JP2019113168A - Linear motion actuator and manufacturing method thereof - Google Patents

Abstract

To provide a linear motion actuator capable of determining the minimum number of spline teeth in a spline shaft part and a spline hole part that makes a position of an end face of a linear motion element in a stroke end in a shrinkage direction enter an allowable range while allowing displacement of teeth in spline coupling of the spline shaft part and the spline hole part.SOLUTION: The number of teeth in the spline shaft part and the spline hole part is determined in such a manner that, even in a case where spline teeth are displaced with respect to a target spline fitting position of a spline shaft part 32 and a spline hole part 35a, a distance between an axial end face of a projection 36 closer to a rotational motion element 22 in a stroke end in a shrinkage direction and an end face of the rotational motion element opposite to the axial end face is settled within a predetermined allowable range S.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a linear actuator including a ball screw mechanism that converts rotational motion transmitted to a rotational motion element into linear motion, and a method of manufacturing the same.

This type of linear motion actuator has a ball screw mechanism having a ball screw shaft and a ball screw nut screwed to the ball screw shaft through a large number of balls, and rotates one of the ball screw shaft and the ball screw nut. It is a motion element, and the other is a linear motion element that moves linearly.
Some of the linear actuators described above are provided with a stroke limiting mechanism in order to limit axial movement of the linear motion element (e.g., Patent Document 1).
The linear actuator described in Patent Document 1 has a ball screw mechanism having a ball screw portion of a ball screw shaft which is a linear motion element, and a ball screw nut which is a rotational movement element which is screwed to this via a plurality of balls. A device having

In the stroke limiting mechanism of Patent Document 1, a projection projecting in the radial direction is provided on a shaft portion provided coaxially with the ball screw portion of the ball screw shaft, and a locking portion on the ball screw nut (described as a stopper portion in Patent Document 1) Is provided. Then, the ball screw shaft is made to stroke in the direction of contraction by the rotation of the ball screw nut, and the projection abuts on the locking portion at the stroke end, thereby restricting the rotation of the ball screw nut.
The projection is formed to project in the radial direction from the outer peripheral surface of the cylindrical portion having a spline hole formed on the inner peripheral surface.
A spline shaft portion is formed on the outer periphery of the shaft portion of the ball screw shaft, and the cylindrical portion is fixed by spline connection of the spline hole portion of the cylindrical portion to the spline shaft portion.

Patent No. 5293887

By the way, the linear actuator achieves the high precision operation of the linear motion element by finely adjusting the axial end position of the linear motion element at the stroke end in the direction of contraction.
In Patent Document 1, assuming that the lead of the ball screw mechanism is Lb and the number of teeth is Z, if one spline of the spline hole of the cylindrical portion is shifted with respect to the spline shaft, the shaft end position is Since Lb / Z shift occurs, the axial end position of the linear motion element is finely adjusted by shifting the spline holes in the circumferential direction (see paragraph [0069] of the specification of Patent Document 1).

As described above, the axial end position of the linear motion element can be finely adjusted by changing the rotational phase (spline fitting phase) of the spline shaft and the spline hole.
By the way, if the number of teeth of the spline shaft and the spline hole is large, the above method can be used. However, if the number of teeth of the spline shaft and the spline hole is small, the shaft end position is largely shifted every time one tooth is shifted. It is not possible to accurately adjust the axial end position of the linear motion element by changing the fitting phase.
Therefore, according to the present invention, the minimum spline shaft portion in which the position of the end face of the linear motion element at the stroke end in the compression direction falls within the allowable range while allowing the tooth shift at the spline connection of the spline shaft portion and the spline hole portion It is an object of the present invention to provide a linear actuator capable of determining the number of spline teeth of a spline hole and a spline hole, and a method of manufacturing the same.

  In order to achieve the above object, a linear actuator according to an aspect of the present invention includes a rotary motion element and a linear motion element, and converts a ball screw mechanism that converts rotational motion transmitted to the rotary motion element into linear motion. The ball screw mechanism has a protrusion provided on the linear motion element, the protrusion is formed on the outer circumferential surface of a cylindrical portion having a spline hole formed on the inner circumferential surface, and the cylindrical portion is on the outer periphery of the linear motion element The spline hole portion is splined to the formed spline shaft portion to be fixed to the linear motion element, and the projection is rotated by the abutment of the locking portion formed on the rotational motion element at the stroke end of the linear motion element in the contraction direction. A linear actuator that restricts the rotational movement of a moving element, which can shrink even if the spline teeth are shifted with respect to the spline fitting position of the spline shaft and the spline hole. As the amount of protrusion of the axial end face of the linear movement element with respect to the axial end surface of the rotating movement elements in the direction of the stroke end is within the allowable range, and setting the number of teeth of the spline shaft section and the spline hole portion.

  A method of manufacturing a linear motion actuator according to an aspect of the present invention includes a ball screw mechanism having a rotary motion element and a linear motion element, and converting the rotational motion transmitted to the rotary motion element into linear motion. The screw mechanism has a protrusion provided on the linear movement element, the protrusion is formed on the outer peripheral surface of a cylindrical part having a spline hole formed on the inner peripheral surface, and the cylindrical part is a spline formed on the outer periphery of the linear movement element The spline hole is fixed to the shaft by spline connection to the linear motion element, and the projection is engaged with the locking portion formed on the rotational motion element at the stroke end of the linear motion element in the compression direction. In a method of manufacturing a linear actuator configured to restrict rotational movement, a spline hole is splined in a spline shaft after assembly of a ball screw mechanism is completed. And the projection of the axial end face of the linear motion element with respect to the axial end face of the rotary motion element at the stroke end in the shrinking direction even if the spline teeth are shifted with respect to the spline fitting position of the spline shaft and the spline hole. The number of teeth of the spline shaft portion and the spline hole portion is set so that the amount is within the allowable range.

  According to the linear motion actuator and the method of manufacturing the same according to the present invention, the position of the end face of the linear motion element at the stroke end in the direction of contraction is allowed while allowing the tooth shift at the spline connection of the spline shaft and the spline hole. It is possible to determine the minimum number of spline shaft portions that fall within the range and the number of spline teeth of the spline holes.

It is a front view showing a direct-acting actuator of a 1st embodiment concerning the present invention. It is a side view of FIG. It is sectional drawing on the AA line of FIG. It is sectional drawing on the BB line of FIG. It is a figure showing a ball screw nut, and (a) is a perspective view, (b) is a front view, (c) is a side view, and (d) is a sectional view on the DD line of (c). It is a figure which shows the principal part of a ball screw axis, and (a) is a figure which expanded and showed an involute spline shaft part, (b) is a sectional view on the EE line of (a). It is a figure which shows a rotation prevention member, Comprising: (a) is a perspective view, (b) is a front view, (c) is a principal part enlarged view of a front view, (d) is sectional drawing. It is a front view of a ball screw mechanism. It is a schematic diagram which shows the state in which the processus | protrusion provided in the linear motion element in the stroke end of a compression direction and the latching | locking part of the rotational motion element are contact | abutting. (A) is in front of the stroke end in the shrinking direction, and the projection provided on the linear motion element and the locking portion of the rotary motion element are separated in a small rotational phase, (b) It is a figure which shows the state which has separated the stop part by the phase of the large rotation direction. It is a schematic diagram which shows the state which the end surface of the linear motion element in the stroke end of a shrinkage direction is located out of tolerance | permissible_range. It is a figure which shows the relationship between the formula which calculates | requires the number of teeth Z which concerns on this invention, coefficient N, and the position precision S of the axial end of a linear motion element. It is a figure explaining adjustment of the number of teeth Z by the coefficient N which concerns on this invention.

  Next, a first embodiment of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic, and the relationship between the thickness and the planar dimension, the ratio of the thickness of each layer, and the like are different from the actual ones. Therefore, specific thicknesses and dimensions should be determined in consideration of the following description. Moreover, it is a matter of course that parts having different dimensional relationships and ratios among the drawings are included.

In addition, the first embodiment described below exemplifies an apparatus and a method for embodying the technical idea of the present invention, and the technical idea of the present invention includes materials, shapes, and structures of component parts. , Arrangement, etc. are not specified to the following. The technical idea of the present invention can be variously modified within the technical scope defined by the claims described in the claims.
In addition, the term which shows directions, such as "upper", "lower", "bottom", "front", "rear", etc. which are described by the following description is used with reference to the direction of an attached drawing.

[Configuration of Linear Actuation Actuator of First Embodiment]
1 is a front view showing the linear motion actuator according to the first embodiment, FIG. 2 is a side view, FIG. 3 is a sectional view taken along line AA of FIG. 1, and FIG. 4 is a sectional view taken along line BB of FIG. It is.
In the figure, reference numeral 10 denotes a linear actuator, and the linear actuator 10 has a main housing 11A and a sub housing 11B which are both die-casted of, for example, aluminum or an aluminum alloy.
As shown in FIG. 3, the main housing 11A has a motor mounting portion 13 for mounting the electric motor 12 on the front side, and a ball for mounting the ball screw mechanism 20 disposed parallel to the motor mounting portion 13 on the back side. And a screw mechanism mounting portion 14. The motor mounting portion 13 and the ball screw mechanism mounting portion 14 are formed such that central axes thereof are parallel to each other.

The motor mounting portion 13 is, as shown in FIG. 3, a flange mounting portion 13a for mounting a mounting flange 12a of the electric motor 12 formed on the front side and an electric motor 12 formed on the rear side of the flange mounting portion 13a. A large diameter hole portion 13b for inserting the large diameter portion 12b, a small diameter hole portion 13c for inserting the small diameter portion 12c of the electric motor 12 communicated with the back surface side of the large diameter hole portion 13b, and a back surface side of the small diameter hole portion 13c And a pinion housing 13d communicating with the motor.
The ball screw mechanism mounting portion 14 communicates with the ball screw mechanism storage portion 14a formed at a position corresponding to the small diameter hole portion 13c of the motor mounting portion 13 formed on the back side, and communicates with the ball screw mechanism storage portion 14a It has the cylindrical part 14b to extend, and the seal | sticker accommodating part 14c connected to the front end of this cylindrical part 14b.

  As shown in FIG. 3, the sub housing 11B is configured to cover the pinion housing 13d and the ball screw mechanism housing 14a formed on the back side of the main housing 11A. The sub-housing 11B forms the pinion housing 16 and the ball screw mechanism housing 17 corresponding to the pinion housing 13d and the ball screw mechanism housing 14a of the main housing 11A, and further forms the breather 18 on the lower side. . Here, the ball screw mechanism accommodating portion 17 is formed with an accommodating cylindrical portion 17 a on the back side. The thrust needle bearing 17b is disposed at a position where the thrust needle bearing 17b contacts the axial end face of the accommodation cylindrical portion 17a, which will be described later.

As shown in FIG. 3, the electric motor 12 has a pinion gear 15 mounted on the tip of its output shaft 12d. Then, the electric motor 12 is mounted on the motor mounting portion 13. The electric motor 12 is mounted by inserting the electric motor 12 into the motor mounting portion 13 from the side of the pinion gear 15 and mounting the mounting flange 12a to the flange mounting portion 13a in a state where the pinion gear 15 is stored in the pinion storage portion 13d. Do.
On the other hand, as shown in FIG. 4, the ball screw mechanism 20 is a ball screw rotatably supported by rolling bearings 21a and 21b with seals in the ball screw mechanism accommodating portions 14a and 17 of the main housing 11A and the subhousing 11B. A nut 22 and a ball screw shaft 24 screwed to the ball screw nut 22 via a large number of balls 23 are provided.

  As shown in FIG. 5, the ball screw nut 22 is constituted by a nut cylindrical member 25 in which a ball screw groove 25a and a ball circulating groove 25b are formed on the inner peripheral surface. Here, as a ball circulation method of the ball screw nut 22, as shown in FIG. 5D, for example, an S-shaped circulation groove 25b in which one ball circulating portion exists in one turn is integrated with the ball screw nut 22. The form formed in is adopted. The circulation groove 25b is formed by cold forging, and the ball screw groove 25a is formed by cutting.

  The nut cylindrical member 25 is rotatably supported by the ball screw mechanism accommodating portion 14a via rolling bearings 21a and 21b at both axial end sides of the outer peripheral surface. A driven spline shaft 25c is formed between the inner rings of the rolling bearings 21a and 21b on the outer peripheral surface of the nut cylindrical member 25. Further, when viewed from the front, a fan-shaped convex engagement portion 25d is integrally formed on the front end surface of the nut cylindrical member 25 so as to protrude. Here, the side surface in the circumferential direction of the ridge engaging portion 25d is a flat surface.

Further, as shown in FIG. 3, the nut cylindrical member 25 splines the driven gear 26 to the driven spline shaft 25c. The driven gear 26 meshes with a pinion gear 15 mounted on the output shaft 12 d of the electric motor 12. The driven gear 26 has an involute spline hole 26 a formed on the inner peripheral surface thereof for meshing with the driven spline shaft 25 c.
As shown in FIG. 4, the ball screw shaft 24 is mounted on a cylindrical portion 14b formed in the main housing 11A and a storage cylindrical portion 17a formed in the sub housing 11B.

The ball screw shaft 24 has a ball screw portion 31 formed on the rear end side (right side in FIG. 4) from the axial center portion, and a ball connected to the front end side (left side in FIG. 4) of the ball screw portion 31. The involute spline shaft portion 32 having a diameter smaller than that of the screw portion 31 and the connecting shaft portion 33 having a smaller diameter than the involute spline shaft portion 32 connected to the front end of the involute spline shaft portion 32 ing.
A linear motion transmission device to which axial movement is transmitted from the linear motion actuator 10 is coupled to the coupling shaft portion 33.

The involute spline shaft portion 32 of the ball screw shaft 24 has spline teeth formed by rolling.
The involute spline shaft portion 32 of the ball screw shaft 24 has a bottom 39 formed between the plain teeth 38, as shown in FIG.
As shown in FIG. 6B, the first tooth bottom 39a is formed along the axial direction on the connecting shaft 33 side, and the diameter of the tooth bottom 39 is larger than the first tooth bottom 39a on the ball screw 31 side. The second tooth base 39b having a larger diameter is formed, and the diameter is gradually increased between the first tooth base 39a and the second tooth base 39b from the first tooth base 39a side to the second tooth base 39b side The tooth bottom 39c is formed.
And, a plurality of tooth bases 39 of the above-mentioned configuration are formed at a position of axial symmetry centering on the axis of the involute spline shaft 32.

As shown in FIGS. 3 and 4, the cylindrical portion 35 of the detent member 34 is splined to the involute spline shaft portion 32 of the ball screw shaft 24. At this time, the axial end surface of the cylindrical portion 35 spline-connected to the involute spline shaft portion 32 abuts on the end surface 31 a of the ball screw portion 31 on the involute spline shaft portion 32 side.
The anti-rotation member 34 is, as shown in FIG. 7, a cylindrical portion 35 having an involute spline hole 35a formed on the inner peripheral surface, and a stopper 36 formed on the outer peripheral surface of the cylindrical portion 35 and projecting radially outward. And.

The involute spline hole 35a is formed with spline teeth by punching.
The stopper 36 is a portion that protrudes in a rectangular shape when viewed from the axial direction, and the first stopper circumferential side surface 36 a and the second stopper circumferential direction that stand up at positions circumferentially spaced apart from each other on the outer peripheral surface of the cylindrical portion 35 A side face 36b and a stopper end face 36c connected at the rising edge portions of the first and second stopper circumferential side faces 36a and 36b are provided.

The first stopper circumferential direction side surface 36a is a flat surface, and the circumferential side surface of the ridge engaging portion 25d of the ball screw nut 22 abuts in a surface contact state at a stroke end described later.
In addition, both the side surface of the 1st stopper circumferential direction side 36a and the side surface of the circumferential direction of the protruding line latching | locking part 25d may not be a flat surface, but a cylindrical surface or a curved surface of a spherical surface may be sufficient as it.
The second stopper circumferential direction side surface 36b is formed as a slope surface in which the distance to the first stopper circumferential direction side surface 36a gradually increases from the stopper end surface 36c toward the outer peripheral surface of the cylindrical portion 35.

As shown in FIG. 7B, the position where the first stopper circumferential side surface 36a intersects the outer peripheral surface of the cylindrical portion 35 is defined as a first intersecting position 43a, and the second stopper circumferential side surface 36b and the outer peripheral surface of the cylindrical portion 35. The position where the point intersects is set as the second intersection point 43b.
Thus, the stopper 36 has a width dimension in the axis orthogonal direction of the stopper end face 36c as a, and a width dimension in the axis orthogonal direction of the base end side of the stopper 36 between the first intersection position 43a and the second intersection position 43b. Then, they are formed to have a relationship of a <b.
7C, the center of gravity of the stopper 36 is G, the height from the base end of the stopper 36 to the center of gravity G is e1, and the height from the center of gravity G to the end surface 36c of the stopper Assuming that the dimension is e2, they are formed to have a relationship of e1 <e2.

Further, as shown in FIG. 7D, when the axial dimension of the cylindrical portion 35 is L1 and the axial dimension of the stopper 36 is L2, the rotation preventing member 34 has a relationship of L1> L2 In addition, the stopper 36 is formed at a position close to the one end side opening of the cylindrical portion 35.
Here, as shown in FIG. 7D, the side surface of the stopper 36 facing the axial direction on the side where the cylindrical portion 35 protrudes is referred to as a stopper axial direction side surface 36d.
The involute spline hole portion 35 a of the cylindrical portion 35 is spline-connected to the involute spline shaft portion 32 of the ball screw shaft 24 in the rotation preventing member 34 configured as described above.

Then, as shown in FIG. 3 and FIG. 8, when the stopper 36 of the rotation preventing member 34 abuts against the ridge engaging portion 25d of the ball screw nut 22, the ball screw shaft 24 is in the stroke end position in the contraction direction. Become.
As shown in FIG. 4, the axial length of the ball screw nut 22 is set to substantially the same size as the axial length of the ball screw portion 31 of the ball screw shaft 24, and the ball screw shaft 24 is at the stroke end position in the contraction direction. When moved, the entire area of the ball screw portion 31 is accommodated in the ball screw nut 22.
Further, as shown in FIG. 4, a guide member 40 is attached to the inner peripheral surface of the cylindrical portion 14b of the main housing 11A.

The guide member 40 is a cylindrical body formed by cutting in the axial direction in a plane along a chord equal to or less than the diameter of the circle when the cylinder is viewed in cross section, and a guide groove 40c is formed along the axial direction .
The guide member 40 is held inside a support hole 41a formed in the cylindrical portion 14b of the main housing 11A. The stopper 36 of the rotation prevention member 34 of the ball screw shaft 24 is engaged with the guide groove 40c.
Further, on the outer peripheral surface on the front end side of the guide member 40, an engagement groove 40d is formed which engages with the protrusion 41c of the support hole 41a in the circumferential direction.
Further, in the main housing 11A, a seal 50 which is in sliding contact with the outer peripheral surface of the connecting shaft portion 33 of the ball screw shaft 24 is mounted on the seal accommodating portion 14c of the ball screw mechanism mounting portion 14. doing.

[About the number of teeth of splines of involute spline shaft and involute spline hole]
Spline connection of the involute spline hole portion 35a of the rotation preventing member 34 and the involute spline shaft portion 32 is performed after the ball screw shaft 24 is assembled to the ball screw nut 22 via the large number of balls 23.
9 (a) and 9 (b) show a state where the ball screw shaft 24 has moved to the stroke end position in the direction of contraction by the abutment of the stopper 36 of the rotation preventing member 34 and the projection 25d of the ball screw nut 22. ing.

As shown in FIG. 9B, the axial position of the stopper axial direction side surface 36d of the stopper 36 has an ideal design position. The ideal position in the axial direction of the stopper axial side surface 36 d is such that the axial distance from the axial end face of the ball screw nut 22 is X, and the linear movement connected to the connecting shaft portion 33 of the ball screw shaft 24 This position is a position where the performance of the transmission device can be optimally exhibited, and is a position where the stopper 36 does not contact the ridge engaging portion 25d even if it reversely rotates in the extension direction from the stroke end position in the compression direction.
The axial ideal position of the stopper axial direction side surface 36d is set to a predetermined allowable range S with a certain width. In addition, the value of the tolerance | permissible_range S is set to 0.3 mm, for example.
By the way, since the involute spline hole 35a is formed by punching and the involute spline shaft 32 is formed by rolling, spline teeth are not processed in consideration of assembly.

Therefore, the spline teeth of the involute spline hole portion 35a and the involute spline shaft portion 32 are spline-fitted so that the stopper 36 and the convex engagement portion 25d abut and the ball screw shaft 24 is positioned at the stroke end position in the contraction direction. There is also a case where spline connection is performed in the joint position, and the stopper 36 and the convex engagement portion 25d are separated, and the ball screw shaft 24 deviates several teeth with respect to the target spline fitting position deviated from the stroke end position in the contraction direction. In some cases, spline connection is performed at the position.
When the involute spline hole 35a and the involute spline shaft 32 are splined at a position shifted by several teeth from the target spline fitting position at which the ball screw shaft 24 deviates from the stroke end position in the shrinking direction, the stopper The ball screw shaft 24 is moved in the shrinking direction until the contact 36 is in contact with the ridge engaging portion 25d.

FIG. 10 (a) shows a state in which the involute spline hole 35a and the involute spline shaft 32 are splined when the stopper 36 and the ridge engaging portion 25d are in a small rotational phase, as shown in FIG. 11 shows a state where the involute spline hole 35a and the involute spline shaft 32 are splined when the stopper 36 and the ridge engaging portion 25d are in the phase of the large rotational direction.
In the case of FIG. 10 (a), the ball screw shaft 24 is only slightly moved in the shrinking direction until the stopper 36 abuts against the ridge engaging portion 25d, so the stopper axial direction side surface 36d of the stopper 36 It is likely to be located within the allowable range S.

  However, in the case of FIG. 10 (b), when the number of spline teeth of the involute spline hole 35a and the involute spline shaft 32 is small, the spline teeth are shifted by one each other so that the ball screw shaft 24 is contracted. The amount of movement increases, and there is a possibility that the stopper axial direction side surface 36d of the stopper 36 may move in the direction of contraction in a state where it exceeds the allowable range S (see FIG. 11). Conversely, if the number of spline teeth of the involute spline hole 35a and the involute spline shaft 32 is increased, even if the ball screw shaft 24 deviates from the stroke end position in the contraction direction, the spline teeth The amount of movement of the ball screw shaft 24 in the direction of contraction due to the shift of one tooth becomes smaller, and the stopper 36 and the ridge engaging portion 25d come into contact and the ball screw shaft 24 is close to the stroke end position in the direction of contraction. It becomes.

However, in order to increase the number of spline teeth of the involute spline hole 35a and the involute spline shaft 32, there is a processing limit.
Therefore, in the first embodiment, the number of teeth Z of the splines of the involute spline shaft 32 and the involute spline hole 35a is set by the following equation (1).
Z> (N × Lb) / S ...... (1)
As shown in FIG. 9, the symbol S indicates the stopper axial direction side surface 36d when the stopper 36 abuts against the ridge engaging portion 25d and the ball screw shaft 24 moves to the stroke end position, and the ball opposed thereto. It is a predetermined tolerance of the ideal axial distance between the axial end face of the screw nut 22. Further, as shown in FIG. 9, reference symbol Lb is a lead of the ball screw mechanism 20. Furthermore, the code N is a coefficient.

Therefore, when the number of teeth of the splines of the involute spline shaft 32 and the involute spline hole 35a is set to the number of teeth exceeding the number of Z in the above equation (1), the spline connection of the involute spline shaft 32 and the involute spline hole 35a It is possible to determine the minimum number of teeth that fall within the tolerance range S while allowing for tooth misalignment.
FIG. 12 shows the relationship between the coefficient N and the number of teeth Z based on the equation (1). According to FIG. 12, when the allowable range S is optional, the number of teeth in the allowable range S can be obtained. Then, it can be seen that the number of teeth Z also increases as the coefficient N increases.
Ru.

FIG. 13 is a diagram for explaining the adjustment of the number of teeth Z by the coefficient N.
The above equation (1) can be transformed into the following equation (2).
Lb / Z <S / N ...... (2)
From equation (2), when Lb / Z, that is, the lead Lb is divided by the number of teeth Z, the amount of axial movement of the ball screw mechanism 20 when it is rotated by one tooth can be obtained.

Here, assuming that the movement amount S ′ of the ball screw mechanism 20 in the axial direction when one tooth rotates, the following equation (3) is obtained.
S '= Lb / Z ...... (3)
And, in the case of N = 1, from Equations (2) and (3), S '<S ... (4)
The following equation is obtained, and when it rotates by one tooth, it will be out of the allowable range S. That is, as shown in FIG. 13, in the case of N = 1, the target spline fitting position of the involute spline hole portion 35 a with respect to the involute spline shaft portion 32 deviates from the allowable range S when one tooth shifts. .

Also, in the case of N = 2, from the equations (2) and (3), S '<S / 2 ... (5)
The following equation is obtained, and when it rotates by two teeth, it will be out of the allowable range S. That is, as shown in FIG. 13, in the case of N = 2, the spline fitting position of the involute spline hole 35 a with respect to the involute spline shaft 32 falls within the allowable range S when one slippage occurs. If 2 teeth shift, it will be out of tolerance range S.

Furthermore, in the case of N = 3, from the equations (2) and (3), S '<S / 3 ... (6)
The following equation is obtained, and it will be out of tolerance range S when it rotates by 3 teeth. That is, as shown in FIG. 13, in the case of N = 3, the spline fitting position of the involute spline hole 35 a with respect to the involute spline shaft portion 32 falls within the allowable range S when 2 teeth shift. If 3 teeth shift, it will be out of tolerance range S.

Thus, by changing the coefficient N, the number of teeth Z falling within the allowable range S is adjusted even when the spline teeth are shifted with respect to the spline fitting position of the involute spline hole 35a with respect to the involute spline shaft 32 can do.
Therefore, as shown in FIG. 13, when the coefficient N is a value smaller than 3, there is no robustness of the assembly accuracy of the cylindrical portion 35 of the rotation stopping member 34 with respect to the involute spline shaft portion 32.

That is, when the coefficient N = 1, the spline fitting position of the involute spline hole 35 a can not be shifted to another tooth with respect to the involute spline shaft 32. Further, in the case of the coefficient N = 2, shift the target spline fitting position of the involute spline hole 35a with respect to the involute spline shaft 32 by only 0.5 teeth in the forward and reverse rotational directions. I can not
On the other hand, when the coefficient N is a value of 3 or more, the spline teeth have one or more teeth in the forward direction and the reverse direction with respect to the spline fitting position of the involute spline hole 35a with respect to the involute spline shaft 32. As a result, the cylindrical portion 35 of the locking member 34 can be easily assembled with respect to the involute spline shaft portion 32.
Here, in consideration of the workability of the spline teeth, the case of N = 3 is preferable.

  Incidentally, the rotational movement element described in the present invention corresponds to the ball screw nut 22, and the linear movement element described in the present invention corresponds to the ball screw shaft 24, and the spline shaft described in the present invention Corresponds to the involute spline shaft 32. Further, the cylindrical body described in the present invention corresponds to the cylindrical portion 35, and the spline hole portion described in the present invention corresponds to the involute spline hole portion 35a, and the locking portion described in the present invention Corresponds to the convex hooks 25d. Also, the protrusions described in the present invention correspond to the stoppers 36. Furthermore, the axial end face on the rotational movement element side of the protrusion described in the present invention corresponds to the stopper axial direction side face 36d, and the allowable range described in the present invention Of the axial distance between the stopper axial direction side 36d when the ball screw shaft 24 moves to the stroke end position and the axial end face of the ball screw nut 22 opposite to the same. It corresponds to the range.

[Assembling method of linear actuator according to the first embodiment]
Next, a method of assembling the linear motion actuator 10 of the first embodiment will be described.
The ball screw mechanism 20 used in the linear motion actuator 10 is transported in advance to the assembly plant in a unitized state at the manufacturing plant.
In the united ball screw mechanism 20, the involute spline hole 35a of the cylindrical portion 35 of the rotation preventing member 34 is splined to the involute spline shaft 32 of the ball screw shaft 24. Further, grease is applied to the ball screw portion 31 of the ball screw shaft 24 and screwed into the ball screw nut 22 via the ball 23.

Then, the ball screw shaft 24 is moved to and held at the stroke end position in the contraction direction so that the entire area of the ball screw portion 31 of the ball screw shaft 24 is accommodated in the ball screw nut 22.
Then, in the assembling method of the linear motion actuator 10, first, the guide member 40 is mounted and held in the support hole 41a of the main housing 11A.
Next, with the engagement groove 40d of the guide member 40 facing the projection 41c of the support hole 41a, the guide member 40 is inserted into the support hole 41a to engage the projection 41c in the engagement groove 40d. And the guide member 40 which has blocked the axial movement inside the support hole 41a.

Next, the driven gear 26 is splined to the outer peripheral surface of the nut cylindrical member 25 of the ball screw nut 22 of the unitized ball screw mechanism 20, and the rolling bearings 21a and 21b are mounted on both sides thereof. And 21b fix the driven gear 26 by the inner ring.
Next, the ball screw mechanism 20 is inserted into the ball screw mechanism accommodating portion 14a of the main housing 11A from the connecting shaft portion 33 side, and the stopper 36 is engaged with the guide groove 40c of the guide member 40 attached to the main housing 11A.

Next, the outer ring of the rolling bearing 21a is fitted into the inner peripheral surface of the ball screw mechanism housing 14a, and is stored in the driven gear 26 ball screw mechanism housing 14a, completing the mounting of the ball screw mechanism 20 on the main housing 11A. Do.
Next, the electric motor 12 is inserted into the motor mounting portion 13 of the main housing 11A from the side of the pinion gear 15, and the pinion gear 15 is meshed with the driven gear 26 of the ball screw mechanism 20. Then, the mounting flange 12a of the electric motor 12 is bolted to the flange mounting portion 13a.

The attachment of the electric motor 12 to the main housing 11A may be performed before the attachment of the ball screw mechanism 20 to the main housing 11A.
Thus, when the mounting of the electric motor 12 and the ball screw mechanism 20 to the main housing 11A is completed, the sub-housing 11B is mounted on the back side of the main housing 11A via a packing (not shown) and fixed by fixing means such as bolting. Then, the seal 50 is inserted into the seal storage portion 14c of the main housing 11A and the snap ring 51 prevents the seal 50 from being removed, thereby completing the assembly of the linear actuator 10.

[Operation of Linear Motion Actuator of First Embodiment]
In this state, consider a case where the electric motor 12 is rotationally driven to transmit rotational driving force from the pinion gear 15 to the driven gear 26, and the ball screw nut 22 is rotated clockwise as viewed in FIG. 8, for example. In this case, the rotational force of the ball screw nut 22 is transmitted to the ball screw shaft 24 through the ball 23 so that the ball screw shaft 24 tends to rotate clockwise in the same direction as the ball screw nut 22.

At this time, the stopper 36 of the anti-rotation member 34 fixed to the ball screw shaft 24 also tries to rotate clockwise, but since the stopper 36 is engaged in the guide groove 40c of the guide member 40 Rotation of the direction is restricted. For this reason, the rotation prevention member 34 exerts a rotation prevention function of the ball screw shaft 24 by regulating the rotation of the stopper 36.
Then, by continuing to turn the ball screw nut 22 clockwise as seen in FIG. 8, the ball screw shaft 24 moves without turning leftward as seen in FIGS. 3 and 4. At this time, the stopper 36 moves while sliding in the guide groove 40 c of the guide member 40.

Thereafter, when the ball screw nut 22 continues to rotate clockwise as viewed in FIG. 8 and the ball screw shaft 24 reaches a desired forward position, the electric motor 12 is stopped to move the ball screw shaft 24 forward. Stop.
On the other hand, when the ball screw nut 22 is rotated counterclockwise in FIG. 8 by reversely driving the electric motor 12 from the state where the ball screw shaft 24 has reached the desired forward position, the ball screw shaft 24 Since the stopper 36 is engaged with the guide groove 40c of the guide member 40, it is retracted without being rotated in the axial direction while being detented. At this time, the stopper 36 moves while sliding in the guide groove 40 c of the guide member 40.

Then, when the stopper 36 fixed to the ball screw shaft 24 receding in the axial direction and the projection engaging portion 25 d of the ball screw nut 22 rotating in the counterclockwise direction face in the circumferential direction, As shown in FIG. 8, the first stopper circumferential direction side surface 36 a of the stopper 36 abuts on the ridge engaging portion 25 d.
In this manner, the first stopper circumferential side surface 36a of the stopper 36 and the convex hook engaging portion 25d of the ball screw nut 22 come into contact with each other in surface contact, thereby restricting further reverse rotation of the ball screw nut 22. The ball screw shaft 24 reaches the stroke end position in the contraction direction.
At the stroke end position in the contraction direction, the entire area of the ball screw portion 31 is accommodated in the ball screw nut 22.

[Operation and effect of linear actuator according to the first embodiment]
Next, the operation and effect of the linear motion actuator 10 of the first embodiment will be described.
The linear actuator 10 of the first embodiment sets the number of spline teeth of the involute spline shaft 32 and the involute spline hole 35a according to the following equation (1).
Z> (N × Lb) / S ...... (1)
As a result, since the number of teeth of the splines of the involute spline shaft portion 32 and the involute spline hole portion 35a is set to the number of teeth exceeding the number of Z in the above equation (1), the involute spline shaft portion 32 and the involute spline hole portion 35a It is possible to determine the minimum number of teeth that fall within the allowable range S while allowing the teeth to slip off at the time of spline connection.

Further, if the coefficient N is set to a value of 3 or more in the above equation (1), one or more teeth in the forward and reverse directions with respect to the target spline fitting position of the involute spline hole 35a to the involute spline shaft 32 Since the spline teeth can be shifted by this, the assembly of the cylindrical portion 35 of the locking member 34 with respect to the involute spline shaft portion 32 can be easily performed.
And if the coefficient N is set to 3 in said Formula (1), the workability of the spline tooth of the involute spline axial part 32 and the involute spline hole 35a can be improved.

Here, when the lead Lb is 3,
Z> (3 x 3) / 0.30 = 30
Therefore, when the number of teeth of the involute spline shaft 32 and the involute spline hole 35a is set to 30, the assembly of the cylindrical portion 35 of the rotation prevention member 34 with respect to the involute spline shaft 32 can be easily performed. , And the processability of spline teeth can be improved.
Also, when the lead Lb is 3.5,
Z> (3 x 3.5) / 0.30 = 35
Therefore, when the number of teeth of the involute spline shaft 32 and the involute spline hole 35a is set to 35, the cylindrical portion 35 of the rotation prevention member 34 can be easily assembled to the involute spline shaft 32. , And the processability of spline teeth can be improved.

  In the first embodiment, the ball screw nut 22 is driven to rotate by the electric motor and the ball screw shaft 24 is used as a linear motion element. However, the present invention is not limited to this. The present invention can be applied to the case where the screw shaft 24 is a rotational movement element rotated by a rotational drive source, and the ball screw nut 22 is a linear movement element.

10 linear actuator 11A main housing 11B sub housing 12 electric motor 12a mounting flange 12b large diameter portion 12c small diameter portion 12d output shaft 13 motor mounting portion 13a flange mounting portion 13b large diameter hole portion 13c small diameter hole portion 13d pinion housing portion 14 ball screw Mechanism mounting portion 14a Ball screw mechanism storage portion 14b Cylindrical portion 14c Seal storage portion 15 Pinion gear 16 Pinion storage portion 17 Ball screw mechanism storage portion 17a Storage cylindrical portion 17b Thrust needle bearing 18 Breather 20 Ball screw mechanism 21a, 21b Rolling bearing 22 Ball screw Nut 22a Ball screw nut 22 end face 23 Ball 24 Ball screw shaft 25 Nut cylindrical member 25a Ball screw groove 25b Ball circulation groove 25c Driven spline shaft 25d Convex bar lock 26 Driven gear 26a Involute spline hole 31 Ball screw 31b End face 32 of ball screw 32 Involute spline shaft 33a Two-sided width 33 Connecting shaft 34 Anti-rotation member 35 Cylindrical part 35a Involute spline hole 36 Stopper 36a First stopper circumferential side 36b 2nd stopper circumferential direction side surface 36c stopper end surface 36d stopper axial direction side surface of stopper 38 spline teeth 39 involute spline shaft portion tooth bottom 39a first tooth bottom 39b second tooth bottom 39c inclined tooth bottom 43a first intersection position 43b second intersection Position 40c Guide groove 40d Engagement groove 41a Support hole 41c Projection 50 Seal 51 Retaining ring a Width dimension in the direction orthogonal to the axis of stopper end face Width dimension in the direction perpendicular to the axis of the stopper end G Center of gravity position of stopper e1 Stopper From the proximal end to the center of gravity Height dimension e2 Height dimension from the center of gravity to the end face of the stopper L1 Axial dimension of the cylindrical part L2 Axial dimension of the stopper Lb Ball screw mechanism lead N factor S Coefficient side surface of the stopper at the stroke end in the contraction direction A predetermined allowable range of the ideal axial distance between the axial end surface of the ball screw nut facing this and the axial distance between the axial end surface of the stopper screw axial side and the axial end surface of the ball screw nut

Claims (10)

A ball screw mechanism having a rotational movement element and a linear movement element, and converting the rotational movement transmitted to the rotational movement element into a linear movement;
The ball screw mechanism has a projection provided on the linear motion element,
The projection is formed on an outer peripheral surface of a cylindrical portion having a spline hole formed on an inner peripheral surface,
The cylindrical portion is fixed to the linear motion element by spline coupling the spline hole portion to a spline shaft portion formed on an outer periphery of the linear motion element.
The linear motion actuator restricts the rotational movement of the rotational movement element by the abutment of a locking portion formed on the rotational movement element at the stroke end of the linear movement element in the contraction direction of the linear movement element.
Even when the spline teeth are shifted with respect to the spline fitting position of the spline shaft portion and the spline hole portion, an axial end surface on the rotational movement element side of the protrusion at the stroke end in the contraction direction and the axial end surface The number of teeth of the spline shaft portion and the spline hole portion is set such that the distance between the end face of the rotary motion element opposed to the end face is within a predetermined allowable range. Dynamic actuator.   The linear motion actuator according to claim 1, wherein the spline shaft portion is formed by rolling. The number of teeth of the spline shaft portion and the spline hole portion is Z,
A predetermined allowable range of a distance between an axial end face on the rotational movement element side of the projection at the stroke end in the contraction direction and an end face of the rotational movement element facing the axial end face is S,
The lead of the ball screw mechanism is Lb,
The linear motion actuator according to claim 1 or 2, which has a relationship of the following equation (1), where N is a coefficient.
Z> (N × Lb) / S ...... (1)   The linear motion actuator according to claim 3, wherein the coefficient N is set to 3.   The linear motion actuator according to claim 3, wherein the coefficient N is set to a value larger than 3. A ball screw mechanism having a rotational movement element and a linear movement element, and converting the rotational movement transmitted to the rotational movement element into a linear movement;
The ball screw mechanism has a projection provided on the linear motion element,
The projection is formed on an outer peripheral surface of a cylindrical portion having a spline hole formed on an inner peripheral surface,
The cylindrical portion is fixed to the linear motion element by spline coupling the spline hole portion to a spline shaft portion formed on an outer periphery of the linear motion element.
A method of manufacturing a linear motion actuator, wherein the projection is configured to restrict rotational motion of the rotational motion element by abutting a locking portion formed on the rotational motion element at a stroke end of the linear motion element in the direction of contraction. In
After the assembly of the ball screw mechanism is completed, the spline hole is splined to the spline shaft, and
Even when the spline teeth are shifted with respect to the spline fitting position of the spline shaft portion and the spline hole portion, an axial end surface on the rotational movement element side of the protrusion at the stroke end in the contraction direction and the axial end surface The linear motion actuator is characterized in that the number of teeth of the spline shaft portion and the spline hole portion is set such that the distance between the end face of the rotational motion element facing the surface is within a predetermined allowable range. Manufacturing method.   The method according to claim 6, wherein the spline shaft portion is formed by rolling. The number of teeth of the spline shaft portion and the spline hole portion is Z,
A predetermined allowable range of a distance between an axial end face on the rotational movement element side of the projection at the stroke end in the contraction direction and an end face of the rotational movement element facing the axial end face is S,
The lead of the ball screw mechanism is Lb,
The method for manufacturing a linear motion actuator according to claim 6 or 7, characterized in that the following equation (1) is satisfied, where N is a coefficient.
Z> (N × Lb) / S ...... (1)   The method according to claim 8, wherein the coefficient N is set to three.   The method according to claim 8, wherein the coefficient N is set to a value greater than 3.

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