FR2841887A1 - Jib crane for moving objects in a horizontal plane has vertical tower to which main arm is connected for rotation about main axis, and second arm connected to main arm for rotation about second axis, adjustable via tie rod - Google Patents

Abstract

The jib crane includes a vertical tower (1) supporting a main arm (2) rotatably connected to the tower on a main vertical axis (X-X), with the main arm connected to a second arm (3) about a second vertical axis of rotation (Y-Y). The first axis includes two supports (7,8), one (7) of which is fixed and the other (8) of which is adjustable. The position of the second axis is adjustable by a tie rod (9) whose length is adjustable for compensating the jib arm under effects of a load. The ends of the tie rod are respectively connected to the main arm and to the main axis and another part by an adjustable connection provided between the main axis and the end adjacent the main arm, permitting compensation of twisting of the main arm.

Description

The present invention relates to a bracket

  with pivoting arms for moving objects in a horizontal plane. There are known brackets comprising a vertical ft supporting a main arm connected to the ft by a first vertical axis of rotation, this main arm being connected to a satellite arm by a second vertical axis of rotation, the free end of this satellite arm being intended to endure a

load to be moved.

  These arms are subjected to bending and twisting forces which affect the verticality of the two aforementioned axes of rotation, which generates a deviation of the trajectory of the arms relative to a horizontal plane. To this end, two-arm brackets are known, in which the verticality of the two axes of rotation is adjustable. Each of these two axes

  includes a fixed bearing and an adjustable bearing.

  However, the presence of these adjustment means, in particular those located near the second axis between the main arm and the satellite arm increases

the inertia of the moving crew.

  The resulting drawback is particularly noticeable in the case of large spans. The object of the present invention is to remedy this drawback by creating a bracket with two arms with adjustable axes whose inertia is reduced and which therefore is compatible with large spans,

for example reaching 5 m.

  According to the invention, the bracket comprising a vertical ft supporting a main arm connected to the ft by a first vertical axis of rotation, this main arm being connected to a satellite arm by a second vertical axis of rotation, the free end of this arm satellite being intended to support a moving load, the first axis comprising two bearings, the position of one of these bearings being fixed and that of the other being adjustable, is characterized in that the position of the second axis is adjustable d firstly by a tie rod of adjustable length to compensate for the deflection of the arms under the effect of the load, one end of this tie rod being connected to the main arm and the other end of which is connected to the first axis and on the other hand by adjustable connecting means provided between the first axis and the adjacent end of the main arm making it possible to compensate for the torsion of the main arm. Thus the means for adjusting the verticality of the second axis of rotation and for compensating for the deflection and

  the inertia are located near the first axis, i.e. near the ft.

  Consequently, thanks to the invention, the bracket is able to move loads in a plane

  horizontal with spans of up to 5 m.

  According to one embodiment of the invention, the position of said bearing is adjustable by two opposite screws screwed in parts fixed relative to the ft, the end of these screws being in contact with a movable part integral with said bearing, the two screws opposite being located in the plane of the first

axis and axis of the main arm.

  These two screws thus make it possible to move the bearing and therefore to adjust the verticality of the first axis. According to a feature of the invention, the two bearings of the first axis are carried by two horizontal tabs fixed to the ft and the end of the main arm adjacent to the ft is connected to a vertical tube, the ends of which are mounted in rotation on integral pivots each of one of said legs, the position of one of said pivots being adjustable by means of said screws, the ends of the tube being rotatably mounted on the pivots at

by means of bearings forming a ball joint.

  This arrangement allows the pivot to be moved

  mobile and the tube relative to the fixed pivot.

  According to another advantageous feature of the invention, the main arm is connected to the tube by a horizontal axis of rotation integral with said tube by two flanges. The position of these two flanges relative to said tube can be adjusted by means of screws arranged in such a way that they can rotate the main shaft around its axis in order to compensate for the torsion which may be

exerted on said tree.

  Other characteristics and advantages of the present invention will appear more clearly on

  reading the following description of several

  preferred embodiments of the invention with reference to the corresponding appended drawings in which - FIG. 1 is an elevation view of the bracket according to the invention, - FIG. 2 is a plan view from above of the bracket according to FIG. 1, - Figure 3 is an enlarged view of detail A of Figure 1, - Figure 4 is an enlarged view of the upper part of Figure 3, - Figure 5 is an enlarged view of the lower part of Figure 3, - Figure 6 is a sectional view along the

plan VI - VI of figure 5.

  Figures 1 and 2 show a bracket comprising a vertical ft 1 supporting a main arm 2 connected to the ft 1 by a first vertical axis X - X 'of rotation, this main arm 2 being connected to a satellite arm 3 by a second vertical axis Y -Y 'of rotation. The free end of the satellite arm 3 is intended to support a load to be moved. To this end, the satellite arm 3 carries an electric motor 4 or an electric or pneumatic actuator which is connected to a system of cables 5 and of pulley 6 to control the lifting and

lowering a load.

  Main arms 2 and satellite 3 extend

in a horizontal plane.

  The main arm 2 is capable of rotating at an angle of almost 3600 around the axis X XI. The satellite arm 3 is capable of rotating around the axis Y -Y 'at an angle defined by

  the extreme positions shown in Figure 2.

  In all positions, the arms 2 and 3 undergo under the effect of the load a bending which varies according to the value of this load and the angular position of the satellite arm 3 relative

main arm 2.

  The main arm 2 is also twisted due to the non-aligned position of the satellite arm 3 as shown in FIG. 2. In the example shown, the total range of the

arms 2 and 3 reaches 5 m.

  Because of this large range, it is understood that the bending and torsional forces exerted on the arms 2 and 3, have the effect of modifying the

  verticality of axes X - X 'and Y - Y'.

  It will thus be understood that there is an advantage in compensating for these bending and twisting forces in order to maintain the verticality of said axes X - X 'and Y

- Y.

  To this end, the first axis X - X 'comprises two bearings 7, 8 (see FIG. 3), the position of one 7 of these bearings being fixed and that of the other 8 being adjustable. According to the invention, the position of the second axis Y Y 'is adjustable on the one hand by a tie rod 9 of adjustable length to compensate for the deflection of the arms 2, 3 under the effect of the load. One end of the tie rod 9 is connected at 10 to the main arm 2 and the other end of this tie rod 9 is connected to the

first axis X - XI.

  Furthermore, adjustable connection means which will be detailed below, provided between the first axis X - X 'and the adjacent end 2a of the main arm 2 make it possible to compensate for the torsion

exerted on the main arm 2.

  In the example shown in Figures 1, 3 and 4, the bearing 8 of the first axis X - X 'whose position

  is adjustable is the upper level.

  It can be seen in particular in FIG. 4 that the position of said bearing 8 is adjustable by two opposite screws 11, 12 screwed into parts 13, 14 fixed relative to the ft 1. The end of these screws 11, 12 is in contact with a part 15 integral with the bearing 8, but free relative to the lug 16 connected to the ft 1. The two opposite screws 11, 12 are located in the plane of the first axis X - X 'and of the axis Z - Z' of the arms

main 2.

  We also see in Figures 1 and 3 that the two bearings 7, 8 of the first axis X - X 'are carried by two horizontal tabs 17, 16 fixed to ft 1 and that the end 2a of the main arm 2 adjacent to ft 1 is connected to the lower part of a vertical tube 18 whose ends are rotatably mounted on pivots 19, 20 each secured to one of said legs 17, 16. The position of the pivot

  upper 20 is adjustable by means of screws 11, 12.

  For the above adjustment to be possible, the opposite ends of the tube 18 are rotatably mounted on the pivots 19, 20 by means of bearings

22 forming a ball joint.

  As shown on the other hand in Figures 1, 3 and 4, the tie rod 9 is connected to the vertical tube 18 at a point located near the upper bearing 8 of the first axis X - X ', by means of a ball joint 23 screwed onto the end of the tie rod 9 and locked on this end by a nut 24. This ball joint 23 is retained in a complementary cavity 25 formed

  in a part 26 integral with the vertical tube.

  Furthermore, the adjustable connection means making it possible to compensate for the torsion of the main arm 2 are arranged between the vertical tube 18 of the first axis X - X 'and the adjacent end 2a of the main arm 2. As shown in FIGS. 5 and 6 , the main arm 2 is connected to the tube 18 by a horizontal axis of rotation R - R 'integral with said tube 18 by two flanges 27. The position of these two flanges 27 relative to the tube 18 can be adjusted by means of screws 28 arranged in such a way that they can rotate the main arm 2 around its axis ZZ 'in order to compensate for the twist

  likely to be exerted on this arm 2.

  Furthermore, screws 29 are provided to block the rotation of the main arm 2 around the horizontal axis R - R 'and the axis Z - Z' of the main arm 2, after having adjusted the means for

compensate for deflection and twist.

  To adjust the verticality of the axes X - X 'and Y Y' of the arms 2 and 3 so as to compensate for the bending and torsional forces exerted by a load

  given, we can proceed as follows.

  We start by adjusting the verticality of the axis X - X 'by acting on the screws 11 and 12 so as to move the upper pivot 20 to the right or to the left of FIG. 4. This movement is possible thanks to the play j existing in the lug 16. When the adjustment position is obtained, the part is blocked by tightening the screws 30. The verticality of the axis Y - Y 'is then adjusted, to compensate for the bending, by adjusting the length of the tie rod 9 by screwing or unscrewing the ball joint 23. When the adjustment position is obtained, the ball joint 23 is blocked by means of the nut 24. The verticality of the axis Y - Y ′ is then adjusted to compensate for the

  torsion, by acting on the screws 28.

  When the adjustment position is obtained, the rotation of the arm 2 is blocked around the axes R - R 'and Z - Z' by tightening the screws 29 and 31. The main advantage of the bracket which has just been described is that the means for adjusting the verticality of the second axis Y - Y 'are not located near this axis, but near the first axis X - XI located near the ft 1. This results in a reduction in the inertia of the crew mobile particularly advantageous in the case of long-span jibs.

Claims (8)

REVENDI CATIONS   1 - Stem comprising a vertical ft (1) supporting a main arm (2) connected to the ft by a first vertical axis (X - X ') of rotation, this main arm (2) being connected to a satellite arm (3) by a second vertical axis (Y - Y ') of rotation, the free end of this satellite arm (3) being intended to support a load to be moved, the first axis (X - X') comprising two bearings (7, 8) , the position of one (7) of these bearings being fixed and that of the other (8) being adjustable, characterized in that the position of the second axis (Y - Y ') is adjustable on the one hand by a tie rod (9) of adjustable length to compensate for the deflection of the arms under the effect of the load, one end of this tie rod (9) being connected to the main arm (2) and the other end of which is connected to the first axis (X - X ') and on the other hand by adjustable connecting means provided between the first axis (X - X') and the adjacent end of the main arm (2) allowing   compensate for the torsion of the main arm (2).   2 - Stem according to claim 1, characterized in that the bearing (8) of the first axis (X - XI) whose position is adjustable is the upper bearing.   3 - gallows according to one of claims 1 or   2, characterized in that the position of said bearing (8) is adjustable by two opposite screws (11, 12) screwed in two fixed parts (13, 14) relative to the ft (1), the end of these screws (11 , 12) being in contact with a movable part (15) integral with said bearing (8), the two opposite screws (11, 12) being located in the plane of the first axis (X - X ') and of   the axis (Z - Z ') of the main arm (2).   4 - Stem according to claim 3, characterized in that the two bearings (7, 8) of the first axis (X - X ') are carried by two horizontal tabs (16, 17) fixed to the ft (1) and in that the end of the main arm (2) adjacent to the ft (1) is connected to a vertical tube (18), the ends of which are mounted in rotation on pivots (20, 21) each secured to one of said legs (16, 17), the position of one (20) of said pivots   being adjustable by means of said screws (11, 12).   - Stem according to claim 4, characterized in that the ends of the tube (18) are mounted in rotation on the pivots (20, 21) at   means of bearings (22) forming a ball joint.   6 - Stem according to one of claims 4 or   , characterized in that the tie rod (9) is connected to the vertical tube (18) at a point located near the upper bearing (8) of the first axis (X - X '), by means of a ball joint (23) screwed onto the end of the tie rod (9) and locked on this end by a nut (24), this ball joint (23) being retained in a complementary cavity (25) formed in a part (26) integral with the vertical tube (18).   7 - gallows according to one of claims 4 to   6, characterized in that said adjustable connecting means making it possible to compensate for the torsion of the main arm (2) are arranged between the vertical tube (18) of the first axis (X - X ') and the adjacent end of the main arm (2).   8 - bracket according to claim 7, characterized in that the main arm (2) is connected to the tube (18) by an axis of rotation (R - R ') horizontal integral with said tube (18) by two flanges (27), the position of these two flanges (27) relative to said tube (18) which can be adjusted by means of screws (28) arranged in such a way that they can pivot the main arm (2) about its axis (Z - Z ') to compensate for the   torsion likely to be exerted on said arm.   9 - bracket according to claim 8, characterized in that it comprises means for blocking the rotation of the main arm (2) around said horizontal axis (R - R ') and said axis (Z - Z') of the main arm, after having settled the means for compensate for deflection and twist.