This application claims priority to European Patent Application EP13164517 filed Apr. 19, 2014.
The present invention relates to the field of roller screw mechanisms for transforming a rotary movement into a linear translation movement, and vice versa.
Such a mechanism is provided with a screw having an outer thread, with a nut arranged around the screw and having an inner thread, and with a plurality of longitudinal rollers having an outer thread engaging the outer and inner threads of the screw and of the nut. The outer thread of each roller is extended axially at each end by gear teeth themselves extended axially by a cylindrical stud or pivot extending outwards.
In a first type of roller screw mechanism, the threads of the rollers and the thread of the nut have helix angles that are identical to each other and different to that of the thread of the screw such that, when the screw rotates in relation to the nut, the rollers rotate on themselves and roll about the screw without moving axially inside the nut. The rollers are rotationally guided by gear wheels mounted in a non-threaded part of the nut and having inner gear teeth meshing with the gear teeth of the rollers. The roller screw mechanism further comprises two end spacer rings each mounted radially between the screw and the associated gear wheel. Each spacer ring includes a plurality of axial through-holes inside which the studs of the rollers are housed. The spacer rings enable the rollers to be carried and the regular circumferential spacing thereof to be kept. Such mechanism is called a planetary roller screw.
A second type of roller screw mechanism has a similar operating principle but is different as a result of an inverted arrangement. The helix angles of the threads of the rollers, of the screw and of the nut are selected such that, when the screw rotates in relation to the nut, the rollers rotate on themselves about the screw and move axially in the nut. The rollers are rotationally guided by outer gear teeth provided on the screw and meshing with the gear teeth of the rollers. Two spacer rings are also provided to ensure the even circumferential position of the rollers. Such mechanism is called an inverted roller screw.
With the current design of roller screw mechanisms, at each side of the thread provided on the nut, there is a zone which is not used for carrying the loads. For a given axial dimension of the nut, this leads to a limited load capacity of the roller screw mechanisms
One aim of the present invention is to overcome this drawback.
It is a particular object of the present invention to provide a roller screw mechanism wherein, for a given axial dimension, the load capacity is increased.
In one embodiment, the roller screw mechanism includes a screw provided with an outer thread, a nut surrounding and coaxial with the screw, the nut being provided with an inner thread, a plurality of rollers radially disposed between the screw and the nut and each provided with an outer thread engaging the outer and inner threads and with two outer gear teeth, two gear wheels each provided with gear teeth meshing with the gear teeth of the rollers, and two spacer rings for maintaining the rollers circumferentially spaced apart. The spacer rings are axially offset towards the inside relative to the gear teeth of the gear wheels.
Thanks to the relative disposition of the spacer rings and the gear teeth of the gear wheels, the contact points between the outer thread of each roller and the threads of the screw and the nut can be increased. For a given axial dimension of the nut, the load capacity of the roller screw mechanism is thus significantly increased. The lifetime of the mechanism is also increased.
Preferably, each spacer ring is axially located between the outer thread of each roller and one of the outer gear teeth of the roller. Each spacer ring may comprise a plurality of recesses radially open and in which parts of the rollers are located.
In one embodiment, each roller comprises an outer groove axially located between the outer thread and each outer gear teeth, each groove of the rollers being located in one of the recesses of each spacer ring. The roller screw mechanism may further comprise two elastic retainer rings each mounted in a groove provided on the associated spacer ring in order to radially hold therebetween the rollers into the recesses of the spacer ring.
In one embodiment, the gear wheels are mounted in a non-threaded part of the nut. Preferably, each spacer ring is radially disposed between the outer thread of the screw and the associated gear wheel. Each spacer ring may be mounted into a bore of the associated gear wheel extending the gear teeth. In another embodiment, the gear wheels are provided on the screw.
In one embodiment, each roller provides, at each axial end, an end frontal surface oriented axially outwards and delimiting axially the associated outer gear teeth. As an alternative, each roller may further provide, at each axial end, a cylindrical stud extending axially outwards the associated outer gear teeth. Such studs may be provided to guide the rollers during the threading operations.
The gear teeth of the rollers and the gear teeth of the gear wheels may each have in cross-section an involute profile.
Alternatively, the gear teeth of the rollers and the gear teeth of the gear wheels each have in cross-section a circular arc-profile. For instance, the gear teeth of the rollers and the gear teeth of the gear wheels may each have in cross-section a hypocycloid profile.
The invention also relates to an actuator comprising a rotating means and a roller screw mechanism as defined above, the screw of the mechanism being coupled with the rotating means.
The present invention and its advantages will be better understood by studying the detailed description of specific embodiments given by way of non-limiting examples and illustrated by the appended drawings on which:
In
The rollers 20 are identical to each other and are distributed regularly around the screw 12. Each roller 20 extends along an axis 20a which is coaxial with the axis 12a of the screw and comprises an outer thread 22 engaging the thread 14 of the screw and the thread 18 of the nut.
As shown more clearly on
Referring once again to
The mechanism 10 further comprises two annular guides or spacer rings 44, 46 mounted in the nut 16 each axially at one side of the outer thread 22 of the rollers. Each spacer ring 44, 46 is mounted radially between the thread 14 of the screw and the associated gear wheel 36, 38. Each spacer ring 44, 46 is mounted into a bore (not referenced) of the associated gear wheel 36, 38 extending axially inwards the gear teeth 40, 42. As shown more clearly on
Referring once again to
Each spacer ring 44, 46 is axially located between the outer thread 22 of each roller and the end frontal surface 28, 30 of the roller. Each spacer ring 44, 46 is axially disposed next to one of the gear teeth 40, 42 of the gear wheel 36, 38. Each spacer ring 44, 46 is axially offset towards the inside of the nut 16 with regard to the associated gear teeth 40, 42. Each spacer ring 44, 46 is axially located between the outer thread 22 of each roller 20 and the associated gear teeth 40, 42 meshing with the gear teeth 24, 26 of the roller.
The mechanism 10 further comprises elastic retainer rings 50, 52 each mounted in a groove (not referenced) formed on the bore of the associated spacer ring 44, 46 in order to radially hold the rollers into the recesses of the spacer ring. The retainer rings 50, 52 radially bear against the bore of the associated spacer ring 44, 46 and are neither in contact with the associated roller 20 nor the screw 12. The elastic retainer rings 50, 52 may be formed from metal or synthetic material. As an alternative, the retainer rings 50, 52 can be avoided.
As an example, the threads 22 of the rollers and the thread 18 of the nut have helix angles that are identical to each other and different to that of the thread 14 of the screw such that, when the screw 12 rotates in relation to the nut 16, the rollers 20 rotate on themselves and roll about the screw 12 without moving axially inside the nut 16. The rollers 20 are rotationally guided parallel with the axis 20a by the gear teeth 40, 42 of the gear wheels and by the spacer rings 44, 46. The screw 12 is axially or longitudinally moveable in relation to the rollers 20.
In the disclosed example, each gear teeth 24, 26 of the rollers are axially spaced apart from the thread 22 by the associated groove 32, 34. Alternatively, the thread 22 of each roller may be extended axially at each end by the gear teeth 24, 26. In another variant, a smooth space portion may provided axially between the thread 22 and each gear teeth 24, 26. In these two cases, each roller is deprived of grooves and there is no elastic retainer ring.
In the disclosed example, the gear teeth 24, 26 of the rollers and the gear teeth 40, 42 of the gear wheels each have in cross-section an involute profile. Alternatively, the gear teeth may have in cross-section a different profile.
In the second example illustrated on
In the third example illustrated on
In the second and third examples, with the convex-concave tooth profile between the gear teeth 24, 26 of the rollers and the gear teeth 40, 42 of the gear wheel, the outer diameter of the gear teeth 24, 26 of each roller is lower than the diameter of the thread root of the outer thread 22 of the roller regardless of the pitch of the roller. For that reason, the interference between the outer thread 22 of each roller and the gear teeth 24, 26 provided at each end of the roller can be avoided during the machining operations of the roller.
The disposition of each spacer ring 44, 46 axially offset towards the inside of the nut relative to the gear teeth 40, 42 of the associated gear wheel permits to obtain, for a given axial dimension of the nut 18, a roller screw mechanism with an increased load capacity. Providing such an arrangement enables the contact points between the thread 22 of each roller and the threads 14, 18 of the screw and of the nut to be increased compared with a conventional roller screw mechanism wherein the disposition of the spacer rings is axially inverted. Here, the useful length of the inner thread 18 of the nut is increased.
In the illustrated examples, for each roller, each gear teeth 24, 26 is delimited axially on the outer side by the end radial surface 28, 30 since the spacer ring 44, 46 is mounted axially on the inner side, i.e. on the side of the outer thread 22 of the roller. This leads to have rollers 20 deprived of cylindrical studs or pivots extending axially outwards the gear teeth. Accordingly, for a given axial dimension of the nut, the useful length of the outer thread 22 of each roller meshing with the threads 14, 18 of the screw and the nut can be increased while having both the rollers, the gear wheels 36, 38 and the spacer rings 44, 46 entirely housed inside the nut.
Although the invention has been illustrated on the basis of a planetary roller screw mechanism, it should be understood that the invention can also be applied to an inverted roller screw mechanism comprising gear wheels mounted on the screw and having outer gear teeth meshing with gear teeth of the rollers. With such an inverted roller screw mechanism, each spacer ring is axially offset towards the inside of the mechanism relative to the gear teeth of the associated gear wheel as described above for the planetary roller screw mechanism.
Number | Date | Country | Kind |
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13164517 | Apr 2014 | EP | regional |