DE1043743B - Differential roller screw drive - Google Patents

Description

Differential Roller Screw Drive The invention relates to a Differential roller screw drive, in which between a spindle and a nut part, z. B. a coaxial spindle nut, thread rolls are arranged, the thread is in engagement with these two parts. The rollers transfer when rolling practically just the movements that, without these roles, are frictional movements between the directly adjacent surfaces of these two parts would then occur.

Such a differential roller screw drive is already known. In this case, the roller threads have the same inclination - which in the limit case can be zero can - like the screw thread of one of the two parts (spindle or nut), between which the rollers are arranged so that they do not move longitudinally with reference to this part. The prerequisite is that these roles are not exposed to any sliding movement, which is why a spur gear is provided at each end of the roller is that meshes with a ring gear on this part.

In the known differential roller screw drive, the nut formed by two parts that rotate together with a housing with which they are slidably wedged. By means of a threaded ring screwed into the housing ends the two nut parts can be brought closer to each other to avoid any play between balance the rollers and the threaded spindle.

As shown later, equalizing a game results in the usual Thread profiles for sliding the roller threads on the threads of the two parts, with which the rollers on the other hand when rotating through their with the ring gear of this Parts of meshing gears are connected. Such sliding causes wear, whereby the sliding is increased according to the wear.

This disadvantage requires a very high level of accuracy in the manufacture of the spindle, whereby the manufacturing price is increased considerably; if on the other hand despite Precision work if even the slightest play remains, signs of wear and tear occur that are rapidly increasing.

The invention is based on the object of eliminating this disadvantage.

The invention consists in that the thread profiles of the rollers and the profiles of the two parts that the rollers use when rotating through their gears are connected, are formed in a manner known per se from two circular arcs, which are symmetrical to a transverse plane perpendicular to the longitudinal axis of the bearing, and that the ratio of the radii of these circular arcs of the part and the rollers are equal to the ratio of the threads of this part and these rollers.

The invention will be explained in more detail with reference to the drawing. 1 shows a longitudinal section of the differential roller screw drive according to the invention, FIG. 2 shows a section along the line 2-2 in FIG. 1, FIGS. 3 and 4 partial longitudinal sections on a greatly enlarged scale in two positions of engagement of a roller with the two nut parts, FIG. 5 shows a graphical representation with the point of contact between the nut and the roller in two positions, FIG. E shows a partial section of a further exemplary embodiment, FIG. 7 shows a longitudinal section of another embodiment, FIG. 8 shows a section along the line 8-8 in FIG. 7, FIG. 9 a representation corresponding to FIG. 5, FIG. 10 a section of a further embodiment of the differential roller screw drive according to the invention. According to the embodiment shown in FIGS. 1 and 2, the differential roller screw drive has an outer housing formed by a cylindrical tube 1 with the axis XX. A base 2 is provided at one end of the housing and an internal thread 3 is provided at the other end. The two nut parts 5 and 6, between which there is a play 7, are slidably fastened to the tube 1 by means of a wedge 4. The nut part 5 is supported against the annular bottom 2 of the tubular housing 1. Near the bottom 2 it has a recess 5 a for the mounting of the ring gear 8, which is non-rotatably connected to the nut part s by a wedge 9. A toothed ring 11 , which is mounted in a recess 12 of the nut part 6, is also connected to the nut part 6 by a wedge 10.

A threaded ring serving for adjustment is supported against the nut part 6 13, which is screwed into the housing 1 will. The ring 13 can be secured in every set position. To do this, he shows a Slot 14, which can be pulled together by several clamping screws 15.

The prescribed parts rotate together around the X-X axis.

The two nut parts 5 and 6 have internal screw threads 16, which have an inclination P with respect to a perpendicular to the axis X-X, which in Borderline could be zero.

Coaxially, a spindle 17 is provided which is provided with an external thread 18 which is the same as the thread 16 of the nut in profile and dimensions. The inclination q of the spindle thread is different from the inclination P of the thread 16 and can be zero in the limit case.

The flank radius V of the spindle 17 is smaller than the flank radius E of the nut parts so that between the inner surfaces of the nuts and the screw spindle an annular gap remains. Rollers 19 are arranged in this space, which are provided with a thread 20 with the flank radius R. The roles 19 cooperate with the nuts and the spindle. The thread 20 has the same inclination P as the thread 16 of the nuts.

The maximum number of rollers 19 is equal to (n-n '), where n and n' are the Denote the number of threads of the nut and the spindle; the values n and n ' become positive for a right-hand thread and negative for a left-hand thread. If n is the same n 'is chosen, the number of roles is indefinite.

Preferably, the thread 20 of each roller is catchy. In this case A simple calculation shows that the ratio of the flank radii E and R is the Nuts and rollers is equal to n. Consequently n must be> 3, because for n = 2 it would be the roll radius is equal to half the nut radius, and there would be no space for the spindle.

Each roller is provided with gear wheels 21 and 22 at its ends, which are cut directly into the thread 20. The gears mesh with the corresponding ones Toothed rings 8 and 11, which are attached to nuts 5 and 6, respectively. The relationship the number of teeth of the gears 21 or 22 and of the ring gear 8 or 11 is the same the ratio of the number of turns of the thread of the nut and the rollers. It is n if the nut has n threads and the rollers have a single thread.

Thanks to the double engagement, once between the mother's sprockets and the rollers in the ratio n, on the other hand between the screw threads whose Gear numbers are in the same ratio n to each other, the roles become, if they rotate in the nut, not shifted lengthways relative to the nut. After n revolutions you are exactly at your starting point.

To facilitate assembly, the rollers run in smooth journals 23 and 24, which sit in rings 25 and 26 and form a kind of basket with the rollers.

The just described construction of the arrangement according to the AG is in itself no longer new; there are, however, still pertinent to the known Differences that in the screw drive according to the invention an elastic definition of the adjusting ring 15 is provided in the threaded hole 3 and especially in the Choice of the profile of the threads, which in borderline cases have no incline.

The thread profiles used so far were of a trapezoidal base formed at the top in the shape of an arc of a circle, convex or straight. These profiles lead to a The threads slide on each other as soon as one deviates from the original diameter. In contrast, the profile used according to the invention is designed as follows.

The thread 20 of each roller 19 has a convex profile in section, consisting of two circular arcs ab and bc (Fig. 3) of radius s. The arc of a circle are symmetrical to the transverse plane Y-Y, which is perpendicular to the longitudinal axis X-X of the shoot stands.

The thread 16 of each nut part 5, 6 has a concave profile which is formed by two circular arcs de and ef with the radius S. The circular arcs are also symmetrical to a transverse plane.

The two radii s and S fall at the point of contact of the two profiles, z. B. at m, together.

The ratio S-s is equal to the ratio of the number of gears in the selected Example equal to n.

The spindle 17 has n 'threads 18; the thread profile is not of importance and can be of a known type.

As a result of the specially designed threads 16 and 20, sliding of the roller thread on the nut thread is not possible, whatever the value of the initial play or the play caused by wear.

Proof of this is provided below. Fig. 3 represents the precise engagement between the nut parts and a roller with flank radii E and R, and a nominal flank radius V of the spindle 17 (Fig. 1, 2).

As already stated, the spur gears have after n revolutions of the roller 21 and 22 forcibly completed a revolution in the ring gears 8 and 11, and at the same time has described the thread 20n revolutions around the thread 16 of the nuts, and the Roller 19 has returned to its starting point without sliding; touch the threads again at the same point m a.

If the flank radius of the spindle 17 is less than the nominal value V, backlash would occur between the rollers and the spindle if the Nut parts 5 and 6 and the rollers 19 remain in the position according to FIG. This Game can be canceled by screwing in the collar 13 (Fig. 1), the as a result, the nut part 6, 6a (FIG. 4) approaches the nut part s or 5a. The roles 19 are moved parallel to the axis X-X of the device so that they are out of the Position according to FIG. 3 in position 19a according to FIG. 4 and the point of contact migrates from m (Fig. 3) to in '.

The mother's contact radius is now El, and after the graphic one Representation in Fig. 5 is E¹ = (E-L), the new roller contact radius is then R1 = (R-1).

The rolling condition for the new contact radius is From this it follows that the following condition must be met. Radius m0 m Radius m0 m In Fig. 5, ef indicates the profile of the nut parts and ab and albl denote the various positions of the corresponding roller profile.

x is the central angle of the two and i0 of the profile ef.

and the y is the angle-between the transverse plane Y-Y.

10 of the profile czib 'and zfz20 of the radius point zn2 close then again the angle x, where the point m2 is the one on the profile a¹b¹ corresponds to the arrived point m of the profile ab.

A simple calculation gives the following: consequently If, according to the invention, n is chosen, the condition (1) the requirement is met for a good rolling engagement of the new thread position without sliding.

It can be seen that the condition for all values of x is therefore fulfilled for all points of contact m. Conversely, the condition could be are not met by the usual profiles, in which a sliding of the profiles inevitably occurs when the point of contact shifts from m to m¹, since condition (1) is not met.

Fig. 6 shows a modified embodiment of the Vorist between the direction according to FIGS. 1 to 5.

Threaded collar 13 and the nut part 6 one (or more) elastic Disc 27 arranged, which automatically and elastically compensates for any play.

7, 8 and 9 illustrate another embodiment of the invention The nut is formed here by the tubular housing 28 itself, the has an internal thread 29. The spindle is formed by two sub-spindles 30 and 31, which are provided with threads 32 and 33. These threads have the same inclination however opposite direction of pitch as the thread 35 of the rollers 26, wherein the slope can be zero in the limit.

The spindle 31 is slidably supported by a wedge 38 on a journal 39 of the spindle 30. The axial play 40 between the two sub-spindles 30 and 31 can be adjusted by means of a nut 41 which is screwed onto the end of the pin 39 provided with a thread 42. The rollers 36 follow the shaft 37 and the sub-spindles 30, 31 during their longitudinal displacement, provided that the threads of these rollers have the same but opposite inclination as the threads 32 and 33. Each roller is provided with two spur gears 43, one of which meshes with a spur gear 44 which is arranged on those of the corresponding sub-spindle. The ratio of the teeth 44-43 is equal to the ratio of the number of threads of the threaded spindle and rollers, the number of threads of this ratio being n 'if spindle means and the rollers are provided with a single thread. The thread profiles of the rollers and the spindle correspond to the first embodiment. The relationship (Fig. 9) the radius of the symmetrical circular arc profiles is equal to the ratio of the number of turns of the thread of the spindle and rollers, which in the present example is n '.

One can with reference to FIG. 9, as has already happened for Fig. 5, show that when the contact point 'shifts to the m "as a result of a game of the rollers in the nut, whereby deviations L' of m and l ' For the rolling radius between the spindle and the rollers, no sliding occurs because the necessary and sufficient condition is fulfilled because is chosen. the same for this construction. Finally, FIG. 10 shows an embodiment according to which a vertical spindle 45 is displaced in a nut 46 which is fixed in height. The nut 46 is fastened in a tubular housing 48 by a wedge 47 which is seated on a support 49, at least one of the two parts (screw or nut) being rotatable. The nut 46 is made of a single piece here, because any play is avoided by the weight of the spindle or a pressure which is constantly exerted by the spindle thread 50 on the thread 51 of the rollers 52 or by these on the thread 53 of the nut. The rollers 52 are immovable with respect to the nut in the longitudinal direction as a result of the gears 54 and 55 provided at the roller ends which mesh with the ring gears 56 and 57 wedged in the nut.

The double circular arc thread profiles correspond to those in the first Embodiment described. The elastic deformation of the thread under load has not yet been taken into account.

The device is used with weak, but also with greater loads work satisfactorily when the ratio of the arc radius of the part, in which the rollers are connected in rotation by their spur gears, and said roles is largely the same as the ratio between the threads this part and the rollers without load.

For very heavy loads, the ratio of the radius would have to be without Load a little different (e.g. on the order of 1%) from that Ratio of the number of gears, so that the ratios under very heavy load are the same.

There could also be just a single interlocking between each role and that of the two parts (spindle and nut) should be provided, the opposite these roles must not shift lengthways, provided that the two Rings 24, 25 (Fig. 1) are rigidly connected to one another.

Claims (6)

1. Differential roller screw drive with coaxial spindle and nut, the thread of which in the borderline case have no inclination, between which, in engagement with them, thread rolls are arranged, the threads of which have the same inclination as those of one of the two parts, each with at least one on are provided with a gear seated at one end, meshing a ring gear which is firmly connected to one of the parts, characterized in that the thread profiles (ab) of the rollers (19, 36, 52) and the profiles (ef) of the two parts (5, 6 or 30, 31), with which the rollers (19 or 36) are connected during rotation by their gears (21, 22), are formed in a manner known per se from two circular arcs which are symmetrical to a perpendicular to the bearing longitudinal axis (XX) standing transverse plane (YY), and that the ratio the radius of this circular and ab) of the part and the rollers are equal to the arc ratio (n or n ') of the threads of this part and these rollers. 2. Screw drive according to claim 1, in which one part is a nut, characterized in that the profile (ab) of the thread of the rollers is convex, (ef) the thread of the nut parts while (5, 6) is concave. 3. Screw drive according to claim 1, characterized in that both the profile of the thread of the roll (36) is convex as well as that of the thread of the screw is convex. 4. Screw drive according to claim 1, wherein the nut part consists of two parts axially through a ring can be set that screws into the threaded housing is, in which these nut parts are slidably wedged, characterized in that this adjusting ring (13) has a slot (14) on the circumference, which by means of clamping screws (15) can be compressed so that the ring (13) is secured in each end position is. 5. screw drive according to claim 4, characterized in that between the Adjusting ring (13) and the adjoining nut part (6) at least one elastic ring (27) sits. 6. Screw drive according to claim 1, wherein the spindle consists of two sub-spindles is formed which are slidably keyed together, characterized in that an adjusting nut (41) is screwed onto the end of a pin (39) of the sub-spindle (30) is, so that the play between the two spindle stumps (30, 31) can be regulated can. Publications considered: Swiss Patent No. 290 685; U.S. Patent No. 1876,796.