JP2015199583A - Column post swinging device for crane, and backlash adjusting method for the device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a swinging device for the column post of a crane, which can adjust the backlash easily between a pinion gear and a rack gear, in a swinging device for swinging the column post of the crane in a horizontal direction by the swinging device using the pinion gear and the rack gear.SOLUTION: In this swinging device 10, a plurality of flange bolt fitting holes 16 equivalently arranged on a common circumference along the circumference direction of a flange 15 of a cylinder tube 14 are offset in the circumference center of the flange bolt fitting holes 16 with respect to the axis of the cylinder tube 14. As a result, the backlash between the pinion gear 12 and the rack gear 19 can be stepwise changed in a manner to correspond to the fastening positions of the flange bolt fitting holes 16 in the circumferential direction.

Description

  The present invention relates to a rack-and-pinion-type swiveling device that horizontally swivels a column post of a crane with respect to a vehicle base on which the crane is mounted, and in particular, backlash adjustment of the rack-and-pinion. Regarding the mechanism.

An example of this type of swivel device is shown in FIG. The swivel device 100 shown in the figure has a housing 120, and the column post base end portion 2a of the crane is mounted on a vehicle base (not shown) using the housing 120 as a base. In the housing 120, a pinion gear 12 supported by a bearing 13 is provided so as to be rotatable around an axis line extending in the vertical direction. The pinion gear 12 is integrated with a swivel shaft portion 2b extending below the column post base end portion 2a. Connected to rotate. On both side surfaces 120a of the housing 120, two sets (four in total) of hollow cylindrical cylinder tubes 114 projecting in a horizontal direction in pairs at left and right opposing positions are mounted.
An annular flange 115 having an inlay portion 130 for fitting with a tube mounting hole 125 formed in the flange mounting portion 121 on the side surface 120a of the housing without gap is fixed to the end portion of each cylinder tube 114.

  As shown in FIG. 8, a plurality of flange bolt mounting holes 116 equally distributed on the same circumference along the circumferential direction of the flange surface 115 m and a slide rod 117 described later are fitted into the flange 115. The inner hole 115n is processed, and the center line of the inner hole 115n of the flange 115 and the center of the circle formed by the arrangement of the plurality of flange bolt mounting holes 116 are coaxial with the center axis of the spigot portion 130. Further, the central axis of the cylindrical portion of the cylinder tube 114 and the central axis of the inner hole 115n of the flange 115 are formed so as to be accurately coaxial. As shown in FIG. 7, each cylinder tube 114 is attached to the housing 120 by fitting the spigot portion 130 of the cylinder tube 114 into the tube attachment hole 125 of the flange attachment portion 121 and attaching them using the plurality of flange attachment bolts 11.

  On the other hand, on both side surfaces 120a of the housing 120, a flange mounting portion 121 for attaching the cylinder tube 114 and a tube mounting hole 125 formed in the flange mounting portion 121 are formed so as to be coaxial with each other in two sets on the left and right sides. Yes. The flange mounting portion 121 of the housing 120 has a plurality of female screws equally distributed on the same circumference along the circumferential direction of the tube mounting hole 125 so as to face the plurality of flange bolt mounting holes 116 of the cylinder tube 114. 122. The female screw 122 is a bottomed hole. The center of the tube attachment hole 125 and the center formed by the circle of the plurality of female screws 122 are concentric.

The central axes of the left and right cylinder tubes 114, 114 with respect to the housing 120 are precisely formed in a pair of left and right coaxials by an appropriate centering effect by the inlay.
A cylindrical slide rod 117 having pistons 18 at both ends is fitted in the pair of left and right cylinder tubes 114 and 114. The central axis of the left and right cylinder tubes 114, 114 and the central axis of the piston 18 in the cylinder tube form a coaxial axis.

  The operation of the slide rod 117 is performed by supplying and discharging pressure oil. Pressure oil piping is provided at both ends of the pair of cylinder tubes 114 and 114, and the slide rod 117 slides left and right along the axis of the cylinder tubes 114 and 114. Therefore, by these structures, when the slide rod 117 slides, the sliding surface pressure between the piston 18 at both ends and the inner wall of the cylinder tube 114 operates smoothly without shifting from side to side.

  A rack gear 19 is formed on the side surface of each slide rod 117 so as to mesh with the pinion gear 12. As a result, in a state where the pinion gear 12 is sandwiched by the rack gears 19 of the two slide rods 117 arranged side by side, the rackion is achieved by the pinion gear 12 connected to the column post base end 2a and the rack gear 19 of the slide rod 117. An and pinion mechanism is configured.

  In the turning operation by the turning device 100 described above, the pressure oil is supplied and discharged so that the pressure oil flows into the pair of cylinder tubes 114 and 114 from one end of the cylinder tube 114 and the pressure oil flows out from the other. At the same time, the pressure oil supply and discharge directions to the two cylinder tubes 114 and 114 arranged side by side are controlled to be opposite to each other. As a result, the two slide rods 117 and 117 are slid in opposite directions according to the pressure oil supply / discharge direction, and the rack gear 19 of each slide rod 117 simultaneously rotates the pinion gear 12 to simultaneously rotate the column post base end 2a ( That is, the column post is turned in the horizontal direction.

Japanese Utility Model Publication No. 63-82037

  By the way, at the meshing portion of the rack gear 19 and the pinion gear 12, it is important to adjust the backlash in order to make the operation of the rack and pinion mechanism smooth. That is, if the backlash amount is small, undercut occurs due to tooth interference, and if the backlash amount is large, play occurs in the horizontal direction of the column post along with the rotational play of the crane boom. If backlash occurs in the left-right direction of the column post, the boom swings to the left and right when the crane stops suddenly during the turning operation, and heavy load occurs.

  Further, the tooth surfaces collide with each other at the meshing portion, so that the tooth surfaces are worn and the tooth width is narrowed, and the teeth are damaged. Usually, the backlash amount of the rack-and-pinion mechanism can be adjusted by an adjusting mechanism in which any one of the gears can appropriately change the distance between the teeth. For example, the center-to-center distance can be changed by pressing the rack gear from its rear surface and translating it in the direction facing the pinion gear.

  Here, for example, Patent Literature 1 discloses a rack and pinion backlash adjustment mechanism. The technology described in this document rotates a cylindrical sleeve having an integral structure with an eccentric hole into which a rack gear is fitted and inserted around a cylindrical central axis when adjusting the backlash of a rack and pinion in a fuel injection device of a diesel engine. By doing so, the rack gear is translated to the pinion gear side, and the distance between the centers of the rack gear and the pinion gear is adjusted.

  However, in the technique described in Patent Document 1, it is unclear how to fix the cylindrical sleeve after positioning the integrally structured cylindrical sleeve, and the means for sliding the rack gear in the axial direction of the cylindrical sleeve is also unknown. It is. Therefore, it is difficult to employ this as a rack and pinion backlash adjusting mechanism for a column post turning device for a crane column post such as the turning device 100 having the above-described structure.

  That is, in the swivel device 100 having the above-described structure, the cylindrical slide rod 117 having the pistons 18 at both ends has the piston 18 that slides on the inner wall of the cylinder tube 114. The center-to-center distance between the rack gear and the pinion gear cannot be adjusted unless 114 is moved horizontally to the pinion gear 12 side. However, the mounting position of the cylinder tube 114 is determined by the position of the flange mounting portion 21 due to the inlay structure with the fitting surface of the flange mounting portion 21 of the housing 120 and cannot be moved.

Further, the column post base end portion 2a is also firmly supported so as not to be broken by the crane's suspension load, and it is difficult to change the center-to-center distance by movement on the pinion gear 12 side. That is, in the column post turning device of the crane, it is difficult to adjust the backlash by means of parallel movement of the center-to-center distance between the rack gear and the pinion gear.
Therefore, the present invention has been made paying attention to such a problem, and in a turning device for turning a column post of a crane in a horizontal direction by a rack-and-pinion method, backlash between a pinion gear and a rack gear is reduced. An object of the present invention is to provide a column post turning device for a crane column and a backlash adjusting method thereof that can be easily adjusted.

  In order to solve the above-described problem, a column post turning device for a crane according to an aspect of the present invention is a turning device for horizontally turning a column post of a crane with respect to a base of a vehicle on which the crane is mounted. And a housing mounted between the base end portion of the column post and the base, and is housed in the housing so as to be rotatable about an axis line directed in the vertical direction and integrated with the base end portion of the column post A pair of hollow cylindrical cylinder tubes each having an annular flange surface mounted on a flange mounting portion opposed to both side surfaces of the housing, and a pair of cylinder tubes sliding on each other. Pressure oil that has a rack gear that is fitted and meshed perpendicularly to the pinion gear and that is fed to and discharged from the pair of cylinder tubes A swivel device of a rack and pinion system provided with slide rods having pistons at both ends so as to move more slidably, wherein the cylinder tube has an annular flange portion having an inlay portion at its end, A cylindrical portion welded to the inside of the inner hole of the flange portion, and the flange portion has a plurality of bolt mounting holes equally distributed on the same circumference along the circumferential direction on the annular flange surface. A central axis of the inner hole of the flange portion and a central axis of the cylindrical portion are coaxially arranged, and the central axis of the spigot portion and the plurality of bolt mounting holes The center axis of the same circumference by arrangement forms a second coaxial arrangement that forms a coaxial, and the first coaxial arrangement and the second coaxial arrangement are formed with their center lines eccentric. That features To.

  Here, in the column post turning device for a crane according to an aspect of the present invention, the pair of cylinder tubes has a central axis of the same circumference due to the arrangement of the plurality of bolt mounting holes with respect to a central axis of the cylindrical portion. The flange mounting portion of the housing is formed with a plurality of female screws equally distributed on the same circumference along the circumferential direction at a position facing the plurality of bolt mounting holes. And changing the mounting position of the flange with respect to the flange mounting portion of the housing in the circumferential direction to change the same by the same amount, thereby changing the backlash between the pinion gear and the rack gear in the circumferential direction of the plurality of bolt mounting holes. It is preferable that the position can be changed step by step corresponding to the mounting position.

  Moreover, in the column post turning device for a crane according to an aspect of the present invention, two pairs of the cylinder tubes are arranged in parallel, and the slide rods are slidably fitted to the pair of cylinder tubes arranged in parallel. The pinion gear is sandwiched from both sides in the radial direction by the rack gear, and the slide rod is formed on the surface opposite to the side on which the rack gear is formed along the sliding movement direction. The housing has a smooth surface, and the housing has a sliding plate that is in sliding contact with the smooth surface at a position facing the smooth surface of the slide rod, and a pressing means that presses the sliding plate toward the smooth surface. It is preferable to provide.

  Further, each cylinder tube is formed with an inlay portion formed concentrically with an eccentric position of the plurality of bolt mounting holes while fitting with a tube mounting hole formed in the flange mounting portion of the housing without a gap. An O-ring is interposed between the outer peripheral surface of the spigot portion and the fitting surface of the tube mounting hole of the housing, and the meshing portion of the rack gear and the pinion gear is filled with lubricating oil inside the housing. Therefore, it is preferable that the lubricating state is always maintained.

  In order to solve the above-described problem, a backlash adjustment method for a column post turning device for a crane according to an aspect of the present invention is a rack and pinion in the column post turning device for a crane according to an aspect of the present invention. A mechanism for adjusting the backlash of the mechanism, wherein the mounting position of the flange with respect to the flange mounting portion of the housing of each of the pair of cylinder tubes is rotated by the same amount in the circumferential direction. The backlash between the rack gears is changed corresponding to the mounting positions in the circumferential direction of the plurality of bolt mounting holes.

  According to the present invention, the cylinder tube is composed of an annular flange portion having an inlay portion at its end, and a cylindrical portion welded to the inside of the inner hole of the flange portion, and the flange portion is an annular shape thereof. A plurality of bolt mounting holes equally distributed on the same circumference along the circumferential direction on the flange surface, and a central axis of the inner hole of the flange portion and a central axis of the cylindrical portion form a first axis In addition to the coaxial arrangement, the central axis of the spigot part and the central axis of the same circumference by the arrangement of the plurality of bolt mounting holes are the second coaxial arrangement, and the first coaxial arrangement and the second coaxial arrangement With the coaxial arrangement, since the centerlines of each other are formed eccentrically, by changing the mounting position of the flange portion of the pair of cylinder tubes in the circumferential direction relative to the flange mounting portion of the housing, Bag between pinion gear and rack gear Rush to correspond to the circumferential direction of the mounting positions of the plurality of bolt mounting holes and may be varied. Therefore, the backlash between the pinion gear and the rack gear can be easily adjusted, and is particularly suitable for adjusting the backlash of the rack and pinion of the column post turning device of the crane.

  In particular, the pair of cylinder tubes has a plurality of bolt mounting holes equally distributed on the same circumference along the circumferential direction of the flange of each cylinder tube, and the center of the circumference where the plurality of bolt mounting holes are formed. , The mounting positions of the flange portions of the pair of cylinder tubes are the same in the circumferential direction relative to the flange mounting portions of the housing. By changing, the backlash between the pinion gear and the rack gear can be changed step by step in correspondence with the circumferential mounting positions of the plurality of bolt mounting holes. Therefore, the backlash between the pinion gear and the rack gear can be easily adjusted, and is particularly suitable for adjusting the backlash of the rack and pinion of the column post turning device of the crane.

1 is a side view of a folding crane that is an embodiment of a crane that employs a column post turning device for a crane according to an aspect of the present invention. It is a disassembled perspective view of the turning apparatus of FIG. It is a figure explaining the turning apparatus of FIG. 1, the figure (a) is the top view, (b) is a front view, (c) is a side view (figure corresponding to FIG. 1), The part is shown broken away. It is explanatory drawing which expands and shows the principal part of the turning apparatus shown in FIG. 3, and the same figure is an enlarged view of FIG.3 (c). It is explanatory drawing which expands and shows the principal part of the turning apparatus shown in FIG. 3, and the same figure is a principal part enlarged view of Fig.3 (a). It is a figure explaining one Embodiment of the cylinder tube of the turning apparatus of this invention, The figure (a) is a left view, (b) is a front view. It is a disassembled perspective view explaining an example of the conventional turning apparatus. It is a figure explaining an example of the cylinder tube of the conventional turning apparatus, The figure (a) is a left view, (b) is a front view.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings as appropriate. In addition, the same code | symbol is attached | subjected about the component similar to the turning apparatus demonstrated with reference to FIG.
As shown in FIG. 1, the folding crane 1 is a crane used for forestry or the like, and the example in the figure is an example of being mounted on a vehicle 8 that travels by a crawler 7. As shown in the figure, the folding crane 1 is configured such that a column post 2 is erected on a base 9 of a vehicle 8 via a turning device 10 with respect to a vehicle 8 to be mounted so as to be turnable. The swivel device 10 has a substantially box-shaped housing 20, and the column post base end 2 a is mounted on the base 9 of the vehicle 8 with the housing 20 as a base. A folding boom 3 is pivotally supported at the upper end of the column post 2 so as to be freely raised and lowered. In addition, a crane operation unit 4 is provided at an upper part on the rear side of the column post 2 so that the working state can be seen from above. The crane operation unit 4 is provided with an operator seat 5 and a control lever 6.

Next, the swivel device 10 will be described in detail.
As shown in FIGS. 2 and 3, a pinion gear 12 having an upper end and a lower end supported by bearings 13 is provided in the housing 20 of the swivel device 10 so as to be rotatable around an axis line in the vertical direction. The pinion gear 12 is connected to a pivot shaft 2b extending below the column post base end 2a by a key 43 so as to rotate integrally with the column post base end 2a.

  A cover mounting portion 40 is formed in an annular shape around the opening at the opening on the upper surface of the housing 20. The annular cover 41 is fixed to the cover mounting portion 40 by a large number of cover fixing bolts 42, thereby closing the gap between the lower surface of the column post base end portion 2a and the opening of the upper surface of the housing 20. Yes. In addition, two sets (four in total) are mounted on both side surfaces 20a of the housing 20 in parallel with a pair of hollow cylindrical cylinder tubes 14 that protrude in the horizontal direction in pairs at left and right opposing positions.

  In the left and right cylinder tubes 14, 14, a slide rod 17 having pistons 18 at both ends is operated by supplying and discharging pressure oil into the pair of left and right cylinder tubes 14, 14. Pressure oil piping ports 51 are provided at both ends of the pair of cylinder tubes 14 and 14, and the slide rod 17 slides left and right along the axis of the cylinder tubes 14 and 14.

  On the side surface of the slide rod 17, a rack gear 19 is formed in which the pinion gear 12 and the central axes are orthogonally engaged with each other. Thus, the swivel device 10 includes the pinion gear 12 connected to the column post base end 2a and the rack gear 19 of the slide rod 17 in a state where the pinion gear 12 is sandwiched between the rack gears 19 of the two slide rods 17 arranged side by side. A rack-and-pinion mechanism is configured.

  Further, as shown in FIG. 5, each slide rod 17 has a smooth surface 31 along the longitudinal direction on the surface opposite to the side on which the rack gear 19 is formed. The housing 20 has a sliding plate 23 that is in sliding contact with the smooth surface 31 at a position facing the smooth surface 31 of the slide rod 17, and a sliding plate press that presses the sliding plate 23 toward the smooth surface 31. As a means, two sets of push screws 24 are provided, and play of the distance between the centers of the rack and pinion mechanism due to the deflection of the slide rod 17 is suppressed. The smooth surface 31 can be adjusted by freely translating it in the pinion gear axial direction with two sets of push screws 24.

The inside of the housing 20 is filled with an appropriate amount of lubricating oil, and always protects the two solid surfaces from severe wear of the meshing portion between the rack gear 19 and the pinion gear 12. Accordingly, in order to prevent leakage of lubricating oil from the inside of the housing 20, each cylinder tube 14 has a fitting surface between the outer peripheral surface of the spigot portion 30 and the tube mounting hole 25 of the housing 20 as shown in FIG. 5. An O-ring 32 is interposed therebetween.
The structure of the both side surfaces 20a of the housing 20 includes a flange mounting portion 21 to which the cylinder tube 14 is attached, and a tube mounting hole 25 formed in the flange mounting portion 21 and fitted into the spigot portion 30 of the cylinder tube 14 without a gap. It is formed so as to form two rows and one axis in one set on the left and right.

  The flange mounting portion 21 of the housing 20 has a plurality of female screws 22 equally distributed on the same circumference along the circumferential direction of the tube mounting hole 25 so as to face the plurality of flange bolt mounting holes 16 of the cylinder tube 14. doing. The center of the circle formed by the arrangement of the plurality of tube mounting holes 25 and the center formed by the circle formed by the arrangement of the plurality of female screws 22 are concentric. The female screw 22 is a bottomed hole. This is to prevent leakage of lubricating oil in the housing 20 described later.

  As shown in FIG. 6, an annular flange portion 15 having an inlay portion 30 for being fitted to the flange mounting portion 21 of the housing side surface 20 a without a gap is fixed to the end portion of each cylinder tube 14. As shown in the figure, the flange portion 15 has a plurality of flange bolt mounting holes 16 arranged equally on the same circumference C along the circumferential direction of the flange surface 15m, and a slide rod 17 described later. An inner hole 15n for machining is processed.

  Here, only the inner hole 15n of the flange portion 15 and 15t, which will be described later, are not formed in a coaxial circumferential shape, and the center line CL1 is formed eccentrically by an eccentric amount ΔE. In the center line CL2 of the flange portion 15, the fixing structure of the flange portion 15 and the cylindrical portion 14e of the cylinder tube 14 is an inlay structure in which the cylindrical portion tip 14s is fitted to the inner hole inner side 15t of the flange portion 15 and then welded. ing. Therefore, the inner hole 15n of the flange portion 15 and the central axis (center G (see FIG. 4), that is, CL1) of the cylindrical portion of the cylinder tube 14 are coaxial.

That is, as for the axis of the cylinder tube 14, the center axis of the inlay portion 30 and the center of the circle of the plurality of flange bolt mounting holes 16 (the center of the circumference C (see FIG. 4)) together form a coaxial CL2. In addition, there is an axis CL1 that is coaxially formed by the inner hole 15n of the flange portion 15 and the center G of the cylindrical portion of the cylinder tube 14, and the two shafts are structured to be eccentric by an eccentric amount ΔE.
When each cylinder tube 14 is attached to the housing 20, the spigot portion 30 of the cylinder tube 14 is fitted into the tube attachment hole 25 of the flange attachment portion 21 and attached using a plurality of flange attachment bolts 11.

  Here, the cylinder tube 14 has a structure in which the central axis CL2 of the inlay portion 30 as an attachment portion and the main cylinder tube center G (CL1) of the cylinder tube 14 are eccentric. The pair of left and right cylinder tubes 14 and 14 must be mounted so that the center G between them does not cause an axial shift. The misalignment between the center axes of the slide rods 17 causes a difference in the left and right sliding surface pressures between the pistons 18 at both ends of the slide rod 17 and the inner wall of the cylinder tube 14, thereby hindering smooth operation and a rack-and-pinion mechanism. The center-to-center distance cannot be adjusted correctly.

In order to prevent such a problem, the surface of the flange 15 of the cylinder tube 14 is provided with a mark M so as to show the eccentricity with respect to the center G of the cylindrical portion of the cylinder tube 14 as shown in FIG.
On the other hand, on the outside of the flange mounting portion 21 on the housing 20 side, a scale N (circled numbers 1 to 4 are attached as a guideline for adjustment) opposite to the mark M of the cylinder tube 14 is attached. . When the cylinder tube 14 is attached, the mark M and the scale N serve as a reference position for the center axes of the left and right cylinder tubes 14 and 14 with respect to the housing 20 to be accurately formed as a pair of left and right axes.

  That is, when the mark M of the left and right cylinder tubes 14 indicates the same scale with respect to the scale N on the housing 20 side, the center axes of the left and right cylinder tubes 14 and 14 are coupled to each other with an appropriate centering effect by the inlay. This is a proof that an accurate pair of left and right coaxials is formed. Further, when adjusting the distance between the center of the rack gear and the pinion gear by translating, the mark M indicates the same scale N on the left and right, which proves that the left and right cylinder tubes 14 and 14 are coaxial.

  As a result, the swivel device 10 rotates the pair of cylinder tubes 14 and 14 opposed to each other in the circumferential direction by the same number of scales, thereby reducing the distance between the centers of the pinion gear 12 and the rack gear 19 to a plurality of flanges. Corresponding to the bolt mounting holes 16, they can be translated in stages. That is, the backlash between the pinion gear 12 and the rack gear 19 can be adjusted stepwise for each circumferentially spaced pitch of the flange mounting bolts 11.

  In the example of this embodiment, since the flange 15 is fastened by 10 bolts as the plurality of flange mounting bolts 11, the cylinder tube 14 can be rotated 36 ° per pitch in the circumferential direction of the same circumference C. it can. Assuming that the value of the eccentricity ΔE is 1.5 mm, for example, the center distance between the pinion gear 12 and the rack gear 19 can be adjusted in six steps within a rotation range of 180 ° within a range of 0 mm to 3 mm. It should be noted that the pair of cylinder tubes 14 and 14 arranged opposite to each other are adjusted simultaneously so as to be in the same position.

Next, the turning operation by the above-described turning device 10 and the function and effect of the turning device 10 will be described.
In the turning operation by the turning device 10 described above, the pressure oil is supplied to and discharged from the pair of cylinder tubes 14 and 14 so that the pressure oil flows in from the end of one cylinder tube 14 and flows out from the other. At the same time, the pressure oil supply and discharge directions to the two cylinder tubes 14 and 14 arranged side by side are controlled in opposite directions. As a result, the two slide rods 17, 17 arranged in parallel according to the pressure oil supply / discharge direction are slid in opposite directions, and the rack gear 19 of each slide rod 17 simultaneously rotates the pinion gear 12, thereby causing the column post base The end 2a (that is, the column post 2) turns in a predetermined range (for example, a range of 400 °) in the horizontal direction. If the cylinder tube 14 that drives the rack gear 19 is hydraulic as in the present embodiment, when an unreasonable force is applied to the rack and pinion mechanism as compared with the electric motor drive, There is an advantage that an extra load is not applied to the structure itself by escaping a part of the pressurized oil that has been compressed to a high pressure.

Further, according to the swivel device 10 of the present embodiment, since the pair of cylinder tubes 14 and 14 are arranged in parallel, the required torque is reduced while the height of the swivel device 10 is reduced to a compact configuration. The pinion gear 12 can be rotated.
By the way, the above-described folding crane 1 is provided with the crane operation part 4 having the operator's seat 5 and the control lever 6 at the upper part on the rear side of the column post 2, so that the working state can be easily looked down and the workability is improved. On the other hand, the crane operating unit 4 also turns with the horizontal turning of the column post 2. Therefore, when the rack and pinion backlash of the turning device 10 is large, the backlash at the time of turning becomes large, so that the operator feels uneasy and may fall.

  On the other hand, according to the turning device 10 of the present embodiment, the pair of opposed cylinder tubes 14 and 14 are equally arranged on the same circumference C along the circumferential direction of the flange portion 15 of each cylinder tube 14. The plurality of flange bolt mounting holes 16 are formed so that the center of the circumference C where the plurality of flange bolt mounting holes 16 are formed is the same eccentric amount ΔE with respect to the axis (center G) of each cylinder tube 14. Since it is eccentric, the mounting position of the flange portion 15 of the pair of cylinder tubes 14 and 14 facing each other with respect to the flange mounting portion 21 of the housing 20 is rotated and changed by the same amount in the circumferential direction. The center-to-center distance between the pinion gear 12 and the rack gear 19 can be translated stepwise corresponding to the plurality of flange bolt mounting holes 16.

  Therefore, the backlash between the pinion gear 12 and the rack gear 19 can be easily adjusted in stages, and the crane operating unit 4 can reduce the backlash and suppress the play at the time of turning, so that the crane operating unit 4 as in the present embodiment can be used as the column post 2. Even in the crane provided at the upper rear side, the operator can concentrate on the work with peace of mind. Therefore, the turning device 10 of the present embodiment is particularly suitable for adjusting the backlash of the rack and pinion mechanism of the column post turning device of the folding crane 1.

Further, according to the swivel device 10 of the present embodiment, since the mark M is attached to the annular flange 15 of the cylinder tube 14 and the scale N corresponding to the backlash amount is attached to the housing 20 side, the pinion gear 12 and the rack gear are provided. This is more preferable for easily adjusting the backlash with respect to 19.
That is, according to the swivel device 10 of the present embodiment, when adjusting the backlash amount, the plurality of flange mounting bolts 11 for mounting the cylinder tube 14 are removed, and the cylinder tube 14 is rotated around the mark M in accordance with the desired scale N. The cylinder tube 14 is re-fixed with a plurality of flange mounting bolts 11 at a desired position. In addition, when rotating the cylinder tube 14, while being able to hold | maintain the cylinder tube 14, if a jig | tool which utilizes the internal thread 22 of the flange attachment bolt 11 is prepared, adjustment can be performed still more easily.

  For example, a plurality of claws are protruded from the jig, and the jig is manually inserted so that the mark M of the flange portion 15 is aligned with a scale N corresponding to a desired backlash amount while the claws are inserted into the female screw 22. The cylinder tube 14 can be easily rotated and the positioning of the flange bolt mounting hole 16 of the cylinder tube 14 and the female screw 22 of the housing 20 can be easily performed.

  Here, when the pinion gear 12 actually rotates, the clearance in the facing direction between the rack gear 19 and the pinion gear 12 is not always constant due to the relationship between the pressure angle and the deflection of the slide rod 17. According to the apparatus 10, the pinion gear 12 is configured to be sandwiched from both radial sides by the rack gear 19 of the slide rod 17 slidably fitted to the pair of cylinder tubes 14 and 14 arranged in parallel. It is suitable as a configuration for suppressing the above.

  Furthermore, according to the turning device 10 of the present embodiment, the slide rod 17 has the smooth surface 31 formed along the longitudinal direction on the surface opposite to the side on which the rack gear 19 is formed, and the housing is Since the slide plate 23 slidably contacts the smooth surface 31 at a position facing the smooth surface 31 of the slide rod 17 and the press screw 24 as a pressing means for pressing the slide plate 23 toward the smooth surface 31, It can be adjusted by freely moving the pinion gear 12 in the axial direction in accordance with the parallel movement of the rack gear 19, and the pinion gear 12 is clamped from both sides in the radial direction to suppress the deflection of the slide rod 17 and to suppress the fluctuation of the backlash amount. Even more preferred.

Further, according to the turning device 10 of the present embodiment, since the O-ring 32 is interposed on the fitting surface between the end of the cylinder tube 14 and the tube mounting hole 25 of the housing 20, when adjusting the backlash amount, There is no need to remove the lubricating oil filled in the housing 20, and the lubricating oil does not leak when adjusting the backlash amount.
The column post turning device for a crane according to the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

For example, in the swivel device 10 of the above-described embodiment, a configuration example in which two pairs of cylinder tubes 14 and 14 arranged opposite to each other are arranged in parallel has been described. Even if it is a set, a swivel device can be constituted and the present invention can be applied. However, in order to reduce the backlash fluctuation and to rotate the pinion gear 12 with a required torque while reducing the height of the swivel device 10 and making it a compact configuration, the pair of cylinder tubes 14 and 14 are arranged in two. It is preferable to arrange them in parallel.
Moreover, in the turning apparatus 10 of the said embodiment, although the example provided with the smooth surface 31, the sliding plate 23 slidably contacting this, and the press screw 24 as a press means was demonstrated, it can also be set as the structure which does not have these. However, in order to suppress the deflection of the slide rod 17 and more reliably suppress the fluctuation of the backlash amount, it is preferable to include the smooth surface 31 sliding plate 23 and the pressing means.

Further, for example, the swivel device 10 of the above embodiment has been described with an example in which the mark M is attached to the annular flange portion 15 of the cylinder tube 14 and the scale N corresponding to the backlash amount is attached to the housing 20 side. Not limited to this, it is also possible to adopt a configuration in which such a mark M and a scale N corresponding to the backlash amount are not provided. However, in order to easily adjust the backlash, it is preferable to provide such marks and scales. In particular, as in the above-described embodiment, two pairs of cylinder tubes are arranged side by side, for a total of four cylinder tubes. If it is the structure which adjusts, it is desirable to provide such a mark and a scale.
Further, for example, in the above-described embodiment, the example in which the O-ring is interposed on the fitting surface between the cylinder tube 14 and the housing 20 to prevent leakage of the lubricating oil has been described. If the periphery of the pinion gear is a dry structure, naturally the lubricating oil will not leak out, so this type of lubricating oil leakage preventing means can be omitted.

  Further, for example, in the above-described embodiment, each cylinder tube 14 is fitted to the tube mounting hole 25 formed in the flange mounting portion 21 of the housing 20 without a gap and is formed concentrically with the eccentric positions of the plurality of flange bolt mounting holes 16. Although the example in which the formed inlay portion 30 is formed has been described, a plurality of bolt mounting holes are arranged in the axis of the cylinder tube as in the above embodiment even in the case where the inlay portion 30 is not provided. The backlash can be adjusted by forming it eccentrically. However, in order to more surely prevent axial misalignment between the pair of left and right cylinder tubes 14 and 14, as in the above-described embodiment, the fitting surface of the spigot portion 30 of the cylinder tube 14 and the tube mounting hole 21 It is preferable that the inlay structure according to is provided at the same eccentric position as the eccentricity of the plurality of bolt mounting holes.

1 Folding crane (crane)
2 Column post 2a Column post base end (base end of column post)
2b Rotating shaft portion (base end portion) 3 Boom 4 Crane operating portion 5 Seat 6 Control lever 7 Crawler 8 Vehicle 9 Base 10 Rotating device 11 (Fixing cylinder tube) Flange mounting bolt 12 Pinion gear 13 Bearing 14 Cylinder tube 15 Flange portion 16 Flange bolt mounting hole 17 Slide rod 18 Piston 19 Rack gear 20 Housing 21 Flange mounting portion 22 Female screw (flange mounting portion) Female screw 23 Sliding plate 24 Push screw (sliding plate pressing means)
25 Tube mounting hole 30 Inlay portion 31 Smooth surface (of slide rod) 32 O-ring 40 Cover mounting portion 41 Cover 42 Cover fixing bolt 43 Key

Claims (5)

In a turning device for turning a column post of a crane horizontally with respect to a base of a vehicle on which the crane is mounted,
A housing mounted between the base end portion of the column post and the base, and is housed in the housing so as to be rotatable around an axis line directed in the vertical direction and rotates integrally with the base end portion of the column post. And a pair of hollow cylindrical cylinder tubes each having an annular flange surface mounted on a flange mounting portion disposed opposite to both side surfaces of the housing. The pair of cylinder tubes are slidably fitted to each other. And a rack and a slide rod having pistons at both ends so as to slide and move by pressure oil supplied to and discharged from the pair of cylinder tubes. A pinion type swivel device,
The cylinder tube is composed of an annular flange portion having an inlay portion at an end thereof, and a cylindrical portion welded to an inner side of an inner hole of the flange portion, and the flange portion is the annular flange surface. Having a plurality of bolt mounting holes equally distributed on the same circumference along the circumferential direction,
The center axis of the inner hole of the flange part and the center axis of the cylindrical part are the first coaxial arrangement, and the center axis of the spigot part and the same by the arrangement of the plurality of bolt mounting holes A second coaxial arrangement forming a coaxial axis with the central axis of the circumference,
The first post-coaxial arrangement and the second coaxial arrangement are formed such that their centerlines are decentered from each other.   The pair of cylinder tubes are formed such that the central axes of the same circumference by the arrangement of the plurality of bolt mounting holes are eccentric with respect to the central axis of the cylindrical portion, and the flange mounting portion of the housing is A plurality of female screws equally distributed on the same circumference along the circumferential direction at positions facing the plurality of bolt mounting holes, and the mounting position of the flange with respect to the flange mounting portion of the housing The backlash between the pinion gear and the rack gear can be changed in stages corresponding to the mounting positions in the circumferential direction of the plurality of bolt mounting holes. The turning device for a column post of a crane according to claim 1 characterized by the above-mentioned. Two pairs of cylinder tubes are arranged side by side, and the pinion gear is configured to be sandwiched from both sides in the radial direction by rack gears of the slide rods slidably fitted to the pair of cylinder tubes arranged side by side. ,
The slide rod has a smooth surface formed along the sliding direction on a surface opposite to the side on which the rack gear is formed, and the housing faces the smooth surface of the slide rod. 3. The column post for a crane according to claim 1, further comprising: a sliding plate in sliding contact with the smooth surface; and a pressing unit that presses the sliding plate toward the smooth surface. Swivel device.   Each cylinder tube is fitted with a tube mounting hole formed in the flange mounting portion of the housing without a gap, and an inlay portion formed concentrically with an eccentric position of the plurality of bolt mounting holes is formed. An O-ring is interposed between the outer peripheral surface of the portion and the fitting surface of the tube mounting hole of the housing, and the meshing portion of the rack gear and the pinion gear is filled with lubricating oil inside the housing. The crane column post turning device according to any one of claims 1 to 3, wherein the turning device is always in a lubrication state. A method of adjusting the backlash of the rack and pinion mechanism in the column post turning device for a crane according to any one of claims 1 to 4,
The backlash between the pinion gear and the rack gear is changed around the plurality of bolt mounting holes by changing the mounting positions of the flanges with respect to the flange mounting portions of the housing in the circumferential direction by the same amount. A method for adjusting the backlash of a column post turning device for a crane, which is changed according to the mounting position in the direction.

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