JP7275625B2 - Strut backstop device - Google Patents

Description

The present invention relates to a strut backstop arrangement having a crane strut backstop.

For example, FIG. 1 of Patent Document 1 describes a conventional crane. The crane has a boom, a jib hoistably attached to the boom, struts (front struts and rear struts in the same document) that hoist the jib, and a backstop that limits rotation of the struts relative to the boom. . The assembled crane is shown in FIGS. 4 and 5 of the document. When the crane is assembled, the boom is laid down and the strut (rear strut) is rotated rearward. At this time, it is necessary to prevent the backstop from interfering with the boom.

JP 2017-105559 A

To prevent the backstop from interfering with the boom, if the backstop is held in place against the strut before the strut is rotated rearward, the work for this holding is labor intensive. Further, when a member is provided for suppressing interference between the backstop and the boom (details will be described later), it is desirable to make this member as small and light as possible.

SUMMARY OF THE INVENTION Accordingly, the present invention provides a strut backstop device that facilitates the assembly work of a crane and that can reduce the size and weight of members for suppressing interference between the tip of the backstop and the boom. With the goal.

A strut backstop device is provided on a crane. The crane includes a boom, a jib and a strut. The boom is attached to the upper revolving structure so that it can rise and fall. The jib is hoistably attached to the boom. The strut is hoistably attached to the boom for hoisting the jib relative to the boom. The strut backstop device includes a backstop rotatably attached to the strut and an inclined portion provided on the boom. When the boom is in the collapsed state, the inclined portion is arranged at a position where the tip portion of the backstop suspended from the strut can come into contact with the inclined portion, and the inclined portion is arranged downward toward the tip side of the boom. incline against

With the above configuration, the assembly work of the crane can be easily performed, and the member for suppressing interference between the tip portion of the backstop and the boom can be reduced in size and weight.

It is the figure which looked at the crane 1 from the side. FIG. 2 is a side view of a strut 20 and the like when the crane 1 shown in FIG. 1 is in an assembled and disassembled state; FIG. 3 is a side view of a state in which the rear strut 23 is rotated to the rear side X2 from the state shown in FIG. 2; FIG. 4 is a side view showing a state in which the rear strut 23 is rotated to the rear side X2 from the state shown in FIG. 3; FIG. 5 is a side view showing a state in which the rear strut 23 has rotated forward X1 from the state shown in FIG. 4 ; It is the figure which looked at the backstop front-end|tip part 42 and the guide member 51 which are shown in FIG. 3 from the side. It is the figure which looked at the backstop front-end|tip part 42 shown in FIG. 5, the guide member 51, etc. from the side. 4 is a side view of the backstop tip portion 42 shown in FIG. 3; FIG. FIG. 9 is a cross-sectional view taken along line F9-F9 in FIG. 8; FIG. 7 is a view equivalent to FIG. 6 showing a lateral guide portion 160 and the like as a modification of the lateral guide portion 60 shown in FIG. 6; 11 is a cross-sectional view taken along line F11-F11 in FIG. 10; FIG.

The crane 1 having the strut backstop device 30 shown in FIG. 1 will be described with reference to FIGS. 1 to 11. FIG.

A crane 1 is a construction machine that performs work using a boom 15 and a jib 17 . The crane 1 includes a lower traveling body 11 , an upper revolving body 13 , a boom 15 , a jib 17 , a strut 20 and a strut backstop device 30 .

The undercarriage 11 allows the crane 1 to travel. The undercarriage 11 may include crawlers or wheels. The upper revolving body 13 is arranged above the lower traveling body 11 Z<b>1 and is rotatable with respect to the lower traveling body 11 . The upper swing body 13 includes a boom mounting portion 13b and a counterweight 13c. The boom attachment portion 13b is a portion to which the base end portion of the boom 15 is attached.

The boom 15 is attached to the upper slewing body 13 so as to be able to rise and fall. The boom 15 may be a lattice boom having a lattice structure, or a telescopic boom having a box-like structure and capable of telescoping. A case where the boom 15 is a lattice boom will be described below. The boom 15 can be disassembled and comprises a lower boom 15a, an intermediate boom 15b and an upper boom 15c. The lower boom 15a is provided on the most base end side of the boom 15 (the side attached to the upper swing body 13). The upper boom 15c is provided on the most tip side of the boom 15 (the side opposite to the side attached to the upper swing body 13). The intermediate boom 15b is provided between the lower boom 15a and the upper boom 15c. The number of intermediate booms 15b may be one or plural. The surface of the upper side Z1 of the boom 15 when the boom 15 is in a collapsed state (described later) is referred to as a boom rear surface 15e.

(definition of direction, etc.)
Let the vertical direction be an up-down direction Z (upper side Z1, lower side Z2). A lateral direction Y is the direction in which the axis of rotation of the boom 15 extends with respect to the upper revolving body 13 . A direction orthogonal to the up-down direction Z and the lateral direction Y is defined as a front-rear direction X (front side X1, rear side X2). The direction (longitudinal direction) in which the central axis of the boom 15 extends is defined as the "boom 15 axial direction". In the axial direction of the boom 15, the side from the base end of the boom 15 (the portion attached to the upper rotating body 13) toward the tip is defined as the "boom 15 front end side", and the opposite side is defined as the "boom 15 base end side". . As shown in FIG. 2, the boom 15 may fall down. The axial direction of the boom 15 is the front-rear direction X or substantially the front-rear direction X when the boom 15 is in the collapsed state. When the boom 15 is in a collapsed state, the tip side of the boom 15 is the front side X1, and the base end side of the boom 15 is the rear side X2. 2 to 7 illustrate the case where the axial direction of the boom 15 coincides with the longitudinal direction X when the boom 15 shown in FIG. 2 is in the collapsed state. Further, as shown in FIG. 1 , the longitudinal direction of the upper rotating body 13 is the front-rear direction X when the crane 1 is in a working posture (a posture in which work is possible). In the longitudinal direction X, the side (orientation) from the counterweight 13c toward the boom mounting portion 13b is the front side X1, and the opposite side is the rear side X2.

The jib 17 is attached to the boom 15 so as to be able to rise and fall (rotate). The lateral direction Y is the direction in which the axis of rotation of the jib 17 extends relative to the boom 15 . The axial direction of rotation of the rotating member among the members described below is the horizontal direction Y. As shown in FIG. The jib 17 is attached to the tip of the boom 15 (upper boom 15c). The jib 17 is a lattice jib having a lattice structure. The jib 17 can be disassembled, and includes a lower jib 17a, an intermediate jib 17b, and an upper jib 17c in order from the base end (the side attached to the boom 15) to the tip end. Note that the jib 17 may not have the intermediate jib 17b.

Strut 20 hoists jib 17 relative to boom 15 . The strut 20 includes a front strut 21 and a rear strut 23. Only one strut 20 may be provided (in this case, the following rear strut 23 is read as the strut 20).

The front strut 21 is attached to the jib 17 or the upper boom 15c so as to be able to rise and fall. The front strut 21 has a sheave provided at the tip of the front strut 21 . The tip of the front strut 21 and the tip of the jib 17 are connected by a jib guy line G1. The front strut 21 may have, for example, a lattice structure, or may have, for example, a box-shaped structure (similar to the rear strut 23).

The rear strut 23 is hoistably attached to the boom 15 (more specifically, the upper boom 15c). Below, the case where the crane 1 is in the working posture will be described. The rear strut 23 is arranged on the rear side X2 and the lower side Z2 of the front strut 21 . The rear strut 23 is arranged to extend from the upper boom 15c to the rear side X2. The rear strut 23 includes a rear strut proximal end portion 23f and a rear strut distal end portion 23t.

The rear strut base end portion 23 f is the end portion of the rear strut 23 that is attached to the boom 15 . The rear strut tip portion 23 t is the end portion of the rear strut 23 opposite to the side attached to the boom 15 . The rear strut 23 has a sheave provided at a rear strut tip portion 23t. The rear strut tip portion 23t and the boom 15 are connected by a strut guy line G3. A jib hoisting rope R1 is hung between the sheave of the rear strut tip portion 23t and the sheave of the tip portion of the front strut 21 . A winch (not shown) winds up and lets out the jib hoisting rope R1. Then, the distance between the tip of the front strut 21 and the tip of the rear strut 23t changes. As a result, the jib 17 rises and falls with respect to the boom 15 . The front strut 21 and the rear strut 23 may be connected so that the distance between the front strut 21 tip and the rear strut tip 23t is constant. In this case, the angle of the strut 20 with respect to the boom 15 may be changed by winding and unwinding the rope (similarly when only one strut 20 is provided).

The strut backstop device 30 includes a backstop 40, a boom side member 50, and a lateral guide portion 60 (see FIG. 6).

Backstop 40 is a rear strut backstop that limits rotation of rear strut 23 relative to boom 15 . A proximal end of the backstop 40 is rotatably connected to the rear strut 23 . The base end portion of the backstop 40 is connected to, for example, the central portion of the rear strut 23 in the longitudinal direction. As shown in FIG. 2 , the backstop 40 includes a backstop body portion 41 and a backstop tip portion 42 .

The backstop main body 41 is substantially bar-shaped and can be expanded and contracted (see FIG. 5). The backstop main body 41 may be provided with, for example, a hydraulic cylinder, or may be provided with a telescopic structure including a spring or the like.

The backstop tip portion 42 is the tip portion of the backstop 40 (the end portion opposite to the side connected to the rear strut 23). As shown in FIG. 8 , the backstop distal end portion 42 includes a distal end frame portion 43 , a backstop side attachment portion 45 and rollers 47 .

The tip frame portion 43 is a frame attached to the tip portion of the backstop body portion 41 . As shown in FIG. 9, the tip frame portion 43 is, for example, plate-like or substantially plate-like. For example, two tip frame portions 43 may be provided, or only one tip frame portion 43 may be provided.

The backstop side attachment portion 45 is a portion attached to the boom 15 when the crane 1 shown in FIG. 1 is in the working posture. The backstop side mounting portion 45 shown in FIG. 8 may be separated from the boom 15 (see FIG. 2) when the crane 1 (see FIG. 2) is disassembled. The backstop side mounting portion 45 is attachable to and detachable from a boom side mounting portion 55 (see FIG. 6), which will be described later. The backstop side attachment portion 45 is, for example, the pin hole 45a and its surrounding portion. The pin hole 45a is a hole (more specifically, the inner surface of the hole) that penetrates the tip frame portion 43 in the lateral direction Y, and a pin P can be inserted therein.

The roller 47 can contact an inclined portion 51a (see FIG. 6), which will be described later, to smoothen the movement of the backstop tip portion 42 with respect to the inclined portion 51a. The roller 47 is rotatable with respect to the backstop body portion 41 . Specifically, the roller 47 is rotatably supported by the tip frame portion 43 . As shown in FIG. 9, the roller 47 is arranged so as to be sandwiched in the horizontal direction Y between the two plate members of the tip frame portion 43 . As shown in FIG. 7 , the roller 47 is arranged so as not to interfere with the boom side mounting portion 55 when the backstop side mounting portion 45 is mounted on the boom side mounting portion 55 . Specifically, the roller 47 is arranged on the rear side X2 of the pin hole 45a.

As shown in FIG. 2, the boom side member 50 is provided on the boom 15, more specifically, provided (fixed) on the boom rear surface 15e. The boom side member 50 includes a guide member 51 and a boom side attachment portion 55 .

The guide member 51 guides movement of the backstop tip 42 relative to the boom 15 . The guide member 51 protrudes upward Z1 from the boom back surface 15e when the boom 15 is in the collapsed state. The guide member 51 may be provided on the intermediate boom 15b or may be provided on the upper boom 15c. As shown in FIG. 6, the guide member 51 has a configuration (shape, arrangement, etc.) that allows the roller 47 to roll. For example, the guide member 51 may have a plate shape extending in the front-back direction X and the up-down direction Z, or may have a block shape, a box shape, or the like. The guide member 51 includes an inclined portion 51a and a wall portion 51b. Below, as shown in FIG. 2, the case where the boom 15 is in the collapsed state will be described.

The inclined portion 51a (see FIG. 6) moves the backstop tip portion 42 to the front side X1 when the backstop 40 suspended from the strut 20 is lowered (details will be described later). The inclined portion 51a (see FIG. 6) is arranged at a position where the tip portion (the backstop tip portion 42) of the backstop 40 suspended from the strut 20 can come into contact. As shown in FIG. 6, the inclined portion 51a is inclined with respect to the front-rear direction X (the axial direction of the boom 15) so as to be disposed on the lower side Z2 toward the front side X1 (the tip side of the boom 15). When viewed from the lateral direction Y, the inclined portion 51a may be linear, curved, or a combination of these shapes (the same applies to the wall portion 51b). The inclined portion 51a is a rail (strut backstop rail) configured so that the roller 47 can roll on the inclined portion 51a.

The wall portion 51b restricts (suppresses) the backstop tip portion 42 from moving to the rear side X2 relative to the inclined portion 51a. The wall portion 51b protrudes upward Z1 from the rear side X2 end portion of the inclined portion 51a.

The boom side attachment portion 55 is a portion to which the backstop tip portion 42 shown in FIG. 7 is attached when the crane 1 (see FIG. 1) is in the working posture. The boom side mounting portion 55 is fixed to the boom 15 . The boom-side mounting portion 55 is fixed to the boom rear surface 15e, for example, to the pipe 15p that constitutes the boom rear surface 15e. The boom side mounting portion 55 is, for example, plate-shaped. The boom side mounting portion 55 has, for example, a pin hole 55a. The pin hole 55a is a hole (more specifically, the inner surface of the hole) that passes through a member (for example, a plate-like member) that constitutes the boom-side mounting portion 55 in the lateral direction Y, into which the pin P can be inserted. The boom side mounting portion 55 and the backstop side mounting portion 45 are arranged such that the boom side mounting portion 55 and the backstop side mounting portion 45 are aligned when the backstop tip portion 42 is moved along the inclined portion 51a. is placed. More specifically, the boom-side mounting portion 55 and the backstop-side mounting portion 45 are aligned so that the pin holes 55a and 45a are aligned when the backstop tip portion 42 is moved along the inclined portion 51a. placed. For example, the boom-side mounting portion 55 is arranged near the front X1 end of the inclined portion 51a, and is arranged on the front side X1 and the upper side Z1 of the front X1 end of the inclined portion 51a. For example, the boom side attachment portion 55 is arranged so as to be sandwiched from the lateral direction Y by the two tip end frame portions 43 (see FIG. 9) when attached to the backstop side attachment portion 45 .

The lateral guides 60 limit lateral Y movement of the backstop tip 42 relative to the guide member 51 (relative to the ramp 51a and relative to the wall 51b) shown in FIG. The lateral guide portion 60 is provided on at least one of the backstop tip portion 42 and the guide member 51 . In the example shown in FIG. 6 , the lateral guide portion 60 is provided on the backstop tip portion 42 and fixed to the tip frame portion 43 . The lateral guides 60 are positioned to sandwich the guide member 51 from the left and right when the backstop distal end 42 is placed in the vicinity of the guide member 51 . Specifically, for example, as shown in FIG. 9, the lateral guide section 60 includes lateral guide members 61.61.

For example, two lateral guide members 61 are provided. The two horizontal guide members 61 protrude from the tip frame portion 43 to the left and right (both sides on the outside in the horizontal direction Y). When the backstop tip 42, shown in FIG. 6, is positioned near and in contact with the guide member 51, the two lateral guide members 61, 61, shown in FIG. are arranged so as to be sandwiched between The lateral guide member 61 is, for example, plate-shaped (see FIG. 8). The lateral guide member 61 shown in FIG. 6 is designed to reduce lateral Y deviation of the backstop leading edge 42 with respect to the guide member 51 when the backstop leading edge 42 is brought closer to the guide member 51. in). Specifically, for example, as shown in FIG. 9, the lateral guide member 61 includes a lateral guide slope 61a. When the backstop 40 is in a suspended state (see FIG. 2), the lateral guide slopes are arranged so that the distance between the lateral guide members 61 in the lateral direction Y becomes narrower toward the front side X1 (see FIG. 2). 61a is inclined with respect to the front-rear direction X.

10 and 11 show a lateral guide portion 160 that is a modification of the lateral guide portion 60 (see FIG. 9). Regarding the lateral guide portion 160, differences from the lateral guide portion 60 (see FIG. 9) will be mainly described. As shown in FIG. 10 , the lateral guide portion 160 is provided on the guide member 51 . The lateral guide portions 160 may be provided on the left and right sides of the inclined portion 51a (both sides on the outer side in the lateral direction Y), or may be provided on the left and right sides of the wall portion 51b. The lateral guide portion 160 is arranged along (extending) the inclined portion 51a and the wall portion 51b. As shown in FIG. 11, the lateral guide portion 160 includes a lateral guide slope 161a having the same function as the lateral guide slope 61a (see FIG. 9). The horizontal guide slopes 161a (see FIG. 11) arranged on the outer side in the lateral direction Y of the wall portion 51b shown in FIG. It inclines with respect to the front-back direction X so that it may become. In the lateral guiding slopes 161a (see FIG. 11) arranged on the outer side in the lateral direction Y of the sloped portion 51a, the interval in the lateral direction Y between the lateral guiding slopes 161a becomes narrower toward the rear side X2 and the upper side Z1. , it is inclined with respect to each of the front-rear direction X and the up-down direction Z. As shown in FIG. 11 is a cross-sectional view taken along line F11-F11 in FIG. 10, and is a view seen from the upper side Z1 (a view along the wall portion 51b). On the other hand, when viewed from the direction along the inclined portion 51a shown in FIG. 10, the cross-sectional shape of the horizontal guide portion 160 is, for example, the same shape as the horizontal guide portion 160 shown in FIG.

(activation)
Assembly of the crane 1 shown in FIG. 1 is performed as follows. The procedure for assembling the crane 1 will be described below, but the procedure may be changed as appropriate. Also, the disassembly of the crane 1 is performed in the reverse (or substantially reverse) procedure to the assembly of the crane 1 described below.

The crane 1 is transported in a disassembled state. The rear strut 23 is transported separated from the boom 15 . During transportation, the strut guy line G3 is separated into a strut side portion G3s attached to the rear strut 23 and a boom side portion G3b placed on the boom 15, as shown in FIG. The backstop 40 is connected to the rear strut 23 and disconnected from the boom 15 during shipping.

The transported rear strut 23 and the like are assembled so as to be in the state shown in FIG. 2, for example. At this time, the boom 15 is in the collapsed state. The rear strut base end 23f is connected to the upper boom 15c. The rear strut 23 is lifted by an auxiliary crane (an assembly/disassembly crane different from the crane 1) and is in an upright state. The backstop 40 hangs (hangs down) from the rear strut 23 . The backstop 40 is in a state of contraction from when the crane 1 is in the working posture (see FIG. 5). It may be in a state close to a reduced state. A strut-side portion G3s of the strut guy line G3 hangs down (hangs down) from the rear strut tip portion 23t. A boom side portion G3b of the strut guy line G3 is placed on the boom back surface 15e. At this time, the jib 17 (for example, the lower jib 17a) may or may not be attached to the upper boom 15c (the same applies to the front strut 21).

Next, as shown in FIG. 3, the rear strut 23 is rotated to the rear side X2. More specifically, the rear strut 23 is rotated with respect to the boom 15 about the rear strut base end 23f in the direction in which the rear strut distal end 23t moves rearward X2. Rotation of the rear strut 23 is performed by an auxiliary crane that suspends the rear strut 23 . At this time, the strut side portion G3s of the strut guy line G3 moves to the rear side X2 and the lower side Z2 while hanging down from the rear strut tip portion 23t. In addition, the backstop 40 moves to the rear side X2 and the lower side Z2 while hanging from the rear strut 23 . Then, the backstop tip portion 42 approaches the boom back surface 15 e and approaches the guide member 51 . Then, as shown in FIG. 6, the backstop tip portion 42 contacts the inclined portion 51a. More specifically, the roller 47 contacts the inclined portion 51a.

As the backstop tip 42 approaches the guide member 51 , a lateral guide member 61 (more specifically, the ramp 51 a shown in FIG. 9) guides the lateral Y position of the backstop tip 42 relative to the guide member 51 . . Therefore, the backstop tip portion 42 can be brought into contact with the inclined portion 51a without manually adjusting the position of the backstop tip portion 42 in the lateral direction Y by the operator. Further, when the backstop tip 42 approaches the guide member 51 or when the backstop tip 42 is in contact with the guide member 51, the backstop 40 may swing in the horizontal direction Y. At this time, the lateral guide portion 60 restricts the lateral Y movement of the backstop distal end portion 42 with respect to the guide member 51 . Therefore, even if the backstop 40 swings in the horizontal direction Y, the backstop tip portion 42 can be brought into contact with the inclined portion 51a.

When the backstop tip portion 42 approaches the guide member 51, for example, when the backstop 40 swings in the front-rear direction X, the backstop tip portion 42 may try to move to the rear side X2. At this time, the wall portion 51b restricts the movement of the backstop tip portion 42 to the rear side X2 of the inclined portion 51a. Specifically, for example, the backstop tip portion 42 (more specifically, the roller 47) contacts the wall portion 51b. Therefore, the backstop tip portion 42 can be brought into contact with the inclined portion 51a without manually adjusting the position of the backstop tip portion 42 in the front-rear direction X by the operator.

With the backstop tip portion 42 in contact with the inclined portion 51a, as shown in FIG. 4, the rear strut 23 is further rotated rearward X2. At this time, the base end of the backstop 40 moves to the lower side Z2 and the rear side X2 together with the rear strut 23 . At this time, as shown in FIG. 6, the backstop tip portion 42 moves along the inclined portion 51a to the lower side Z2 and the front side X1. As a result, the backstop 40 is folded against the rear strut 23, as shown in FIG. More specifically, when viewed from the lateral direction Y, the angle formed by the longitudinal direction of the rear strut 23 and the longitudinal direction of the backstop 40 becomes smaller.

When the rear strut 23 is rotated to the rear side X2 up to a predetermined hoisting angle (first hoisting angle θ1 described below), the lower Z2 end of the strut side portion G3s of the strut guy line G3 connects to the boom side portion G3b. placed where possible. Then, the strut side portion G3s and the boom side portion G3b are connected.

The rear strut 23 is rotated to the rear side X2 up to a predetermined hoisting angle (second hoisting angle θ2 described below). Then, the backstop side mounting portion 45 of the backstop tip portion 42 indicated by the chain double-dashed line in FIG. More specifically, the pin hole 45a of the backstop side mounting portion 45 and the pin hole 55a of the boom side mounting portion 55 communicate in the horizontal direction Y. As shown in FIG. Then, the backstop side mounting portion 45 and the boom side mounting portion 55 are connected to each other by, for example, a pin P (see FIG. 7). As a result, the backstop 40 and boom 15 are connected.

As shown in FIG. 4, the hoisting angle of the rear strut 23 when the strut side portion G3s and the boom side portion G3b of the strut guy line G3 are connected is defined as a first hoisting angle θ1. The “height angle” of the rear strut 23 is the angle between the longitudinal direction X and the longitudinal direction of the rear strut 23 . The hoisting angle of the rear strut 23 shown in FIG. 4 when the backstop side mounting portion 45 and the boom side mounting portion 55 shown in FIG. 5 are connected is defined as a second hoisting angle θ2. The second hoisting angle θ2 may be equal to, larger than, or smaller than the first hoisting angle θ1. When the first hoisting angle θ1 and the second hoisting angle θ2 are equal, there is no need to adjust the hoisting angle of the rear strut 23 from the first hoisting angle θ1 to the second hoisting angle θ2 (or vice versa). Workability is improved.

Next, as shown in FIG. 5, the rear strut 23 is raised and the backstop body 41 is extended. At this time, the backstop 40 is set to the length of the backstop 40 when the crane 1 shown in FIG. 1 is in the working posture. Next, for example, the jib 17 is assembled, the jib guy line G1 is connected to the jib 17 and the front strut 21, the boom 15 is raised, the jib 17 is raised relative to the boom 15, and the crane 1 is in the working posture.

(examination)
As shown in FIG. 3, when a member (guide member 51 in this embodiment) for guiding the backstop tip portion 42 when the rear strut 23 is rotated to the rear side X2 is not provided (this case is [example A] ) will be considered. In this [Example A], the backstop 40 needs to be secured and released ([Work A1] and [Work A3] below). In addition, it is necessary to make two reciprocating motions of the rear strut 23 ([Work A2] and [Work A4] below).

The details of this [Example A] are as follows. In this [Example A], the backstop 40 interferes with the boom 15 when the rear strut 23 is rotated to the rear side X2. Therefore, before the rear strut 23 is rotated to the rear side X2, for example, in a state where the rear strut 23 stands up (see the two-dot chain diagram in FIG. 3), the backstop 40 is fixed to the rear strut 23. It is bound (fixed) ([Work A1]). This lashing is performed by, for example, a lashing pin or the like. Then, the rear strut 23 is rotated to the rear side X2, and the strut guy line G3 (the boom side portion G3b and the strut side portion G3s) is connected (see FIG. 4). Next, the rear strut 23 is erected again ([Work A2]). Then, the lashing of the backstop 40 to the rear strut 23 is released ([Work A3]). At this time, for example, in order to remove the lashing pin, it is necessary to adjust the undulating angle of the rear strut 23 so that the weight of the backstop 40 does not apply to the lashing pin. Next, the rear strut 23 is again rotated to the rear side X2 ([operation A4]). A backstop 40 is then connected to the boom 15 .

A case where a rail parallel to the boom back surface 15e is provided for moving the backstop tip 42 to the rear side X2 when the rear strut 23 is rotated to the rear side X2 (this case is referred to as [example B] ). In this [Example B], it is necessary to flip up the backstop 40 ([Work B1] below). In addition, it is necessary to make one reciprocating motion of the rear strut 23 ([Work B2] below). Moreover, there is a problem that it becomes difficult to arrange the rails.

The details of this [Example B] are as follows. In this [Example B], the rear strut 23 is held (supported) so that the angle formed by the longitudinal direction of the rear strut 23 and the longitudinal direction of the backstop 40 becomes a predetermined angle larger than 0 ([Work B1]). This work is performed in a state (not shown) in which the rear strut 23 is laid down in the longitudinal direction X, such as a state in which the rear strut 23 is placed on the front strut 21 shown in FIG. Then, the backstop 40 is held in a state in which the backstop 40 is flipped up with respect to the rear strut 23 (for example, see FIG. 3 of Patent Document 1 above). It should be noted that if the backstop 40 is in the flipped-up position during transportation of the rear strut 23, the transportation height increases, so it is difficult to set the backstop 40 in the flipped-up position in advance. Next, the rear strut 23 shown in FIG. 3 is erected, the rear strut 23 is rotated to the rear side X2, and the strut guy line G3 is connected (similar to FIG. 4). When the rear strut 23 is rotated rearward X2, the backstop tip 42 contacts the rail and moves rearward X2 along the rail. Next, the rear strut 23 is erected ([Work B2]). A backstop 40 is then connected to the boom 15 .

In this [Example B], a rail parallel to the boom rear surface 15e is provided for moving the backstop tip portion 42 to the rear side X2. Therefore, there is the following problem. When the rear strut 23 is rotated to the rear side X2, the proximal end of the backstop 40 moves to the rear side X2 along with the rotation of the strut 20 to the rear side X2. Move to the rear side X2 along the rail. Therefore, compared to the case where the backstop tip portion 42 moves to the front side X1 when the rear strut 23 is rotated to the rear side X2 as in the present embodiment, in this [example B], the rail that is long in the front-rear direction X is required. Therefore, the arrangement of this rail is difficult. For example, it is necessary to arrange the rails so as not to interfere with members on the boom back surface 15e. Also, for example, if the rail straddles the intermediate boom 15b and the upper boom 15c, the rail must be disassembled. Then, when assembling and disassembling the intermediate boom 15b and the upper boom 15c, it is necessary to disassemble and assemble the rails, and the work is troublesome. In addition, if a gap or step is formed in the disassembled portion of the rail, the backstop tip portion 42 may get caught in the gap or step, and the work is troublesome.

On the other hand, in this embodiment, the crane 1 can be assembled more easily than in [Example A] and [Example B]. Specifically, it is not necessary to reciprocate the rear strut 23 until the connection of the strut guy line G3 and the connection between the backstop 40 and the boom 15 are completed after the rear strut 23 is erected.

Further, in this embodiment, a long rail such as that in [Example B] is not necessary. More specifically, when strut 20 is rotated rearward X2, the proximal end of backstop 40 moves rearward X2 and distal backstop 42 moves along slope 51a (see FIG. 6). Move forward X1. Therefore, compared to the case where the base end of the backstop 40 moves to the rear side X2 and the backstop distal end portion 42 moves to the rearward side X2, the moving distance of the backstop distal end portion 42 in the front-rear direction X can be shortened. Therefore, the length of the guide member 51 (more specifically, the inclined portion 51a (see FIG. 6)) in the front-rear direction X can be shortened compared to the long rail of [Example B]. Therefore, compared to the long rail in [Example B], a space for arranging (installing) the guide member 51 can be easily secured, and the guide member 51 can be easily arranged on the boom 15 . In addition, since the length of the guide member 51 in the front-rear direction X can be shortened compared to the long rail in [Example B], the guide member 51 can be made smaller and lighter. Moreover, as a result of being able to reduce the weight of the guide member 51, the lifting capacity of the crane 1 can be improved. More specifically, the lifting capacity of the crane 1 decreases as the mass of the tip of the boom 15 and its vicinity (the portion including the guide member 51) increases. On the other hand, in the present embodiment, the weight of the guide member 51 can be reduced as compared with the long rail of [Example B] described above, so the hoisting capacity of the crane 1 can be improved compared to [Example B] described above. Further, in this embodiment, when the rear strut 23 is rotated to the rear side X2, the backstop tip portion 42 of the backstop 40 hanging from the rear strut 23 automatically moves along the inclined portion 51a (see FIG. 6). to the front side X1. Therefore, the backstop 40 does not need to be lashed to the rear strut 23, nor need to be flipped up.

(effect)
The effects of the strut backstop device 30 provided on the crane 1 shown in FIG. 1 are as follows.

(Effect of the first invention)
The crane 1 includes a boom 15, a jib 17, and a rear strut 23 (strut 20). The boom 15 is attached to the upper slewing body 13 so as to be able to rise and fall. The jib 17 is attached to the boom 15 so as to be able to rise and fall. Rear strut 23 is hoistably attached to boom 15 to hoist jib 17 relative to boom 15 . The strut backstop device 30 includes a backstop 40 and an inclined portion 51a (see FIG. 6). Backstop 40 is rotatably attached to rear strut 23 .

[Configuration 1-1] As shown in FIG. 3, the inclined portion 51a (see FIG. 6) is provided on the boom 15. As shown in FIG. When the boom 15 is in the collapsed state, the inclined portion 51a (see FIG. 6) is arranged at a position where the tip portion (the backstop tip portion 42) of the backstop 40 suspended from the rear strut 23 can come into contact.

[Construction 1-2] When the boom 15 is in the collapsed state, as shown in FIG. 15-axis direction).

In the strut backstop device 30, as shown in FIG. 3, when the boom 15 is in the collapsed state, the backstop 40 is suspended from the rear strut 23, and the rear strut 23 is rotated to the rear side X2 (work α). ) is performed. As shown in FIG. 6, during this work α, the backstop tip portion 42 comes into contact with the inclined portion 51a due to the above [Configuration 1-1]. Then, the inclined portion 51a is inclined with respect to the front-rear direction X so as to be arranged on the lower side Z2 toward the front side X1, as in the above [Configuration 1-2]. Therefore, as shown in FIG. 4, when the rear strut 23 is rotated rearward X2 to lower the proximal end of the backstop 40, the distal end of the backstop 42 moves along the inclined portion 51a as shown in FIG. It can be moved to the front side X1. Therefore, as shown in FIG. 4, interference between the backstop tip portion 42 and the boom 15 can be suppressed.

In order to suppress interference between the backstop tip 42 and the boom 15 during the above work α, the backstop 40 is held at a predetermined position with respect to the rear strut 23 (for example, by lashing or supporting in a flip-up posture). etc.), the work for this holding takes time and effort. On the other hand, in the strut backstop device 30, interference between the backstop tip portion 42 and the boom 15 can be suppressed by causing the backstop 40 to hang down from the rear strut 23 and rotating the rear strut 23 to the rear side X2. Therefore, the assembly work of the crane 1 can be easily performed. More specifically, it facilitates work on the backstop 40 when assembling the crane 1 .

In order to suppress interference between the backstop tip portion 42 and the boom 15, a rail is provided such that the backstop tip portion 42 moves to the rear side X2 when the rear strut 23 is rotated to the rear side X2. becomes longer in the front-rear direction X (for example, see [Example B] above). On the other hand, in the strut backstop device 30, interference between the backstop tip portion 42 and the boom 15 can be suppressed by moving the backstop tip portion 42 to the front side X1 when the rear strut 23 is rotated to the rear side X2. . Therefore, a rail long in the front-rear direction X (for example, see [Example B] above) for moving the backstop tip portion 42 to the rear side X2 becomes unnecessary. Therefore, a member (a member having an inclined portion 51a (see FIG. 3), for example, a guide member 51 (see FIG. 3)) for suppressing interference between the backstop tip portion 42 and the boom 15 can be reduced in size and weight.

(Effect of the second invention)
[Arrangement 2] As shown in FIG. A roller 47 is provided at the backstop tip 42 and can contact the inclined portion 51a.

[Configuration 2] allows the backstop distal end portion 42 to move smoothly along the inclined portion 51a.

(Effect of the third invention)
The strut backstop device 30 includes a boom-side mounting portion 55 fixed to the boom 15 . The backstop 40 includes a backstop side mounting portion 45 that can be attached to and detached from the boom side mounting portion 55 .

[Configuration 3] The boom-side mounting portion 55 and the backstop-side mounting portion 45 are arranged so as to be aligned with each other when the backstop distal end portion 42 is moved along the inclined portion 51a.

According to the above [Configuration 3], the boom side mounting portion 55 and the backstop side mounting portion 45 can be aligned by moving the backstop tip portion 42 along the inclined portion 51a. Therefore, the work of connecting the backstop 40 to the boom 15 can be easily performed. In addition, compared to the case where a member for aligning the boom side mounting portion 55 and the backstop side mounting portion 45 is provided separately from the inclined portion 51a, a member fixed to the boom 15 (for example, the boom side member 50) is reduced. It can be made smaller and lighter.

(Effect of the fourth invention)
[Configuration 4] The strut backstop device 30 includes a wall portion 51b that protrudes upward Z1 from the end portion of the inclined portion 51a on the rear side X2 (base end side of the boom 15).

According to [Configuration 4], when the backstop tip end portion 42 comes into contact with the wall portion 51b, it is possible to restrict the movement of the backstop tip end portion 42 to the rear side X2 relative to the inclined portion 51a. As a result, the backstop tip portion 42 can be brought into contact with the inclined portion 51a more reliably. As a result, the need to manually adjust the position of the backstop distal end portion 42 in the front-rear direction X with respect to the inclined portion 51a can be suppressed. Therefore, the work related to the backstop 40 can be performed more easily.

(Effect of the fifth invention)
[Configuration 5] The strut backstop device 30 includes a lateral guide portion 60 . The lateral guide portion 60 limits the movement of the backstop tip portion 42 in the lateral direction Y with respect to the inclined portion 51a.

According to the above [Configuration 5], when the backstop tip portion 42 moves in the lateral direction Y with respect to the inclined portion 51a, the lateral guide portion 60 restricts this movement. As a result, the backstop tip portion 42 can be brought into contact with the inclined portion 51a more reliably. Therefore, it is possible to suppress the necessity of manually adjusting the position of the backstop tip portion 42 in the lateral direction Y with respect to the inclined portion 51a. Therefore, the work related to the backstop 40 can be performed more easily.

(Modification)
The above embodiments may be modified in various ways. For example, the arrangement and shape of each component of the above embodiment may be changed. For example, the number of components may vary and some components may not be provided. For example, fixing, coupling, etc. between components may be direct or indirect. For example, what has been described as a plurality of mutually different components may be treated as one member or part. For example, what has been described as one member or portion may be divided into a plurality of different members or portions.

For example, in the above-described embodiment, the inclined portion 51a and the wall portion 51b are an integral member (the guide member 51), but they may be provided separately. For example, the guide member 51 and the boom side mounting portion 55 may be provided integrally or separately. For example, the roller 47 may not be provided, and the tip frame portion 43 may contact the inclined portion 51a. The position of the backstop tip 42 relative to the ramp 51a may be manually adjusted.

REFERENCE SIGNS LIST 1 crane 13 upper rotating body 15 boom 17 jib 20 strut 30 strut backstop device 40 backstop 45 backstop side mounting portion 47 roller 51a inclined portion 51b wall portion 55 boom side mounting portion 60, 160 lateral guide portion
X fore and aft direction (boom axis direction when the boom is in the collapsed state)
X1 front side (boom tip side when the boom is in the collapsed state)
X2 rear side (bottom end side of boom when boom is in down position)

Claims (6)

a boom hoistably attached to the upper swing structure;
a jib hoistably attached to the boom;
a strut hoistably attached to the boom for hoisting the jib relative to the boom;
A strut backstop device provided on a crane comprising
a backstop rotatably attached to the strut;
an inclined portion provided on the boom;
with
When the boom is in the collapsed state, the inclined portion is arranged at a position where the tip portion of the backstop suspended from the strut can come into contact with the inclined portion, and the inclined portion is arranged downward toward the tip side of the boom. slanted with respect to
Strut backstop device. a boom hoistably attached to the upper swing structure;
a jib hoistably attached to the boom;
a strut hoistably attached to the boom for hoisting the jib relative to the boom;
A strut backstop device provided on a crane comprising
a backstop rotatably attached to the strut;
an inclined portion provided on the boom;
with
When the boom is in the collapsed state, the inclined portion is arranged at a position where the tip portion of the backstop suspended from the strut can come into contact with the inclined portion, and the inclined portion is arranged downward toward the tip side of the boom. tilted with respect to
When the boom is in a collapsed state, the strut is rotated toward the boom base end side so that the tip end portion of the backstop moves toward the boom tip end side and downward along the inclined portion. an inclined portion is configured,
Strut backstop device. The strut backstop device according to claim 1 or 2 ,
The backstop includes a roller provided at the tip of the backstop and capable of contacting the inclined portion.
Strut backstop device. The strut backstop device according to any one of claims 1 to 3 ,
A boom side mounting portion fixed to the boom,
The backstop has a backstop side mounting portion that is detachable from the boom side mounting portion,
The boom-side mounting portion and the backstop-side mounting portion are arranged so as to be aligned with each other when the tip portion of the backstop is moved along the inclined portion.
Strut backstop device. The strut backstop device according to any one of claims 1 to 4 ,
A wall portion projecting upward from the end of the inclined portion on the base end side of the boom,
Strut backstop device. The strut backstop device according to any one of claims 1 to 5 ,
a lateral guide for limiting lateral movement of the tip of the backstop relative to the ramp;
Strut backstop device.

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