JP2019018965A - Separation preventing structure for derrick top pin - Google Patents

Abstract

To provide a structure for preventing a derrick top pin from being separated from a boom or a derrick cylinder, the structure reducing separation components and being realized with a simple configuration.SOLUTION: A separation preventing structure for a derrick top pin comprises: a derrick top pin with an insertion hollow, which has an open central part and an outer extension part; and a separation preventing bracket having an insertion part with an insertion body and an insertion projection, and a rotation prevention pin provided at an angle separated from the insertion projection. While the insertion part is kept inserted in the insertion hollow and the rotation prevention pin is kept at the same angle or substantially at the same angle with the outer extension part, the rotation prevention pin is inserted into the insertion hollow from the outer extension part. Thereby, circumferential rotation of the separation preventing bracket with respect to the derrick top pin is restricted.SELECTED DRAWING: Figure 8C

Description

  The present invention relates to a derrick top pin retaining structure for connecting a boom of a crane and a derrick cylinder.

  Patent Document 1 discloses a mobile crane including a boom that can be attached to and detached from a revolving structure. In this crane, the boom is connected to a derrick cylinder (boom hoisting cylinder) attached to the revolving body, and the boom is raised or lowered with respect to the revolving body as the derrick cylinder expands and contracts. In the connecting portion between the boom and the derrick cylinder, a hole is provided in each of the boom and the derrick cylinder. A derrick top pin is inserted into these holes from the inside of the boom, whereby the boom and the derrick cylinder are connected.

JP-A-7-101675

  In a crane like the above-mentioned patent document 1, a derrick top pin is fixed to a boom using separate members, such as a bolt and a screw. These separate members prevent the derrick top pin from coming off from the boom or the derrick cylinder. Here, the retaining structure of the derrick top pin is required to be realized with an easy configuration with few separated parts.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to prevent the derrick top pin from coming off from the boom or the derrick cylinder, which is realized with an easy configuration with few separated parts. To provide a structure.

  In order to achieve the above object, an aspect of the present invention is a derrick top pin retaining structure for connecting a boom and a derrick cylinder of a crane, the derrick top pin having an end surface, and the inner side from the end surface. And the opening of the insertion cavity at the end surface is continuous with the opening center and the opening center, and extends outward from the opening center to the outer peripheral side. A detachable bracket comprising a derrick top pin having a protruding portion, and an insertion portion insertable into the insertion cavity of the derrick top pin, wherein the insertion portion protrudes outward from the insertion body and the insertion body And the retaining bracket includes a detent pin provided at an angular position away from the inserting protrusion in the circumferential direction. A bracket, wherein the insertion body is coaxial or substantially coaxial with the opening central portion, and the insertion projection is in the same or substantially the same angular position as the outward extension portion in the circumferential direction. The insertion bracket can be inserted into the insertion cavity, and the retaining bracket in which the insertion section is inserted into the insertion cavity until the insertion protrusion is separated from the outward extension portion in the circumferential direction. , The movement of the retaining bracket in the axial direction with respect to the derrick top pin is restricted, the insertion portion is inserted into the insertion cavity, and the rotation prevention pin is moved outward in the circumferential direction. In a state where the angular position is the same as or substantially the same as the extension part, the locking pin is inserted into the insertion cavity from the outer extension part, thereby preventing the slipping-off. Rotation about the circumferential direction with respect to the derrick top pin of the bracket is restricted.

  According to the present invention, it is possible to provide a structure for preventing the derrick top pin from coming off from the boom or the derrick cylinder, which is realized with an easy configuration with few separation parts.

FIG. 1 is a schematic diagram illustrating an example of a crane according to the first embodiment. FIG. 2A is a diagram schematically showing a connection structure between the boom and the derrick cylinder according to the first embodiment in a cross section that is substantially parallel to the central axis of the derrick top pin and does not pass through the outward extending portion. is there. FIG. 2B is a diagram schematically illustrating the connection structure between the boom and the derrick cylinder according to the first embodiment in a cross section that is substantially parallel to the central axis of the derrick top pin and passes through the outward extending portion. is there. FIG. 3 is a diagram schematically showing a surface of the derrick top pin according to the first embodiment that faces outward in the axial direction when attached to the boom. FIG. 4 is a perspective view schematically showing how the retaining bracket is attached to the derrick top pin attached to the boom according to the first embodiment. FIG. 5 is a diagram schematically illustrating a state in which the retaining bracket according to the first embodiment is viewed from the first surface side of the retaining bracket. FIG. 6 is a diagram schematically illustrating a state in which the retaining bracket according to the first embodiment is viewed from one side in the width direction of the retaining bracket. FIG. 7A is a diagram schematically illustrating a state in which the retaining bracket is attached to the derrick top pin and disposed at the first angular position with respect to the derrick top pin in the first embodiment. FIG. 7B shows a state in which the retaining bracket is attached to the derrick top pin and disposed at the second angular position with respect to the derrick top pin, and the insertion portion is in the first movement position in the first embodiment. It is a figure which shows the state located in FIG. FIG. 7C shows a state in which the retaining bracket is attached to the derrick top pin and disposed at the second angular position with respect to the derrick top pin, and the insertion portion is in the second movement position in the first embodiment. It is a figure which shows the state located in FIG. FIG. 8A is a diagram schematically showing the state shown in FIG. 7A in a cross section that is substantially parallel to the central axis of the retaining bracket and passes through the outwardly extending portion. FIG. 8B is a diagram schematically showing the state shown in FIG. 7B in a cross section that is substantially parallel to the central axis of the retaining bracket and does not pass through the outwardly extending portion. FIG. 8C is a diagram schematically showing the state shown in FIG. 7C in a cross section that is substantially parallel to the central axis of the retaining bracket and does not pass through the outwardly extending portion.

  A first embodiment of the present invention will be described with reference to FIGS. 1 to 8C.

  FIG. 1 shows an example of a crane 1 of the present embodiment. As shown in FIG. 1, the crane 1 includes a traveling body 2 and a revolving body 3 disposed on the traveling body 2, and the revolving body 3 can turn with respect to the traveling body 2. Further, the base end portion of the boom 7 is connected to the revolving structure 3. The boom 7 can be expanded and contracted in the axial direction, and can be raised and lowered with respect to the revolving structure 3. When the swing body 3 swings, the boom 7 swings together with the swing body 3.

  A derrick cylinder (boom hoisting cylinder) 8 is provided between the revolving unit 3 and the boom 7. By extending or contracting the derrick cylinder 8, the boom 7 rises or falls with respect to the revolving structure 3. The hoisting direction of the boom 7 (arrow Y1 and arrow Y2 side in FIG. 1) intersects with the axial direction of the boom 7 (substantially perpendicular). Here, in the boom 7, a direction substantially perpendicular to the axial direction of the boom 7 and intersecting (substantially perpendicular) to the undulating direction of the boom 7 is defined as the width direction of the boom 7.

  When transporting the crane 1, the boom 7 is transported separately from the traveling body 2 and the swing body 3. For this reason, the boom 7 is detachably attached to the derrick cylinder 8.

  The connection structure of the boom 7 and the derrick cylinder 8 will be described with reference to FIGS. 2A and 2B. In the present embodiment, two derrick cylinders 8 are attached to the boom 7. For this reason, the connection part 11 with the derrick cylinder 8 is formed in the boom 7 on both sides in the width direction. A distal end portion (one end portion) 9 of the derrick cylinder 8 is disposed in the connecting portion 11. Moreover, the connection part 11 is provided with the outer side surface 15 which faces an outer side about the width direction of the boom 7. FIG.

  A hole 17 is formed in the connecting portion 11 of the boom 7, and a hole 19 is formed in the distal end portion 9 of the derrick cylinder 8. The hole 17 of the boom 7 penetrates the connecting portion 11 in the width direction of the boom 7. The hole 19 of the derrick cylinder 8 passes through the tip of the derrick cylinder 8 in the width direction of the boom 7. By inserting a derrick top pin (connection pin) 21 into the holes 17 and 19, the derrick cylinder 8 is attached to the connection part 11 of the boom 7. At this time, the derrick cylinder 8 is attached to the connecting portion 11 of the boom 7 with the holes 17 and 19 being coaxial or substantially coaxial with each other. The derrick top pin 21 can be removed from the holes 17 and 19. For this reason, the derrick cylinder 8 is detachably attached to the boom 7.

  The derrick top pin 21 has a central axis (longitudinal axis) L, and extends along the central axis L between the end faces 23 and 24. In a state where the derrick top pin 21 is inserted into the holes 17 and 19, the central axis L is parallel or substantially parallel to the width direction of the boom 7 and is coaxial or substantially coaxial with the holes 17 and 19. Further, the end surface 24 of the derrick top pin 21 is arranged in a state of facing inward in the width direction of the boom 7, and the end surface 23 of the derrick top pin is disposed in a state of facing out in the width direction of the boom 7.

  A derrick top pin attaching / detaching cylinder 20 is attached to each of the derrick top pins 21. The derrick top pin attaching / detaching cylinder 20 is disposed between the connecting portions 11 in the width direction of the boom 7. Each of the derrick top pin attaching / detaching cylinders 20 extends along the width direction of the boom 7, and expands and contracts in the width direction of the boom 7. Each of the derrick top pin attaching / detaching cylinders 20 has one end fixed to the boom 7 and the other end connected to the end surface 24 of the corresponding derrick top pin 21. As each of the derrick top pin attaching / detaching cylinders 20 expands and contracts in the width direction of the boom 7, the corresponding derrick top pin 21 moves relative to the boom 7 in the width direction of the boom 7.

  When the boom 7 is attached to the derrick cylinder 8, the tip portion 9 of the derrick cylinder 8 is disposed inside the connecting portion 11 of the boom 7, and the holes 17 and 19 are coaxial or substantially coaxial with each other. The top pin attaching / detaching cylinder 20 is extended. Accordingly, the derrick top pin 21 moves outward in the width direction with respect to the boom 7 and is inserted into the holes 17 and 19. The boom 7 is attached to the derrick cylinder 8 by inserting the derrick top pin 21 into the holes 17 and 19.

  When removing the boom 7 from the derrick cylinder 8, the derrick top pin attaching / detaching cylinder 20 is contracted. As a result, the derrick top pin 21 moves inward in the width direction with respect to the boom 7 and is removed from the holes 17 and 19. By removing the derrick top pin 21 from the holes 17 and 19, the connection between the derrick cylinder 8 and the boom 7 is released, and the boom 7 can be detached from the derrick cylinder 8.

  As shown in FIGS. 2A and 2B, an insertion cavity 25 is formed in the derrick top pin 21 from the end face 23 toward the inside. The insertion cavity 25 extends from the end surface 23 toward the opposite end surface 24 along the central axis L of the derrick top pin 21. The insertion cavity 25 opens at the opening 27 at the end face 23. Further, the insertion cavity 25 has a first cavity extension part 26 and a second cavity extension part 28 continuous to the opening 27 side of the first cavity extension part 26. The first cavity extending portion 26 forms an end portion (inner side) opposite to the opening 27 in the insertion cavity 25. Each of the cavity extending portions 26 and 28 has a substantially circular shape in a cross section perpendicular to or substantially perpendicular to the central axis L. However, the second cavity extending portion 28 has a larger diameter and a larger cross-sectional area perpendicular or substantially perpendicular to the central axis L than the first cavity extending portion 26. That is, in the second cavity extending portion 28, the peripheral wall of the insertion cavity 25 is compared with the first cavity extending portion 26 over the entire circumference in the circumferential direction of the insertion cavity 25 (around the central axis L). And dent to the outer peripheral side.

  The second cavity extending portion 28 is continuous with the opening 27. As shown in FIG. 3, the opening 27 includes a pair of opening central portions (main opening portions) 31 through which the central axis L passes and a pair of openings extending from the opening central portion 31 to the outer peripheral side (side away from the central axis L). And an outwardly extending portion (sub-opening portion) 33. Each of the outward extending portions 33 is continuous with the opening center portion 31. The outward extending portions 33 are arranged away from each other about the central axis L, that is, in the circumferential direction of the insertion cavity 25. In the present embodiment, the outwardly extending portions 33 are disposed on the opposite sides with respect to the central axis L, and are disposed approximately 180 ° apart from each other in the circumferential direction. In the present embodiment, since the opening center portion 31 and the outward extending portion 33 are configured as described above, the opening 27 of the insertion cavity 25 formed in the end face 23 intersects the central axis L (substantially vertical). ) It becomes a keyhole shape extending along the direction. In FIG. 2A, the derrick top pin 21 is shown in a cross section that is parallel or substantially parallel to the central axis L and does not pass through the outward extending portion 33. In FIG. It is shown in a cross section that is parallel or substantially parallel to L and that passes through the outwardly extending portion 33. FIG. 3 shows the derrick top pin 21 as viewed from the opening 27 side.

  The opening area of the opening 27 is larger than the cross-sectional area perpendicular or substantially perpendicular to the central axis L of the first cavity extending portion 26, and is perpendicular or substantially perpendicular to the central axis L of the second cavity extending portion 28. Small compared to the cross-sectional area. In addition, the derrick top pin 21 includes an engagement surface 30 at a boundary portion between the first cavity extension portion 26 and the second cavity extension portion 28, and the second cavity extension portion 28 and the opening 27 are connected to each other. An engagement surface 29 is provided at the boundary portion. In the second cavity extending portion 28, the groove portion 35 extends between the engagement surfaces 29 and 30 in the direction along the central axis L. The groove portion 35 extends along the circumferential direction of the insertion cavity 25. Moreover, the groove part 35 is extended over the whole in the angular range different from the outward extension part 33 about the circumferential direction of the insertion cavity 25.

  As shown in FIG. 4, a retaining bracket 40 is attached to the end surface 23 of the derrick top pin 21 to prevent the derrick top pin 21 from coming out of the holes 17 and 19. The retaining bracket 40 is attached to the end surface 23 of the derrick top pin 21 from the outside of the boom 7 in a state where the derrick top pin 21 is inserted into the holes 17 and 19.

  5 and 6 show the configuration of the retaining bracket 40. FIG. As shown in FIGS. 5 and 6, the retaining bracket 40 includes a bracket body 41. The bracket body 41 has a central axis C, and extends along the central axis C between the end faces 42 and 43. The bracket body 41 includes a first surface 44 facing one side in a direction (substantially perpendicular) intersecting the central axis C, and a second surface 45 facing the opposite side of the first surface 44. Here, the direction along the central axis C is defined as the axial direction of the retaining bracket 40. The direction intersecting (substantially perpendicular) to the central axis C and intersecting (substantially perpendicular) in the direction in which the first surface 44 and the second surface 45 face is the width direction of the retaining bracket 40. And 5 is a view of the retaining bracket 40 viewed from the side where the first surface 44 faces, and FIG. 6 is a view of the retaining bracket 40 viewed from one side in the width direction.

  The bracket body 41 includes a holding portion 46 that can be held, and an insertion portion 49 that is provided on the end face 43 side (arrow C1 side) with respect to the holding portion 46. The insertion portion 49 forms the end surface 43 of the bracket body 41.

  The holding portion 46 extends along the width direction of the retaining bracket 40. The holding part 46 includes two extending parts 47. The extending portion 47 is provided on the opposite side of the center axis C with respect to the width direction of the retaining bracket 40. Each of the extending portions 47 includes a protruding portion 48 that protrudes toward the end surface 43 on the end surface on the side where the end surface 43 of the holding portion 46 is located. The protruding portions 48 form both ends of the holding portion 46 in the width direction of the retaining bracket 40.

  The insertion part 49 includes an insertion end part 51. The insertion end 51 forms an end face 43. The insertion end 51 extends along the central axis C, and is formed in a substantially cylindrical shape centering on the central axis C in the present embodiment. The diameter of the insertion end 51 is the same as or substantially the same as the diameter of the first cavity extension 26 provided on the derrick top pin 21, or is larger than the diameter of the first cavity extension 26. Slightly small.

  The insertion portion 49 includes an insertion main body 50 that extends along the central axis C. In the direction along the central axis C, the insertion body 50 is disposed between the holding portion 46 and the insertion end portion 51. The diameter of the insertion body 50 is formed to be equal to or smaller than the diameter of the insertion end 51.

  The insertion portion 49 includes a pair of insertion protrusions 52 extending from the outer periphery of the insertion main body 50 to the outer peripheral side (side away from the central axis C). The insertion protrusions 52 are arranged away from each other about the central axis C, that is, in the circumferential direction of the insertion body 50. In the present embodiment, the insertion protrusions 52 are disposed on the opposite side of each other across the central axis C, and are disposed approximately 180 ° apart from each other in the circumferential direction. In the present embodiment, in the insertion portion 49, a cross section perpendicular or substantially perpendicular to the central axis C formed by the insertion main body 50 and the insertion protrusion 52 is along the direction intersecting the central axis C (the width direction of the bracket main body 41). The key is extended. Further, the insertion protrusion 52 includes a first engagement surface 53 facing the end surface 42 side and a second engagement surface 54 facing the end surface 43 side.

  The insertion protrusion 52 extends to an outer position with respect to the outer periphery of the insertion end 51. For this reason, when the insertion portion 49 is viewed along the central axis C from the end surface 43 side, a part of the insertion protrusion 52 extends from the outer periphery of the insertion end portion 51 to the side away from the central axis C. In addition, the cross-sectional area of the extension portion of the insertion protrusion 52 from the outer periphery of the insertion body 50 is the same or substantially the same as the area of the outward extension portion 33 on the end surface 23 of the derrick top pin 21, or It is slightly smaller than the area of the outward extending portion 33.

  A detent unit 61 is attached to the bracket body 41. The anti-rotation unit 61 is arranged away from each of the insertion protrusions 52 about the central axis C, that is, in the circumferential direction of the insertion body 50. In the present embodiment, the rotation prevention unit 61 is disposed approximately 90 ° away from each of the insertion protrusions 52 in the circumferential direction.

  The anti-rotation unit 61 includes a case 63 fixed to the bracket body 41 and an anti-rotation pin 65 attached to the case 63. The rotation prevention pin 65 is supported by the case 63 inside the case 63. The detent pin 65 extends along the central axis C (axial direction) of the bracket body 41. Further, the rotation prevention pin 65 is attached to the case 63 and the bracket body 41 so as to be movable in the axial direction of the retaining bracket 40.

  In the axial direction of the bracket main body 41, the anti-rotation pin 65 forms an operation portion 67 that forms an end portion on the side where the end surface 42 of the bracket main body 41 faces, and a pin that forms an end portion (end surface 69) on the side that the end surface 43 faces. An end portion 68 and an extending portion 66 extending along the axial direction are provided between the operation portion 67 and the pin end portion 68. In the operation unit 67, an operation of moving the rotation prevention pin 65 with respect to the case 63 and the bracket body 41 along the axial direction is performed.

  A spring (elastic member) 70 is arranged inside the case 63. The spring 70 extends along the axial direction of the retaining bracket 40. One end of the spring 70 is connected to the inside of the case 63, and the other end of the spring 70 is connected to the pin end portion 68 of the detent pin 65. As the rotation prevention pin 65 moves along the axial direction with respect to the case 63, the spring 70 expands and contracts. When the spring 70 expands and contracts, the elastic force of the spring 70 is transmitted to the rotation prevention pin 65. For example, in a state in which the spring 70 is contracted from the natural length, the elastic force of the spring 70 acts on the anti-rotation pin 65 so that the end surface 69 of the pin end portion 68 faces.

  Next, an operation procedure in attaching the retaining bracket 40 to the derrick top pin 21 will be described with reference to FIGS. 7A to 7C and FIGS. 8A to 8C. When work is performed using the crane 1, the boom 7 is attached to the derrick cylinder 8 connected to the swing body 3 before the work is started. At this time, when the derrick top pin attaching / detaching cylinder 20 is extended, the derrick top pin 21 is inserted into the holes 17 and 19, whereby the boom 7 and the derrick cylinder 8 are connected. A detachable bracket 40 is attached to the derrick top pin 21 in order to prevent the derrick top pin 21 from being removed from the holes 17 and 19.

  In attaching the retaining bracket 40 to the derrick top pin 21, the operator holds the holding portion 46 of the retaining bracket 40, and the center axis C of the retaining bracket 40 and the center axis L of the derrick top pin 21 are coaxial. Alternatively, the insertion portion 49 of the retaining bracket 40 is inserted into the insertion cavity 25 of the derrick top pin 21 from the outside in the width direction of the boom 7 in a substantially coaxial state. At this time, as shown in FIGS. 7A and 8A, the insertion protrusions 52 are inserted at the same or substantially the same angular position as one of the outwardly extending portions 33 around the central axes C and L. The part 49 is inserted into the insertion cavity 25 (first engaged state). The insertion portion 49 can be inserted into the insertion cavity 25 only when the insertion protrusion 52 is at the same or substantially the same angular position as the outward extension portion 33 in the circumferential direction.

  In the first engagement state, the insertion end portion 51 passes through the opening central portion 31 of the opening 27 and the second cavity extending portion 28 and is inserted into the first cavity extending portion 26. As described above, the diameter of the insertion end 51 is the same as or substantially the same as the diameter of the first cavity extension 26, or slightly smaller than the diameter of the first cavity extension 26. small. For this reason, in the state where the insertion end 51 is inserted into the first cavity extending portion 26, the central axis C of the retaining bracket 40 and the central axis L of the derrick top pin 21 are coaxial or substantially coaxial. Therefore, the insertion end 51 is inserted into the first cavity extension 26 so that the center axis C of the retaining bracket 40 is attached in a state of being inclined with respect to the center axis L of the derrick top pin 21. Thus, the posture of the retaining bracket 40 with respect to the derrick top pin 21 is defined. When the derrick top pin 21 is inserted into the hole 17 of the boom 7 and the insertion portion 49 of the retaining bracket 40 is inserted into the insertion cavity 25, the protruding portion 48 of the extension portion 47 is It faces the outer surface 15 and is not inserted into the insertion cavity 25.

  Further, in the first engagement state, the insertion protrusion 52 passes through the outward extension portion 33 of the opening 27 and is disposed in the second cavity extension portion 28.

  Further, when the insertion portion 49 is inserted into the insertion cavity 25 as described above, the rotation prevention unit 61 is separated from the outward extension portion 33 by about 90 ° about the central axis C (L). The insertion portion 49 is inserted into the insertion cavity 25 while being positioned at the angular position. At this time, the end surface 69 of the pin end portion 68 of the rotation preventing pin 65 abuts on the edge portion of the insertion cavity 25 or the end surface 23 of the derrick top pin 21. For this reason, when the insertion portion 49 of the retaining bracket 40 is inserted into the insertion cavity 25, the detent pin 65 is pressed outward in the width direction of the boom 7 by the end surface 23 of the derrick top pin 21. For this reason, as the insertion portion 49 is inserted into the insertion cavity 25, the detent pin 65 moves to the side where the end face 42 faces the case 63, and the spring 70 contracts from the natural state. Therefore, in the first engagement state, the spring 70 is contracted from its natural length, and the elastic force of the spring 70 acts on the rotation prevention pin 65.

  In the first engagement state, the retaining bracket 40 is located at the first angular position with respect to the derrick top pin 21. In the first engagement state, the insertion portion 49 of the retaining bracket 40 is movable along the central axis C (L) with respect to the derrick top pin 21 in the insertion cavity 25 of the derrick top pin 21. is there. Further, in the first engagement state, the retaining bracket 40 can rotate about the central axis C (L) with respect to the derrick top pin 21.

  From the first engaged state, the operator rotates the retaining bracket 40 in which the insertion portion 49 is inserted into the insertion cavity 25 with respect to the derrick top pin 21 about the central axis C. At this time, the insertion protrusion 52 of the retaining bracket 40 moves around the central axis C in the second cavity extension portion 28, and the insertion protrusion 52 is separated from the outward extension portion 33 in the circumferential direction (first). 2 engagement state). Then, the retaining bracket 40 is rotated with respect to the derrick top pin 21 until the insertion protrusion 52 is separated from the outward extending portion 33 by approximately 90 ° in the circumferential direction. 7B and 8B show a state in which the retaining bracket 40 is rotated by 90 ° in the circumferential direction from the state shown in FIGS. 7A and 8A.

  In the second engagement state, the retaining bracket 40 is located at a second angular position different from the first angular position with respect to the derrick top pin 21. Further, in the second engagement state, the insertion protrusion 52 of the insertion portion 49 is positioned at an angular position that is approximately 90 ° away from the outward extension portion 33 about the axis of the central axis C (L). In the second engagement state, the insertion protrusion 52 is disposed between the engagement surfaces 29 and 30 in the groove portion 35. At this time, the engagement surface 53 of the insertion protrusion 52 and the engagement surface 29 of the groove portion 35 face each other, and the engagement surface 54 of the insertion protrusion 52 and the engagement surface 30 of the groove portion 35 face each other.

  In the second engagement state, the insertion protrusion 52 interferes with the engagement surfaces 29 and 30 of the groove portion 35, thereby restricting the movement of the retaining bracket 40 along the central axis C (L) relative to the derrick top pin 21. . Further, in the second engaged state, the retaining bracket 40 can rotate about the central axis C (L) with respect to the derrick top pin 21.

  In the second engagement state, the movement of the retaining bracket 40 along the central axis C (L) with respect to the derrick top pin 21 is restricted. For this reason, when the retaining bracket 40 is attached to the derrick top pin 21 in the second engagement state, for example, the derrick top pin 21 is moved inward in the width direction of the boom 7 by the derrick top pin attaching / detaching cylinder 20. When the driving force is applied, the driving force is transmitted to the retaining bracket 40 via the derrick top pin 21. The protruding portion 48 of the extending portion 47 of the holding portion 46 of the retaining bracket 40 contacts the outer surface 15 of the connecting portion 11 of the boom 7 from the outside in the width direction of the boom 7. As a result, the inward movement of the retaining bracket 40 and the derrick top pin 21 with respect to the boom 7 is restricted.

  Therefore, when the retaining bracket 40 is attached to the derrick top pin 21 in the second engagement state, the inward movement of the derrick top pin 21 with respect to the boom 7 is restricted, and the derrick top pin 21 is moved from the holes 17 and 19. It is prevented from being pulled out. Thereby, the derrick cylinder 8 is prevented from being unintentionally removed from the boom 7, and the work stability is improved.

  As shown in FIGS. 7B and 8B, in the state where the rotation prevention unit 61 is located at the same or substantially the same angular position as the outward extending portion 33 around the axis of the central axis C, the rotation prevention pin 65 The end surface 69 of the pin end portion 68 does not interfere with the end surface 23 of the derrick top pin 21. Therefore, the rotation preventing pin 65 is not restricted by the end surface 23 of the derrick top pin 21 from moving in the axial direction with respect to the derrick top pin 21.

  In the present embodiment, the rotation prevention unit 61 is provided with a spring 70. In a state where the rotation prevention pin 65 is in contact with the end surface 23 of the derrick top pin 21, the rotation prevention pin 65 is pressed by the elastic force of the spring 70. As described above, in the state where the rotation prevention unit 61 is at the same or substantially the same angular position as the outward extending portion 33 in the circumferential direction, the rotation prevention pin 65 moves in the axial direction with respect to the derrick top pin 21. This is not restricted by the end face 23. Therefore, in the state where the rotation prevention unit 61 is at the same or substantially the same angular position as the outward extension portion 33, the rotation prevention pin 65 is moved by the elastic force of the spring 70 as shown in FIGS. 7C and 8C. The pin end portion 68 of the detent pin 65 is inserted into the outwardly extending portion 33 of the derrick top pin 21 while moving relative to the pin 41. Then, when the pin end portion 68 is inserted into the outward extending portion 33, the rotation preventing pin 65 and the outward extending portion 33 are engaged (third engaged state).

  In the third engagement state, the outer peripheral surface of the pin end portion 68 of the locking pin 65 abuts against the edge of the outward extending portion 33, so that the retaining bracket 40 is centered on the central axis C with respect to the derrick top pin 21. The rotation about the axis (L) is restricted. Therefore, the retaining bracket 40 cannot rotate around the central axis C with respect to the derrick top pin 21. As a result, the insertion protrusion 52 is positioned at an angular position away from the outward extending portion 33, and the insertion protrusion 52 extends outward from the second angular position at which the insertion portion 49 is prevented from being removed from the insertion cavity 25. The retaining bracket 40 is located at the same or substantially the same angular position as the protruding portion 33, and the retaining bracket 40 is at the first angular position where the insertion protrusion 52 can be removed from the insertion cavity 25 through the outward extending portion 33. The rotation with respect to the pin 21 is restricted. Thereby, the retaining bracket 40 is effectively attached to the derrick top pin 21. Further, by effectively attaching the retaining bracket 40 to the derrick top pin 21, it is possible to effectively prevent the derrick top pin 21 from being removed from the holes 17 and 19.

  Further, when the derrick cylinder 8 is removed from the boom 7, the operator has inserted the pin end portion 68 of the detent pin 65 into the outward extending portion 33 of the derrick top pin 21 (third engagement). State), the operation portion 67 of the rotation prevention pin 65 is moved outward with respect to the case 63. Then, the pin end 68 of the locking pin 65 is pulled out from the outward extending portion 33 by moving the locking pin 65 outward with respect to the bracket body 41 (second engaged state). Then, the retaining bracket 40 is rotated with respect to the derrick top pin 21 in a state where the detent pin 65 is pulled out from the outward extending portion 33. The insertion portion 49 is inserted into the insertion cavity with the insertion protrusion 52 of the retaining bracket 40 positioned at the same or substantially the same angular position as the outwardly extending portion 33 of the derrick top pin 21 (first engagement state). The retaining bracket 40 is removed from the derrick top pin 21 by being pulled out from 25. The derrick top pin attaching / detaching cylinder 20 contracts with the retaining bracket 40 removed from the derrick top pin 21, so that the derrick top pin 21 moves inward in the width direction of the boom 7 and is removed from the holes 17 and 19. Get rid of. When the derrick top pin 21 is removed from the holes 17 and 19, the connection between the derrick cylinder 8 and the boom 7 is released, and the derrick cylinder 8 can be removed from the boom 7.

  Further, in the present embodiment, the rotation prevention pin 65 is attached to the case 63 in a state where it is pressed by the spring 70 in a state where it is at an angular position away from the outward extending portion 33. For this reason, in a state where the rotation prevention pin 65 is at the same or substantially the same angular position as the outward extending portion 33, the rotation prevention pin 65 is pressed by the elastic force from the spring 70, so that the outside of the opening 27. Automatically move toward the outwardly extending portion 33 and is automatically inserted into the outwardly extending portion 33. Thereby, in the first engagement state, the operator simply rotates the retaining bracket 40 from the first angular position to the second angular position with respect to the derrick top pin 21, and the derrick top pin 21 is removed. Therefore, it is possible to form a retaining structure that reliably prevents the detachment. Thereby, an operator's effort at the time of forming the retaining structure of the derrick top pin 21 is reduced.

  The spring 70 may not be provided. In this case, the rotation prevention pin 65 is inserted into or removed from the outward extending portion 33 by the operation of the operation portion 67 by the operator.

  As described above, in this embodiment, the retaining bracket 40 is attached to the derrick top pin 21 to form a retaining structure from the holes 17 and 19 of the derrick top pin 21. For this reason, it is possible to prevent the derrick top pin 21 from coming off the boom 7 or the boom hoisting cylinder 8 using only the retaining bracket 40. That is, the retaining structure for the derrick top pin 21 can be formed without using parts other than the retaining bracket 40 such as screws and bolts. Since the retaining structure can be formed without using a separate part such as a screw or bolt, the separate part is not lost. Further, the number of work steps for forming the retaining structure is reduced, and the retaining bracket 40 can be easily attached to the derrick top pin 21. In addition, since the retaining structure can be formed without using screws, bolts, etc., it is possible to prevent foreign matters such as sand from being caught in the fixing portions by the screws, bolts.

  Further, in the retaining structure of the present embodiment, the retaining bracket 40 is attached to the derrick top pin 21, thereby preventing the retaining bracket 40 from rotating with respect to the derrick top pin 21. For this reason, rotation of the retaining bracket 40 relative to the derrick top pin 21 can be prevented without attaching parts for preventing the retaining bracket 40 to rotate to the boom 7 by welding or the like. Thereby, the welded product to the boom 7 for preventing rotation of the retaining bracket 40 becomes unnecessary.

  In the above-described embodiment and the like, the derrick top pin (21) retaining structure for connecting the boom (7) of the crane (1) and the derrick cylinder (8) has a derrick top pin (21) having an end surface (23). An insertion cavity (25) is formed from the end face (23) toward the inside, and an opening (27) of the insertion cavity (25) at the end face (23) 31) and a derrick top pin (21) having an outwardly extending part (33) that is continuous with the opening center part (31) and extends from the opening center part (31) to the outer peripheral side, A retaining bracket (40) comprising an insertion portion (49) insertable into the insertion cavity (25) of the derrick top pin (21), the insertion portion (49) comprising an insertion body (50), Outside the insertion body (50) And an insertion protrusion (52) protruding to the side, and the retaining bracket (40) includes a retaining pin (65) provided at an angular position away from the insertion protrusion (52) in the circumferential direction. A retaining bracket (40), wherein the insertion body (50) is coaxial or substantially coaxial with the opening central portion (31), and the insertion protrusion (52) extends outward in the circumferential direction. The insertion portion (49) can be inserted into the insertion cavity (25) only when the angular position is the same or substantially the same as that of the portion (33), and the insertion protrusion (52) is inserted in the outer direction in the circumferential direction. The retaining bracket (4) is rotated by rotating the retaining bracket (40) in which the insertion portion (49) is inserted into the insertion cavity (25) until it is separated from the side extending portion (33). ) In the axial direction with respect to the derrick top pin (21) is restricted, the insertion portion (49) is inserted into the insertion cavity (25), and the detent pin (65) is inserted in the circumferential direction. In a state where the angular position is the same as or substantially the same as that of the outward extending portion (33), the detent pin (65) is inserted into the insertion cavity (25) from the outward extending portion (33). Accordingly, the rotation of the retaining bracket (40) in the circumferential direction with respect to the derrick top pin (21) is restricted.

  In addition, this invention is not limited to the said embodiment, In the implementation stage, it can change variously in the range which does not deviate from the summary. Further, the embodiments may be implemented in combination as appropriate, and in that case, the combined effect can be obtained. Furthermore, the present invention includes various inventions, and various inventions can be extracted by combinations selected from a plurality of disclosed constituent elements. For example, even if several constituent requirements are deleted from all the constituent requirements shown in the embodiment, if the problem can be solved and an effect can be obtained, the configuration from which the constituent requirements are deleted can be extracted as an invention.

  DESCRIPTION OF SYMBOLS 1 ... Crane, 7 ... Boom, 8 ... Derrick cylinder, 21 ... Derrick top pin, 25 ... Insert cavity, 27 ... Opening, 31 ... Opening center part, 33 ... Outward extension part, 40 ... Retaining bracket, 49 ... Insertion part, 52 ... insertion protrusion, 65 ... detent pin.

Claims (2)

A derrick top pin retaining structure for connecting the crane boom and the derrick cylinder,
A derrick top pin having an end surface, wherein an insertion cavity is formed from the end surface toward the inside, and an opening of the insertion cavity at the end surface is continuous with an opening center portion, and the opening center portion, A derrick top pin having an outwardly extending portion extending from the center of the opening to the outer peripheral side;
A retaining bracket including an insertion part that can be inserted into the insertion cavity of the derrick top pin, wherein the insertion part includes an insertion body and an insertion protrusion that protrudes outward from the insertion body, and The retaining bracket includes a retaining bracket provided with a detent pin provided at an angular position away from the insertion protrusion in the circumferential direction;
Comprising
The insertion portion is only in a state where the insertion main body is coaxial or substantially coaxial with the opening central portion, and the insertion protrusion is in the same or substantially the same angular position as the outward extension portion in the circumferential direction. Can be inserted into the insertion cavity,
The derrick top pin of the retaining bracket is rotated by rotating the retaining bracket in which the insertion portion is inserted into the insertion cavity until the insertion protrusion is separated from the outward extending portion in the circumferential direction. Movement in the axial direction relative to
In the state where the insertion portion is inserted into the insertion cavity and the rotation prevention pin is at the same or substantially the same angular position as the outward extension portion in the circumferential direction, the rotation prevention pin extends outward. By being inserted into the insertion cavity from the exit portion, rotation of the retaining bracket with respect to the derrick top pin in the circumferential direction is restricted,
Retaining structure. The retaining bracket further comprises an elastic member that applies an elastic force to the detent pin,
In a state where the insertion portion is inserted into the insertion cavity, and the detent pin is separated from the outward extension portion in the circumferential direction, the elastic member contracts due to the pressure from the derrick top pin,
By rotating the retaining bracket in which the insertion portion is inserted into the insertion cavity until the rotation prevention pin is in the same or substantially the same angular position as the outward extension portion in the circumferential direction, The anti-rotation pin moves toward the outward extending portion by the elastic force from the elastic member, and the anti-rotation pin is inserted into the insertion cavity from the outward extending portion.
The retaining structure according to claim 1.