LINEAR ACCURACY WITH IMPROVED INDEXING MEANS

The linear actuator addresses inaccuracies and wear issues by using rollers pressed against lateral paths in grooves, enhancing precision and durability through rolling contact and ball bearings.

FR3160001B1Active Publication Date: 2026-06-19LINEATEC

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Patents
Current Assignee / Owner
LINEATEC
Filing Date
2024-03-07
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing linear actuators suffer from inaccuracies in the longitudinal position of the nut due to lateral play, premature wear of indexing elements, and shocks, especially in high-frequency applications with high loads, exacerbated by long stroke lengths and machining tolerances.

Method used

The linear actuator incorporates indexing means with rollers supported by a support element that permanently press against opposing lateral paths in grooves, minimizing lateral play and wear by promoting rolling contact, and using ball bearings to enhance durability and accuracy.

Benefits of technology

This design significantly reduces inaccuracies and wear, ensuring precise longitudinal positioning of the nut and reducing shocks, even in high-load, high-frequency operations.

✦ Generated by Eureka AI based on patent content.
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Abstract

LINEAR ACTUATOR WITH IMPROVED INDEXING MEANS Linear actuator (1) comprising: - an actuating rod (2) arranged telescopically in an external tube (3) and linearly movable along a longitudinal direction (II) between a retracted position and at least one extended position relative to said external tube (3), - an actuating member (4) shaped to generate the longitudinal movements of the actuating rod (2), comprising a threaded rod (5) rotating about the longitudinal direction (II) and a nut (6) cooperating by screwing with the threaded rod (5) to be moved bidirectionally in translation along the longitudinal direction (II) by rotation of said threaded rod (5), said nut (6) being mechanically coupled to the actuating rod (2), - indexing means (7) for the rotation of the nut (6) in the external tube (3), shaped to lock the nut (6) in rotation by relative to the external tube (3),and comprising at least one first longitudinal groove (8) formed in the outer tube (3) and comprising two opposing lateral support tracks (8a, 8b), and at least one first indexing member (10) integral with the nut (6) and slidably engaged between the two lateral support tracks of the first longitudinal groove (8). The first indexing member (10) comprises rollers which are permanently pressed against the two lateral support tracks of the first longitudinal groove (8). Figure to be published with the abbreviation: Fig. 2,
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Description

Title of the invention: LINEAR ACTUATOR WITH IMPROVED INDEXING MEANS TECHNICAL FIELD OF THE INVENTION

[0001] The present invention relates to linear actuators, and more particularly to the guidance of an actuating rod of a linear actuator.

[0002] A linear actuator AL according to the prior art as illustrated in [Fig. 1] comprises: - an actuating rod TA arranged telescopically in an external tube TE and linearly movable along a longitudinal direction DL between a retracted position and at least one extended position relative to said external tube TE, - an actuating member OA (here a ball screw VB) shaped to generate the longitudinal movements of the actuating rod TA, comprising a threaded rod TF rotating about the longitudinal direction DL and a nut EC cooperating by screwing with the threaded rod TF to be moved bidirectionally in translation along the longitudinal direction DL by rotation of said threaded rod TF, said nut EC being mechanically coupled to the actuating rod TA, - indexing means MI for rotation of the nut EC in the outer tube TE, shaped to prevent rotation of the nut EC relative to the outer tube TE.

[0003] In the linear actuator AL illustrated in [Fig. 1], the indexing means comprise: - two longitudinal grooves RL1 and RL2 formed in the outer tube TE, each comprising two opposing lateral support paths, - two indexing elements Oïl and OI2 fixed to the nut EC and respectively engaged by sliding between the two lateral support paths of the longitudinal grooves RL1 and RL2.

[0004] In practice, the indexing elements consist of pads made of a material with a low coefficient of friction in the longitudinal grooves.

[0005] To be mounted in the longitudinal grooves, the indexing members are inserted between the lateral support tracks of the corresponding longitudinal groove, and a lateral clearance must be provided between the indexing members and the lateral support tracks.

[0006] A first drawback is that the lateral play induces an inaccuracy in the longitudinal position of the nut when the threaded rod is rotated.

[0007] A second drawback is that the indexing elements wear out too quickly due to friction against the lateral support tracks. This premature wear increases the inaccuracy in the longitudinal position of the nut.

[0008] A third drawback is that lateral play can cause shocks (particularly when the direction of rotation of the threaded rod is reversed), which can lead to premature wear of the indexing elements, especially when the linear actuator is used in high-frequency applications with high loads. This premature wear also increases the inaccuracy in the longitudinal position of the nut.

[0009] These disadvantages are even more pronounced when the stroke of the indexing elements in the longitudinal grooves has a large length, because the longer the stroke, the greater the lateral play in order to take into account the machining tolerances of the longitudinal grooves. Description of the invention

[0010] One problem proposed by the present invention is to provide a linear actuator with improved indexing means, exhibiting less inaccuracy in the longitudinal position of its nut, and reducing the risks of shocks and premature wear.

[0011] To reach these objects and others, the invention proposes a linear actuator comprising: - an actuating rod arranged telescopically in an external tube and linearly movable along a longitudinal direction between a retracted position and at least one extended position relative to said external tube, - an actuating member shaped to generate longitudinal movements of the actuating rod, comprising a threaded rod rotating about the longitudinal direction and a nut cooperating by screwing with the threaded rod to be moved bidirectionally in translation along the longitudinal direction by rotation of said threaded rod, said nut being mechanically coupled to the actuating rod, - means for indexing the nut in rotation within the outer tube, shaped to lock the nut against rotation relative to the outer tube, and comprising: • at least one first longitudinal groove formed in the outer tube and comprising two opposing lateral support paths, • at least one first indexing element fixed to the nut and engaged by sliding between the two lateral support paths of the first longitudinal groove; according to the invention: - the first indexing element comprises a first pair of rollers substantially aligned longitudinally and having diameters smaller than the width between the two lateral support paths, - the first pair of rollers is supported by a first support element attached to the nut, - the first support element is shaped so as to permanently press one roller of said first pair of rollers against one of said two lateral support paths and the other roller of said first pair of rollers against the other of said lateral support paths.

[0012] The actuation member can be a ball screw or any other helical linkage member operating on the screw / nut principle.

[0013] Since the rollers are constantly pressed against the two opposing lateral tracks, the indexing member is received without lateral play in the first longitudinal groove, which effectively limits the risk of impact during a reversal of the threaded rod's direction of rotation. The accuracy in determining the longitudinal position of the nut as a function of the threaded rod's rotation (which can be determined using an encoder, for example) is also increased.

[0014] The permanent pressing of the rollers against the two opposing lateral paths also makes it possible to compensate for the manufacturing tolerances of the longitudinal groove, in particular if the latter is long.

[0015] Finally, the permanent pressing of the rotating rollers against the two opposing lateral paths promotes rolling with little (or even no) sliding of the rollers against the lateral support paths, which limits the risks of premature wear.

[0016] Preferably, for more reliable, more precise and more balanced indexing around the longitudinal direction, it can be provided that: - the indexing means comprise at least one second longitudinal groove formed in the outer tube and comprising two opposing lateral support tracks, - the indexing means comprise at least one second indexing member integral with the nut and slidably engaged between the two lateral support tracks of the second longitudinal groove, - the second indexing element comprises a second pair of rollers substantially aligned longitudinally and having diameters smaller than the width between the two lateral support paths, - the second pair of rollers is supported by a second support element attached to the nut, - the second support element is shaped so as to permanently press a first roller of said second pair of rollers against one of said two lateral support paths and the other roller of said second pair of rollers bearing against the other of said lateral support paths.

[0017] To further reduce the risks of premature wear, the rollers can advantageously be of the ball bearing type with a coaxial inner ring and outer ring between which balls are arranged.

[0018] Preferably, when an indexing member is disposed outside the corresponding longitudinal groove, the rollers define between them a maximum width, taken transversely to their substantially longitudinal alignment direction, which is greater than the width of the corresponding longitudinal groove.

[0019] The mounting of the indexing member in the corresponding longitudinal groove is thus done in a state of pre-stress which considerably lengthens the life of said indexing member.

[0020] Advantageously, it can be foreseen that: - each support element extends longitudinally in a first direction between a first end and a second end, and extends transversely in a second direction between the first and second lateral edges, - the support element comprises a first arm extending along the first lateral edge towards a free end located near the first end and a second arm extending along the second lateral edge towards a free end located near the second end, - each arm has at its free end means for receiving a roller, shaped to receive a roller in a rotational manner around a direction of rotation substantially perpendicular to the first and second directions, - the free end of the first arm can be moved elastically towards the second lateral edge while the free end of the second arm can be moved elastically towards the first lateral edge.

[0021] Such a support element is simple, inexpensive to produce and reliable.

[0022] Preferably, it can be provided that: - the elastic displacement capacity of the first arm towards the second lateral edge is provided by a slot formed in the support element from its first end towards its second end, - the elastic displacement capacity of the second arm towards the first lateral edge is provided by a slot made in the support element from its second end towards its first end.

[0023] The elastic displacement capabilities of the first and second arms are thus achieved in a simple way with a compact support element.

[0024] For an even smaller footprint, the slots can be made so as to present an overlap along the first direction.

[0025] Advantageously, the indexing member(s) are received in the respective longitudinal groove(s) by deformation of the first and / or second arms of the support elements. The arms of the support elements, tending to return to their initial position (before deformation), thus press the rollers against the lateral support tracks.

[0026] Preferably, the support elements are respectively attached and fixed by means of a flange in respective radial recesses formed in the outer wall of the nut. The flange allows the support elements to be fixed in a precise and constant orientation on the nut.

[0027] Advantageously, the linear actuator may include a first and a second longitudinal groove formed in the outer tube in diametrically opposite positions.

[0028] Preferably, each longitudinal groove can be delimited by two opposing lateral rails attached and fixed in a longitudinal slot formed in the side wall of the outer tube. The lateral rails can be easily machined separately from the outer tube, thus with greater precision. The lateral rails can be made of a material less prone to premature wear and undergo finishes and treatments (in particular heat treatments) that provide them with better wear resistance than the outer tube.

[0029] Alternatively, however, it can be provided that each longitudinal groove can be machined directly into the constituent mass of the outer tube.

[0030] To ensure reliable sliding of the nut in the outer tube, a guide ring can advantageously be provided between the nut and the inner surface of the outer tube, preferably two guide rings spaced apart along the longitudinal direction.

[0031] The guide ring(s) may preferably be made of a polymer material. For example, guide rings marketed under the name TURCITE® T59 by TRELLEBORG AB may be used. SUMMARY DESCRIPTION OF THE DRAWINGS

[0032] Other objects, features and advantages of the present invention will become apparent from the following description of particular embodiments, made in relation to the accompanying figures, among which:

[0033] [Fig.1] Fig.1 is a longitudinal cross-sectional view of a linear actuator according to the prior art;

[0034] [Fig.2] The [Fig.2] is a longitudinal cross-sectional view of a particular embodiment of a linear actuator according to the present invention;

[0035] [Fig.3] The [Fig.3] is a perspective view of an external tube of the linear actuator of the [Fig.2] in which a nut is guided in translation;

[0036] [Fig.4] The [Fig.4] is a perspective view of the outer tube and nut of the [Fig.3] taken in longitudinal section;

[0037] [Fig.5] The [Fig.5] is a longitudinal sectional view of the outer tube and nut of the [Fig.3];

[0038] [Fig.6] The [Fig.6] is a partial top view of the outer tube and nut of the [Fig.3];

[0039] [Fig.7] The [Fig.7] is a partial and bottom view of the outer tube and nut of the [Fig.3];

[0040] [Fig.8] The [Fig.8] is a partial cross-sectional view of the external tube and nut of the [Fig.3] according to a first transverse plane;

[0041] [Fig.9] The [Fig.9] is a partial cross-sectional view of the outer tube and nut of the [Fig.3] along a second transverse plane;

[0042] [Fig. 10] The [Fig. 10] is a perspective view of a support element used in the embodiment of the [Fig.2];

[0043] [Fig. 11] [Fig. 11] is a top view of the support element of [Fig. 8] in a resting state; and

[0044] [Fig. 12] The [Fig. 12] is a top view of the support element of the [Fig.8] in a state of partial elastic deformation. DESCRIPTION OF PREFERRED METHODS OF IMPLEMENTATION

[0045] When identical numerical references are used in several figures, embodiments or variants of the invention, these numerical references designate identical or similar elements in each of the figures, embodiments or variants.

[0046] Schematic figures 2 to 12 illustrate a particular embodiment of a linear actuator 1 according to the present invention (the linear actuator 1 is only partially represented compared to the prior art linear actuator illustrated in [Fig. 1]). This linear actuator 1 comprises: - an actuating rod 2 arranged telescopically in an external tube 3 and linearly movable along a longitudinal direction II between a retracted position and at least one extended position relative to said external tube 3, - an actuating member 4 shaped to generate the longitudinal movements of the actuating rod 2, comprising a threaded rod (externally) 5 rotating about the longitudinal direction II and a nut 6 (internally threaded) cooperating by screwing with the threaded rod 5 to be moved bidirectionally in translation along the longitudinal direction II by rotation of said threaded rod 5, said nut 6 being mechanically coupled to the actuating rod 2, - indexing means 7 in rotation of the nut 6 in the external tube 3, shaped so as to lock the nut 6 in rotation relative to the external tube 3.

[0047] The actuation member 4 is shown here only schematically. It can be a ball screw (as in [Fig. 1] of the prior art) or any other helical linkage member operating on the screw / nut principle.

[0048] In the embodiment shown in Figures 2 to 12, the indexing means 7 comprise: - a first longitudinal groove 8 formed in the external tube 3 and comprising two opposing lateral support paths 8a and 8b (see figures 8 and 9 more specifically), - a second longitudinal groove 9 formed in the external tube 3 and comprising two opposing lateral support paths 9a and 9b (see figures 8 and 9 more specifically), - a first indexing member 10 integral with the nut 6 and engaged in longitudinal displacement between the two lateral support paths 8a and 8b of the first longitudinal groove 8, - a second indexing member 11 fixed to the nut 6 and engaged in longitudinal movement between the two lateral support paths 9a and 9b of the second longitudinal groove 9.

[0049] The first indexing member 10 comprises a first pair of rollers 10a and 10b, offset longitudinally from each other and having diameters DIOa and DlOb less than the width L8 between the two lateral support tracks 8a and 8b. The first pair of rollers 10a and 10b is carried by a first support element 12 integral with the nut 6. The first support element 12 is shaped so as to permanently press the roller 10a in rolling contact against the lateral support track 8a and the other roller 10b in rolling contact against the other lateral support track 8b. As can be seen in [Fig.6], there remains a JlOa clearance between the roller 10a and the lateral support path 8b, as well as a JlOb clearance between the roller 10b and the lateral support path 8a.

[0050] Similarly, the second indexing member 11 comprises a second pair of rollers 1la and 11b offset longitudinally from each other and having diameters DIla and DI1b less than the width L9 between the two lateral support tracks 9a and 9b. The second pair of rollers 1la and 11b is carried by a second support element 13 integral with the nut 6. The second support element 13 is shaped so as to permanently press the roller 1la in rolling contact against the lateral support track 9a and the other roller 11b in rolling contact against the other lateral support track 9b. As can be seen in [Fig.7], there remains a play Jlla between the roller lia and the lateral support path 9b, as well as a play J 11b between the roller 11b and the lateral support path 9a.

[0051] The support elements 12 and 13 are respectively attached to the nut 6 by means of a flange 20 or 21 in respective radial housings 22 or 23 provided in the outer wall of the nut 6 (figures 4 and 5).

[0052] As can be seen more particularly in figures 8 and 9, which are partial sections respectively along a first transverse plane PI and along a second transverse plane P2, the rollers 10a, 10b, 1la and 11b are of the ball bearing type with an inner ring 14 and an outer ring 15 coaxial between which balls 16 are arranged.

[0053] It can be seen more particularly in figures 10 to 12 that each of the first 12 and second 13 support elements extends longitudinally along a first direction II-II (intended to be parallel to the longitudinal direction II) between a first end 12a or 13a and a second end 12b or 13b, and extends transversely along a second direction III-III between a first 12c or 13c and a second lateral edge 12d or 13d.

[0054] The support elements 12 and 13 each have a first arm 12e or 13e extending along the first lateral edge 12c or 13c to a free end 120e or 130e located near the first end 12a or 13a. The support elements 12 and 13 also each have a second arm 12f or 13f extending along the second lateral edge 12d or 13d to a free end 120f or 130f located near the second end 12b or 13b.

[0055] Each arm 12e, 13e, 12f or 13f has at its free end receiving means 17 for a roller 10a, 10b, 1la or 11b which are shaped to receive a roller 10a, 10b, 1la or 11b in a rotational manner about a direction of rotation IV-IV or VV substantially perpendicular to the first II-II and second III-III directions. Here, the receiving means 17 comprise a tube 17a with an internal thread 17b around which the inner ring 14 of the rollers 10a, 10b, 1la or 11b is fitted with a small clearance, which are then held captive on their respective tube 17a by a screw 17c engaging in the internal thread 17b (see figures 8 and 9).

[0056] As is more particularly illustrated in [Fig. 12], the free end 120e or 130e of the first arm 12e or 13e can be moved elastically in the direction of the second lateral edge 12d or 13d, while the free end 120f or 130f of the second arm 12f or 13f can be moved elastically in the direction of the first lateral edge 12c or 13c.

[0057] The elastic displacement capacity of the first arm 12e or 13e towards the second lateral edge 12d or 13d is provided by a slot 18 formed in the support element 12 or 13 from its first end 12a or 13a towards its second end 12b or 13b. The elastic displacement capacity of the second arm 12f or 13f towards the first lateral edge 12c or 13c is provided by a slot 19 made in the support element 12 or 13 from its second end 12b or 13b towards its first end 12a or 13a.

[0058] Slots 18 and 19 have an overlap R along the first direction II-II. This overlap R can be increased to provide the support elements 12 and 13 with an even smaller footprint along the first direction II-II.

[0059] On [Fig. 11], the arms 12e, 13e, 12f and 13f are not elastically displaced, so that the slots 18 and 19 have respective widths L18 and L19 that are substantially constant over their entire length.

[0060] Thus, when an indexing member 10 or 11 is disposed outside the corresponding longitudinal groove 8 or 9, the rollers 10a and 10b, or the rollers 11a and 11b, define between them a maximum width LM ([Fig. 11]), taken transversely to their substantially longitudinal alignment direction (first direction II-II), which is greater than the width L8 or L9 ([Fig.6] or 7) of the corresponding longitudinal groove 8 or 9.

[0061] In [Fig. 12], the arms 12e, 13e, 12f and 13f are elastically displaced, so that the slots 18 and 19 have respective widths L18 and L19 which are not constant along their entire length. The rollers 10a and 10b, or the rollers 11a and 11b, then define between themselves a width L, taken transversely to their substantially longitudinal alignment direction (first direction II-II), which is less than or equal to the width L8 or L9 of the corresponding longitudinal groove 8 or 9: the indexing elements 10 or 11 can then be inserted into the corresponding groove 8 or 9.

[0062] In other words, the indexing members 10 and 11 are received in a compressed state in the respective longitudinal grooves 8 and 9 by deformation of the first arms 12e or 13e, and / or by deformation of the second arms 12f or 13f of the support elements 12 or 13. After insertion and fixing of the support elements 12 and 13, the elasticity of the arms 12e or 13e pushes the roller 10a or 11b against the lateral support path 8a or 9b, and the elasticity of the arms 12f or 13f pushes the roller 10b or 11a against the lateral support path 8b or 9a.

[0063] In the embodiment of figures 2 to 12, and as is more particularly visible in figures 8 and 9, the longitudinal grooves 8 and 9 are delimited by two opposing lateral rails 80a and 80b on the one hand, and two opposing lateral rails 90a and 90b on the other hand, brought in and fixed in a respective longitudinal light 800 or 900 provided in the lateral wall of the external tube 3.

[0064] Alternatively, the longitudinal grooves 8 and 9 can be machined directly into the constituent mass of the side wall of the outer tube 3.

[0065] It can be seen more particularly in figures 4 and 5 that guide rings 24 and 25 are arranged between the nut 6 and the inner surface 3a of the outer tube 3. The two guide rings 24 and 25 are spaced apart from each other along the longitudinal direction II.

[0066] The guide rings allow satisfactory coaxiality to be maintained between the nut 6 and the inner surface 3a of the outer tube 3.

[0067] As previously explained, the indexing members 10 and 11 are received in the respective longitudinal grooves 8 and 9 by deformation of the first arms 12e or 13e, and / or by deformation of the second arms 12f or 13f of the support elements 12 or 13. Thus, overall, there remains no lateral play between the first pair of rollers 10a and 10b transverse to the first longitudinal groove 8. Similarly, overall, there remains no lateral play between the second pair of rollers 11a and 11b transverse to the second longitudinal groove 9.

[0068] When the nut 6 slides in the outer tube 3, the respective indexing members 10 and 11 remain permanently in contact (by rolling) with the lateral support tracks 8a and 8b on the one hand, and with the lateral support tracks 9a and 9b on the other hand, thanks to the elasticity of the arms 12e, 13e, 12f and 13f which allows them to absorb the geometric imperfections of the longitudinal grooves 8 and 9 and to dampen the shocks when the direction of rotation of the threaded rod 5 is reversed. Simultaneously, greater accuracy is provided in determining the longitudinal position of the nut 6 when the threaded rod 5 is rotated.

[0069] The present invention is not limited to the embodiments that have been explicitly described, but includes the various variants and generalizations contained within the scope of the following claims.

Claims

1. Demands Linear actuator (1) comprising: - an actuating rod (2) arranged telescopically in an external tube (3) and linearly movable along a longitudinal direction (II) between a retracted position and at least one extended position relative to said external tube (3), - an actuating member (4) shaped to generate the longitudinal movements of the actuating rod (2), comprising a threaded rod (5) rotating about the longitudinal direction (II) and a nut (6) cooperating by screwing with the threaded rod (5) to be moved bidirectionally in translation along the longitudinal direction (II) by rotation of said threaded rod (5), said nut (6) being mechanically coupled to the actuating rod (2), - indexing means (7) for rotation of the nut (6) in the outer tube (3), shaped to lock the nut (6) against rotation relative to the outer tube (3), and comprising: • at least one first longitudinal groove (8) formed in the outer tube (3) and comprising two opposing lateral support paths (8a, 8b), • at least one first indexing member (10) integral with the nut (6) and engaged by sliding between the two lateral support paths (8a, 8b) of the first longitudinal groove (8), in which: - the first indexing member (10) comprises a first pair of rollers (10a, 10b) offset longitudinally from each other and having diameters (DIOa, DlOb) less than the width (L8) between the two lateral support paths (8a, 8b), - the first pair of rollers (10a, 10b) is carried by a first support element (12) integral with the nut (6), - the first support element (12) is shaped so as to permanently press a first roller (10a, 10b) of said first pair of rollers (10a, 10b) in rolling contact against one of said two lateral support tracks (8a, 8b) and the other roller (10a, 10b) of said first pair of rollers (10a, 10b) in rolling contact against the other of said lateral support paths (8a, 8b), characterized in that: - each support element (12, 13) extends longitudinally in a first direction (II-II) between a first end (12a, 13a) and a second end (12b, 13b) and extends transversely in a second direction (III-III) between first (12c, 13c) and second (12d, 13d) lateral edges, - the support element (12, 13) comprises a first arm (12e, 13e) extending along the first lateral edge (12c, 13c) towards a free end (120e, 120f) located in the vicinity of the first end (12a, 13a) and a second arm (12f, 13f) extending along the second lateral edge (12d, 13d) towards a free end (120f, 1301) located in the vicinity of the second end (12b, 13b), - each arm (12e, 13e, 12f, 13f) has at its free end (120e, 130e, 120f, 130f) means for receiving (17) a roller (10a, 10b, 11a, 11b),shaped to receive a roller (10a, 10b, 1la, 11b) in a rotational manner around a direction of rotation (IV-IV) substantially perpendicular to the first (II-II) and second (III-III) directions, - the free end (120e, 130e) of the first arm (12e, 13e) can be moved elastically in the direction of the second lateral edge (12d, 13d) while the free end (120f, 130f) of the second arm (12f, 13f) can be moved elastically in the direction of the first lateral edge (12c, 13c).

2. Linear actuator (1) according to claim 1, characterized in that: - the indexing means (7) comprise at least one second longitudinal groove (9) formed in the outer tube (3) and comprising two opposing lateral support paths (9a, 9b), - the indexing means (7) comprise at least one second indexing member (11) integral with the nut (6) and slidably engaged between the two lateral support paths (9a, 9b) of the second longitudinal groove (9), - the second indexing member (12) comprises a second pair of rollers (1a, 11b) offset longitudinally from each other and having diameters (DI1a, DI1b) less than the width (L9) between the two lateral support paths (9a, 9b), - the second pair of rollers (lia, 11b) is carried by a second support element (13) integral with the nut (6), - the second support element (13) is shaped so as to permanently press a first roller (lia, 11b) of said second pair of rollers (lia, 11b) in rolling contact against one of said two lateral support paths (9a, 9b) and the other roller (lia, 11b) of said second pair of rollers (lia, 11b) in rolling contact against the other of said lateral support paths (9a, 9b).

3. Linear actuator (1) according to any one of claims 1 or 2, characterized in that the rollers (10a, 10b, 1la, 11b) are of the ball bearing type with an inner ring (14) and an outer ring (15) coaxial between which balls (16) are arranged.

4. Linear actuator (1) according to any one of claims 1 to 3, characterized in that, when an indexing member (10, 11) is disposed outside the corresponding longitudinal groove (8, 9), the rollers (10a-10b, 11a-11b) define between them a maximum width LM, taken transversely to their substantially longitudinal alignment direction, which is greater than the width (L8, L9) of the corresponding longitudinal groove (8, 9).

5. Linear actuator (1) according to any one of claims 1 to 4, characterized in that: - the elastic displacement capacity of the first arm (12e, 13e) in the direction of the second lateral edge (12d, 13d) is provided by a slot (18) formed in the support element (12, 13) from its first end (12a, 13a) in the direction of its second end (12b, 13b), - the elastic displacement capacity of the second arm (12f, 13f) in the direction of the first lateral edge (12c, 13c) is provided by a slot (19) formed in the support element (12, 13) from its second end (12b, 13b) in the direction of its first end (12a, 13a).

6. Linear actuator (1) according to claim 5, characterized in that the slots (18, 19) are made so as to present an overlap (R) along the first direction (II-II).

7. A linear actuator (1) according to any one of claims 1 to 6, characterized in that the indexing member(s) (10, 11) are received in the respective longitudinal groove(s) (8, 9) by deformation of the first (12th, 13th) and / or second (12f, 13f) arms of the support elements (12, 13).

8. Linear actuator (1) according to any one of claims 1 to 7, characterized in that the support elements (12, 13) are respectively attached and fixed by means of a flange (20, 21) in respective radial housings (22, 23) formed in the outer wall of the nut (6).

9. Linear actuator (1) according to any one of claims 1 to 8, characterized in that it comprises a first (8) and a second (9) longitudinal grooves formed in the outer tube (3) in diametrically opposed positions.

10. Linear actuator (1) according to any one of claims 1 to 9, characterized in that each longitudinal groove (8, 9) is delimited by two opposing lateral rails (80a-80b, 90a-90b) attached and fixed in a longitudinal slot (800, 900) formed in the lateral wall of the outer tube (3).

11. Linear actuator (1) according to any one of claims 1 to 9, characterized in that each longitudinal groove (8, 9) is machined directly into the constituent mass of the external tube (3).

12. Linear actuator (1) according to any one of claims 1 to 11, characterized in that at least one guide ring (24, 25) is disposed between the nut (6) and the inner surface (3a) of the outer tube (3), preferably two guide rings (24, 25) spaced apart along the longitudinal direction (II).

13. Linear actuator (1) according to claim 12, characterized in that the guide ring(s) (24, 25) are made of a polymer material.