JP6478571B2 - Electric linear actuator and electric brake device - Google Patents

Description

  The present invention relates to an electric linear actuator that linearly drives a driven member such as a brake pad by converting a rotational movement of an electric motor into a linear movement, and an electric brake device using the electric linear actuator.

  Patent Literature 1 and Patent Literature 2 listed below are electric linear motion actuators that linearly drive a driven member that is movably supported in the axial direction by converting rotational motion of a rotor shaft of an electric motor into linear motion by a motion conversion mechanism. What has been described in the past is known.

  In the electric linear actuator described in Patent Document 1 and Patent Document 2, an outer ring member is slidably incorporated in a cylindrical cylinder chamber formed in a housing, and an electric motor is mounted on the axis of the outer ring member. A rotating shaft that is rotationally driven is provided, and a planetary roller that is incorporated between the rotating shaft and the outer ring member is rotatably supported by a carrier that is rotatably supported around the rotating shaft. By rotating, the planetary roller revolves while rotating by frictional contact with the rotating shaft, and the spiral groove or circumferential groove formed on the outer diameter surface of the planetary roller and the spiral protrusion provided on the inner diameter surface of the outer ring member The outer ring member is linearly moved in the axial direction by screw engagement.

  In the electric linear actuator, the outer ring member is linearly moved in the axial direction by the screw engagement of the spiral groove or the circumferential groove provided on the planetary roller and the spiral protrusion provided on the outer ring member. A large boosting function can be ensured without separately installing a planetary gear type reduction mechanism, and it is suitable for use in an electric brake device having a relatively small linear motion stroke.

JP 2011-179535 A JP 2012-149747 A

  By the way, in the electric linear actuator described in Patent Document 1 and Patent Document 2, the outer ring member is clearance-fitted with respect to the inner diameter surface of the cylinder chamber in the housing in order to smoothly slide the outer ring member in the axial direction. As a fit, the slide guide gap is provided between the inner diameter surface of the cylinder chamber and the outer diameter surface of the outer ring member. The sliding guide clearance is preferably as the sliding ring gap smoothly slides the outer ring member, and the sliding resistance acting on the outer ring member is preferably reduced. However, if the clearance is too large, the outer ring member may be rattled or skewed. For this reason, it is usually set to about several tens of μm.

  However, the following problems may occur in the slide guide gap of the above size. That is, in the adoption of an electric actuator for an electric brake device in which a brake pad is linearly driven by an outer ring member and a disk rotor is pressed by the brake pad to apply a braking force to the disk rotor, the brake pad is a disk rotor. When braking is performed, the axial load applied from the planetary roller to the outer ring member gradually increases as the braking force increases. Further, an axial load is applied as a reaction force from the brake pad to the outer ring member.

  At this time, the axial load applied to the outer ring member is a spiral ridge having a V-shaped section provided on the inner diameter surface of the outer ring member and a spiral groove having a V-shaped section formed on the outer diameter surface of the planetary roller or the circumference. It acts on the screw engaging part which consists of the taper surface of a groove | channel, A part of the axial load becomes a radial component force, and presses an outer ring member toward radial direction outward. The outer ring member is elastically deformed radially outward by the pressing, and the diameter of the outer ring member is increased, and the enlarged diameter portion reduces the slide guide gap, and in some cases, forms a negative slide guide gap to linearly move the outer ring member. Inhibits.

  Further, when the disc rotor is braked, a contact force is applied to the brake pad by contact with the disc rotor, and a tangential force is applied to the outer ring member via the brake pad. The outer ring member is skewed by the load of the tangential force, and the enlarged ring portion of the outer ring member slides in a state of being in strong contact with the inner diameter surface of the cylinder chamber in the housing, thereby obstructing the linear motion of the outer ring member. Wear and seizure may occur.

  An object of the present invention is to suppress the inhibition of linear motion due to the expansion of the diameter of the outer ring member due to elastic deformation.

  In order to solve the above-described problems, in the electric linear actuator according to the present invention, a cylindrical outer ring member is slidably assembled with a clearance fit in a cylindrical cylinder chamber formed in the housing. A rotating shaft that is driven to rotate by an electric motor is provided on the shaft center of the outer ring member, and a planetary roller built between the outer diameter surface of the rotating shaft and the inner diameter surface of the outer ring member is rotatable about the rotating shaft. The rotating shaft is rotatably supported by a carrier supported on the outer surface of the planetary roller, and a spiral groove or a circumferential groove is formed on the outer diameter surface of the planetary roller to mesh with a spiral protrusion provided on the inner diameter surface of the outer ring member. In the electric linear actuator, the planetary roller is rotated and revolved by the frictional contact with the rotation shaft by the rotation of the outer ring member to linearly move the outer ring member in the axial direction. An amount obtained by increasing the gap amount in the radial direction so that the gap amount of the gap fitting portion of the outer ring member with respect to the cylinder chamber can absorb the expansion due to the elastic deformation of the outer ring member at least at the portion corresponding to the planetary roller. A configuration with an increased clearance fit was adopted.

  In the electric brake device according to the present invention, the brake pad is linearly driven by the electric linear actuator, and the disc rotor is pressed by the brake pad to apply a braking force to the disc rotor. In the brake system, a configuration using the electric linear actuator according to the present invention is adopted as the electric linear actuator.

  In the electric linear actuator having the above-described configuration, when the rotating shaft is rotated by driving the electric motor, the planetary roller revolves while rotating due to frictional contact with the rotating shaft, and is formed on the outer diameter surface of the planetary roller. The outer ring member linearly moves in the axial direction by the screw engagement of the spiral groove or the circumferential groove and the spiral protrusion provided on the inner diameter surface of the outer ring member.

  For this reason, by connecting the brake pad of the electric brake device to the outer ring member or the carrier, the brake pad can be linearly driven and pressed against the disk rotor, and a braking force can be applied to the disk rotor.

  Here, during braking in which the brake pad presses the disk rotor, the axial load applied from the planetary roller to the outer ring member gradually increases as the braking force increases. The axial load is a screw engagement comprising a spiral protrusion having a V-shaped section provided on the inner diameter surface of the outer ring member and a spiral groove having a V-shaped section formed on the outer diameter surface of the planetary roller or a tapered surface of a circumferential groove. Acting on the joint part, a part of the axial load becomes a radial component force and presses the outer ring member outward in the radial direction. By the pressing, the outer ring member is elastically deformed radially outward and expands in diameter.

  At this time, between the cylinder chamber and the outer ring member, the gap amount at which the fitting portion of the outer ring member with respect to the cylinder chamber can absorb the expansion due to elastic deformation of the outer ring member at least at the portion corresponding to the planetary roller. Therefore, the enlarged gap fit portion is increased in the radial direction, and the enlarged gap fit portion absorbs the enlarged diameter portion due to elastic deformation of the outer ring member. For this reason, it is suppressed that the enlarged diameter part of an outer ring member contacts the internal-diameter surface of a cylinder chamber strongly, and an outer ring member is linearly moved smoothly, without inhibiting linear movement.

  Here, when the disc rotor is braked, a rotating force is applied to the brake pad by contact with the disc rotor, and a tangential force is applied to the contact portion between the brake pad and the outer ring member. At this time, when the fitting gap at the opening end of the housing is large, the outer ring member skews due to the load of the tangential force, and the spiral groove or the circumferential groove formed on the outer diameter surface of the planetary roller and the inner diameter of the outer ring member A difference occurs in the load borne by the screw engagement of the spiral protrusion provided on the surface, and the durability of the screw engagement portion is lowered.

  Therefore, it is preferable that the axial position of the increased gap fitting portion is set to a portion other than the portion from the opening end of the housing to the shaft end surface on the housing opening end side of the planetary roller. In this case, the slide guide gap at the opening end of the housing can be made a minute radial gap, so that the skew of the outer ring member can be suppressed and the effect of preventing damage to the screw engaging portion can be obtained.

  In addition, by setting the axial position of the increased clearance fit portion within the slide region of the outer ring member, the outer diameter surface of the outer ring member is the inner diameter surface on both axial sides of the increased clearance fit portion of the cylinder chamber. Can be reliably slidably guided, and the skew of the outer ring member can be more effectively suppressed. At the same time, even when the outer ring member moves linearly outward, the outer periphery of the rear end portion in the sliding direction is increased in amount so that the outer ring member does not fit into the gap fit portion, so that the outer ring member is loaded from the disk rotor. It is possible to prevent the outer ring member from being bent due to the tangential force.

  In the electric linear actuator according to the present invention, as described above, in the mutual engagement between the cylinder chamber and the outer ring member, the amount of clearance at the portion corresponding to at least the planetary roller is the amount of clearance between the outer ring member and the cylinder chamber. The axial force applied to the outer ring member from the planetary roller via the screw engaging portion by increasing the gap amount that can absorb the expansion due to the elastic deformation of the shaft to the amount increased in the radial direction. Thus, when the outer ring member is elastically deformed and expands in diameter, the expanded diameter portion can be absorbed by the gap fit portion. Therefore, it is suppressed that the enlarged diameter part by the elastic deformation of the outer ring member comes into strong contact with the inner diameter surface of the cylinder chamber, and the outer ring member can be always linearly moved smoothly without hindering linear movement.

A longitudinal sectional view showing an embodiment of an electric linear actuator according to the present invention Sectional drawing which expands and shows a part of FIG. Sectional view along line III-III in FIG. Sectional drawing which shows the other example of the guide part which slide-guides an outer ring member Sectional drawing which shows the further another example of the guide part which slide-guides an outer ring member Sectional drawing which shows the further another example of the guide part which slide-guides an outer ring member A longitudinal sectional view showing an embodiment of an electric brake device according to the present invention Right side view of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 3 show the electric linear actuator A employed in the electric brake device B shown in FIGS.

  In the electric brake device shown in FIGS. 7 and 8, a caliper 11 is provided on the outer periphery of the disc rotor 10 that rotates integrally with a wheel (not shown), and the outer periphery of the outer side surface of the disc rotor 10 is provided at one end of the caliper 11. The claw part 12 which opposes a part in an axial direction is provided, and the outer side brake pad 13 is supported by the claw part 12.

  Further, an inner brake pad 14 is disposed opposite to the outer peripheral portion of the inner side surface of the disk rotor 10, and the inner brake pad 14 is attached to the disk rotor 10 by an electric linear actuator A provided on the other side of the caliper 11. I try to move it.

  A mount 15 is provided on the outer periphery of the inner side surface of the disk rotor 10. The mount 15 is fixedly supported by a knuckle (not shown). A pair of opposed pin support pieces 16 are provided on both sides of the mount 15, and slide pins 17 extending in a direction orthogonal to the disk rotor 10 are provided at the respective ends of the pin support pieces 16. The caliper 11 is slidably supported by each.

  Although not shown in detail in the figure, the mount 15 is supported so as to be movable toward the disc rotor 10 in a state in which each of the outer brake pad 13 and the inner brake pad 14 is non-rotatable. doing.

  As shown in FIG. 1, the electric linear actuator A has a housing 20. The housing 20 is integrally formed with the caliper 11 shown in FIG. 7 to form a cylinder, and a cylindrical outer ring member 21 is fitted in a clearance fit in a cylindrical cylinder chamber 20a provided inside thereof. Is slidably incorporated.

  A base plate 22 is provided at one end of the housing 20 outward in the radial direction. The outer surface of the base plate 22 and one end opening of the housing 20 are covered with a cover 23, and the base plate 22 and the cover 23 form a gear case. Forming.

  An electric motor 24 is supported on the base plate 22, and the rotation of the rotor shaft 25 of the electric motor 24 is decelerated and output by a gear reduction mechanism 30 in a gear case formed by the base plate 22 and the cover 23.

  As shown in FIGS. 1 and 8, the gear reduction mechanism 30 includes an input gear 31 attached to the rotor shaft 25 of the electric motor 24, an intermediate gear 32 that meshes with the input gear 31, and a mesh with the intermediate gear 32. The outer diameter of the output gear 33 is larger than the outer diameter of the intermediate gear 32, and the outer diameter of the intermediate gear 32 is larger than the outer diameter of the input gear 31.

  As shown in FIG. 1, the output gear 33 is supported at one end of the rotating shaft 34. The rotating shaft 34 passes through a bearing member 35 incorporated in one end portion of the housing 20 and is rotatably supported by a plurality of bearings 36 incorporated in the penetrating portion so as to be coaxial with the outer ring member 21. .

  Here, the bearing member 35 is prevented from moving to the gear reduction mechanism 30 side by a retaining ring 37 attached to the inner diameter surface of the housing 20.

  As shown in FIGS. 1 and 2, a carrier 40 that is rotatable within the outer ring member 21 around the rotation shaft 34 is incorporated on the rotation shaft 34. As shown in FIGS. 2 and 3, the carrier 40 includes a pair of discs 41 a and 41 b that face each other in the axial direction, and a plurality of column members 42 that maintain a constant spacing between the discs 41 a and 41 b.

  Each of the plurality of column members 42 is provided integrally with the outer side disc 41 b, and the inner side disc 41 a is coupled to the column member 42 by tightening a bolt 43 screwed into the end surface of the column member 42.

  The carrier 40 is rotatably supported around the rotation shaft 34 by slide bearings 44a and 44b incorporated in the inner diameter surfaces of the pair of disks 41a and 41b, and is attached to the shaft end portion of the rotation shaft 34. The retaining ring 45 prevents the rotating shaft 34 from coming off the shaft end.

  In each of the pair of disks 41 a and 41 b in the carrier 40, a pair of shaft insertion holes 46 opposed in the axial direction are formed at intervals in the circumferential direction. A shaft end portion of the roller shaft 47 is inserted into each of the pair of opposed shaft insertion holes 46, and a pair of opposed bearings 48 are fitted to the respective roller shafts 47, and the planetary roller 49 is rotatably supported by the bearings 48. Has been.

  Here, the shaft insertion holes 46 formed in the pair of disks 41a and 41b are long holes in the radial direction. The roller shaft 47 is movable in a range where it abuts on both ends of the long hole, and the roller shaft 47 is elastically deformed in the radial direction so as to wrap around the shaft end portion of each roller shaft 47. The planetary roller 49 is pressed against the outer diameter surface of the rotary shaft 34 by being biased inward. For this reason, when the rotating shaft 34 rotates, the planetary roller 49 rotates by frictional contact with the outer diameter surface of the rotating shaft 34.

  A plurality of circumferential grooves 52 are formed on the outer diameter surface of the planetary roller 49 at the same pitch as the pitch of the spiral protrusions 51 having a V-shaped cross section provided on the outer ring member 21. The protrusion 51 is screw-engaged. In place of the circumferential groove 52, a spiral groove having a lead angle different from that of the spiral protrusion 51 and having the same pitch may be formed.

  Among the pair of disks 41a and 41b in the carrier 40, between the inner disk 41a located on the bearing member 35 side and the opposed portion in the axial direction of the planetary roller 49, the thrust bearing 53 and the pressure seat are sequentially arranged from the planetary roller 49 side. A plate 54 and a pressure receiving seat plate 55 are incorporated, and the pressure seat plate 54 and the pressure receiving seat plate 55 are in contact via a spherical seat 56. In addition, a gap is provided between the fitting surfaces of the pressure receiving seat plate 55 and the roller shaft 47, and the roller shaft 47 and the pressure seat plate 54 are aligned with the pressure receiving seat plate 55 within the range of the gap. Yes.

  As shown in FIG. 1, a backup plate 57 and a thrust bearing 58 are incorporated between the inner side disk 41 a and the above-described bearing member 35 that rotatably supports the rotating shaft 34, and the outer ring member 21 to the planetary roller 49. The thrust bearing 58 supports the axial reaction force applied to the carrier 40 via the bearing.

  A pressing member 59 is fitted in the outer side end portion of the outer ring member 21. An anti-rotation groove 60 is formed on the distal end surface of the pressing member 59, and the outer ring member 21 is engaged by the engagement of the anti-rotation groove 60 and the anti-rotation protrusion 19 provided on the pad holder 18 of the inner brake pad 14 shown in FIG. Is prevented from rotating with respect to the inner brake pad 14.

  A boot 61 is attached between the outer side end of the housing 20 and the outer ring member 21, and the boot 61 seals between the outer end of the housing 20 and the tip of the outer ring member 21.

  In the electric brake device configured as described above, FIG. 7 shows a state in which the braking force is released from the disk rotor 10, and the pair of brake pads 13 and 14 are separated from the disk rotor 10.

  When the electric motor 24 shown in FIG. 1 is driven in the state in which the braking force is released as described above, the rotation of the rotor shaft 25 of the electric motor 24 is decelerated by the gear reduction mechanism 30 and transmitted to the rotating shaft 34, and the rotating shaft 34 rotates in the braking direction.

  Since the outer diameter surfaces of the plurality of planetary rollers 49 are in elastic contact with the outer diameter surface of the rotating shaft 34, the planetary roller 49 rotates due to contact friction with the rotating shaft 34 due to the rotation of the rotating shaft 34. While revolving.

  At this time, since the circumferential groove 52 formed on the outer diameter surface of the planetary roller 49 is screw-engaged with the spiral protrusion 51 provided on the inner diameter surface of the outer ring member 21, the circumferential groove 52 and the spiral protrusion are formed. The outer ring member 21 is moved in the axial direction by the thread engagement of the strip 51, and the inner brake pad 14 in contact with the outer ring member 21 is in contact with the disk rotor 10 to press the disk rotor 10 in the axial direction. start. The caliper 11 moves toward the direction in which the outer brake pad 13 supported by the claw portion 12 approaches the disc rotor 10 by the reaction force of the pressing force, and the outer brake pad 13 contacts the disc rotor 10, The outer brake pad 13 strongly clamps the outer periphery of the disk rotor 10 from both sides in the axial direction with the inner brake pad 14, and a braking force is applied to the disk rotor 10.

  When the braking force is applied as described above, the axial load applied from the planetary roller 49 to the outer ring member 21 gradually increases as the braking force increases.

  At this time, the axial load applied to the outer ring member 21 is a spiral ridge 51 having a V-shaped section provided on the inner diameter surface of the outer ring member 21 and a spiral having a V-shaped section formed on the outer diameter surface of the planetary roller 49. It acts on the screw engaging part which consists of the taper surface of a groove | channel or the circumferential groove | channel 52, and a part of axial load becomes a radial direction component force, and presses the outer ring member 21 toward radial direction outward. The outer ring member 21 is elastically deformed and expanded radially outwardly by the pressing, and a slide guide gap is formed by a clearance fit between the inner diameter surface of the cylinder chamber 20a of the housing 20 and the outer diameter surface of the outer ring member 21. Reduce the amount.

  Here, when the gap amount between the slide guide gaps is a standard size of about several tens of μm, the enlarged diameter portion of the outer ring member 21 is elastically brought into contact with the inner diameter surface of the cylinder chamber 20a so that the negative slide guide gap is eliminated. It forms and inhibits the linear motion of the outer ring member 21.

  In order to prevent the occurrence of the inconvenience as described above, in the embodiment, as shown in FIG. 2, the outer ring member 21 is fitted to the cylinder chamber 20a by the clearance fit of the outer ring member 21 over the entire axial direction. The gap fitting portion g is increased by increasing the gap amount that can absorb the expansion due to elastic deformation in the radial direction. Specifically, the gap amount in the increased gap fit portion g is set to be several times the standard size.

  As described above, when the outer ring member 21 is elastically deformed and expanded in diameter by providing an increased gap fit portion g formed between the inner diameter surface of the cylinder chamber 20a and the outer diameter surface of the outer ring member 21 in the housing 20. In addition, the enlarged diameter portion can be absorbed by the gap fitting portion g.

  Therefore, it is suppressed that the enlarged-diameter part by the elastic deformation of the outer ring member 21 comes into strong contact with the inner diameter surface of the cylinder chamber 20a, and the outer ring member 21 does not hinder linear movement and always moves linearly smoothly.

  In FIG. 2, the gap fitting portion g is increased over the entire axial direction of the gap fitting portion between the inner diameter surface of the cylinder chamber 20 a and the outer diameter surface of the outer ring member 21 in the housing 20, but is not limited thereto. It is not a thing.

  In FIG. 4, the gap fitting portion g1 corresponding to the planetary roller 49 is used as a gap fitting portion for increasing the amount, and the gap fitting portion g2 in other remaining portions is a standard slide guide gap portion of a standard size. It is said. The increased gap fitting portion g1 is formed by providing a groove in a portion of the inner peripheral surface of the housing 20 corresponding to the planetary roller 49.

  Here, when the disc rotor 10 (see FIG. 7) is braked, a contact force is applied to the brake pad 14 by contact with the disc rotor 10, and a tangential force is applied to the outer ring member 21 via the brake pad 14. . The outer ring member 21 is skewed by the load of the tangential force, and the enlarged diameter portion of the outer ring member 21 slides in a state of being in strong contact with the inner diameter surface of the cylinder chamber 20a, thereby obstructing the linear motion of the outer ring member 21 and sometimes contacting. This will cause wear and seizure at the part.

  Further, when the outer ring member 21 is skewed, the load borne by the screw engagement of the spiral groove or circumferential groove 52 formed on the outer diameter surface of the planetary roller 49 and the spiral protrusion 51 provided on the inner diameter surface of the outer ring member 21. A difference occurs in the resistance, and the durability of the screw engaging portion is lowered.

  As shown in FIG. 4, only the clearance fit portion g1 corresponding to the planetary roller 49 is used as an increased clearance fit portion, so that this increased clearance fit portion g1 is located within the sliding region of the outer ring member 21. Is done. In addition, the inside of the sliding area of the outer ring member 21 means that, as shown in FIG. 7, the brake pad 14 is moved from a standby position where the tip of the outer ring member 21 slightly protrudes from the opening end of the housing 20 as shown in FIG. 4. Is a moving range where the pad holder 18 has moved to a position where it contacts the disk rotor 10 due to wear.

  Thus, by setting the increased clearance fit portion g1 in the slide region of the outer ring member 21, the outer diameter of the outer ring member 21 is the inner diameter surface at both axial sides of the increased clearance fit portion g1 of the cylinder chamber 20a. The surface can be reliably guided to slide.

  As a result, the skew of the outer ring member 21 can be effectively suppressed, the smooth linear motion of the outer ring member 21 is prevented from being inhibited, and at the same time, the screw engaging portion is prevented from being damaged. it can.

  Further, even when the outer ring member 21 is largely linearly moved outward, the outer periphery of the rear end portion in the sliding direction is increased in amount so that the outer ring member 21 does not fit into the gap fitting portion g1, so that the outer ring member is removed from the disk rotor 10. It is possible to prevent the outer ring member 21 from being twisted by the tangential force applied to the member 21.

  It should be noted that a portion other than the range from the opening end of the housing 20 to the outer end surface of the planetary roller 49 may be used as a gap fitting portion for increasing the amount on the inner diameter surface of the housing 20. Even in this case, since the outer ring member 21 can be slidably guided along the inner periphery of the opening end of the housing 20, the effect of preventing skew of the outer ring member 21 can be obtained.

  In FIG. 4, a ring groove 27 is formed on the inner periphery of the opening end of the housing 20 with a gap from the increased gap fitting portion g1, and an elastic seal ring 28 is incorporated in the ring groove 27. The inner diameter surface of the seal ring 28 is brought into elastic contact with the outer diameter surface of the outer ring member 21.

  As described above, by providing the seal ring 28, it is possible to prevent leakage of the lubricating oil that lubricates the sliding guide surface of the outer ring member 21 to the outside. Here, as shown in FIG. 5, by setting the formation position of the ring groove 27 to the increased gap fit portion g1, the axial length of the increased gap fit portion g1 can be shortened, and the amount is increased. The formation of the gap fitting part g1 can be facilitated.

  In FIG. 6, an annular groove 29 having a width corresponding to the axial length of the planetary roller 49 is provided in a portion corresponding to the planetary roller 49 on the inner diameter surface of the housing 20, and a seal is provided in the annular groove 29. The ring 28 is incorporated so that the inner diameter surface of the seal ring 28 is brought into elastic contact with the outer diameter surface of the outer ring member 21.

  Also in the case shown in FIG. 6, when the outer ring member 21 is expanded in diameter, the increased diameter portion can be absorbed by the elastic deformation of the seal ring 28, and the outer ring member 21 can be smoothly slid. In addition, leakage of the lubricating oil that lubricates the sliding guide surface of the outer ring member 21 to the outside by the seal ring 28 can be prevented.

A Electric linear actuator B Electric brake device 10 Disc rotor 20 Housing 20a Cylinder chamber 21 Outer ring member 24 Electric motor 34 Rotating shaft 40 Carrier 49 Planetary roller 51 Spiral ridge 52 Circumferential groove

Claims (4)

A cylindrical outer ring member (21) is slidably assembled with a clearance fit in a cylindrical cylinder chamber (20a) formed in the housing (20), and is mounted on the axis of the outer ring member (21). The rotating shaft (34) rotated by the electric motor (24) is provided, and the planetary roller (49) incorporated between the outer diameter surface of the rotating shaft (34) and the inner diameter surface of the outer ring member (21) is provided. It is rotatably supported by a carrier (40) supported so as to be rotatable about a rotating shaft (34), and the planetary roller (49) is provided on the outer diameter surface of the outer ring member (21). A spiral groove or a circumferential groove (52) meshing with the spiral protrusion (51) is formed, and the planetary roller (49) is moved by frictional contact with the rotation shaft (34) by the rotation of the rotation shaft (34). Rotate and revolve the outer ring The electric linear motion actuators wood (21) so as to linearly move in the axial direction,
The clearance amount of the clearance fitting portion of the outer ring member (21) with respect to the cylinder chamber (20a) at least at the portion corresponding to the planetary roller (49) can absorb the expanded diameter due to elastic deformation of the outer ring member (21). and an amount-increasing gap fit portion with increased amount of clearance amount in a radial direction to the axial position of the fit portion if said amount-increasing gap, the outer end face of the planetary rollers (49) from the open end of the housing (20) An electric linear actuator characterized in that it is a part other than the above range. It said amount-increasing the axial position of the fit portion a clearance, electric linear motion actuator of claim 1 in which the slide region of the outer ring member (21). A seal ring (28) that prevents the leakage of the lubricating oil that elastically contacts the outer diameter surface of the outer ring member (21) and lubricates the sliding portion of the outer ring member (21) into the increased clearance fit portion. The electric linear motion actuator according to claim 1 or 2 is attached. The brake pad (14) is linearly driven by the electric linear actuator (A), and the disc rotor (10) is pressed by the brake pad (14) to apply a braking force to the disc rotor (10). In the electric brake device
The electric brake apparatus according to any one of claims 1 to 3 , wherein the electric linear actuator (A) comprises the electric linear actuator according to any one of claims 1 to 3 .

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