JP5306520B1 - Crane attachment - Google Patents

Abstract

A bending moment acting on a crane attachment such as a boom is reduced.
Four diagonal connection assistants in which main members 25a, 25d and 25b, 25c arranged at diagonal positions are diagonally arranged in the vertical direction and crossed at the tip of a boom 26 having a lattice structure. A frame structure 31 having a configuration in which the members 27 are connected to each other is provided. Further, the point sheave 32 is installed on the boom neutral axis line at the tip of the boom 26 with respect to the position where the framework structure 31 is installed, and the pendant rope 34 is connected to the support shaft 33 that supports the point sheave 32. Since the pendant rope 34 is connected on the boom neutral axis, it is possible to prevent a bending moment based on the component force in the boom neutral axis direction in the tension of the pendant rope 34 from being generated in the boom 26. Therefore, the bending moment acting on the boom 26 can be reduced.
[Selection] Figure 1

Description

  The present invention relates to a crane attachment such as a jib or a boom for securing a working radius and / or height required for a crane suspension (hook).

  A crawler crane as an example of a crane is generally connected to a front end portion of an upper swing body mounted on a lower traveling body so that a boom as an attachment of the crane can be rotated (raised and lowered) vertically. A boom hoisting device and a hoisting device are provided between the boom and the upper swing body.

  FIG. 6 shows an example of a boom as an attachment of a conventional crane. The boom 1 includes four main members 2 (cords) arranged at equal intervals in the front, rear, left and right directions, and the four main members. The auxiliary member 3 (brace) for connecting two adjacent main members 2 to each other is used as a lattice structure, and the base end portion of the boom 1 is connected to a foot pin (not shown) provided on the base end portion. And connected to the upper swing body 4. Further, a guide sheave support bracket 6 supporting a guide sheave 5 is provided behind the tip of the boom 1 so as to project, and one end of a pendant rope 7 is connected to the guide sheave support bracket 6. In addition, a point sheave support bracket 9 that supports the point sheave 8 is provided in a protruding manner in front of the tip of the boom 1.

  Thus, the boom 1 is raised and lowered without causing the pendant rope 7 to interfere with the boom 1 by operating the boom raising and lowering device 10 with the other end of the pendant rope 7 connected to the boom raising and lowering device 10. It is made to be able to. Further, the hoisting wire rope 12 of the hoisting device 11 is hung between the point sheave 8 and the hook block sheave 14 of the hook block 13 through the guide sheave 5, and the hoisting device 11 is By operating, the hook 15 can be moved up and down integrally with the hook block 13 (see, for example, Patent Document 1).

  As another example of a boom as an attachment of a conventional crane, as shown in FIG. 7 (a), a top link 17 is provided in front of the tip of a boom 16 having a lattice structure similar to that shown in FIG. A top sheave 18 is pivotally attached to the top link 17, a pendant link 19 is provided at the rear of the tip of the boom 16, a guide sheave 20 is pivotally attached to the pendant link 19, and more than the pendant link 19. There is a configuration in which a second pendant link 21 protruding rearward of the tip of the boom 16 is provided, and a pendant rope 22 is connected to the second pendant link 21. In the figure, 23 is a boom hoisting device, and 24 is a hoisting device.

Thus, as shown in FIG. 7 (b), the resultant force P _C of tension T of the load W and pendant rope 22 hanging acting on the boom 16 when lifting the luggage, the center C _{B (neutral} axis) of the boom 16 around (For example, refer to Patent Document 2).

JP 2010-76926 A Japanese Patent Laid-Open No. 11-43288

  However, in the case where the pendant rope 7 is connected to the guide sheave support bracket 6 at the rear of the tip of the boom 1 as described in Patent Document 1, the connection position of the pendant rope 7 and the neutral axis ( Bend based on the component force in the direction of the boom neutral axis (boom centroid) in the tension generated in the pendant rope 7 in addition to the bending moment based on the weight of the boom 1. A moment is generated. In particular, as the overall length of the boom 1 becomes longer, the angle formed by the pendant rope 7 and the neutral axis of the boom 1 becomes narrower, so that the component force in the neutral axis direction of the boom 1 in the tension generated in the pendant rope 7 increases. Accordingly, the bending moment generated in the boom 1 is further increased.

On the other hand, when the condition of the suspension load W acting on the boom 16 is changed, such as when the hoisting angle of the boom 16 is changed or when the total length of the boom 16 is changed, the one described in Patent Document 2 is changed. , shown in FIG. 7 (b), the distance from the boom center C _B to the working position of the resultant force P _C hanging load W and the tension T of the pendant rope 22 is connected to the installation position and pendant rope 19 of the top wheel 18 because varies between a position, it is impossible to effectively reduce the bending moment based on the neutral axis direction component force of the resultant force P _C. When the suspension load W is not applied, the component force in the neutral axis direction of the boom 16 at the tension T of the pendant rope 22 is applied to the boom 16 in the same manner as described in Patent Document 1 above. Therefore, the bending moment generated in the boom 16 cannot be reduced. Therefore, what was described in the said patent document 2 does not suggest this invention.

  Therefore, the present invention seeks to provide a crane attachment that can reduce the acting bending moment.

  In order to solve the above-mentioned problems, the present invention provides a crane attachment comprising four main members arranged in four directions and an auxiliary member for connecting the main members to each other, corresponding to claim 1. In the above structure, a skeleton structure is formed by connecting the main members arranged at diagonal positions to the distal end portion of the attachment by four diagonal connection auxiliary members arranged obliquely in the vertical direction. It is set as the structure made to provide.

Further, according to claim 2, in the above-described configuration, a support shaft is installed on the neutral axis of the attachment , and either one of the installation of the point sheave to the support shaft and the connection of the pendant rope to the support shaft Or it is set as the structure made to perform both.

  Further, according to claim 3, a joint is provided at the intersection of the diagonal connection auxiliary members of the frame structure in the above configuration, and the diagonal connection auxiliary members are connected to each other through the joint. The configuration.

  Further, in correspondence with claim 4, the outer diameters of the two diagonal connection auxiliary members of the frame structure in the above configuration are set to be smaller than the remaining two diagonal connection auxiliary members. The auxiliary members for corner connection are connected to each other.

According to the crane attachment of the present invention, the following excellent effects are exhibited.
(1) In a crane attachment comprising four main members arranged in four directions and an auxiliary member for connecting the main members to each other, they are arranged obliquely in the vertical direction at the tip of the attachment. Since the frame structure is formed by connecting the main members arranged at the diagonal positions by the four diagonal connecting auxiliary members, the pendant rope interferes with the attachment. It can be connected near the neutral axis of the attachment. Accordingly, even when the suspension load condition is changed, the component force in the neutral axis direction of the attachment at the tension acting on the pendant rope can be applied to the vicinity of the neutral axis of the attachment. Therefore, since the bending moment based on the component force in the neutral axis direction can be reduced, the bending moment generated in the attachment can be reduced.
(2) Also, a support shaft is installed on the neutral axis of the attachment so that either one or both of the installation of the point sheave to the support shaft and the connection of the pendant rope to the support shaft are performed. Since it is configured, both the component force in the attachment neutral axis direction and the component force in the attachment neutral axis direction of the suspension load in the tension acting on the pendant rope can be applied to the neutral axis of the attachment. Therefore, since it is possible to prevent the bending moment based on the component force in the neutral axis direction from acting on the attachment, the bending moment generated in the attachment can be reduced. Moreover, the component force of the attachment neutral axis direction in the resultant force of the suspension load and the tension acting on the pendant rope can be equally applied to each main member. Therefore, the cross-sectional area of the other main member is adjusted to the main member with a large ratio of the component force applied, as in the case where the component force in the attachment neutral axis direction in the resultant force cannot be equally applied to each main member. There is no need to raise it. Therefore, it is possible to prevent the attachment weight from being increased more than necessary, and to improve the lifting performance.
(3) Further, since a joint is provided at the intersection of the diagonal connection auxiliary members in the frame structure, and the diagonal connection auxiliary members are connected to each other via the joint, the diagonal connection is provided. The auxiliary members can be easily connected to each other. Therefore, the frame structure can be easily provided at the distal end portion of the attachment.
(4) Furthermore, the outer diameters of the two diagonal connection auxiliary members in the frame structure are made smaller than the remaining two diagonal connection auxiliary members, and the diagonal connection auxiliary members are connected to each other. Therefore, it is possible to easily connect the small-diameter diagonal connection auxiliary member to the diagonal connection auxiliary member while avoiding the connection portion between the two diagonal connection auxiliary members. it can. Therefore, the frame structure can be easily provided at the tip of the boom without using a joint.

It is a schematic perspective view which shows one Embodiment of the attachment of the crane of this invention. FIG. 2 is a schematic view showing connection of the diagonal connection auxiliary member to the main member in FIG. 1, (A) is a schematic rear view, (B) is a schematic side view, and (C) is A- FIG. It is a schematic enlarged view which shows the connection part of the coupling in FIG. FIG. 2 is a schematic cut plan view illustrating a connection state of each auxiliary member for lower end connection in FIG. 1 to a main member. The other embodiment of this invention is shown and it is a schematic perspective view which shows the connection state of the auxiliary member for diagonal connection in a frame structure, and the small diameter auxiliary member for diagonal connection. It is a schematic side view which shows an example of the boom as an attachment of the conventional crane. The other example of the boom as an attachment of the conventional crane is shown, (A) is a schematic side view, (B) is a power figure which shows the resultant force of a suspension load and the tension of a pendant rope.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  1 to 4 show an embodiment of the present invention. Like the boom as an attachment of the conventional lattice structure crane shown in FIG. 6, four are arranged at equal intervals in the front, rear, left and right directions. Main members (cords) 25a, 25b, 25c, and 25d and auxiliary members (braces) (not shown) that connect the adjacent main members of the four main members 25a, 25b, 25c, and 25d. Four diagonal connection assistants in which main members 25a and 25d, 25b and 25c arranged diagonally are arranged diagonally in the vertical direction and crossed at the tip of a boom 26 having a lattice structure. Main members 25a and 25c, 25b and 25d adjacent to each other in the front-rear direction, connected by the member 27, main members 25a and 25b adjacent to the left and right on the front side, and main members 25a and 25d arranged at diagonal positions, 25b and 5c are connected by the lower end connection auxiliary member 28 at the lower end connection position of the diagonal connection auxiliary member 27, and the main members 25a and 25c, 25b and 25d adjacent in the front-rear direction are connected to the diagonal connection auxiliary member. The upper end connection auxiliary member 29 is connected at the upper end connection position of the member 27, and the upper end connection auxiliary member 29 is connected to the lower end connection auxiliary member 28 by the side reinforcing member 30. A frame structure 31 is provided. Further, the point sheave 32 is installed on the boom neutral axis line at the tip of the boom 26 with respect to the frame structure 31 and the pendant rope 34 is connected to the support shaft 33 that supports the point sheave 32. And

  Specifically, the framework structure 31 is configured as follows.

  That is, as shown in FIGS. 2 (a), (b), and (c), the four diagonal connection auxiliary members 27 are arranged on the neutral axis of the boom 26 that is an intersection of the diagonal connection auxiliary members 27. A joint 35 having eight connecting portions 35a protruding corresponding to the extending direction is arranged, and one main member 25d of the connecting portions 35a of the joint 35 and the main members 25a and 25d arranged at diagonal positions. The joint connecting auxiliary member 27a is connected to the upper end connection position of the joint 35, and the connection portion 35a of the joint 35 disposed on the opposite side of the connection portion 35a and the lower end of the other main member 25a at the diagonal position The joint connecting auxiliary member 27a is connected to the connecting position, and the diagonal connecting auxiliary member 27 formed by the two joint connecting auxiliary members 27a and the joint 35 is connected to the diagonal connecting auxiliary member 27 and the boom. Pender connected on neutral axis While forming a predetermined clearance between the hydrotrope 34, to be connected obliquely to the vertical direction between one of the main member 25d and the other main member 25a which is disposed at diagonal positions. Similarly, the joint connecting auxiliary member 27a is connected to the connecting portion 35a of the joint 35 and the upper end connecting position of the other main member 25a at the diagonal position, and disposed on the opposite side of the connecting portion 35a. The joint connecting auxiliary member 27a is connected to the joint portion 35a of the joint 35 to be connected and the lower end connecting position of the one main member 25d at the diagonal position, and formed from the two joint connecting auxiliary members 27a and the joint 35. The diagonal connection auxiliary member 27 is connected obliquely in the vertical direction between one main member 25d and the other main member 25a arranged at the diagonal positions. Thereby, one main member 25d arranged at a diagonal position and the other main member 25a are connected by two diagonal connection auxiliary members 27 arranged obliquely in the vertical direction and intersecting each other. It is supposed to be. Further, the main members 25b and 25c at the remaining diagonal positions are connected in the same manner as the one main member 25d and the other main member 25a, and two pairs of the main members 25b and 25c are arranged obliquely in the vertical direction and intersected. It is made to be in the connected state by the auxiliary member 27 for corner connection. As a result, the main members 25a and 25d, 25b and 25c arranged at the diagonal positions are connected to each other by the four diagonal connection auxiliary members 27 arranged obliquely in the vertical direction and intersecting each other. It is like that.

  As shown in FIG. 3, the connecting portion 35a of the joint 35 forms a groove between the fitting portion 35b that fits inside the joint connecting auxiliary member 27a and the end of the joint connecting auxiliary member 27a. The groove portion 35c is provided. This makes it possible to build up weld metal with a stable quality with respect to the groove, and to prevent welding defects due to the weld metal being melted out to the inside of the joint connecting auxiliary member 27a. It is made to be able to.

  As shown in FIG. 4, the main members 25a, 25b, 25c, and 25d are connected in the horizontal direction by the lower end connection auxiliary member 28 at the lower end connection position of the diagonal connection auxiliary member 27, as described above. In addition, the main members 25a and 25c, 25b and 25d adjacent in the front-rear direction are connected in the horizontal direction by the upper end connection auxiliary member 29 at the upper end connection position of the diagonal connection auxiliary member 27, respectively. It is. Accordingly, as shown in FIG. 1, the pendant rope 34 can be passed between the main members 25c and 25d on the rear side, and the winding wire rope (not shown) suspended from the point sheave 32 is provided. Is prevented from interfering with the boom 26.

  Further, the main members 25a and 25c, 25b and 25d adjacent in the front-rear direction are side reinforcing members at the connection position of the upper end connection auxiliary member 29 and the connection position of the lower end connection auxiliary member 28 as shown in FIG. 30 are connected in the vertical direction. In this way, the frame structure 31 is provided at the tip of the boom 26.

  On the other hand, the support bracket 36 is located between the main members 25a and 25c and 25b and 25d adjacent in the front-rear direction, as shown in FIGS. The support shaft 33 is installed on the boom neutral axis of the support bracket 36, and the point sheave 32 is rotatably supported by the support shaft 33.

  Further, between the point sheave 32 and the support bracket 36 on the support shaft 33, the tip of the pendant rope 34 that is passed between the main members 25c and 25d on the rear side is connected.

  In the figure, reference numeral 37 denotes a top plate for connecting the tips of the main members 25a, 25b, 25c, and 25d.

  When a boom 26 as an attachment of a crane having such a configuration is mounted on a crane and the boom 26 is raised by a boom hoisting device (not shown) of the crane, tension is applied to the pendant rope 34. Since the pendant rope 34 is connected to the support shaft 33 installed on the neutral axis of the boom 26, the component force in the boom neutral axis direction at the tension acting on the pendant rope 34 acts on the neutral axis of the boom 26. . Further, when the load is lifted with the boom 26 raised, a suspension load acts on the boom 26. The pendant rope 34 is connected to the support shaft 33 installed on the neutral axis of the boom 26 and the point sheave 32 is attached. As a result, the component force in the boom neutral axis direction in the resultant force of the suspension load and the tension acting on the pendant rope 34 acts on the neutral axis of the boom 26.

  Thus, according to the boom as the attachment of the crane in the embodiment shown in FIGS. 1 to 4, four main members 25a, 25b, 25c, 25d arranged at equal intervals in the front, rear, left and right directions; The boom 26 as an attachment of a lattice structure crane including an auxiliary member (not shown) that connects between the adjacent main members of the four main members 25a, 25b, 25c, and 25d, Main members 25a and 25d, 25b and 25c arranged at corner positions are respectively connected by four diagonal connection auxiliary members 27 arranged obliquely in the up-down direction and adjacent to each other. The members 25a and 25c, 25b and 25d, the main members 25a and 25b adjacent to the left and right on the front side, and the main members 25a and 25d, 25b and 25c arranged at diagonal positions are The main members 25a and 25c, 25b and 25d, which are respectively connected by the lower end connection auxiliary member 28 at the lower end connection position of the auxiliary auxiliary member 27 and adjacent in the front-rear direction, are connected to the upper end connection position of the diagonal connection auxiliary member 27. The frame structure 31 is connected to each other by the upper end connection auxiliary member 29 and is connected by the side reinforcing member 30 at the connection position of the upper end connection auxiliary member 29 and the connection position of the lower end connection auxiliary member 28. Furthermore, a point sheave 32 is installed on the boom neutral axis at a position on the tip side of the boom 26 with respect to the frame structure 31, and the pendant rope 34 is connected to a support shaft 33 that supports the point sheave 32. Since it is configured, the component force in the boom neutral axis direction in the tension acting on the pendant rope 34 and the boom neutral axis direction of the suspended load The component force, both can be applied on the neutral axis of the boom 26. Therefore, since it is possible to prevent the bending moment based on the component force in the neutral axis direction from acting on the boom 26, the bending moment generated in the boom 26 can be reduced. Further, the component force in the boom neutral axis direction in the resultant force of the suspension load and the tension of the pendant rope 34 can be equally applied to the main members 25a, 25b, 25c, and 25d. Therefore, as in the case where the component force in the boom neutral axis direction at the resultant force cannot be uniformly applied to each main member, the cross-sectional area of the other main member is set in accordance with the main member to which the component force is applied. Since it is not necessary to raise, the weight of the boom 26 can be prevented from being increased more than necessary, and the lifting performance can also be improved.

  Further, the four diagonal connection auxiliary members 27 are connected to each other through a joint 35 having eight connecting portions 35a that are projected in correspondence with the extending direction of the diagonal connection auxiliary member 27. Therefore, the diagonal connection auxiliary members 27 can be easily connected to each other. Therefore, the frame structure 31 can be easily provided at the tip of the boom 26.

  Next, FIG. 5 shows another embodiment of a boom as an attachment of a crane of the present invention. In the boom 26 as an attachment of a crane according to the embodiment shown in FIGS. Instead of connecting the diagonal connection auxiliary members 27 to each other, half the two diagonal connection auxiliary members 27 out of the four diagonal connection auxiliary members 27 are used for the diagonal connection. After connecting the two diagonal connection auxiliary members 27 as the diagonal connection small diameter auxiliary member 38 having a smaller diameter than the auxiliary member 27, the diagonal connection auxiliary member 27 is connected to the diagonal connection small diameter auxiliary member 27. 38 is connected.

  Specifically, as shown in FIG. 5, for example, the connection between the diagonal connection auxiliary members 27 connected from the lower side of the main members 25c and 25a to the upper side of the main members 25b and 25d is made by welding means such as butt welding. The diagonal connection small-diameter auxiliary member 38 connected to the main member 25c, 25a from the lower side of the main member 25b, 25d with a smaller diameter than the diagonal connection auxiliary member 27 is formed on the diagonal line. The connecting auxiliary member 27 is connected to the diagonal connecting auxiliary member 27 by welding means such as butt welding while avoiding the welded portion of the diagonal connecting auxiliary member 27.

  Other configurations are the same as those shown in FIGS. 1 to 4, and the same components are denoted by the same reference numerals.

  As described above, according to the embodiment shown in FIG. 5, the diagonal connection small-diameter auxiliary member 38 is connected to the diagonal connection auxiliary member 27. The small diameter auxiliary member 38 for diagonal connection can be easily connected to the auxiliary member 27 for diagonal connection by welding or the like, avoiding a connecting portion such as a welded portion. Therefore, the frame structure 31 can be easily provided at the tip of the boom 26 without using the joint 35.

  In addition, although the case where it applied to the boom 26 was demonstrated as an example of an attachment in the said embodiment, you may apply to a jib.

  In the embodiment shown in FIGS. 1 to 4, the case of the joint 35 having the eight connecting portions 35a has been described. However, the present invention is not limited to this. For example, the joint 35 may be a flat plate.

  Furthermore, the outer diameter of the joint connecting auxiliary member 27a in the embodiment shown in FIGS. 1 to 4 may be changed for each main member 25a, 25b, 25c, 25d to be connected.

  In the embodiment shown in FIG. 5, in order to facilitate the connection between the diagonal connection auxiliary members 27, two of the half are used as the diagonal connection small diameter auxiliary members 38, but the connection position is shifted. Of course, the diagonal connecting auxiliary members 27 having the same diameter may be directly connected to each other, and various modifications can be made without departing from the scope of the present invention.

25a, 25b, 25c, 25d Main member 27 Diagonal connection auxiliary member 31 Frame structure 32 Point sheave 34 Pendant rope 35 Joint

Claims (4)

  In a crane attachment comprising four main members arranged in four directions and auxiliary members that connect the main members to each other, the front end of the attachment is arranged obliquely in the vertical direction and crossed. A crane attachment comprising a structure in which a frame structure is formed by connecting the main members arranged at diagonal positions by four diagonal connection auxiliary members. The crane according to claim 1 , wherein a support shaft is installed on a neutral axis of the attachment so that one or both of installation of a point sheave to the support shaft and connection of a pendant rope to the support shaft are performed. Attachment.   The crane attachment according to claim 1 or 2, wherein a joint is provided at a crossing portion of the diagonal connection auxiliary member in the framework structure, and the diagonal connection auxiliary members are connected to each other through the joint.   The diagonal connection auxiliary members are connected to each other by setting the outer diameters of the two diagonal connection auxiliary members in the framework structure to be smaller than the remaining two diagonal connection auxiliary members. Attachment of the crane of 1 or 2.

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