JP5274066B2 - Indirect hot wire tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indirect live-line tool capable of reducing manpower and time in work such as maintaining electric wires to improve work efficiency. <P>SOLUTION: A round gear member 125 is fixed to a position facing the end of the insulating operation rod 110 of a head 120. The end of the insulating operation rod 110 is mounted with a lock mechanism 113 in a position facing the round gear member 125. An operation mechanism 114 with which a user performs locking or unlocking operations by the lock mechanism 113 at hand is arranged along the longitudinal direction of the insulating operation rod 110. When a rod 115 is pressed and moved toward the head 120, the latching nails 131 of the lock mechanism 113 moves toward the head 120 to be in a locked state. In the locked state, the latching nails 131 are latched together by the teeth of the round gear member 125 to suppress rotation of the insulating operation rod 110. Therefore, a user can perform locking and unlocking operations by the operation mechanism 114 without using other indirect live-line tools. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to an indirect hot wire tool used in indirect hot wire work such as high-voltage overhead distribution lines.

  Conventionally, an indirect hot wire tool equipped with an indirect hot wire work tool such as a gripping tool at the tip of an insulating operation rod has been used in order to perform indirect hot wire work such as a high-voltage overhead distribution line safely and efficiently (for example, , See Patent Document 1 and Patent Document 2).

  FIG. 11 shows a configuration example of a conventional stray link tong 200 that is one of indirect hot-line tools. The stray link tong 200 is frequently used as an auxiliary tool for holding an electric wire or using the tool smoothly. The stray link tong 200 includes an insulating operation rod 210 and a head 220 as a holding fitting attached to the tip of the insulation operation rod 210.

  The insulating operation rod 210 is formed of a cylindrical (pipe-shaped) insulating member. As the insulating member, an insulating member such as an epoxy resin reinforced plastic, a polyester resin reinforced plastic, or the like, which is not easily deformed and whose insulating property does not deteriorate is used. In order to prevent an electric shock accident, a safety limit collar 211 for clarifying the boundary between the portion that can be gripped and the other portion is fitted and fixed to the intermediate portion of the insulating operation rod 210.

  The length from the tip to which the head 220 is attached to the safety limit collar 211 is 600 mm (safety limit distance) or more. Further, as a measure against rain, a draining collar 212 is fitted and fixed between the tip of the insulating operation rod 210 and the position where the safety limit collar 211 is fixed. The safety limit collar 211 and the draining collar 212 are made of soft synthetic rubber.

  The head 220 is a part that holds a holding object such as an electric wire in the indirect hot wire operation. The head 220 is formed of an aluminum alloy, for example, in a C-shaped clamp shape. The head 220 has a head body 221 whose one end constitutes a fixed grip piece 222, and a movable grip piece 224 attached to the head body 221 via a screw shaft 223 so as to be movable in the axial direction of the screw shaft 223. have.

  Here, the other end side of the head main body 221 is attached to the tip of the insulating operation rod 210, and a movable grip piece 224 is fixed to one end side of the screw shaft 223, and the other end side of the screw shaft 223 is the head main body 221. The other end side of the insulating operation rod 210 is passed through to the fixed position inside the distal end side. By rotating the insulating operation rod 210, the protrusion length of the screw shaft 223 toward the head 220 can be increased / decreased depending on the rotation direction, and accordingly, the interval between the fixed grip piece 222 and the movable grip piece 224 is adjusted. It is possible.

  A circular gear member 213 is fixed to the tip of the insulating operation rod 210. The circular gear member 213 is formed with teeth protruding in the direction of the head 220 along the circumferential direction on the outer peripheral side of the plate surface. Further, a lock mechanism is fixed to the head 220 at a position facing the tip of the insulating operation rod 210. In this locking mechanism, the insulating operation rod 210 is prevented from rotating by sliding the lock operation button 225 toward the insulating operation rod 210 and engaging the locking claw 226 with the teeth of the circular gear member 213 described above. It is structured to lock.

  FIG. 12A shows a state where the lock operation button 225 is in the unlock position. In this state, the locking claw 226 is not locked to the teeth of the circular gear member 213, and the insulating operation rod 210 can be rotated. For example, when the electric wire 230 is held, the length of the screw shaft 223 protruding toward the head 220 is increased by rotating the insulating operation rod 210 clockwise (clockwise), and the movable gripping piece 224 is fixed. As shown in FIG. 12B, the electric wire 230 is held by the movable holding piece 224 and the fixed holding piece 222 as shown in FIG.

  When the lock operation button 225 is slid to the insulating operation rod 210 side in this electric wire holding state and becomes the lock position, the locking claw 226 is engaged with the teeth of the circular gear member 213 as shown in FIG. The rotation of the insulating operating rod 210 is restricted and the locked state is established. In this locked state, since the insulating operation rod 210 does not rotate, the electric wire holding state in which the electric wire 230 is held by the movable holding piece 224 and the fixed holding piece 222 is stably maintained without being loosened.

From this locked state, when the lock operation button 225 is slid in the direction away from the insulating operation rod 210 to reach the unlock position, the locking claw 226 is attached to the circular gear member 213 as shown in FIG. The electric wire 230 can be released from the state in which the electric wire 230 is held by the movable holding piece 224 and the fixed holding piece 222 by rotating the insulating operation rod 210 without being locked by the teeth.
Japanese Patent Laid-Open No. 9-182229 JP-A-8-275325

  In the above-described stray link tongue 200, the lock operation button 225 of the lock mechanism provided on the head 220 is slid to be in a locked state or the locked state can be released. The operation of the lock operation button 225 is performed using another indirect hot wire tool. Therefore, since two indirect hot-line tools are used at the time of locking and unlocking, there are problems that labor and time are required and workability is not good.

  An object of the present invention is to reduce labor and time in work such as holding an electric wire and improve workability.

The concept of this invention is
A head having a fixed gripping piece and a movable gripping piece is attached to the tip of the insulating operating rod, and the movable gripping piece is moved by rotation of the insulating operating rod so as to move between the fixed gripping piece and the movable gripping piece. An indirect hot wire tool that adjusts the interval of
A circular gear member fixed at a position facing the tip of the insulating operation rod of the head, and formed with teeth protruding in the tip direction of the insulating operation rod along the circumferential direction on the outer peripheral side of the plate surface;
A locking mechanism that is attached to a position of the insulating operation rod facing the head and locks the insulating operation rod so as not to rotate by engaging a locking claw with the teeth of the circular gear member;
The rod is made of an insulating material disposed along the longitudinal direction of the insulating operation rod, one end is connected to the lock mechanism, the other end is extended to the user gripping position of the insulating operation rod, and the other end the operation in indirect active line engineering tools, characterized in that it comprises an operating mechanism for operating the release of the lock and the lock by the lock mechanism.

  In the present invention, a circular gear member is fixed to the head, and a lock mechanism is attached to the distal end side of the insulating operation rod. Locking and unlocking by this locking mechanism is operated by an operating mechanism disposed along the longitudinal direction of the insulating operating rod. Thus, in this invention, the user can perform the operation of locking and unlocking by the operation mechanism, and it is not necessary to use other indirect hot wire tools, and labor and time in work such as electric wire holding can be saved. It can be reduced and workability is improved.

  In the present invention, for example, the operation mechanism is constituted by a rod made of an insulating material arranged along the longitudinal direction of the insulating operation rod. Thereby, since the user can operate locking and unlocking at hand via the rod made of an insulating material, an electric shock accident can be prevented, and the locking and unlocking operation can be performed safely and easily.

  In the present invention, for example, at least a part of the rod described above may be disposed inside the insulating operation rod. Thereby, the circumference | surroundings of an insulated operation stick | rod can be simplified and it can suppress that the rod which comprises an operation mechanism obstructs holding | maintenance operation of a user's electric wire etc.

  In the present invention, for example, the locking mechanism may include a locking claw position holding mechanism that holds the locking claw in the locked position and the unlocked position. In this case, the lock position and the unlock position can be recognized as target positions when the lock and unlock operations are performed by the operation mechanism, and user convenience is improved. In addition, the locking claw position holding mechanism holds the locking claw in the locked position and the unlocked position, so that the locked state or the unlocked state can be stably held. It can be prevented from being released.

  According to the present invention, labor and time in work such as electric wire holding can be reduced, and workability can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a configuration example of a stray link tong 100 as an embodiment.

  The stray link tong 100 includes an insulating operation rod 110 and a head 120 as a holding fitting attached to the tip of the insulation operation rod 110.

  The insulating operation rod 110 is formed of a cylindrical (pipe-shaped) insulating member. As the insulating member, an insulating member such as an epoxy resin reinforced plastic, a polyester resin reinforced plastic, or the like, which is not easily deformed and whose insulating property does not deteriorate is used. In order to prevent an electric shock accident, a safety limit collar 111 for clarifying the boundary between the portion that can be gripped and the other portion is fitted and fixed to the intermediate portion of the insulating operation rod 110.

  The length from the tip to which the head 120 is attached to the safety limit collar 111 is 600 mm (safety limit distance) or more. Further, as a measure against rain, a draining collar 112 is fitted and fixed between the tip of the insulating operation rod 110 and the position where the safety limit collar 111 is fixed. The safety limit collar 111 and the draining collar 112 are made of soft synthetic rubber.

  The head 120 is a portion that holds a holding object such as an electric wire in the indirect hot wire operation. The head 120 is formed of an aluminum alloy, for example, in a C-shaped clamp shape. The head 120 has a head main body 121 whose one end constitutes a fixed grip piece 122 and a movable grip piece 124 attached to the head main body 121 via a screw shaft 123 so as to be movable in the axial direction of the screw shaft 123. have.

  Here, the other end side of the head main body 121 is attached to the tip of the insulating operation rod 110, and a movable grip piece 124 is fixed to one end side of the screw shaft 123. The other end side of the screw shaft 123 is the head main body portion. It passes through the other end side of 121 and enters a certain position inside the distal end side of the insulating operating rod 110. By rotating the insulating operation rod 110, the protrusion length of the screw shaft 123 toward the head 120 can be increased / decreased depending on the rotation direction, and therefore the distance between the fixed grip piece 122 and the movable grip piece 124 is adjusted. It is possible.

  A circular gear member 125 formed of a metal member such as an aluminum alloy is fixed at a position facing the tip of the insulating operation rod 110 of the head 120. The circular gear member 125 is formed with teeth protruding in the distal direction of the insulating operation rod 110 along the circumferential direction on the outer peripheral side of the plate surface. A lock mechanism 113 is attached to the tip of the insulating operation rod 110 at a position facing the circular gear member 125 fixed to the head 120. In addition, an operation mechanism 114 is provided along the longitudinal direction of the insulating operation rod 110 so that the user can operate locking and unlocking by the lock mechanism 113 at hand.

  The operation mechanism 114 is configured such that a rod 115 formed of an insulating material such as an epoxy resin reinforced plastic or a polyester resin reinforced plastic is supported by a support member 116. Here, the support member 116 is a rod-like member, and is in a state of being planted on the insulating operation rod 110. A through hole is formed on the upper end side of the support member 116. The rod 115 is inserted into the through hole of the support member 116 and is supported by the support member 116 so as to be movable in the longitudinal direction of the insulating operation rod 110. One end of the rod 115 is connected to the operation unit of the lock mechanism 113. The other end of the rod 115 is positioned on the rear end side from the safety limit collar 111, and a grip portion 117 is fixed to the other end of the rod 115.

  The lock mechanism 113 will be described with reference to FIGS. The locking mechanism 113 includes a locking claw 131 formed of a metal member such as an aluminum alloy, and a claw holding portion 132 that holds the locking claw 131 movably in the longitudinal direction of the insulating operation rod 110. ing. The claw holder 132 is formed using an insulating material such as epoxy resin reinforced plastic or polyester resin reinforced plastic.

  The locking claw 131 is formed in a prismatic shape as a whole, but the tip portion facing the teeth of the circular gear member 113 fixed to the head 120 has a tapered wedge shape. The claw holding part 132 includes a base part 132 </ b> A and a lid part 132 </ b> B fixed to the distal end side of the insulating operation rod 110. A guide groove 133 having a rectangular cross section extending in the longitudinal direction of the insulating operation rod 110 is formed on the upper portion of the base portion 132A. The guide groove 133 is formed so that its cross section is slightly larger than the cross section of the locking claw 131.

  Thus, the above-mentioned locking claw 131 is disposed inside the guide groove 133 formed in the base portion 132A. Then, a lid portion 132B is fixed to the upper surface of the base portion 132A using, for example, screws 134 in order to prevent the locking claws 131 arranged in the guide grooves 133 from coming off upward.

  As described above, the columnar operation element 131a is integrally formed on the upper surface side of the locking claw 131 disposed in the guide groove 133 of the base portion 132A. As shown in FIGS. 4 and 5, the lid portion 132 </ b> B is provided with a rectangular opening 135, and the columnar operation element 131 a is led out through the opening 135. As described above, the locking claw 131 held by the claw holding part 132 is moved and operated in the longitudinal direction of the insulating operation rod 110 using the above-described operation element 131a.

  A cap portion 119 is fixed to one end of the rod 115 constituting the operation mechanism 114 described above so as to be rotatable by a connecting portion 118. The connecting portion 118 and the cap portion 119 are also formed using an insulating material such as an epoxy resin reinforced plastic or a polyester resin reinforced plastic. The operation element 131 a of the locking claw 131 is press-fitted into the cap part 119. Accordingly, by moving the rod 115 in the longitudinal direction of the insulating operation rod 110, the locking claw 131 can be moved in the longitudinal direction of the insulating operation rod 110.

  The lock mechanism 113 has a position holding mechanism in addition to the configuration described above. That is, in the base portion 132A of the claw holding portion 132, a hole 136 having, for example, a rectangular cross section is formed at a predetermined depth in the bottom surface portion of the guide groove 133. A compression coil spring 137 and a bearing portion 138 in which the bearing 138a is rotatably held are accommodated in this hole 136 in this order. In this case, the bearing portion 138 is urged by the compression coil spring 137 so that a part of the bearing 138 a protrudes from the hole 136.

  Further, on the surface of the locking claw 131 that faces the bottom surface of the guide groove 133, when the locking claw 131 is in the locked position and when the locking claw 131 is in the unlocked position, A groove 139 having a semicircular cross section extending in a direction perpendicular to the longitudinal direction of the insulating operation rod 110 is formed at a position facing the position of the hole 136.

  In the lock mechanism 113 described above, in the unlocked state in which the locking claw 131 is in the unlocked position, the bearing portion 138 is biased by the compression coil spring 137 as shown in FIG. The upper part of the bearing 138 a is engaged with the groove 139 of the locking claw 131. Therefore, the locking claw 131 is stably held in this state.

  In order to change from the unlocked state to the locked state, when the rod 115 is moved in the longitudinal direction of the insulating operation rod 110, the bearing portion 138 is moved by the lower surface of the locking claw 131 as shown in FIG. It is pushed into the hole 136 against the urging force of the compression coil spring 137, and the locking claw 131 is moved in that state. In this case, the bearing 138a is in contact with the lower surface of the locking claw 131, and the locking claw 131 moves smoothly.

In the locked state in which the locking claw 131 has moved to the locked position, as shown in FIG. 5C, the bearing portion 138 is biased by the compression coil spring 137, so that the upper portion of the bearing 138a is engaged. It is engaged with the groove 139 of the pawl 131. Therefore, the locking claw 131 is stably held in this state.

  In the above description, the operation when the locking claw 131 moves from the unlocked position to the locked position has been described. However, the operation when the locking claw 131 moves from the locked position to the unlocked position is described above. The operation is the reverse of that performed.

  In the above-described stray link tongue 100, when the locking claw 131 of the lock mechanism 113 is in the unlocked position and is in the unlocked state, as shown in FIGS. 131 is not locked to the teeth of the circular gear member 125. Therefore, the user can increase or decrease the protruding length of the screw shaft 123 toward the head 120 side by rotating the insulating operation rod 110, and thus can adjust the interval between the fixed grip piece 122 and the movable grip piece 124. That is, in this unlocked state, for example, the electric wire holding state in which the electric wire 230 is held by the fixed holding piece 122 and the movable holding piece 124 can be set, or the electric wire holding state can be released.

  Further, in the above-described stray link tongue 100, when the user grasps the grip portion 117 and moves the rod 115 toward the head 120, the locking claw 131 of the lock mechanism 113 moves from the unlocked position to the locked position. It will be in a locked state. In this locked state, as shown in FIGS. 1B, 3, and 4, the locking claw 131 is locked to the teeth of the circular gear member 125, and the rotation of the insulating operation rod 110 is suppressed. Therefore, the electric wire is stably held without loosening the electric wire holding state in which the electric wire 230 is held by the movable holding piece 124 and the fixed holding piece 122.

  Further, in the above-described stray link tongue 100, when the user grips the grip portion 117 and pulls and moves the rod 115 toward the rear end side of the insulating operation rod 110, the locking claw 131 of the lock mechanism 113 is moved from the locked position. Move to the unlocked position and return to the unlocked state. Therefore, the user can release the electric wire holding state in which, for example, the electric wire 230 is gripped by the movable gripping piece 124 and the fixed gripping piece 122 by rotating the insulating operation rod 110.

  As described above, in the stray link tongue 100, the user can perform locking and unlocking operations with the operation mechanism 114 disposed along the insulating operation rod 110, and other indirect hot tool It is not necessary to use an electric wire, and labor and time in work such as electric wire holding can be reduced, and workability is improved.

  In the stray link tongue 100, the operating mechanism 114 is configured by a rod 115 made of an insulating material, and the user can operate locking and unlocking at hand, so that an electric shock can be prevented, and locking and unlocking can be performed safely and easily. An unlocking operation can be performed.

  In the stray link tongue 100, the locking mechanism 113 holds the locking claw 131 in the locked position and the unlocked position, and the locking claw 131 position holding mechanism (bearing portion 138, compression coil spring 137, groove 139). ), The user can recognize the lock position and the unlock position as the target position when the operation mechanism 114 performs the lock and unlock operation, which improves usability. Further, since the locking claw 131 is held at the locked position and the unlocked position by the position holding mechanism of the locking claw 131, the locked state or the unlocked state can be stably held. It is possible to prevent the locked state from being released.

  It should be noted that the position holding mechanism of the locking claw 131 is not limited to the above-described configuration, and other configurations can of course be taken. For example, instead of a configuration that restricts the movement of the locking claw 131, a configuration that restricts the movement of the rod 115 itself that constitutes the operation mechanism 114 may be adopted.

  Next, another embodiment of the present invention will be described. FIG. 6 shows a configuration example of a stray link tong 100A as another embodiment. 6, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted as appropriate.

  Similar to the above-described stray link tong 100, the stray link tong 100A includes an insulating operation rod 110 and a head 120 as a holding fitting attached to the tip of the insulation operation rod 110. A circular gear member 125 formed of a metal member such as an aluminum alloy is fixed at a position facing the tip of the insulating operation rod 110 of the head 120. In addition, a lock mechanism 113A is attached to the tip of the insulating operation rod 110 at a position facing the circular gear member 125 fixed to the head 120. In addition, an operation mechanism 114 </ b> A for the user to operate the lock mechanism 113 </ b> A to be locked and unlocked by hand is disposed along the longitudinal direction of the insulating operation rod 110.

  The operation mechanism 114A includes four rods 115a to 115d. Each of these rods is formed using an insulating material such as an epoxy resin reinforced plastic or a polyester resin reinforced plastic. The rod 115 a is disposed outside the insulating operation rod 110. As shown in FIGS. 7 and 8, one end of the rod 115a is rotatably connected to a connecting portion 140 provided at the rear end of the locking claw 131A constituting the lock mechanism 113A.

  Further, as shown in FIGS. 7 and 8, the other end of the rod 115a is rotatably connected to one end of the rod 115b. As shown in FIGS. 7 and 8, the rod 115 b is pivotally supported by an insulating operation rod 110 with a shaft 151. Here, one end side of the rod 115 b exists outside the insulating operation rod 110, and the other end side exists inside the insulating operation rod 110. The rod 115 a is supported by a support member 141 planted on the insulating operation rod 110. The rod 115a is inserted into the through hole of the support member 141, and is supported by the support member 141 so as to be movable in the longitudinal direction of the insulating operation rod 110.

  The rod 115c is disposed inside the insulating operation rod 110. One end of the rod 115c is pivotally connected to the other end of the rod 115b described above, as shown in FIGS. As shown in FIGS. 9 and 10, the other end of the rod 115c is rotatably connected to one end of the rod 115d. As shown in FIGS. 9 and 10, the rod 115 d is pivotally supported by the insulating operation rod 110 so as to be rotatable around a shaft 152. Here, one end side of the rod 115 d exists inside the insulating operation rod 110, and the other end side exists outside the insulating operation rod 110. A grip 117 is fixed to the other end of the rod 115d.

  The lock mechanism 113A is configured as shown in FIGS. The lock mechanism 113A is configured in the same manner as the lock mechanism 113 (FIGS. 2 to 5) in the above-described stray link tongue 100 except for the following points. That is, the locking claw 113A does not have the same operating element as the operating element 113a of the locking claw 113 in the lock mechanism 113, and instead is long enough to protrude the rear end side from the guide groove 133. At the rear end portion, the connecting portion 140 is provided to which the rod 115a is rotatably connected as described above. Further, as described above, since there is no operator in the locking claw 113A, the lid portion 132B constituting the claw holding portion 132 is provided with a rectangular opening (see FIGS. 4 and 5). Absent.

  In the above-described stray link tongue 100A, when the locking claw 131A of the lock mechanism 113A is in the unlocked position and is in the unlocked state, as shown in FIGS. 131A is not locked to the teeth of the circular gear member 125. Therefore, the user can increase or decrease the protruding length of the screw shaft 123 toward the head 120 side by rotating the insulating operation rod 110, and thus can adjust the interval between the fixed grip piece 122 and the movable grip piece 124. That is, in this unlocked state, for example, the electric wire holding state in which the electric wire 230 is held by the fixed holding piece 122 and the movable holding piece 124 can be set, or the electric wire holding state can be released.

  In the above-described stray link tongue 100A, when the user grips the grip portion 117 and pushes it toward the head 120, the rod 115d rotates counterclockwise, and the rod 115c moves to the rear end side of the insulating operation rod 110. Then, the rod 115b rotates counterclockwise, the rod 115a moves to the head 120 side, the locking claw 131A of the lock mechanism 113A moves from the unlocked position to the locked position, and is locked. When in this locked state, as shown in FIGS. 6B and 8, the locking claw 131 is locked to the teeth of the circular gear member 125, and the rotation of the insulating operation rod 110 is suppressed. The In this case, the electric wire 230 can be stably held without loosening the electric wire holding state in which the electric wire 230 is held by the movable holding piece 124 and the fixed holding piece 122.

  Further, in the above-described stray link tongue 100A, when the user grips the grip portion 117 and pulls it toward the rear end side of the insulating operation rod 110, the rod 115d rotates clockwise, and the rod 115c moves to the head 120 side. The rod 115b rotates clockwise, the rod 115a moves to the rear end side of the insulating operation rod 110, the locking claw 131A of the lock mechanism 113A moves from the locked position to the unlocked position, and returns to the unlocked state. In this state, the user can release the electric wire holding state in which, for example, the electric wire 230 is held by the movable holding piece 124 and the fixed holding piece 122 by rotating the insulating operation rod 110.

  As described above, in the stray link tong 100A, the user can perform the locking and unlocking operations with the operation mechanism 114A disposed along the insulating operation rod 110, and the stray link tong 100 described above. Similarly to the above, it is not necessary to use another indirect hot-wire tool, and labor and time in work such as electric wire holding can be reduced, and workability is improved.

  Further, in the stray link tong 100A, the operation mechanism 114A is configured by rods 115a to 115d made of an insulating material, and the user can operate locking and unlocking at hand as in the above-described stray link tong 100. Accidents can be prevented, and locking and unlocking operations can be performed safely and easily.

  Further, in the stray link tongue 100A, the lock mechanism 113A has a position holding mechanism (bearing portion 138, compression coil spring 137, groove 139) of the locking claw 131A. Similarly, the lock position and the unlock position can be recognized as target positions when the operation mechanism 114A performs the lock and unlock operations, and the usability is improved. In addition, since the locking claw 131A is held at the locked position and the unlocked position by the position holding mechanism of the locking claw 131A, similarly to the above-described stray link tong 100, the locked state or the unlocked state can be stabilized. For example, the locked state can be prevented from being inadvertently released.

  In addition, in the stray link tongue 100A, a part of the rods 115a to 115d constituting the operation mechanism 114A is disposed inside the insulation operation rod 110, and the periphery of the insulation operation rod 110 can be simplified. It can suppress that the rod which comprises mechanism 114A obstructs holding operation, such as a user's electric wire.

  In the above embodiment, the present invention is applied to the stray link tongs 100 and 100A. However, in the present invention, a head having a fixed gripping piece and a movable gripping piece is attached to the tip of an insulating operation rod. Of course, the present invention can be similarly applied to other indirect hot-line tools in which the movable gripping piece is moved by the rotation of the insulating operation rod to adjust the distance between the fixed gripping piece and the movable gripping piece. is there.

  The present invention can reduce labor and time in work such as electric wire holding and can improve workability, and can be applied to an indirect hot wire tool such as a stray link tong used for electric wire holding or the like.

It is a figure which shows the structural example of the stray link tongs as embodiment of this invention. It is a figure which shows the detailed structure (lock release state) of a lock mechanism and an operation mechanism. It is a figure which shows the detailed structure (lock state) of a lock mechanism and an operation mechanism. It is a figure which shows the detailed structure (lock state) of a lock mechanism and an operation mechanism. It is the figure which cut | disconnected a part which shows the detailed structure of a locking mechanism. It is a figure which shows the structural example of the stray link tong as other embodiment of this invention. It is a figure which shows the detailed structure (lock release state) of a lock mechanism and an operation mechanism. It is a figure which shows the detailed structure (lock state) of a lock mechanism and an operation mechanism. It is a figure which shows the detailed structure (lock release state) of an operation mechanism. It is a figure which shows the detailed structure (locked state) of an operation mechanism. It is a figure which shows the structural example of the conventional stray link tong. It is a figure for demonstrating the operation | movement of a stray link tong.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100,100A ... Stray link tong, 110 ... Insulation operation rod, 111 ... Safety limit collar, 112 ... Draining collar, 113, 113A ... Lock mechanism, 114 ... Operation mechanism, 115 115a to 115d ... rods 116, 141 ... support members, 117 ... grip parts, 118, 140 ... connection parts, 119 ... cap parts, 120 ... heads, 121 ... Head body 122... Fixed gripping piece 123... Screw shaft 124... Movable gripping piece 125 125 Circular gear member 131, 131 A. Operating element 132 ... Claw holder 132A ... Base part 132B ... Lid part 133 ... Guide groove 134 ... Screw 135 ... Opening 136 ... Hole 137 ... Compression coil bar , 138 ... bearing part, 138a ... bearing, 139 ... groove, 151 and 152 ... shaft, 230 ... wire

Claims (3)

A head having a fixed gripping piece and a movable gripping piece is attached to the tip of the insulating operating rod, and the movable gripping piece is moved by rotation of the insulating operating rod so as to move between the fixed gripping piece and the movable gripping piece. An indirect hot wire tool that adjusts the interval of
A circular gear member fixed at a position facing the tip of the insulating operation rod of the head, and formed with teeth protruding in the tip direction of the insulating operation rod along the circumferential direction on the outer peripheral side of the plate surface;
A locking mechanism that is attached to a position of the insulating operation rod facing the head and locks the insulating operation rod so as not to rotate by engaging a locking claw with the teeth of the circular gear member;
The rod is made of an insulating material disposed along the longitudinal direction of the insulating operation rod, one end is connected to the lock mechanism, the other end is extended to the user gripping position of the insulating operation rod, and the other end indirect hot-line engineering tools, characterized in that it comprises an operating mechanism for operating the release of the lock and the lock by the locking mechanism by operation of. The lock mechanism holds the locking pawl in the locked and unlocked positions, indirect hot-engineering tool according to claim 1, characterized in that it comprises a position holding mechanism for nail the locking. The indirect hot wire tool according to claim 1 , wherein at least a part of the rod is disposed inside the insulating operation rod.

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