FR2545185A1 - Spring leg with constant supporting capacity - Google Patents

Abstract

THE INVENTION RELATES TO A SPRING SUPPORT HAVING A CONSTANT BEARING STRENGTH. IN THIS SPRING SUPPORT LOCATED IN A HOUSING 3 RECEIVING A SPRING DEVICE CONNECTED TO A SUPPORT PLATE 1 AND INCLUDING A MOBILE CUP 5 JOINTLY WITH A ROD 6 CONNECTED BY ARTICULATION TO A LEVER 9 AND ARTICULATED ON A SLIDER 8 ADJUSTABLE IN A GUIDING GROOVE 17, A SCREW DEVICE ALLOWS THE ADJUSTMENT OF THE SLIDER AND SHAPES TWO SYMMETRICAL THREADED SPINDLES WITH RESPECT TO THE GROOVE 17 AND CAN BE DRIVEN IN COMMON ROTATION BY A GEAR SYSTEM. APPLICATION ESPECIALLY TO SUSPENSION SYSTEMS WITH CONSTANT LIFT.

Description

SUPPORT P, SPRING HAVING BEARING STRENGTH CONS
AUNT
The invention relates to a spring support having an essentially constant bearing force and serving to support or support a vertically movable load, for example a tubular pipe, and in which a housing comprising a support plate contains a device. with spring which is arranged between the fixed support plate and a movable spring cup and in which in addition to this resting cup comes out is connected one end of a linkage which extends through the spring device and through the fixed support plate and is articulated by its other end so as to be able to pivot on a lever which is mounted so as to be able to pivot on the housing and in which, in addition, the lever is constituted by two flanges in the form of plates, housing the linkage therebetween and which substantially have transverse to the longitudinal extent of the linkage, a guide groove along which the linkage of the linkage e can be moved by means of a slider, to carry out the adjustment of the load, and in which the adjustment of the slider can be carried out by means of a screw member or one takes avac the slider which is supported or is mounted on the lever and extends parallel to the guide groove.

 Such spring supports are known for example from the German patent application put under public inspection under the number 23 33 475. In order to be able to adapt the spring support respectively chosen from the point of view of its constitution to the actual loading conditions , provision is made for a later adjustment of the lift, which is achieved by modifying the ratios of the force action levers by means of an adjustment screw. In the case of spring supports intended for loads high and very high, the arrangement and actuation of the adjustment screw are complex, however, especially as it is arranged outside the slide and the linkage of the linkage. For high chraes it will be necessary to choose an adjustment screw having a consequent dimensioning for an important corresponding dimensioning of the bucket grout, which however would have a detrimental effect on the space requirement of the spring support in the vicinity of the indicated lever. adjusting screw, it would be necessary to implement a corresponding expense, because of the adjusting force to be exerted.

 The object of the invention is to modify or supplement a spring support of the type indicated above, so that the adjustment, that is to say consequently the modification of the length of the force action levers 7 is possible in a simple manner also for large loads to be supported, and can still be carried out manually in which case it must be achieved that the adjustment can be carried out in a single adjustment operation without there being a risk the slide can execute tilting movements or be tilted under the effect of the adjustment operation.

 This problem is solved in accordance with the invention in a spring support of the type indicated above, thanks to the fact that the screw member is constituted by at least two threaded pins arranged symmetrically on both sides of the guide groove and that the threaded spindles can be rotated in common via a reciprocal gear drive system.

 Thanks to these conforming arrangements of the invention, the support of the load is distributed, in a symmetrical manner with respect to the slide, between two threaded pins which can therefore be dimensioned more weakly than would be the case for a single pin. adjustment, and which reliably prevent the slider from being able to execute tilting movements or from being forced to execute tilting movements under the effect of adjustment or adjustment. In addition, thanks to the common drive of the two adjustment pins, it is possible to carry out, by means of an adjustment movement executable by hand, which is generally a rotary movement, the work of adjusting the spring support of the point of view of the effective length of the levers d1ac-.

force.

 According to an embodiment in accordance with the invention, it may be advantageous for the threaded pins to be joined together, in a rotational drive connection, at their end situated opposite the slide, using identical pinions and that the drive is effected by means of one of the threaded pins and that the threaded pins mesh with the slide by means of thread; having opposite directions. Therefore, under the effect of the rotation of one threaded spindle, the other threaded spindle is immediately driven together and this therefore avoids the separate actuation of several threaded spindles.

 According to another embodiment, it is possible to provide that the threaded pins have, on their end turned opposite the slide, identical pinions and can be cranked together in rotation, by means of a pinion rotatably mounted between these pinions or by means of an endless screw rotatably mounted # between said pinions This embodiment offers the possibility of providing, for the drive of the spindles, a reduction by the fact that, when the movement of rotation is triggered by a pinion which can be driven in rotation between the pinions of the threaded spindles, this pinion can be given a smaller diameter If a worm drive system is provided, a reduction is achieved in known manner important since very large adjustment forces can be exerted manually.

 Other characteristics and advantages of the invention will emerge from the description given below taken with reference to the appended drawings, in which - FIG. 1 shows an axial section of a suspension with constant lift; - Figure 2 shows the pin drive system used to adjust the lift of the suspension of Figure l, according to a detailed view on a larger scale - Figure 3 shows a side sectional view of the drive system of the device spindle of Figure 2, constituted by a worm gear mechanism - Figure 4 shows a plan view of the pin drive of Figure 3; and - Figure 5 shows another embodiment of a pin device for adjusting the lift in the case of a spring support of the type described in Figure 1, according to a partial representation.

 Figure 1 shows, in a median longitudinal section, a suspension with constant lift comprising a housing which is formed, from a fixed support plate 1, on one side by a cylindrical part 2 of the housing and the other side by mne also fixed part 3 of housing. In part 2 of the housing is disposed a helical spring 4 which on the one hand bears on the support plate 1 and to which, on the other hand, is hung a spring cup 5.To this spring cup 5 is rigidly fixed a linkage 6 which passes through - in this case also by means of the interposed mounting of a hinge 7 - the fixed support plate 1 and the other end of which is hinged, by the inter- medial of a slide 8, so as to be able to pivot on a lever 9 which is mounted at 10 so as to be able to pivot in the boot part 3. On the lever 9 is further articulated, so as to be able to pivot, a rod threaded 11 which carries, by means of a tensioner 12, the load not shown in detail and illustrated by the arrow 13.

 To be complete, it should be noted that the lever 9 comprises, in front of the drawing plane, another flange of identical constitution, the two flanges being connected together by means of a sheet 14 and a plate 15. Likewise, part 3 of the housing comprises a second flange - again located again in front of the plane of the drawing, in which case the connection is made by a welded plate 15 and moreover by the fixed support plate 1.

 The constant lift suspension shown in Figure 1 is supported and is fixed by its base plate 16 on a support. Naturally, a suspension could also be produced by means of the sheet 15, in which case corresponding suspension means should still be connected to the sheet 15.

 The flanges of the lever Uco-upor-ens a longitudinal groove 17 in which the slide 8 is movable essentially transversely relative to the longitudinal extension of the linkage 6 and can be blocked. The device used for this purpose and visible in FIG. 1 is shown in enlarged view in FIG. 2, in which the same reference numerals have been kept as those chosen for FIG. 1.

 As shown in Figure 2, the slide 8 is adjustable along a guide groove 17 via two threaded pins 18, 19, and one can obtain an adjustment of the lift of the suspension level constant in the case of use considered. The threaded pins 18, 19 are mounted so as to be able to rotate on the plate 15, while being axially blocked, and for this purpose, there is provided, for axial locking, on the one hand rings 20 rigidly connected to the threaded pins 18, 19 and on the other hand two identical pinions 21 and 22, by means of which the rotational movement is communicated to the threaded pins 18 and 19, in order to effect the displacement of the slider 18. A pinion 23 mounted so as to be able to rotate between the pinions 21, 22 and meshing with the latter and whose support in rotation on the plate 15 is produced by means of a stud 24, is used to trigger this rotational movement. In addition to the pinion 23, the body of the pinion carries a polygonal member 25 or the like, on which one can act for example using a tightening wrench in order to actuate it.

 As clearly shown in Figure 2, the meshing system between the pinion 23 on the one hand and the pinions 21, 22 on the other hand, constitutes a reduction so that even in the case of high loads to be supported by the suspension at constant lift or support at constant level, manual adjustment of the slide is still possible in which case on the other side, due to the distribution of the displacement and support forces for the slide 8 between two threaded pins 18, 19, the latter may have a correspondingly reduced diameter, which has a favorable effect on the overall width of the lever 9 - in a direction perpendicular to FIG. 1.

 Figures 3 and 4 show a variant of the object of Figure 2. Insofar as certain elements coincide with elements of Figures 1 and 2, we again use the same reference numbers for these elements in Figures 3 and 4 and an explanation is not given again of the parts of the device to which these references correspond.

 The alternative embodiment of FIGS. 3 and 4 resides in the fact that the threaded pins 18 and 19 can be rotated by helical teeth 30, 31, by means of an endless screw 32 which is mounted so as to be able to rotate in the lever 9 and which projects outside the part 3 of the housing, the worm carrying gripping members 33, 34 on the two ends of its axis. it goes without saying that the passage of the shaft of the endless screw through the part 3 of the housing is a slot in the form of an arc of a circle which allows the lever 9 to move.

 This worm drive device allows on the one hand still a much greater reduction in the direction of the threaded pins 18 and 19 and on the other hand the actuation of adjustment of the slide on another side of the spring suspension or spring support, which may be desirable or necessary depending on the mounting case.

 Figures 3 and 4 also show clearly how the part 3 of the housing and the lever 9 are constituted by two flanges and how also the linkage 6 is articulated on the slide 8 by means of two pieces of ex hoppers housing between them the threaded pins 18, 19. Finally, Figure 5 shows another variant. Here the pin 18 is again mounted and dispcsFa la'façon described in the previous figures while the pin 35 is supported on the one hand on the plate 15 and on the other hand on a plate 36, which is located on the end of the spindle 35 facing away from the plate 15, and is welded to the lever 9 there. This construction conditions the different length of the pins 18 and 35, so that outside of the plate 36, a member grip 37 can be connected to spindle 35 and allows adjustment of the slide 8 from its rib again modified with respect to Figures 1 to 4. The pins 18 and 35 can also be rotated in common by a system di direct meshing of, two pinions 38 and 39 connected together, which implies that the pins 18 and 35 must also include threads in opposite directions.

 Furthermore, for all the embodiments shown with reference to the representation of Figure 1, one can also have side by side several springs which are then connected to a common spring cup. In addition, according to the mounting conditions, the part 2 of the housing can also extend horizontally and be hung or bear support above the part 3 of the housing, in which case the lever 9 possèdealors then known manner another form.

Claims (5)

 1. Spring support having an essentially constant bearing force and serving to support or support a vertically movable load, for example a tubular pipe, and in which a housing (2, 3) comprising a support plate contains a spring device which is arranged between the fixed support plate (1) and a movable spring cup (5) and in which in addition to this spring cup is connected one end of a linkage which extends to through the spring device and through the fixed support plate and is articulated, by its other end, so as to be able to pivot 53 X levisi (9) which is mounted so as to be able to pivot on the housing (2, 3) and in which, in addition, the lever (9) consists of two plate-shaped flanges, housing between them the linkage and which have substantially transverse to the longitudinal extension of the linkage, a guide groove (17) along from which the articulation of the a linkage can be moved by means of a slide (8), in order to adjust the load, and in which the adjustment of the slide (8) can be carried out by means of a screw member (25) is engaged with the slide and is supported or mounted on the lever and extends parallel to the guide groove (17), characterized in that the screw member consists of at least two threaded pins (18, 19; 35) arranged symmetrically on both sides of the guide groove (17) and that the threaded pins can be rotated in common by means of a reciprocal gear drive system (21, 22, 23; 30, 31, 32; 38, 39).  2. Spring support according to claim 1, characterized in that the threaded pins (18, 19; 35) are arranged, in the longitudinal direction of the linkage (6), in front and behind the guide groove ( 17).  3. Spring support according to one of claims 1 or 2, characterized in that the threaded pins (18, 35) are joined together, in a rotation drive connection, at their ex; end opposite the slide (8), using identical pinions (38, 39) and that the drive is carried out by means of one (35) of the threaded pins and that the threaded pins mesh with the slide by means of threads having opposite directions.  4. Spring support according to one of claims 1 or 2, characterized in that the threaded pins (18, 19) have, on their end opposite the slide (8), identical pinions (21, 22; 30, 31) and can be rotated, in common, by means of a pinion (23) rotatably mounted between these pinions or by means of an endless screw (32) rotatably mounted between these pinions.  5. Spring support according to claim 4, characterized in that the intermediate pinion (23) has a pitch diameter smaller than that of the two identical pinions (21, 22).