreover, the problem mentioned above was solved by having mounted the wheel of the advancing part on both horizontal pieces which comprise a guide rail.

  Further, the guide rail is composed of an H-shaped steel in which rectangular flange plates having a predetermined length arranged vertically are connected by a rectangular web plate having a predetermined length. The plurality of traveling bodies are configured by an advancing portion arranged on the lower flange plate of the guide rail, and the advancing portion extends upward from both sides of the rectangular base plate. The above-described problem has been solved by providing a plurality of wheels inside each hanging piece and placing the wheels of the advancing portion on the lower flange plate constituting the guide rail. .

  Further, the guide rail is configured by providing a long groove portion formed in a concave shape in the upper portion in the longitudinal direction, and a plurality of traveling bodies moving along the guide rail cover the guide rail. The advancing part is configured to have a hanging piece extending upward from both sides of the rectangular base plate, and has a plurality of wheels between the hanging pieces, and proceeds. The problem mentioned above was solved by introducing the wheel of the part into the long groove part of the guide rail.

  In addition, the cable disconnection prevention method according to the present invention solves the above-described problem by using the cable disconnection prevention device described above.

  The cable disconnection prevention device according to the present invention includes a guide rail having a predetermined length fixed above a facility and a plurality of traveling bodies that move along the guide rail. The traveling body is directed downward. Because it has an extended hanging rod and the cable is attached to the lower end of the hanging rod, the ground is unevenly subsidized in the area where the cable is installed due to the earthquake, and it is strong against the cable. Even when a tensile force is applied suddenly, the cable can be disconnected by allowing a smooth movement of the cable by a plurality of traveling bodies moving along the guide rail and securing the extra length of the cable. The occurrence of a situation can be reliably prevented.

  Specifically, the cable maintains a state of bending downward between the suspension rods of adjacent traveling bodies, and a strong tensile force acts abruptly on the curved cable. In this case, the cable is smoothly moved by a plurality of traveling bodies that move along the guide rail, and is extended so as to be linear with a reduced degree of bending, thereby securing the extra length of the cable.

  The guide rail has a rectangular top plate having a predetermined length, a hanging piece extending downward from both sides in the longitudinal direction of the top plate, and an inward extending from the lower part of both hanging pieces. The plurality of traveling bodies that move along the guide rail are constituted by advancing portions disposed inside the guide rail, and the advancing portions include a plurality of wheels on both sides thereof. Since the wheels of the advancing part are placed on both horizontal pieces constituting the guide rail, the advancing part of the traveling body can be smoothly moved inside the guide rail to ensure the extra cable length. it can.

  Furthermore, even when the ground is shaken due to an earthquake, the traveling body is housed inside the guide rail, so that it is possible to prevent the traveling body from being detached from the guide rail.

  Further, the guide rail is composed of H-shaped steel in which rectangular flange plates with a predetermined length arranged vertically are connected by a rectangular web plate with a predetermined length. The plurality of traveling bodies are configured by an advancing portion arranged on the lower flange plate of the guide rail, and the advancing portion extends upward from both sides of the rectangular base plate. A plurality of wheels inside each hanging piece, and the wheels of the advancing portion are placed on the lower flange plate constituting the guide rail, so that the lower side constituting the guide rail In this flange plate, the advancing portion of the traveling body can be smoothly moved to ensure the extra cable length.

  In addition, since the H-shaped steel is used as the guide rail, the robustness of the guide rail can be maintained. Moreover, since the H-section steel which is a general steel material is utilized, the cable disconnection prevention apparatus can be manufactured at low cost.

  In addition, the guide rail is configured by providing a long groove formed in a concave shape at the upper part in the longitudinal direction, and a plurality of traveling bodies moving along the guide rail cover the guide rail. The advancing part has a hanging piece extending upward from both sides of the rectangular base plate, and includes a plurality of wheels between the hanging pieces, Since the wheel of the traveling part is introduced into the long groove of the guide rail, the traveling part of the traveling body arranged so as to cover the guide rail can be smoothly moved to secure the extra cable length. Can do.

  Furthermore, since the wheel of the advancing part is introduced into a long groove formed in a concave shape in the guide rail, the extra length of the cable is supported with the heavy cable firmly supported by the traveling body and the suspension rod. Can be secured.

  On the other hand, according to the cable disconnection prevention method of the present invention, by using the cable disconnection prevention device described above, the cable can be smoothly moved by a plurality of traveling bodies moving along the guide rail, and the cable By securing the extra length, it is possible to reliably prevent the occurrence of a situation where the cable is disconnected.

  As described above, the cable disconnection prevention device according to the present invention and the cable disconnection prevention method using the cable disconnection prevention device have an uneven settlement of the ground in the area where the cable is laid due to an earthquake. Even when a strong pulling force is applied to the cable suddenly, the cable can be disconnected by allowing the cable to move smoothly and securing the extra length of the cable. For example, when a joint portion of a facility having different seismic strength can be specified, the present invention is preferably applied in the vicinity of the joint portion.

The structure of the cable disconnection prevention device is shown. (A) is an exploded perspective view showing a state in which a traveling body is arranged inside a guide rail that is partially open at the bottom, and (b) the inside of this guide rail. It is a perspective view which shows the state which has arrange | positioned the traveling body. The cable is attached to the lower ends of the suspension rods of the two traveling bodies that move along the guide rails, and maintains a state of being curved downward between the suspension rods of the two traveling bodies. FIG. The cable is attached to the lower ends of the suspension rods of the three traveling bodies that move along the guide rails, and maintains a state of being curved downward between the suspension rods of adjacent traveling bodies. FIG. In the cable laid in the facility's cave (A / B), the lower end of the suspension rod of three traveling bodies in which part of the cable in the cave (B) moves along the guide rail It is a perspective view which shows the state attached to. In the cable installed in the facility's cave (A / B), the ground was unevenly subsidized in the area where the cable was installed due to the earthquake, and the cave (A / B) became uneven. Sometimes, the cable moves smoothly through the three traveling bodies that move along the guide rails, and extends so as to form a straight line with a reduced degree of curvature, thereby securing the extra length of the cable. It is a perspective view which shows a state. The other structure of the disconnection prevention apparatus of a cable is shown, (a) is a disassembled perspective view which shows the state which arrange | positions a traveling body on the guide rail using H-section steel, (b) A traveling body is shown in this guide rail. It is a perspective view which shows the state which has arrange | positioned. The cable is attached to the lower ends of the suspension rods of the two traveling bodies that move along the guide rails using H-shaped steel, and is bent downward between the suspension rods of the two traveling bodies. It is a perspective view which shows the state which has maintained the state performed. A cable is attached to the lower ends of the suspension rods 3 of the three traveling bodies that move along the guide rails using H-shaped steel, and is directed downward between the suspension rods of adjacent traveling bodies. It is a perspective view which shows the state which is maintaining the curved state. The other structure of the cable disconnection prevention apparatus is shown, (a) is an exploded perspective view showing a state in which a traveling body is arranged on a guide rail having a long groove on the upper part, (b) It is a perspective view which shows the state which has arrange | positioned the traveling body. The cable is attached to the lower ends of the suspension rods of the two traveling bodies that move along the guide rail having a long groove at the top, and is directed downward between the suspension rods of the two traveling bodies. It is a perspective view which shows the state which is maintaining the curved state. A cable is attached to the lower ends of the suspension rods of three traveling bodies that move along a guide rail having a long groove at the top, and is directed downward between the suspension rods of adjacent traveling bodies. It is a perspective view which shows the state which is maintaining the curved state. A cable is laid in the tunnel (A) of the facility where the transformer is installed in the power plant, or in the connecting tunnel (B) connected to the tunnel (A). FIG. It is a perspective view which shows the state by which the cable is laid in the sinus (A * B) of a plant | facility via a cleat. When the ground is unevenly subsidized in the area where the cable is laid due to the earthquake, and the cave (A / B) becomes uneven, a strong pulling force acts on the cable suddenly. It is a perspective view which shows the state which has cut | disconnected.

  As shown in FIGS. 1 (a), (b) and FIG. 2, the cable K disconnection preventing device according to the present invention is provided along a guide rail 1 of a predetermined length fixed above the facility, and along this guide rail 1. The traveling body 2 includes a hanging rod 3 that extends downward, and a cable K is attached to the lower end of the hanging rod 3.

  As shown in FIG. 1 (a), the guide rail 1 includes a rectangular top plate 4 having a predetermined length, and a hanging piece 5 extending downward from both sides in the longitudinal direction of the top plate 4, It is comprised by the horizontal piece 6 extended inward from the lower part of both the hanging pieces 5.

  A long rectangular space is formed inside the guide rail 1. In addition, a long gap space having a predetermined width is also formed between the tip portions of both horizontal pieces 6 extending inward from each other.

  A plurality of traveling bodies 2 that move along the guide rail 1 are constituted by advancing portions 7 that are arranged inside the guide rail 1. As shown in FIG. 1A, the advancing portion 7 is formed in a horizontally long prismatic shape. In addition, the horizontally long prism is provided with a pair of wheels 8 that are respectively fixed in the vicinity of one end and the other end. For this reason, in a horizontally long prism, two wheels 8 are arranged at predetermined intervals on both side surfaces along the longitudinal direction.

  Furthermore, the advancing part 7 fixes the rod-shaped hanging rod 3 to the lower surface of the horizontally long prism. As shown in FIG. 2, the hanging rod 3 includes a pinching portion 9 having a ring structure divided at a lower end portion. The cable K is attached to the lower end portion of the hanging rod 3 by strongly sandwiching the peripheral surface of the cable K by the clamping portion 9.

  The advancing part 7 in the traveling body 2 is disposed inside the guide rail 1 as shown in FIGS. Specifically, the wheels 8 of the traveling part 7 are placed on both horizontal pieces 6 constituting the guide rail 1 so that the traveling part 7 can move inside the guide rail 1.

  The lower portion of the advancing portion 7 is disposed in a gap space formed between the tip portions of both horizontal pieces 6 extending inward in the guide rail 1. Moreover, the hanging rod 3 is in a state of being fixed to the lower surface of the advancing portion 7 disposed in the gap space.

  As shown in FIG. 2, the guide rail 1 itself is fixedly attached to a predetermined column member 10 installed in the sinuses A and B of the facility.

  As shown in FIG. 2, the cable K is attached to the lower ends of the suspension rods 3 of the two traveling bodies 2 that move along the guide rails 1, and the cable K is connected to the two traveling bodies 2. A state of being curved downward is maintained between the hanging rods 3.

  Further, as shown in FIG. 3, the cable K may be attached to the lower end portion of the hanging rod 3 of the three traveling bodies 2 that move along the guide rail 1. At this time, the cable K maintains a state of being curved downward between the hanging rods 3 of the adjacent traveling bodies 2.

  When the ground is unevenly subsidized in an area where the cable K is laid due to an earthquake and a strong pulling force is applied to the cable K suddenly, a plurality of travelings that move along the guide rail 1 are performed. The cable K is allowed to move smoothly through the body 2 and the extra length of the cable K is secured.

  Specifically, as shown by the solid lines in FIGS. 2 and 3, the cable K maintains a state of being bent downward between the hanging rods 3 of the adjacent traveling bodies 2. When a strong pulling force is suddenly applied to the cable K in the state of being cut, the cable K moves smoothly through the traveling body 2 as shown by the two-dot chain line in FIGS. The extra length of the cable K is secured by extending it so as to be linear with a reduced degree.

  For example, as shown in FIG. 4, the cable K is installed in the facility's sinuses A and B via a cleat 100 installed in the facility's sinuses A and B.

  In addition, the cable K is attached to the lower end portion of the suspension rod 3 of the three traveling bodies 2 that move along the guide rails 1 in the tunnel B of the facility. At this time, as shown in FIG. 4, the cable K maintains a state of being curved downward between the hanging rods 3 of the adjacent traveling bodies 2.

  Then, as shown in FIG. 5, the ground is unevenly subsidized in the area where the cable K is laid due to the earthquake, and the cave A and the cave B are forcibly moved up and down. When a strong tensile force is applied to K suddenly, the cable K moves smoothly through the plurality of traveling bodies 2 that move along the guide rails 1 to reduce the degree of bending and become linear. Thus, the extra length of the cable K is secured.

  As another configuration of the cable K disconnection preventing device according to the present invention, as shown in FIG. 6A, the guide rail 1 may be made of H-section steel. The guide rail 1 is made of a so-called H-shaped steel in which rectangular flange plates 20 and 21 having a predetermined length arranged vertically are connected by a rectangular web plate 22 having a predetermined length. ing.

  As shown in FIG. 6B, the plurality of traveling bodies 2 that move along the guide rail 1 are configured by the advancing portions 7 that are arranged on the flange plate 21 on the lower side of the guide rail 1. As shown in FIG. 6A, the advancing portion 7 has a hanging piece 24 that extends upward from both sides of a rectangular base plate 23. The hanging piece 24 is formed in a rectangular plate shape that becomes wider from the bottom to the top. Further, two wheels 25 are attached to the inner side of each hanging piece 24 with a predetermined interval.

  Then, as shown in FIG. 6B, the wheel 25 of the advancing portion 7 is placed on the lower flange plate 21 constituting the guide rail 1 so that the advancing portion 7 can move. At this time, the base plate 23 of the advancing portion 7 moves along the lower flange plate 21 while maintaining a slight gap with respect to the lower flange plate 21.

  Further, a rod-like hanging rod 3 is fixed to the lower surface of the base plate 23 in the advancing portion 7. As shown in FIG. 7, the hanging rod 3 includes a pinching portion 9 having a ring structure divided at a lower end portion. The cable K is attached to the lower end portion of the hanging rod 3 by firmly holding the peripheral surface of the cable K by the holding portion 9.

  As shown in FIG. 7, the guide rail 1 itself is fixedly attached to a predetermined column member 10a installed in the sinuses A and B of the facility.

  As shown in FIG. 7, the cable K is attached to the lower ends of the suspension rods 3 of the two traveling bodies 2 that move along the guide rail 1, and the cable K is connected to the two traveling bodies 2. A state of being curved downward is maintained between the hanging rods 3. Further, as shown in FIG. 8, the cable K may be attached to the lower end portion of the hanging rod 3 of the three traveling bodies 2 that move along the guide rail 1.

  At this time, as shown by the solid lines in FIGS. 7 and 8, the cable K maintains a state of being curved downward between the suspension rods 3 of the adjacent traveling bodies 2.

  When the ground is unevenly subsidized in the area where the cable K is laid due to the earthquake, and a strong pulling force is applied to the cable K suddenly, the two-dot chain line in FIGS. As described above, the cable K moves smoothly through the traveling body 2 and extends so as to form a straight line with a reduced degree of bending, thereby securing the extra length of the cable K.

  As another configuration of the disconnection preventing device for the cable K according to the present invention, as shown in FIG. 9 (a), the guide rail 1 has a horizontally long rectangular column structure and is formed in a concave shape at the top in the longitudinal direction. You may comprise and provide the long groove part 30,

  As shown in FIG. 9B, the plurality of traveling bodies 2 that move along the guide rail 1 are configured by an advancing portion 7 that is disposed so as to cover the guide rail 1. The advancing portion 7 has horizontally long rectangular hanging pieces 32 extending upward from both sides of the horizontally long rectangular base plate 31. Further, three wheels 33 are fixed between the two hanging pieces 32.

  And as shown in FIG.9 (b), the wheel 33 of the advancing part 7 is introduce | transduced into the elongate groove part 30 of the guide rail 1, and the advancing part 7 is made to move. At this time, the guide rail 1 is completely covered by the base plate 31 and the both hanging pieces 32 constituting the advancing portion 7. Further, the base plate 31 and the both hanging pieces 32 of the advancing portion 7 move along the guide rail 1 while maintaining a slight gap with respect to the guide rail 1.

  A rod-like hanging rod 3 is fixed to the lower surface of the base plate 31 in the traveling portion 7. As shown in FIG. 10, the hanging rod 3 includes a pinching portion 9 having a ring structure divided at a lower end portion. The cable K is attached to the lower end portion of the hanging rod 3 by firmly holding the peripheral surface of the cable K by the holding portion 9.

  As shown in FIG. 10, the guide rail 1 itself is fixedly attached to a predetermined column member 10a installed in the sinuses A and B of the facility.

  As shown in FIG. 10, the cable K is attached to the lower ends of the suspension rods 3 of the two traveling bodies 2 that move along the guide rail 1, and the cable K is connected to the two traveling bodies 2. A state of being curved downward is maintained between the hanging rods 3. Moreover, the cable K may be attached to the lower end part of the suspension rod 3 of the three traveling bodies 2 that move along the guide rail 1 as shown in FIG.

  At this time, as shown by the solid lines in FIGS. 10 and 11, the cable K maintains a state of being curved downward between the suspension rods 3 of the adjacent traveling bodies 2.

  When the ground is unevenly subsidized in the area where the cable K is laid due to the earthquake, and a strong pulling force is applied to the cable K suddenly, the two-dot chain line in FIGS. As described above, the cable K moves smoothly through the traveling body 2 and extends so as to form a straight line with a reduced degree of bending, thereby securing the extra length of the cable K.

  In the traveling body 2 shown in the figure, one cable K is supported. However, the present invention is not limited to this, and a plurality of traveling bodies 2 support two or more cables K. There may be.

  In addition to the above, the present invention is not limited to the above-described embodiment, and all the improvements and modifications within the scope that can achieve the object of the present invention are included in the present invention.

  The present invention prevents disconnection of cables installed in facilities such as power plants and substations, but in addition to long cables installed in various facilities, Even when a strong pulling force is suddenly applied due to unequal subsidence in the ground, it can be widely used as an apparatus and method for securing the extra length of the cable.

K ... Cable A ... Cave B ... Cave 1 ... Guide rail 2 ... Traveling body 3 ... Suspension rod 4 ... Top plate 5 ... Vertical piece 6 ... Horizontal piece 7 ... Progression part 8 ... Wheel 9 ... Clamping part 10 ... Column member 10a ... Column member 20 ... Flange plate 21 ... Flange plate 22 ... Web plate 23 ... Base plate 24 ... Hanging piece 25 ... Wheel 30 ... Groove 31 ... Foundation plate 32 ... Hanging piece 33 ... Wheel 100 ... Cleat

Claims (5)

  It is composed of a guide rail of a predetermined length fixed above the facility and a plurality of traveling bodies that move along the guide rail. The traveling body is provided with a hanging rod extending downward. A device for preventing disconnection of a cable, characterized in that a cable is attached to a lower end portion of a hanging rod.   The guide rail has a rectangular top plate of a predetermined length, a hanging piece extending downward from both sides in the longitudinal direction of the top plate, and a horizontal piece extending inward from the lower part of both hanging pieces. The plurality of traveling bodies that are configured by a piece and move along the guide rail are configured by an advancing portion that is disposed inside the guide rail, and the advancing portion includes a plurality of wheels on both sides of the advancing portion. The cable disconnection prevention device according to claim 1, wherein the wheels of the part are placed on both horizontal pieces constituting the guide rail.   The guide rail is composed of H-shaped steel that is formed by connecting a rectangular flange plate with a predetermined length above and below a rectangular web plate with a predetermined length, and moves along this guide rail. The plurality of traveling bodies are configured by a traveling portion disposed on the flange plate on the lower side of the guide rail, and the traveling portion has a hanging piece extending upward from both sides of the rectangular base plate. The cable break prevention device according to claim 1, wherein a plurality of wheels are provided inside each hanging piece, and the wheels of the advancing portion are placed on a lower flange plate constituting the guide rail.   The guide rail is configured by providing a long groove portion formed in a concave shape in the upper part in the longitudinal direction, and a plurality of traveling bodies moving along the guide rail are arranged so as to cover the guide rail. The advancing part has a hanging piece extending upward from both sides of the rectangular base plate, and has a plurality of wheels between both hanging pieces, The cable disconnection preventing device according to claim 1, wherein the wheel is introduced into a long groove portion of the guide rail.   A cable disconnection prevention method using the cable disconnection prevention device according to claim 1.

Images