JP2009012147A - Tool for mounting lock ring into tube - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform both a reduction and an expansion of a diameter of a lock ring by using only one tool, in which driving force is worked in one direction, in a tool for mounting a lock ring into a tube. <P>SOLUTION: A pair of arms 42A, 42B is formed in a scissors shape rotatable around a supporting point 41 defined as a rotary center. Each arm has main bodies 45A, 45B and crossed portions 46A, 46B. When one of the main bodies 45A, 45B and one of the crossed portions 46A, 46B are opened by rotation of both the arms 42A, 42B, the others are closed. Diameter reducing claws 55, 55 for reducing the diameter of the lock ring when the arms 42A, 42B have rotated are provided in the crossed portions 46A, 46B, respectively. Diameter expanding claws 59, 59 for forcedly expanding both ends of a member which constitutes the divided parts of the lock ring to circumferentially expand both the ends away from each other when the arms 42A, 42B have rotated in the same direction as the rotation, are provided in the main bodies 45A, 45B, respectively. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a lock ring mounting tool in a pipe.

  As a pipe to be used for applications such as water pipes, an insertion port formed at the end of the other pipe is inserted into the reception port formed at the end of one of the pipes joined to each other. The annular sealing material is compressed between the inner periphery of the insertion port and the outer periphery of the insertion port, and a protrusion formed on the outer periphery of the insertion port is formed on the lock ring mounted on the inner periphery of the reception port. What has a pipe joint comprised so that separation of the insertion opening from a receptacle may be prevented by hitting from the back side is known (patent documents 1).

  FIG. 8 shows a state when a lock ring is attached to a receiving port constituting such a pipe joint. That is, 11 is a ductile cast iron pipe, and a receiving port 12 is formed at one end thereof. A lock ring receiving groove 13 is formed in an annular shape on the inner periphery of the receiving port 12. The lock ring receiving groove 13 includes a metal lock ring 14 and an outer peripheral surface of the lock ring 14 and an inner peripheral surface of the receiving groove 13 in order to hold the lock ring 14 concentrically with the receiving port 12. A rubber centering ring 15 sandwiched between the two is housed.

  As shown in FIG. 9, the lock ring 14 has a so-called circumferentially divided structure in which a divided portion 16 is formed at one place in the circumferential direction. Reference numerals 17 and 17 denote both end portions of a pair of members constituting the dividing portion 16. The member end portions 17 and 17 are respectively formed with recesses 18 and 18 that face the opening of the receiving port 12 when the lock ring 14 is received in the receiving groove 13. A meat stealing portion 19 opening inward in the radial direction is formed at an appropriate position along the circumferential direction of the lock ring 14. In the portion where the meat stealing portion 19 is formed, a thin portion 20 corresponding to the portion is formed.

  When the lock ring 14 having such a configuration is accommodated in the receiving groove 13 of the receiving port 12, the lock ring 14 in a natural state shown in FIG. By narrowing the divided portions 16 in the circumferential direction, the diameter of the lock ring 14 is reduced as indicated by phantom lines in FIG. 8, and then the reduced diameter lock ring 14 is inserted into the receiving port 12. When the inserted lock ring 14 reaches the position of the receiving groove 13, the reduced diameter state is released. Then, the lock ring 14 expands to its original size due to its elastic force, and fits into the receiving groove 13. Then, in order to center the lock ring 14 with respect to the receiving port 12 with certainty, the diameter of the lock ring 14 is increased by expanding the dividing portion 16 in the circumferential direction.

  FIG. 10 shows a state in which the diameter of the lock ring 14 is reduced by packing the divided portions 16 in the circumferential direction from a natural state. FIG. 11 shows a state where the dividing portion 16 is expanded in the circumferential direction to increase the diameter of the lock ring 14. Since the lock ring 14 is formed with the meat stealing portion 19 and has the thin portion 20 corresponding thereto, the diameter can be smoothly reduced or expanded.

  Conventionally, a diameter reducing tool as shown in FIG. 12 is used to reduce the diameter of the lock ring 14. The diameter reducing tool is formed in a bowl shape and has a pair of arms 22A and 22B that can swing around a fulcrum 21. One arm 22A has a first operating part 23A, a first driven part and 24A, and the other arm 22B has a second operating part 23B and a second driven part 24B. ing. That is, the pair of arms 22A and 22B are provided and operated in a point-symmetric state with the fulcrum 21 as the center. Reduced-diameter claws 25 and 25 are provided at the tips of the first and second actuating portions 23A and 23B, respectively. Then, as shown in FIG. 12 (a), the first and second actuating parts 23A and 23B are open to each other and the first and second driven parts 24A and 24B are open to each other. When the first and second driven parts 24A, 24B are turned around the fulcrum 21 in a closing direction by the above, the first and second actuating parts 23A, 23B are also fulcrum as shown in FIG. It turns in the direction which mutually closes around 21.

  Accordingly, the claws 25 and 25 of the diameter reducing tool in the open state shown in FIG. 12A are fitted into the recesses 18 and 18 of the lock ring 14 in the natural state shown in FIG. As shown in FIG. 12B, when the first and second driven parts 24A and 24B are swung around the fulcrum 21, the first and second actuating parts 23A and 23B are also closed. By turning, the diameter of the lock ring 14 can be reduced as shown in FIG. 10B, and the reduced diameter state can be maintained.

  Therefore, the diameter-reduced lock ring 14 is inserted into the receiving port 12 shown in FIG. 8 together with the diameter reducing tool, and acts on the first and second driven parts 24A and 24B at the position of the receiving groove 13. When the force is released, the lock ring 14 expands in diameter due to elasticity and fits inside the receiving groove 13. Thereafter, the diameter-reducing claws 25, 25 are extracted from the recesses 18, 18 of the lock ring 14, and the diameter-reducing tool is taken out of the receiving port 12.

  Conventionally, a diameter expanding tool as shown in FIG. 13 is used for expanding the diameter of the lock ring fitted in the receiving groove 13 as described above. This diameter expanding tool is formed in a bowl shape like the above-mentioned diameter reducing tool, but its structure and operation are different. That is, the illustrated diameter expanding tool has a pair of arms 27A and 27B that can swing around a fulcrum 26. One arm 27A has a first operating portion 28A and a first driven portion 29A, and the other arm 27B has a second operating portion 28B and a second driven portion 29B. That is, the pair of arms 27 </ b> A and 27 </ b> B are provided and operated in a line-symmetric state with the fulcrum 26 as the center. Diameter expanding claws 30 and 30 are provided at the tips of the first and second operating portions 28A and 28B, respectively. Then, as shown in FIG. 13 (a), the first and second actuating parts 28A and 28B are closed from each other and the first and second driven parts 29A and 29B are opened from each other. When the first and second driven parts 29A and 29B are swung around the fulcrum 26 in a closing direction by pressure or the like, the first and second actuating parts 28A and 28B, as shown in FIG. It pivots around the fulcrum 26 so as to open each other.

  Therefore, the diameter-enlarging tool in the closed state shown in FIG. 13 (a) is inserted into the receiving port 12 of the tube 11 shown in FIG. 8, and the claws 30 and 30 are inserted into the receiving grooves shown in FIG. 11 (a). When the first and second driven portions 29A and 29B are swung in the direction of closing around the fulcrum 26 as shown in FIG. As a result, the first and second actuating portions 28A, 28B are swung in the opening direction, and as shown in FIG. 11 (b), the member end portions 17, 17 are pressed in the circumferential direction to expand the diameter of the lock ring 14, Thereby, the centering of the lock ring 14 can be performed reliably.

When the diameter of the lock ring 14 is increased, the first and second actuating portions 28A and 28B are swung again in the closing direction so as to be separated from the member end portions 17 and 17 of the lock ring 14 and receive the diameter increasing tool in that state. Remove to the outside of the mouth 12.
Japanese Utility Model Publication 4-90790

  Thus, in the prior art, after the lock ring 14 is mounted in the receiving groove 13 of the receiving port 12 shown in FIG. 8 using the lock ring reducing tool shown in FIG. 12, the lock ring diameter increasing tool shown in FIG. In order to expand the diameter of the split portion 16 of the lock ring 14. For this reason, there exists a subject that the work man-hour for replacement | exchange of a tool is needed. This man-hour includes man-hours for the operator to pick up a tool, man-hours for attaching / detaching the tool to / from the actuator that holds the driven parts 24A, 24B, 29A, 29B and applies the driving force. .

  In addition, if the actuator not only drives the driven parts 24A, 24B, 29A, and 29B to turn in the closing direction as described above, but also drives them to turn in the opening direction, one tool is reduced in diameter. However, in this case, another problem arises that the structure of the actuator becomes extremely complicated.

  Accordingly, an object of the present invention is to enable both the diameter reduction and the diameter expansion of a lock ring with only one tool on which a driving force is applied in one direction.

  In order to achieve this object, the present invention provides a mounting tool for mounting a lock ring having a split portion formed at one place in the circumferential direction inside a pipe, and a pair of arms that can pivot about a fulcrum. Each arm has a main body portion and an intersecting portion, and is arranged so that the intersecting portions of both arms intersect each other at a position farther from the fulcrum than the main body portion. When the one of the crossing portion opens, the other closes, and either the main body portion or the crossing portion can be engaged with the end of the member constituting the split portion of the lock ring. In addition, when the pair of arms pivots in the engaged state, an engagement portion for reducing the diameter of the lock ring is provided by bringing the end portions of the members close to each other, and either the main body portion or the intersecting portion is provided. On the other hand, the lock ring When the pair of arms pivots in the same direction as the case where the pair of arms reduce the diameter of the lock ring in the engaged state, the end portions of the members are mutually engaged. A diameter-enlarging engagement portion that expands the lock ring by pushing it in the circumferential direction is provided.

  According to the present invention, the pair of arms has a main body portion and an intersecting portion, and when one of the main body portion and the intersecting portion is opened by turning both arms, the other is closed, Since one of the two portions is provided with a diameter reducing engagement portion and the other is provided with a diameter expanding engagement portion, the lock ring can be contracted only by one-way movement of the pair of arms in the opening direction or the closing direction. It is possible to combine the functions of performing diameter and diameter expansion. For this reason, both the diameter reduction and diameter expansion of the lock ring can be performed with only one tool on which the driving force is applied in one direction.

  1 to 3 show a lock ring mounting tool in a tube according to an embodiment of the present invention. The mounting device 40 has a pair of first and second arms 42A and 42B that can swing and swing about a fulcrum 41, and is formed in a bowl shape. The first arm 42A has a first operating part 43A and a first driven part 44A, and the second arm 42B has a second operating part 43B and a second driven part 44B. is doing. That is, the pair of arms 42 </ b> A and 42 </ b> B are provided so as to be symmetric with respect to the fulcrum 41 and operate.

  The first operating portion 43A of the first arm 42A includes a main body portion 45A provided at a position on the arm proximal end side near the fulcrum 41, and an intersecting portion provided at a position closer to the distal end side of the arm than the main body portion 45A. 46A. Similarly, the second actuating portion 43B of the second arm 42B is provided at a position on the arm proximal end side close to the fulcrum 41, and at a position closer to the distal end side of the arm than the main body portion 45B. And an intersecting portion 46B.

  The intersecting portion 46A of the first arm 42A is pivoted from one surface 48 parallel to the pivoting direction of the first arm 42A at the tip of the main body 45A of the first operating portion 43A. It has the 1st extension part 49 formed so that the 2nd operation part 43B of the 2nd arm 42B might be extended along a moving direction. That is, the first extending portion 49 has a proximal end portion connected to the surface 48 at the distal end of the main body portion 45A, and a distal end portion extending from the main body portion 45A to the second arm 42B. The second actuating part 43B is formed so as to extend in the direction where it is located. Further, a first projecting portion 50 formed to extend in a direction away from the fulcrum 41 is provided at the tip of the first extending portion 49.

  The intersecting portion 46B of the second arm 42B has an extension portion 51 integrally formed so as to be longer than the main body portion 45A of the first operating portion 43A from the tip of the main body portion 45B of the second operating portion 43B. A second extension portion 53 formed so as to extend from the end surface 52 of the extension portion 51 in a direction in which the first arm 42A is positioned along the turning swing direction of the second arm 42B; It has the 2nd protrusion part 54 formed so that it might extend from the position of the front-end | tip of the 2nd extension part 53 in the direction perpendicular | vertical to the turning rocking | fluctuation direction of the 2nd arm 42B.

  The intersecting portions 46A and 46B of the first and second arms 42A and 42B are arranged in a state of intersecting each other, and the first and second arms 42A and 42B are in the opening direction as shown in FIGS. When the turning operation is performed, the first projecting portion 50 and the second projecting portion 54 are configured to close each other, and the first and second arms 42A and 42B are operated to close each other. The protrusion 50 and the second protrusion 54 are configured to pivot in the opening direction.

  Diameter reduction claw portions 55 and 55 are provided at the tip of the first protrusion 50 and the tip of the second protrusion 54, respectively. These diameter-reducing claw portions 55 and 55 are arranged at positions aligned with each other by the intersection portions 46A and 46B having the above-described configuration, and together with the first and second projecting portions 50 and 54. It is configured to open and close.

  On the front end side of the main body portion 45A of the first arm 42A, a surface 58A opposite to the surface 48, and on the front end side of the main body portion 45B of the second arm 42B, a surface 58B on the same side as the surface 58A A diameter-enlarging claw portion 59 is provided for each.

  In other words, the diameter-reducing claw portion 55 is provided on the one surface 48 side of the first arm 42A, whereas the diameter-enlarging claw portions 59, 59 are formed by the first and second arms 42A, 42B is provided on the surface 58A, 58B side opposite to the surface 48.

  The diameter-enlarging claw portions 59, 59 are similarly opened / closed in response to the opening / closing turning operation of the first and second arms 42A, 42B.

  The mounting tool 40 is used in a state where the first and second driven parts 44A and 44B shown in FIG. 1 are accommodated in the actuator 60 as shown in FIGS. The actuator 60 is driven by air pressure or the like so that the first and second driven parts 44A, 44B pivot in the closing direction around the fulcrum 41. A driving force can be applied to 44B.

  In such a configuration, when the lock ring is mounted in the receiving groove of the receiving port, the arms 42A and 42B of the mounting tool 40 are moved in the direction of the axis of the lock ring 14 as shown in FIG. The locking ring 14 is brought close to the diameter reduction claw portions 55 and 55 into the recesses 18 and 18 of the locking ring 14. When the first and second projecting portions 50 and 54 of the first and second arms 42A and 42B are thus fitted with the diameter-reducing claw portions 55 and 55 into the recesses 18 and 18 of the lock ring 14, respectively. In addition, inclined surfaces 62 and 62 that can extend along the inner peripheral surface 61 of the lock ring 14 are formed. Accordingly, the diameter reducing claws 55 and 55 can be fitted into the recesses 18 and 18 of the lock ring 14 in a stable state.

  Next, the actuator 60 is actuated to drive the first and second arms 42A and 42B to pivot in a direction to open each other. Then, as described above, the diameter-reducing claw portions 55 and 55 move in the direction of closing each other, and as shown in FIG. 5, the divided portions 16 of the lock ring 14 are packed to elastically reduce the diameter of the lock ring 14.

  As a result, the lock ring 14 is held by the mounting tool 40 in a reduced diameter state, so that the lock ring 14 in this state is inserted into the inside of the receiving port 12 of the tube 11 together with the distal end portion of the mounting tool 40 as shown in FIG. To do. Then, by releasing the operating force by the actuator 60 at the position of the lock ring receiving groove, the lock ring 14 is expanded to the original state by the elastic force and fits into the receiving groove. At this time, since the diameter reducing claws 55 and 55 are disengaged from the recesses 18 and 18, the mounting tool 40 is taken out of the receiving port 12.

  Next, the wearing tool 40 is reversed, and the diameter-enlarging claw tools 59, 59 are fitted into the split portion 16 of the lock ring 14 as shown in FIG. Then, the actuator 60 is operated again, and the first and second operating portions 43A and 43B of the first and second arms 42A and 42B are driven to pivot in the direction to open each other, thereby increasing the diameter-enhancing nail tool 59, 59 also open each other, thereby expanding the diameter of the lock ring 14 so as to widen the dividing portion 16 in the circumferential direction, and the lock ring is reliably centered.

  Thus, the diameter-reducing claw portions 55 and 55 and the diameter-enlarging claw portions 59 and 59 are both turned by the actuator 60 in the direction of opening the first and second operating portions 43A and 43B of the wearing tool 40. A predetermined function can be achieved by driving, and both the diameter reduction and the diameter expansion of the lock ring 14 can be achieved simply by inverting and using one mounting tool 40 that is driven in one direction. It can be carried out.

  In the above description, the diameter-reducing claw portions 55, 55 are provided at the intersecting portions 46A, 46B of the arms 42A, 42B, and the diameter-enlarging claw portions 59, 59 are provided on the main body portions 45A, 45B. On the contrary, the diameter expanding claw portions 59 and 59 may be provided at the intersecting portions 46A and 46B, and the diameter reducing claw portions 55 and 55 may be provided at the main body portions 45A and 45B. Further, the first and second actuating parts 43A and 43B are opened when the first and second driven parts 44A and 44B are closed, but the first and second driven parts 44A, When 44B closes, 1st and 2nd operation part 43A, 43B may also be closed.

It is a figure which shows the lock ring mounting tool in the pipe | tube of embodiment of this invention. It is a perspective view of the principal part which shows the state which attached the actuator to the mounting tool of FIG. FIG. 3 is a perspective view showing a state in which the first and second arms are turned open from the state shown in FIG. 2. It is a figure which shows a mode that a lock ring is diameter-reduced using the mounting tool. It is a perspective view which shows a mode that the lock ring was hold | maintained in the diameter-reduced state with the mounting tool. It is a perspective view which shows a mode that the lock ring of the same diameter reduction state is inserted in the inside of the receptacle of a pipe | tube. It is a figure which shows a mode that diameter of a lock ring is expanded using the mounting tool. It is a figure which shows a mode that a lock ring is mounted | worn inside the receptacle of a pipe | tube. It is a perspective view of the lock ring in FIG. It is a figure which shows a mode that the diameter of the lock ring of FIG. 9 is reduced. It is a figure which shows a mode that the diameter of the lock ring of FIG. 9 is expanded. It is a figure which shows the conventional lock ring diameter reducing tool. It is a figure which shows the conventional lock ring diameter expanding tool.

Explanation of symbols

14 Lock ring 16 Dividing part 17 Member both ends 18 Recessed part 41 Support point 42A 1st arm 42B 2nd arm 45A Body part 45B Body part 46A Crossing part 46B Crossing part 55 Reduction diameter claw part 59 Expansion diameter claw part

Claims (1)

A mounting tool for mounting a lock ring in which a split portion is formed at one place in the circumferential direction inside the pipe,
A pair of arms is formed in a bowl shape that can turn around a fulcrum,
Each arm has a main body and an intersection,
It is arranged so that the intersecting part of both arms intersects each other at a position farther from the fulcrum than the main body part, and when one of the main body part and the intersecting part is opened by turning both arms, the other is closed. And
Either the main body part or the intersecting part can be engaged with a member end part constituting the split part of the lock ring, and the member end part is turned when the pair of arms are swung in the engaged state. An engagement portion for reducing the diameter of the lock ring to reduce the diameter of the lock ring by bringing the two close together,
When the other end of the main body and the intersecting portion can be engaged with the end of the member constituting the split portion of the lock ring, and the pair of arms reduce the diameter of the lock ring in the engaged state A lock ring mounting tool in a pipe, comprising: a diameter-enlarging engagement portion for expanding the lock ring by pushing the member end portions apart in the circumferential direction when swiveling in the same direction.

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