JP2019137488A - Tension member support device and tension member disassembling method - Google Patents

Abstract

To ensure support of a tension member and to miniaturize a device more than ever before.SOLUTION: A frame 61 is attached to a lower tension member 30 so as to be restricted for rotation against the lower tension member 30. A roller 80 is provided by only one shaft for one frame 61. The roller 80 is disposed on a side Z2 below the lower tension member 30 in a state where the tension member 25 is drooped, and on the side Z2 below the lower tension member 30 in a state where the tension member 25 is folded on a rear side X2. A rotary shaft 80a of the roller 80 with respect to the frame 61 is disposed on a side X1 before a center shaft 30a in the state where the tension member 25 is drooped.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a tension member support device that supports a tension member of a gantry of a crane, and a tension member disassembling method.

  For example, in FIG. 10 and FIG. 16 of Patent Document 1, a tension member of a crane gantry is described. 14 and 15 of the same document describe a roller support that supports the lower end of the tension member from below. As shown in FIG. 14 of the document, this roller support prevents the tension member from interfering with the ground and being damaged (see paragraph 0091 of the document).

JP 2014-40323 A

  However, the roller support shown in FIG. 15 of the same document is only connected to the tension member and is not connected to the tension member. Therefore, the tension member may fall from the roller support and interfere with the ground. Further, paragraph 0096 of the document describes that a roller support is attached to a tension member so as to be rotatable. In this case, when the roller support moves on the ground, the roller support rotates with respect to the tension member, and the tension member may interfere with the ground. As described above, in the roller support described in the document, the support of the tension member is not reliable.

  Further, the roller of the roller support described in FIG. 15 of the same document is provided with two axes. For this reason, the roller support may become large (details will be described later).

  Accordingly, an object of the present invention is to provide a tension member support device that can reliably support a tension member and that can be downsized as compared with the related art.

  The tension member support device is a tension member that constitutes a gantry attached to a swing frame of a crane and supports the tension member that can be bent in the front-rear direction of the swing frame from below when the gantry is assembled and disassembled. . The tension member support device includes a frame and a roller. The frame is attached to a lower tension member constituting a lower portion of the tension member, and rotation with respect to the lower tension member is restricted. The roller is rotatably attached to the frame. The roller is provided with only one shaft in one frame, and is below the lower tension member when the tension member is suspended and when the tension member is bent rearward. It is arranged below the lower tension member. The rotation shaft of the roller with respect to the frame is disposed in front of a central axis extending in the longitudinal direction of the lower tension member when the tension member is suspended.

  With the above configuration, the tension member can be reliably supported, and the apparatus can be made smaller than before.

It is the figure which looked at the crane in which a tension member support device is used from the side. It is the figure which looked at the state at the time of disassembly and assembly of the gantry 20 shown in FIG. 1, and is a figure which shows the state in which the tension member 25 was bent by the rear side X2. FIG. 3 is a perspective view of the tension member support device 50 and the like shown in FIG. 2. It is the figure which expanded the tension member support apparatus 50 shown in FIG. It is F5 arrow line view of FIG. It is F6-F6 arrow sectional drawing of FIG. FIG. 3 is a view corresponding to FIG. 2 showing a state in which the tension member 25 shown in FIG. FIG. 8 is a perspective view of the tension member support device 50 and the like shown in FIG. 7. It is the figure which expanded the tension member support apparatus 50 shown in FIG. FIG. 8 is a view corresponding to FIG. 7 in which the state of the gantry 20 shown in FIG.

  The crane 1 shown in FIG. 1, the tension member support device 50 used in the crane 1 shown in FIG. 2, and the support member 90 shown in FIG. 10 will be described with reference to FIGS.

  As shown in FIG. 1, the crane 1 is a construction machine that performs an operation of lifting a suspended load using a boom 15. The crane 1 includes a lower traveling body 11, a turning frame 13, a boom 15, a gantry 20, and a hoisting device 40.

  The lower traveling body 11 causes the crane 1 to travel. The lower traveling body 11 may include a crawler, for example, and may include a wheel, for example.

  The turning frame 13 can turn with respect to the lower traveling body 11 and is disposed on the upper side Z <b> 1 from the lower traveling body 11. A boom 15 or the like is attached to the revolving frame 13. The direction of the rotation axis of the turning frame 13 with respect to the lower traveling body 11 is defined as a vertical direction Z. In the vertical direction Z, a side from the lower traveling body 11 toward the turning frame 13 is an upper side Z1, and the opposite side is a lower side Z2. The longitudinal direction of the revolving frame 13 is defined as the front-rear direction X. In the front-rear direction X, the side from the tension member attachment portion 13a (described later) toward the attachment portion of the boom 15 to the revolving frame 13 is defined as a front side X1, and the opposite side is defined as a rear side X2. A direction perpendicular to the vertical direction Z and the front-rear direction X is defined as a horizontal direction Y. The turning frame 13 includes a tension member attaching portion 13a.

  The tension member attaching portion 13a is disposed at the rear X2 end portion of the revolving frame 13. The tension member attaching portion 13a is a portion to which a lower portion (lower Z2 portion) of a tension member 25 (described later) is attached. The tension member attaching portion 13a has a pin hole into which the tension member connecting pin 13b can be inserted. The tension member connection pin 13 b is a pin for attaching the tension member 25 to the turning frame 13.

  The boom 15 is attached to the front side X1 portion of the revolving frame 13 so as to be rotatable (can be undulated) with respect to the revolving frame 13. The direction of the rotation axis of the boom 15 with respect to the turning frame 13 is the lateral direction Y. Hereinafter, the direction of the rotation axis of rotation of each member is the horizontal direction Y.

  The gantry 20 is a structure that supports the boom 15 from the rear side X2. The gantry 20 is attached to the turning frame 13. The gantry 20 includes a compression member 21 and a tension member 25.

  The compression member 21 is attached to the turning frame 13 so as to be able to rotate (raise and lower) with respect to the turning frame 13. The compression member 21 can be raised and lowered with respect to the revolving frame 13 by expansion and contraction of the telescopic cylinder 23 shown in FIG. The telescopic cylinder 23 is attached to the turning frame 13.

  As shown in FIG. 1, the tension member 25 is connected to the tip end portion (rear side X2 end portion) of the compression member 21 and the tension member attaching portion 13a. The tension member 25 is formed by connecting a plurality of link members. Two tension members 25 are provided, one on each side in the lateral direction Y (left and right). FIG. 1 shows only one tension member 25 out of the two tension members 25. Each of the two tension members 25 includes an upper tension member 27 and a lower tension member 30. As shown in FIG. 2, the tension member 25 can be bent in the front-rear direction X. The tension member 25 can be bent around a rotation axis extending in the lateral direction Y.

  As shown in FIG. 1, the upper tension member 27 constitutes an upper Z1 portion (for example, an upper half) of the tension member 25 when the gantry 20 is assembled. The upper tension member 27 is rotatably connected to the upper Z1 end portion of the compression member 21.

  The lower tension member 30 constitutes a lower Z2 portion (for example, the lower half) of the tension member 25 when the gantry 20 is assembled. The lower tension member 30 is rotatably connected to the lower Z2 end of the upper tension member 27. The lower tension member 30 shown in FIG. 2 can be bent with respect to the upper tension member 27 in the rear side X2 and the front side X1. The lower tension member 30 is formed by connecting a plurality of link members (not shown). In a state where a plurality of link members constituting the lower tension member 30 are assembled, the lower tension member 30 cannot be bent. A central axis of the lower tension member 30 extending in the longitudinal direction of the lower tension member 30 is defined as a central axis 30a. As shown in FIG. 3, the lower tension member 30 includes a lower tension member main body 31 and a tension member lower pin hole 33.

  The lower tension member main body 31 includes, for example, two plate-like structures 31a. The two plate-like structures 31a and 31a are arranged at intervals in the horizontal direction Y and face each other in the horizontal direction Y. The lower tension member main body 31 may be constituted by a single plate-like structure. As shown in FIG. 9, the lower tension member main body 31 includes a contour forming surface 32.

  The contour constituting surface 32 is a surface constituting the contour of the lower tension member 30 when viewed from the lateral direction Y. The contour forming surface 32 faces the radially outer side of the support device connection pin 71 (described later). The contour constituting surface 32 includes, for example, an axially extending surface 32a, an axially orthogonal extending surface 32b, and an inclined surface 32c. The axially extending surface 32a extends parallel to the central axis 30a (may be substantially parallel). The axially extending surface 32a is a surface on the front side X1 of the lower tension member 30 when the tension member 25 is in a suspended state (see FIG. 7). When viewed from the lateral direction Y, the axis orthogonal direction extending surface 32b extends in a direction orthogonal to the central axis 30a (may be a substantially orthogonal direction). The axially orthogonal direction extending surface 32b is a surface on the lower side Z2 of the lower tension member 30 when the tension member 25 is in a suspended state. The inclined surface 32c is connected to the axially extending surface 32a and the axially orthogonal extending surface 32b and extends in a direction inclined with respect to the central axis 30a. The inclined surface 32c is a surface connected to the lower Z2 surface of the lower tension member 30 and the front X1 surface when the tension member 25 is in a suspended state.

  As shown in FIG. 3, the tension member lower pin hole 33 is formed at the end of the lower tension member main body 31 opposite to the side to which the upper tension member 27 (see FIG. 2) is connected. “End” means an end and a portion in the vicinity thereof (the same applies hereinafter). The tension member lower pin hole 33 is used for two purposes. Specifically, the tension member lower pin hole 33 is a pin hole into which the tension member connection pin 13b for connecting the lower tension member 30 to the revolving frame 13 is inserted as shown in FIG. Further, as shown in FIG. 3, the tension member lower pin hole 33 is also a pin hole into which the support device connection pin 71 for connecting the tension member support device 50 to the lower tension member 30 is inserted. The tension member lower pin hole 33 is a long hole. The longitudinal direction of the tension member lower pin hole 33 coincides with the direction in which the central axis 30a (see FIG. 2) extends. Since the tension member lower pin hole 33 is a long hole, alignment between the tension member lower pin hole 33 and another pin hole is facilitated. The tension member lower pin hole 33 may not be a long hole.

  As shown in FIG. 1, the hoisting device 40 raises and lowers the boom 15 with respect to the turning frame 13. The hoisting device 40 includes a sheave 41, a spreader 43, a guy line 45, and a hoisting rope 47. The sheave 41 is a pulley device provided at the distal end portion of the compression member 21. The spreader 43 is a pulley device that is disposed above the sheave 41 when the crane 1 is in a working posture. The guy line 45 is connected to the spreader 43 and the tip of the boom 15. The guy line 45 includes at least one of a link member (guy link) and a rope (guy rope). The hoisting rope 47 is hung on the sheave 41 and the spreader 43. The hoisting rope 47 is fed out and wound up by a winch (not shown) provided in the revolving frame 13. As the hoisting rope 47 is fed and wound, the distance from the sheave 41 to the spreader 43 is changed, and the boom 15 is raised and lowered with respect to the turning frame 13.

  A mast may be provided between the boom 15 and the gantry 20. This mast is attached to the revolving frame 13 so that it can be raised and lowered, and supports the boom 15 from the rear side X2. In this case, the gantry 20 supports the boom 15 from the rear side X2 as a result of supporting the mast from the rear side X2. In this case, the hoisting device 40 hoists the boom 15 as a result of hoisting the mast.

  As shown in FIG. 2, the tension member support device 50 is a device that supports the tension member 25 from the lower side Z2 when the gantry 20 is assembled and disassembled. The tension member support device 50 is attached to the lower tension member 30. The tension member support device 50 can be attached to and detached from the lower tension member 30. As shown in FIG. 4, the tension member support device 50 includes a frame portion 60, a pin portion 70, and a roller 80.

  The frame portion 60 includes a frame 61, a frame pin hole 62 (pin hole), a stopper 63, a frame suspension ring 64, a leg 65, and a frame handle 66. The frame 61, the stopper 63, the frame suspension ring 64, the legs 65, and the frame handle 66 are fixed to each other and provided integrally.

  The frame 61 is attached to the lower Z2 portion of the lower tension member 30. The frame 61 is attached to the lower Z2 portion of the lower tension member 30 when the tension member 25 is in a suspended state (see FIG. 7). The frame 61 is attached to the rear X2 portion and the lower Z2 portion of the lower tension member 30 when the tension member 25 is bent to the rear side X2 (see FIG. 2). The rotation of the frame 61 relative to the lower tension member 30 is restricted. For example, as shown in FIG. 5, the frame 61 is disposed between the two plate-like structures 31 a and 31 a in the lateral direction Y of the lower tension member main body 31. For example, as shown in FIG. 5, the frame 61 includes a frame side plate 61a and a frame center portion 61b. The frame side plate 61a is a plate that constitutes the left and right side surfaces (both sides in the lateral direction Y outside) of the frame 61. The frame center portion 61b is a portion that connects the frame side plates 61a in the lateral direction Y. The frame center portion 61b is configured by, for example, a plate-like member.

  The frame pin hole 62 (pin hole) is a pin hole that is formed in the frame 61 and into which a support device connection pin 71 (described later) can be inserted. As shown in FIG. 6, for example, the frame pin hole 62 connects holes (inner surfaces) formed in the two frame side plates 61 a and 61 a to holes formed in the two frame side plates 61 a and 61 a. Cylinder (inner surface thereof) (a part of the frame central portion 61b).

  As shown in FIG. 3, the stopper 63 restricts the rotation of the frame 61 relative to the lower tension member 30 around the support device connection pin 71. The stopper 63 is fixed to the frame 61 and welded to the frame 61, for example. As shown in FIG. 5, the stopper 63 protrudes left and right (on both sides in the lateral direction Y) from the frame 61. The stopper 63 may include, for example, a plate-like member, or a rib that reinforces the plate-like member. The stopper 63 may be a block-like member, for example. As shown in FIG. 4, the stopper 63 can contact the contour forming surface 32 of the lower tension member 30. In the example shown in FIG. 4, the stopper 63 is in contact with the axially extending surface 32a, for example, may be in contact with the axially orthogonal extending surface 32b, or may be in contact with the inclined surface 32c. The restriction of rotation by the stopper 63 may be such that the frame 61 can rotate within a predetermined range with respect to the lower tension member 30. For example, the frame 61 with respect to the tension member 25 from the state where the stopper 63 is in contact with the axially extending surface 32a (the state as shown in FIG. 4) to the state where the stopper 63 is in contact with the inclined surface 32c (not shown). May be rotatable.

  The frame suspension ring 64 is a portion on which a hanging tool for lifting the tension member support device 50 can be hung. The frame hanging ring 64 is fixed to the frame 61 and welded to, for example, the frame 61 (the same applies to the leg 65 and the frame handle 66). The legs 65 hold (support) the tension member support device 50 with respect to the ground G. For example, the leg 65 holds the tension member support device 50 against the ground G in a state where the frame handle 66 protrudes to the upper side Z <b> 1 from the roller 80. The frame handle 66 is a handle for facilitating the operator to carry the tension member support device 50.

  As shown in FIG. 5, the shaft portion 67 supports the roller 80 with respect to the frame 61. The shaft portion 67 is fixed to the frame 61, for example, to the frame side plate 61a. The shaft portion 67 protrudes on both sides (left and right) outside the frame 61 in the lateral direction Y.

  The pin part 70 can be attached to and detached from the frame part 60. The pin portion 70 includes a support device connection pin 71, a retaining member 73, and a washer 75.

  As shown in FIG. 3, the support device connection pins 71 detachably connect the frame 61 to the lower tension member 30. As shown in FIG. 5, the support device connection pin 71 can be inserted into the frame pin hole 62 and the tension member lower pin hole 33 (see FIG. 3). The support device connection pins 71 are preferably light enough to be handled by human power. For example, the support device connection pin 71 includes a pin main body portion 71a, a plate-like portion 71b, and a pin handle 71c. The pin main body 71 a is a part that is inserted into the frame pin hole 62. As shown in FIG. 6, the pin main body 71a is hollow and cylindrical. In this case, the pin body 71a can be made lighter than when the pin body 71a is solid. The pin body 71a may be solid. The plate-like portion 71b is provided at an end portion in the axial direction of the pin body portion 71a and is fixed (for example, welded) to the pin body portion 71a. The plate-like portion 71b can contact the side surface (the surface on the outer side in the lateral direction Y) of the lower tension member main body 31. As shown in FIG. 5, the pin handle 71 c is a handle for facilitating the operator to carry the support device connection pin 71.

  The retaining member 73 is a member (a retaining pin) that prevents the support device connecting pin 71 from coming off from the tension member lower pin hole 33 (see FIG. 3) and the frame pin hole 62. The retaining member 73 is detachably attached to the distal end portion of the pin main body 71a. The retaining member 73 projects from the pin main body 71a to the outside in the radial direction of the pin main body 71a.

  As shown in FIG. 6, the washer 75 is a member that prevents the retaining member 73 from interfering with the lower tension member 30. The washer 75 is a member that prevents the lower tension member 30 from being damaged. When the tension member lower pin hole 33 (see FIG. 4) is a long hole, the washer 75 prevents the retaining member 73 from entering the tension member lower pin hole 33. The washer 75 is disposed between the side surface of the lower tension member main body 31 and the retaining member 73. The washer 75 is detachably inserted into the pin body 71a. The washer 75 has a plate shape and a ring shape.

  As shown in FIG. 4, the roller 80 rolls (rolls) on the ground G while supporting the lower tension member 30. The roller 80 is rotatably attached to the frame 61. At least a part of the roller 80 is disposed on the lower side Z2 with respect to the lower Z2 end portion of the lower tension member 30 when the tension member 25 is bent to the rear side X2. As shown in FIG. 9, at least a part of the roller 80 is disposed on the lower side Z2 relative to the lower Z2 end of the lower tension member 30 when the tension member 25 is suspended (see FIG. 7). The

  The roller 80 is preferably configured (arranged) so that the stability in the lateral direction Y is as high as possible. As shown in FIG. 6, a plurality of rollers 80 are provided, for example, two. The rollers 80 are disposed on both sides of the lower tension member body 31 on the outer side in the lateral direction Y from the left and right side surfaces (left side from the left side and right side from the right side).

  As shown in FIG. 4, the roller 80 is disposed so that a part of the roller 80 and the lower tension member 30 overlap when viewed from the lateral direction Y. In this case, the lower tension member 30 can be supported at a position closer to the ground G (lower Z2) as compared with the case where the roller 80 and the lower tension member 30 do not overlap when viewed in the lateral direction Y. A rotation shaft of the roller 80 with respect to the frame 61 is a rotation shaft 80a. The roller 80 includes a bearing portion 81, a wheel 83, and a tire 85.

  The rotation shaft 80a is provided on one frame 61 (on one tension member support device 50), and only one shaft is provided. As shown in FIG. 2, when the tension member 25 is bent to the rear side X2, as shown in FIG. 4, the rotation shaft 80a is disposed on the lower side Z2 with respect to the central shaft 30a. As shown in FIG. 7, when the tension member 25 is in a suspended state, as shown in FIG. 9, the rotation shaft 80a is disposed on the front side X1 with respect to the central shaft 30a. For example, when the tension member 25 is suspended, the position of the rotary shaft 80a in the up-down direction Z is substantially the same as the position of the up-down direction Z as the axis orthogonal direction extending surface 32b. For example, when the tension member 25 is suspended, the position of the rotary shaft 80a in the front-rear direction X is substantially the same as the position in the front-rear direction X of the axially extending surface 32a of the lower tension member 30. It is the front side X1 from the extended surface 32a.

  As shown in FIG. 6, the bearing portion 81 is attached to the shaft portion 67 so that the roller 80 can rotate with respect to the shaft portion 67. The wheel 83 is disposed between the bearing portion 81 and the tire 85, and supports the tire 85 from the radially inner side (the radially inner side of the roller 80). As shown in FIG. 4, the tire 85 is a portion that contacts the ground G and is attached to a radially outer portion of the wheel 83. The material of the tire 85 is preferably rubber. In this case, even if there are protrusions such as pebbles on the ground G, the roller 80 is not easily caught by the protrusions. As shown in FIG. 6, the tire 85 is preferably solid. In this case, it is not necessary to maintain the air pressure of the tire 85, and the tire 85 is not punctured. The material of the tire 85 may not be rubber. Instead of the tire 85, for example, a wheel made of metal or the like may be provided. The tire 85 may be hollow.

  As shown in FIG. 10, the support member 90 is used when the gantry 20 is disassembled. When the lower tension member 30 and the tension member support device 50 are lowered from the position Z1 above the support member 90, the support member 90 moves the lower Z2 end portion of the lower tension member 30 and the tension member support device 50 to the rear side. Move to X2. The support member 90 is not used when the gantry 20 is assembled. The support member 90 includes an inclined surface 91.

  The inclined surface 91 (slope) is inclined with respect to the horizontal direction (lowered toward the rear side X2) so that the rear side X2 is disposed on the lower side Z2. The roller 80 rolls on the inclined surface 91. The inclined surface 91 includes a first inclined surface 91a and a second inclined surface 91b. The first inclined surface 91a extends linearly when viewed from the lateral direction Y. The second inclined surface 91b suppresses the roller 80 from falling from the inclined surface 91 to the front side X1. The second inclined surface 91b is disposed on the front side X1 with respect to the first inclined surface 91a. The inclination of the second inclined surface 91b with respect to the front-rear direction X is larger than the inclination of the first inclined surface 91a with respect to the front-rear direction X (the inclination is steep). In addition, without using the support member 90, the inclined surface 91 may be provided using, for example, an inclined ground G. For example, it is good also considering the ground G which inclines so that it may go down toward the back side X2 as the inclined surface 91. FIG. For example, a surface of a plate placed on the ground G that is inclined so as to descend toward the rear side X2 may be used as the inclined surface 91.

(Assembly of gantry 20)
The assembly of the gantry 20 (see FIG. 1) will be described along the assembly procedure. Note that the procedure may be changed.

  In the state shown in FIG. 2, the compression member 21 is attached to the turning frame 13. The tension member 25 is attached to the compression member 21 and bent to the rear side X2. The upper tension member 27 is suspended from the compression member 21. The lower tension member 30 extends from the lower Z2 end of the upper tension member 27 to the rear side X2.

  With the tension member 25 bent to the rear side X2, the tension member support device 50 is attached to each of the left and right lower tension members 30. The details of this attachment are as follows.

  First, one (for example, the right side) lower tension member 30 is lifted by an auxiliary crane or the like. Next, the tension member support device 50 is aligned with the lower tension member 30. At this time, for example, the movement of the tension member support device 50 is performed by an operator's human power (not necessarily performed by human power). At this time, for example, as shown in FIG. 4, the stopper 63 is disposed on the lower side Z <b> 2 with respect to the lower Z <b> 2 surface (axially extending surface 32 a) of the lower tension member 30. Then, by simply lowering the lower tension member 30 and placing the lower tension member 30 on the stopper 63, the lower tension member 30 can be aligned in the vertical direction Z with respect to the tension member support device 50. Further, the tension member lower pin hole 33 and the frame pin hole 62 are aligned (communicated). Here, when the tension member lower pin hole 33 is a long hole that is long in the direction of the central axis 30a (substantially in the front-rear direction X), the tension member support device 50 is aligned with the lower tension member 30 in the direction of the central axis 30a. Is easy.

  Next, the support device connection pin 71 is inserted into the tension member lower pin hole 33 and the frame pin hole 62. For example, insertion of the support device connection pin 71 is performed by an operator's human power (it may not be performed by human power). At this time, for example, as shown in FIG. 6, the plate-like portion 71 b comes into contact with the side surface (the surface on the outer side in the lateral direction Y) of the lower tension member main body 31. Next, the washer 75 is attached to the tip of the pin main body 71a. Next, the retaining member 73 is attached to the pin main body 71a. Thereby, as shown in FIG. 2, the attachment of the tension member support device 50 to one (for example, the right side) lower tension member 30 is completed. Similarly, the tension member support device 50 is attached to the other (for example, the left) lower tension member 30.

  Next, the spreader 43 is lifted by an auxiliary crane or the like. Here, when the spreader 43 is lifted after the tension member support device 50 is attached to the lower tension member 30, the spreader 43 can be lifted using an auxiliary crane that lifts the lower tension member 30.

  Next, the compression member 21 is awakened. Then, the upper tension member 27 moves to the upper side Z1. Then, the end of the lower tension member 30 on the upper tension member 27 side (front side X1) moves to the upper side Z1. Then, the end of the lower tension member 30 on the side opposite to the upper tension member 27 side (front end side, rear side X2) and the tension member support device 50 move to the front side X1. At this time, the roller 80 rolls on the ground G. At this time, the lower tension member 30 moves to the front side X1 while being supported by the tension member support device 50 from the lower side Z2. Therefore, the lower tension member 30 does not interfere with the ground G.

  The compression member 21 is further raised and raised and lowered as necessary (the raising and lowering angle is adjusted). Then, as shown in FIG. 7, the entire tension member 25 hangs down and the roller 80 is left on the ground G (state A). Here, as shown in FIG. 9, when the tension member lower pin hole 33 is a long hole extending in the direction of the central axis 30a, the adjustment of the undulation angle of the compression member 21 such that the state A shown in FIG. Can be easily performed.

  Next, the tension member support device 50 is removed from the lower tension member 30. This removal is performed by a procedure reverse (or almost reverse) to the attachment of the tension member support device 50 to the lower tension member 30. When the tension member support device 50 shown in FIG. 2 is attached, the lower tension member 30 is lifted by the auxiliary crane. On the other hand, when the tension member support device 50 is removed in the state A shown in FIG. 7, the lower tension member 30 is lifted by the compression member 21, so an auxiliary crane for lifting the lower tension member 30 is not necessary.

  Next, as shown in FIG. 1, when the compression member 21 is further raised, the tension member 25 moves to the upper side Z1. Then, the compression member 21 is raised and lowered so that the position of the tension member lower pin hole 33 and the position of the pin hole of the tension member attaching portion 13a shown in FIG. Then, the tension member connection pin 13b is inserted into the tension member lower pin hole 33 and the pin hole of the tension member attaching portion 13a. As a result, the tension member 25 is connected to the turning frame 13. Thereafter, for example, the boom 15 and the like are assembled, and the crane 1 is in a working posture.

(Disassembly of gantry 20)
The disassembly of the gantry 20 is basically performed in the reverse procedure to the assembly of the gantry 20 described above. In the following, differences in the disassembly of the gantry 20 will be mainly described with respect to the procedure opposite to the assembly of the gantry 20.

  In a state where the tension member 25 is removed from the revolving frame 13, the compression member 21 is turned down and the tension member 25 is lowered (moved to the lower side Z2). Then, as shown in FIG. 7, the tension member support device 50 is attached to each of the left and right lower tension members 30. The details of this attachment are as follows.

  The lower Z2 end of the lower tension member 30 is disposed in the vicinity of the ground G on the upper side Z1 of the ground G. The position of the tension member support device 50 with respect to the lower tension member 30 is adjusted by moving the tension member support device 50 and raising and lowering the compression member 21. At this time, for example, as shown in FIG. 9, the stopper 63 is disposed on the front side X <b> 1 with respect to the axially extending surface 32 a of the lower tension member 30. Further, the positions of the tension member lower pin hole 33 and the frame pin hole 62 are aligned. Here, when the tension member lower pin hole 33 is a long hole extending in the direction of the central axis 30a (vertical direction Z), the tension member lower pin hole 33 and the frame pin hole 62 can be easily aligned in the vertical direction Z. It is. Next, as in the assembly of the gantry 20 (see FIG. 1), the support device connection pin 71 is attached to the tension member lower pin hole 33 and the frame pin hole 62. Thereby, the attachment of the tension member support device 50 to the lower tension member 30 is completed.

  Next, as shown in FIG. 10, the compression member 21 is raised to raise the tension member 25 and the tension member support device 50. Next, the inclined surface 91 (for example, the support member 90) is disposed on the lower side Z2 from the roller 80 and at a position facing the roller 80 in the vertical direction Z (directly below the roller 80). For example, the arrangement of the support member 90 is performed by an operator's human power (not necessarily performed by human power).

  Next, the compression member 21 is turned down so that the tension member 25 is lowered. Then, the roller 80 rolls on the inclined surface 91 and moves to the rear side X2. At this time, the configuration (inclination angle, length, etc.) of the inclined surface 91 is set so that the roller 80 can roll the inclined surface 91 to the rear side X2. As a result of the movement of the roller 80 to the rear side X2, the tip end portion (lower Z2 end portion) of the lower tension member 30 moves to the rear side X2. As a result, the lower tension member 30 is bent to the rear side X2 with respect to the upper tension member 27. At this time, the worker applies human power to the rear side X2 (for example, pushing or pulling by hand) on at least one of the lower tension member 30 and the tension member support device 50 (hereinafter referred to as “lower tension member 30”). There is no need. Once the tension member 25 is bent to the rear side X2, the tip portion (rear side X2 end portion) of the lower tension member 30 is further moved to the rear side X2 only by further lowering the compression member 21. The worker may apply human power to the lower tension member 30 or the like. In this case, compared with the case where the inclined surface 91 is not used, it is possible to reduce the operator's human power that needs to be applied to the lower tension member 30 and the like.

(Problem when the roller 80 is not provided)
When the device for supporting the lower tension member 30 shown in FIG. 2 from the lower side Z2 is not provided, there is the following problem [Problem 1]. [Problem 1] In this case, the lower tension member 30 interferes with the ground G when the compression member 21 is raised and lowered with the tension member 25 bent to the rear side X2. Then, the lower tension member 30 may be damaged.

  Further, when the compression member 21 is raised and lowered, it is conceivable that the lower tension member 30 is lifted (supported from the upper side Z1) with an auxiliary crane or the like so that the lower tension member 30 does not interfere with the ground G. When this lifting is performed, there are the following problems [Problem 2-1] to [Problem 2-4]. [Problem 2-1] Two auxiliary cranes, that is, an auxiliary crane for lifting the lower tension member 30 and an auxiliary crane for lifting the spreader 43 are required. [Problem 2-2] Further, it is necessary to coordinately operate the undulation of the compression member 21 and the auxiliary crane that lifts the lower tension member 30, which takes time. [Problem 2-3] The tension members 25 are provided on the left and right sides (two are provided). Therefore, it is necessary to lift the two lower tension members 30. In order to lift the left and right lower tension members 30 at the same time, it is conceivable to use a hanging tool such as a hanging beam. In this case, it is necessary to prepare a hanging beam or the like. [Problem 2-4] If a suspension beam or the like cannot be prepared, two auxiliary cranes are required for lifting the lower tension member 30. Then, three auxiliary cranes are required for lifting the spreader 43 and lifting the lower tension member 30.

  On the other hand, in this embodiment, when the compression member 21 is raised and lowered with the tension member 25 bent to the rear side X2, the roller 80 supports the lower tension member 30 while supporting the lower tension member 30 (or the inclined surface 91 (FIG. 10). Roll))). Therefore, even if the lower tension member 30 is not lifted by the auxiliary crane, the compression member 21 can be raised and lowered while the tension member 25 is bent to the rear side X2. Therefore, [Problem 1] and [Problem 2-1] to [Problem 2-4] do not occur.

(Problem when the roller support is not connected to the lower tension member 30)
When the lower tension member 30 is only placed on a roller support (for example, see FIG. 16 of Patent Document 1) that supports the lower tension member 30 and is not connected to the lower tension member 30, the lower tension member 30 is supported by the roller. There is a risk of falling from the body. Then, the lower tension member 30 may interfere with the ground G, and the lower tension member 30 may be damaged. Moreover, it takes time and effort to lift the lower tension member 30 that has fallen from the roller support with an auxiliary crane and place it on the roller support.

(Problem when the roller support is rotatable relative to the lower tension member 30)
When the rotation of the roller support relative to the lower tension member 30 is not restricted, there is the following problem. In this case, there is a possibility that the roller support rotates with respect to the lower tension member 30 when the roller 80 rolls on the ground G in the front-rear direction X. Then, the roller support cannot support the lower tension member 30, and the lower tension member 30 may interfere with the ground G, and the lower tension member 30 may be damaged. Moreover, it takes time and effort to lift the lower tension member 30 with an auxiliary crane or the like in order to return the roller support rotated with respect to the lower tension member 30 to its original position.

  Further, when the rotation of the roller support relative to the lower tension member 30 is not restricted and the two rollers 80 are provided, the following problem arises. In this case, the biaxial roller 80 is not necessarily grounded when the roller 80 rolls on the ground G in the front-rear direction X. There is a possibility that the uniaxial roller 80 is lifted from the ground G (disposed on the upper side Z1 from the ground G). Then, each of the biaxial rollers 80 needs to have a strength that can appropriately support the load of the lower tension member 30. Therefore, although the two rollers 80 are provided, the roller 80 and the structure supporting the roller 80 cannot be made smaller than when only one roller 80 is provided. For this reason, the roller support may be increased in size.

(Problem when the roller support is restricted from rotating with respect to the lower tension member 30 and the roller 80 is provided with two axes)
When rotation of the roller support relative to the lower tension member 30 is restricted and two rollers 80 are provided so as to sandwich the center shaft 30a, there are the following problems. In this case, as shown in FIG. 7, when the compression member 21 is turned down and the tension member 25 is lowered while the tension member 25 is entirely suspended, the biaxial roller 80 may be grounded. In this state, the roller support does not move in the front-rear direction X even if the compression member 21 is further lowered. Then, the load applied to the roller support becomes larger than the load due to the mass of the lower tension member 30. For example, the load applied to the roller support is a load due to the mass of the entire tension member 25 and the mass of the tip side portion of the compression member 21. Therefore, it is necessary to enlarge the roller 80 and the structure that supports the roller 80 as compared with the case where only the load due to the mass of the lower tension member 30 is applied to the roller support. For this reason, the roller support may be increased in size.

  Further, when the rotation of the roller support with respect to the lower tension member 30 is restricted and the two rollers 80 are provided so as to sandwich the central shaft 30a, the following problems arise. In this case, when the roller 80 is rolling on the ground G in the front-rear direction X, only the one-axis roller 80 is grounded, and the other-axis roller 80 is lifted from the ground G. Even if such a roller 80 on the side floating from the ground G is provided, the roller support is simply increased in size.

  On the other hand, in the tension member support device 50 of the present embodiment, the above problems can be suppressed as follows. The tension member support device 50 may be able to suppress only some of the above problems.

(effect)
The effects of the tension member support device 50 shown in FIG. 2 are as follows.

(Effect of the first invention)
The tension member support device 50 supports the tension member 25 that can be bent in the front-rear direction X of the revolving frame 13 from the lower side Z2 when the gantry 20 is assembled and disassembled. The tension member 25 constitutes a gantry 20 attached to the swing frame 13 of the crane 1. As shown in FIG. 4, the tension member support device 50 includes a frame 61 and a roller 80.

  [Configuration 1-1] The frame 61 is attached to the lower tension member 30 constituting the lower portion (lower Z2 portion) of the tension member 25 shown in FIG. As shown in FIG. 4, the rotation of the frame 61 relative to the lower tension member 30 is restricted. The roller 80 is rotatably attached to the frame 61.

  [Configuration 1-2] The roller 80 is provided on one frame 61 with only one axis.

  [Configuration 1-3] As shown in FIG. 7, the roller 80 is disposed on the lower side Z2 with respect to the lower tension member 30 when the tension member 25 is suspended. As shown in FIG. 2, the roller 80 is disposed on the lower side Z2 than the lower tension member 30 when the tension member 25 is bent to the rear side X2.

  [Configuration 1-4] As shown in FIG. 9, the rotation shaft 80a of the roller 80 with respect to the frame 61 is more than the central shaft 30a extending in the longitudinal direction of the lower tension member 30 when the tension member 25 is suspended. Arranged on the front side X1.

  In the above [Configuration 1-1], as shown in FIG. 4, the rotation of the frame 61 relative to the lower tension member 30 is restricted. Therefore, the problem that the frame 61 rotates with respect to the lower tension member 30, the roller 80 floats from the ground G, and the lower tension member 30 interferes with the ground G can be suppressed. Therefore, the tension member support device 50 can stably support the tension member 25 (the lower tension member 30).

  With the above [Configuration 1-2], the tension member support device 50 can be reduced in size as compared with the case where the roller 80 is provided with two or more axes on one frame 61.

  The roller 80 is arranged as in [Configuration 1-3] above. Therefore, the roller 80 moves the lower tension member 30 to the lower side Z2 regardless of whether the tension member 25 is suspended as shown in FIG. 7 or the tension member 25 is bent to the rear side X2 as shown in FIG. Can be supported from. Therefore, the tension member support device 50 can stably support the tension member 25.

  The tension member support device 50 includes the above [Configuration 1-2] and [Configuration 1-4]. Therefore, as shown in FIG. 7, when the lower tension member 30 is lowered while the roller 80 is in contact with the flat ground G, the roller 80 moves to the front side X1. Then, the lower tension member 30 bends forward X1 with respect to the upper tension member 27. Therefore, it is difficult for the roller 80 to receive a load larger than the load due to the mass of the lower tension member 30 (the load is likely to escape). Therefore, the required strength of the roller 80 and the structure (frame portion 60) that supports the roller 80 can be reduced as compared with the case where a load larger than the load due to the mass of the lower tension member 30 is applied to the roller 80. Therefore, the tension member support device 50 can be reduced in size.

(Effect of the second invention)
[Configuration 2-1] As shown in FIG. 3, a plurality of rollers 80 are provided.

  [Configuration 2-2] The rollers 80 are disposed on both sides (left and right sides) on the outer side in the lateral direction Y with respect to the surface on the outer side in the lateral direction Y of the lower tension member 30.

  With the above [Configuration 2-1], the load applied to one roller 80 can be reduced as compared with the case where only one roller 80 is provided. Therefore, the required strength of the roller 80 and the structure (frame portion 60) that supports the roller 80 can be reduced, and the tension member support device 50 can be downsized.

  With the above [Configuration 2-2], the stability in the lateral direction Y of the tension member support device 50 is compared with the case where the roller 80 is disposed only in the lateral direction Y with respect to the laterally outer side surface of the lower tension member 30. Can be high. Therefore, the tension member support device 50 can support the tension member 25 more stably.

  The tension member support device 50 includes the above [Configuration 2-1] and [Configuration 2-2]. Therefore, compared to the case where one roller 80 is provided from the right side of the lower tension member 30 to the left side of the lower tension member 30 (continuously) from the right side of the lower tension member 30 (when α is assumed), the following An effect is obtained. As compared with the case α, the width of the roller 80 in the lateral direction Y can be narrowed (thinned). Therefore, the tension member support device 50 can be reduced in size. Further, the rotation shaft 80 a (see FIG. 4) of the roller 80 can be easily disposed near the lower tension member 30 as compared with the case α. Therefore, the tension member support device 50 can support the lower tension member 30 more stably.

(Effect of the third invention)
[Configuration 3] As shown in FIG. 4, the tension member support device 50 includes support device connection pins 71. The support device connection pin 71 can be inserted into a tension member lower pin hole 33 (pin hole) formed in the lower tension member 30 and a frame pin hole 62 (pin hole) formed in the frame 61. The support device connection pins 71 removably connect the frame 61 to the lower tension member 30.

  The tension member support device 50 includes the above [Configuration 3]. Therefore, the tension member support device 50 can be easily removed from the lower tension member 30 when the tension member support device 50 is not used. Further, the tension member support device 50 can be easily attached from the lower tension member 30 before the tension member support device 50 is used.

(Effect of the fourth invention)
[Configuration 4] The tension member support device 50 includes a stopper 63 fixed to the frame 61. The stopper 63 comes into contact with a surface (contour forming surface 32) constituting the contour of the lower tension member 30 when viewed from the lateral direction Y, and rotates around the support device connection pin 71 of the frame 61 with respect to the lower tension member 30. To regulate.

  In the above [Configuration 4], the rotation of the frame 61 relative to the lower tension member 30 is restricted by the stopper 63. Therefore, in order to restrict the rotation of the frame 61 relative to the lower tension member 30, it is not necessary to use a pin (hereinafter referred to as “another pin”) different from the support device connection pin 71. Therefore, when attaching the tension member support device 50 to the lower tension member 30, it is not necessary to align the pin holes of other pins. Therefore, it is possible to easily attach the tension member support device 50 to the lower tension member 30 as compared with the case where other pins need to be used. Further, since it is not necessary to use other pins, forgetting to remove or forget other pins does not occur. Therefore, there is no problem that other pins, the frame 61, etc. are broken (for example, bent) due to forgetting to remove or insert other pins. Therefore, it is possible to easily attach and detach the tension member support device 50 to the lower tension member 30. Further, since it is not necessary to use other pins, it is not necessary to provide pin holes for inserting other pins in the lower tension member 30 and the frame 61. Therefore, the lower tension member 30 and the frame 61 can be simply configured.

  In the above [Configuration 4], the stopper 63 contacts the contour configuration surface 32 of the lower tension member 30. Therefore, it is not necessary to provide a dedicated member for contacting the stopper 63 in the lower tension member 30.

(Effect of the fifth invention)
[Configuration 5] The support device connection pin 71 can be inserted into a pin hole (tension member lower pin hole 33) formed in the lower tension member 30. As shown in FIG. 1, the tension member lower pin hole 33 is a pin hole into which a pin (tension member connection pin 13 b) for attaching the lower tension member 30 to the revolving frame 13 can be inserted.

  In the above [Configuration 5], the tension member lower pin hole 33 is used both for inserting the tension member connecting pin 13b and for inserting the supporting device connecting pin 71 shown in FIG. Therefore, it is not necessary to provide the lower tension member 30 with a pin hole dedicated for inserting the support device connection pin 71 (only for mounting the tension member support device 50).

  The effects of the tension member 25 disassembling method of this embodiment are as follows.

(Effect of the sixth invention)
[Configuration 6] As shown in FIG. 10, the tension member 25 is lowered while the tension member support device 50 is attached to the lower tension member 30. As the tension member 25 is lowered, the roller 80 rolls the inclined surface 91 to the rear side X2. The inclined surface 91 is inclined with respect to the horizontal plane so that the rear side X2 is disposed on the lower side Z2.

  In the above [Configuration 1-2] and [Configuration 1-4], the rotation shaft 80a of the roller 80 is provided with only one shaft on the front side X1 with respect to the central shaft 30a when the tension member 25 is suspended. Therefore, as shown in FIG. 7, when the tension member 25 is lowered while the roller 80 is in contact with the flat ground G, the roller 80 moves to the front side X1. On the other hand, the disassembly work of the tension member 25 shown in FIG. 2 is usually performed in a state where the lower tension member 30 is bent to the rear side X2 with respect to the upper tension member 27. Therefore, the tension member 25 disassembling method of the present embodiment includes the above [Configuration 6]. Therefore, as shown in FIG. 10, simply by lowering the tension member 25, the roller 80 moves to the rear side X2, and the lower tension member 30 bends to the rear side X2 with respect to the upper tension member 27 (or easily bends). . Therefore, the operator does not need to apply human power to the rear side X2 on at least one of the lower tension member 30 and the tension member support device 50. Alternatively, it is possible to reduce the operator's human power that needs to be applied to the lower tension member 30 and the like.

(Modification)
The above embodiment may be variously modified. For example, the arrangement and shape of each component may be changed. For example, the number of components may be changed, and some of the components may not be provided. For example, the fixing and connection between the components may be direct or indirect.

  For example, the shape and presence / absence of each component of the frame unit 60 shown in FIG. 4 may be changed. For example, in place of the stopper 63, the “other pin” may be provided. For example, the stopper 63 may restrict the rotation of the frame 61 relative to the lower tension member 30 by contacting a member or the like fixed to the lower tension member 30. For example, at least one of the frame suspension ring 64, the legs 65, and the frame handle 66 may not be provided.

DESCRIPTION OF SYMBOLS 1 Crane 13 Turning frame 20 Gantry 25 Tension member 30 Lower tension member 50 Tension member support device 61 Frame 63 Stopper 71 Support device connection pin 80 Roller 80a Rotating shaft 91 Inclined surface X Longitudinal direction X1 Front side X2 Rear side Z2 Lower side

Claims (6)

A tension member support device that supports a tension member that constitutes a gantry attached to a swing frame of a crane and that can be bent in the front-rear direction of the swing frame from below when the gantry is assembled and disassembled. And
A frame that is attached to a lower tension member that forms a lower portion of the tension member and is restricted from rotating with respect to the lower tension member;
A roller rotatably mounted on the frame;
With
The roller is provided with only one shaft in one frame, and is below the lower tension member when the tension member is suspended and when the tension member is bent rearward. It is arranged below the lower tension member,
The rotation axis of the roller with respect to the frame is disposed on the front side of the central axis extending in the longitudinal direction of the lower tension member when the tension member is suspended.
Tension member support device. The tension member support device according to claim 1,
A plurality of the rollers are provided,
The rollers are disposed on both sides laterally outside the laterally outer surface of the lower tension member.
Tension member support device. The tension member support device according to claim 1 or 2,
A pin hole formed in the lower tension member; and a support device connecting pin that can be inserted into the pin hole formed in the frame and detachably connects the frame to the lower tension member;
Tension member support device. The tension member support device according to claim 3,
Comprising a stopper fixed to the frame;
The stopper is in contact with a surface constituting the contour of the lower tension member when viewed from the side, and restricts rotation of the frame around the support device connection pin with respect to the lower tension member;
Tension member support device. The tension member support device according to claim 3 or 4,
The support device connection pin is a pin hole formed in the lower tension member and can be inserted into a pin hole into which a pin for attaching the lower tension member to the turning frame can be inserted.
Tension member support device. In a state where the tension member support device according to any one of claims 1 to 5 is attached to the lower tension member, the tension member is lowered,
When the tension member is lowered, the roller rolls the inclined surface to the rear side,
The inclined surface is inclined with respect to a horizontal plane so that the rear side is arranged on the lower side,
Tension member disassembly method.

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