JP2018119647A - Clutch unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent occurrence of noise or minute vibration at a brake side clutch part due to leakage of lubricant or intrusion of foreign matter.SOLUTION: A clutch unit comprises a lever side clutch part 11 configured to control transmission/blockage of input rotational torque, and a brake side clutch part 12 configured to transmit the rotational torque from the lever side clutch part 11 to an output side and block rotational torque reversely input from the output side. The brake side clutch part 12 includes: a side plate 25 where rotation is constrained; an output shaft 22 to which rotation is output; and a friction ring 29 attached and fixed to the side plate 25, and configured to impart rotational resistance to the output shaft 22 with sliding torque, which is generated by a fitting margin with the output shaft 22. The fitting margin is provided between an inner peripheral surface 29b of the friction ring 29 and an outer peripheral surface 22c of the output shaft 22.SELECTED DRAWING: Figure 1

Description

  The present invention includes an input-side clutch portion to which rotational torque is input, and an output-side clutch portion that transmits the rotational torque from the input-side clutch portion to the output side and blocks the rotational torque from the output side. It relates to the clutch unit.

  In general, in a clutch unit using an engagement element such as a cylindrical roller or a ball, a clutch portion is disposed between an input member and an output member. The clutch portion is configured to control transmission and interruption of rotational torque by engaging and disengaging an engaging member such as a cylindrical roller or a ball between the input member and the output member.

  The present applicant has previously proposed a clutch unit incorporated in an automobile seat lifter that adjusts the seat seat up and down by lever operation (see, for example, Patent Document 1).

  The clutch unit disclosed in Patent Document 1 transmits a lever-side clutch portion as an input-side clutch portion to which rotational torque is input by lever operation and the rotational torque from the lever-side clutch portion to the output side, A brake-side clutch portion serving as an output-side clutch portion that cuts off rotational torque from the output side.

  The lever side clutch part is separated from the outer ring by engaging and disengaging the outer ring to which rotational torque is input by lever operation, the inner ring that transmits the rotational torque from the outer ring to the brake side clutch part, and the wedge clearance between the outer ring and the inner ring. A cylindrical roller that controls transmission and interruption of the rotational torque of the motor, and a centering spring that accumulates elastic force with the rotational torque from the outer ring and returns the outer ring to the neutral state with the accumulated elastic force when the rotational torque is no longer input. The main part is composed of.

  The brake-side clutch unit includes a side plate and an outer ring that are restricted in rotation, an output shaft that outputs rotational torque, and an interruption and release of the rotational torque from the output shaft by engaging and disengaging the wedge between the outer ring and the output shaft. A plurality of cylindrical rollers and leaf springs that control transmission of rotational torque from the lever side clutch, a cage that holds the cylindrical rollers and leaf springs at equal intervals in the circumferential direction, and rotational resistance to the output shaft The main part is composed of a resin friction ring. The cage is formed integrally with the inner ring of the lever side clutch portion.

  In the lever side clutch portion, when rotational torque is input to the outer ring by lever operation, the cylindrical roller engages with the wedge clearance between the outer ring and the inner ring. Due to the engagement of the cylindrical rollers up to the wedge clearance, rotational torque is transmitted to the inner ring, and the inner ring rotates. At this time, an elastic force is accumulated in the centering spring as the outer ring rotates.

  When there is no input of rotational torque by lever operation, the outer ring returns to the neutral state by the elastic force of the centering spring, while the inner ring maintains the given rotational position. Therefore, the inner ring rotates in a jog by repeating the rotation of the outer ring, that is, by the pumping operation of the operation lever.

  In the brake side clutch portion, when rotational torque is reversely input to the output shaft by sitting on the seat, the cylindrical roller engages with the wedge clearance between the output shaft and the outer ring, and the output shaft is locked to the outer ring. . Due to the locking of the output shaft, the rotational torque reversely input from the output shaft is cut off. Thereby, the seat surface height of the seat is maintained.

  On the other hand, when rotational torque is input from the inner ring of the lever side clutch portion to the cage of the brake side clutch portion, the cage rotates and abuts against the cylindrical roller to press against the elastic force of the leaf spring, The cylindrical roller is detached from the wedge clearance between the outer ring and the output shaft. With the separation of the cylindrical roller, the locked state of the output shaft is released, and the output shaft can be rotated. When the locked state is released, rotational resistance is applied to the output shaft by the friction ring.

  Then, when the cage of the brake side clutch portion further rotates, the rotational torque from the cage is transmitted to the output shaft, and the output shaft rotates. That is, when the retainer is joggingly rotated with the inner ring of the lever side clutch portion, the output shaft is also joggingly rotated. The seat surface height of the seat can be adjusted by the inching rotation of the output shaft.

JP 2011-169402 A

  By the way, in the brake side clutch part of the conventional clutch unit disclosed in Patent Document 1, the friction ring is fixed to the side plate and provided on the outer peripheral surface of the friction ring with respect to the inner peripheral surface of the annular recess of the output shaft. A structure is adopted in which the friction ring is press-fitted into the annular recess of the output shaft with a fitting allowance.

  By adopting such a structure, when releasing the locked state of the output shaft in the brake side clutch, the output shaft slides against the press-fitting surface of the friction ring, so that an appropriate rotational resistance ( (Sliding torque) is applied.

  By applying this rotational resistance, the locked state of the output shaft can be released smoothly during lever operation, improving the operational feeling and adjusting the seat surface height of the seat without causing a sense of incongruity to the passenger. ing.

  Here, in the brake side clutch portion of the conventional clutch unit, a lubricant such as grease is applied to the sliding portions of the respective components including the outer ring, the output shaft, the cylindrical roller, the cage, and the friction ring.

  On the other hand, since the output shaft is rotatably arranged with respect to the side plate to which the friction ring is attached, a gap is easily generated between the side plate and the output shaft, and the lubricant leaks to the outside from the gap. There is a risk of foreign matter entering the inside.

  If there is such a leakage of lubricant or intrusion of foreign matter, there is a possibility that abnormal noise or fine vibration may occur due to sliding of the output shaft with respect to the friction ring when unlocking the brake side clutch portion. When such abnormal noise or slight vibration occurs in the brake side clutch portion, the operation feeling is deteriorated when the lever is operated to unlock the output shaft.

  Therefore, the present invention has been proposed in view of the above-described problems, and the object of the present invention is to prevent abnormal noise and fine vibrations from being generated in the brake side clutch portion due to leakage of the lubricant and entry of foreign matter. It is to provide a clutch unit to obtain.

  The clutch unit according to the present invention transmits an input-side clutch portion that controls transmission and cutoff of input rotational torque, and transmits rotational torque from the input-side clutch portion to the output side, and is reversely input from the output side. The basic structure which consists of an output side clutch part which interrupts | blocks rotational torque is comprised.

  As a technical means for achieving the above-described object, the output side clutch portion of the present invention includes a stationary member whose rotation is constrained, a shaft-shaped output member from which rotation is output, and a stationary member attached and fixed thereto. A ring-shaped braking member that imparts rotational resistance to the output member with a sliding torque generated by a fitting allowance (tightening allowance, hereinafter the same) with the output member, and an inner peripheral surface of the braking member and an outer peripheral surface of the output member It is characterized by providing a fitting allowance between the two. The braking member in the present invention is preferably made of an elastic member.

  In the present invention, by providing a fitting allowance between the inner peripheral surface of the braking member and the outer peripheral surface of the output member, the inner peripheral surface of the braking member and the outer peripheral surface of the output member can be brought into close contact with each other. Therefore, it is possible to prevent the lubricant from leaking to the outside from the gap between the stationary member and the output member, and foreign matters from entering the inside. As a result, when the output clutch portion is unlocked, it is possible to avoid occurrence of abnormal noise or fine vibration due to sliding of the output member with respect to the braking member.

  The brake member in the present invention preferably has a structure having a cylindrical portion whose inner peripheral surface extends in the axial direction of the output member.

  By adopting such a structure, the area where the inner peripheral surface of the braking member and the outer peripheral surface of the output member are in close contact with each other can be increased by the axial dimension of the cylindrical portion. Therefore, since the fitting allowance of a braking member and an output member can be made small, the reduction | decrease of the tightening force by creep in a braking member can be suppressed.

  The output member in the present invention preferably has an annular recess, and a structure in which a fitting margin is provided between the inner peripheral surface of the annular recess of the output member and the outer peripheral surface of the braking member.

  If such a structure is adopted, the area where the outer peripheral surface of the braking member and the inner peripheral surface of the annular recess of the output member are in close contact with the area where the inner peripheral surface of the braking member and the outer peripheral surface of the output member are in close contact with each other. can do. By increasing the contact area between the braking member and the output member, it is possible to further suppress a decrease in the tightening force due to creep in the braking member.

  The clutch unit according to the present invention preferably has a structure in which the input-side clutch portion and the output-side clutch portion are incorporated in the vehicle seat lifter portion.

  If such a structure is adopted, the input side clutch part is a lever side clutch part to which rotational torque is input by lever operation, and the output side clutch part is a brake side clutch part. The operational feeling during operation can be improved.

  According to the present invention, the inner peripheral surface of the braking member and the outer peripheral surface of the output member can be brought into close contact with each other, so that the lubricant leaks to the outside from the gap between the stationary member and the output member, or the foreign matter is inside. Can be prevented from entering. From this, it is possible to avoid occurrence of abnormal noise or fine vibration due to sliding of the output member with respect to the braking member at the time of unlocking at the output side clutch portion.

  When this clutch unit is incorporated in an automobile seat lifter, the operation feeling during lever operation can be improved, and a clutch unit that realizes comfortable lever operation for the user can be provided.

In embodiment of this invention, it is sectional drawing which shows the whole structure of a clutch unit. It is sectional drawing which follows the PP line | wire of FIG. It is sectional drawing which follows the QQ line of FIG. It is a block diagram which shows the seat seat and seat lifter part of a motor vehicle. FIG. 2 is an exploded perspective view showing a side plate, a friction ring, and an output shaft of FIG. 1. FIG. 6 is an assembled sectional view showing the side plate, friction ring and output shaft of FIG. 5. It is sectional drawing which shows the modification of the friction ring of FIG. It is sectional drawing which shows a side plate, a friction ring, and an output shaft in other embodiment of this invention. It is sectional drawing which shows the modification of the friction ring of FIG.

  An embodiment of a clutch unit according to the present invention will be described in detail with reference to the drawings. 1 is a cross-sectional view showing the overall configuration of the clutch unit of this embodiment, FIG. 2 is a cross-sectional view taken along the line P-P in FIG. 1, and FIG. 3 is a cross-sectional view taken along the line Q-Q in FIG.

  In the following embodiments, a clutch unit incorporated in an automobile seat lifter is illustrated, but the present invention can be applied to other than the seat lifter. Before describing the characteristic configuration of this embodiment, the overall configuration of the clutch unit will be described.

  As shown in FIG. 1, the clutch unit 10 of this embodiment has a structure in which a lever side clutch portion 11 as an input side clutch portion and a brake side clutch portion 12 as an output side clutch portion are unitized.

  The lever side clutch part 11 controls transmission and interruption of rotational torque input by lever operation. The brake-side clutch unit 12 has a reverse input blocking function for transmitting the rotational torque from the lever-side clutch unit 11 to the output side and blocking the rotational torque that is reversely input from the output side.

  As shown in FIGS. 1 and 2, the lever side clutch unit 11 transmits to the brake side clutch unit 12 the side plate 13 and the outer ring 14 to which rotational torque is input by lever operation, and the rotational torque input from the outer ring 14. Inner ring 15, a plurality of cylindrical rollers 16 that control transmission and interruption of rotational torque from outer ring 14 by engagement and disengagement between outer ring 14 and inner ring 15, and each cylindrical roller 16 is held at equal intervals in the circumferential direction. A cage 17, an inner centering spring 18 for returning the cage 17 to a neutral state, and an outer centering spring 19 for returning the outer ring 14 to a neutral state are provided.

  The side plate 13 and the outer ring 14 are inserted into a notch recess 14a formed on the outer peripheral edge of the outer ring 14 and crimped by inserting a claw portion 13a formed on the outer peripheral edge of the side plate 13, thereby tightening the side plate 13 on the outer ring 14. And is integrated as an input member of the lever side clutch portion 11. On the inner periphery of the outer ring 14, a plurality of cam surfaces 14b are formed at equal intervals in the circumferential direction. The input of the rotational torque to the outer ring 14 is performed by an operation lever 43 (see FIG. 4) that adjusts the seating surface of the seating seat attached to the side plate 13 by screwing or the like.

  The inner ring 15 includes a cylindrical portion 15a through which the output shaft 22 is inserted, a diameter-enlarged portion 15b in which a brake side end portion of the cylindrical portion 15a extends radially outward, and an outer peripheral end of the diameter-enlarged portion 15b. It consists of a plurality of pillars 15c (see FIG. 3) protruding by bending the part in the axial direction. A wedge clearance 20 is formed between the cylindrical outer peripheral surface 15 d of the cylindrical portion 15 a of the inner ring 15 and the cam surface 14 b formed on the inner periphery of the outer ring 14. Cylindrical rollers 16 are arranged in the wedge clearance 20 by a cage 17 at equal intervals in the circumferential direction.

  The inner centering spring 18 is a C-shaped elastic member having a circular cross section disposed between the cage 17 and the cover 24 of the brake side clutch portion 12, and both ends thereof are part of the cage 17 and the cover 24. It is locked. The inner centering spring 18 is expanded by the rotation of the cage 17 following the outer ring 14 with respect to the cover 24 in a stationary state when the rotational torque input from the outer ring 14 is applied by lever operation, and elastic force is applied. When the rotational torque from the outer ring 14 is released, the cage 17 is returned to the neutral state by the elastic force.

  The outer centering spring 19 positioned radially outside the inner centering spring 18 is a C-shaped strip elastic member disposed between the outer ring 14 and the cover 24, and both ends of the outer centering spring 19 are located at one end of the outer ring 14 and the cover 24. It is locked to the part. The outer centering spring 19 is expanded with the rotation of the outer ring 14 with respect to the cover 24 in a stationary state when the rotational torque input from the outer ring 14 by the lever operation is applied, and an elastic force is accumulated. When the rotational torque is released, the outer ring 14 is returned to the neutral state by the elastic force.

  The cage 17 is a resin-made cylindrical member in which a plurality of pockets 17a for accommodating the cylindrical rollers 16 are formed at equal intervals in the circumferential direction. Both end portions of the inner centering spring 18 are locked to one axial end portion of the cage 17, that is, the axial end portion on the cover 24 side of the brake side clutch portion 12. The cage 17 is disposed between the outer ring 14 and the inner ring 15.

  As shown in FIGS. 1 and 3, the brake-side clutch portion 12 of a type called a lock type includes an inner ring 15 to which rotational torque from the lever-side clutch portion 11 is input, and rotation from the lever-side clutch portion 11. The output shaft 22 serving as an output member from which torque is output, the outer ring 23, the cover 24, and the side plate 25 serving as stationary members whose rotation is restricted, and the engagement and disengagement between the outer ring 23 and the output shaft 22, thereby the output shaft 22 is applied to a plurality of pairs of cylindrical rollers 27 for controlling the interruption of the rotational torque input from 22 and the transmission of the rotational torque input from the inner ring 15, and a separation force in the circumferential direction is applied to each pair of cylindrical rollers 27. The main part is constituted by a leaf spring 28 having an N-shaped cross section and a friction ring 29 as a braking member for imparting rotational resistance to the output shaft 22.

  The shaft portion 22a of the output shaft 22 into which the cylindrical portion 15a of the inner ring 15 is extrapolated is integrally formed with a large-diameter portion 22b whose diameter is increased radially outward. A pinion gear 22d for connecting to the seat lifter 39 (see FIG. 4) is formed coaxially at the output side end of the shaft 22a. Further, the washer 31 is press-fitted into the input side end portion of the shaft portion 22a via the wave washer 30 to prevent the component parts of the lever side clutch portion 11 from coming off.

  A plurality (for example, six) of flat cam surfaces 22e are formed on the outer periphery of the large-diameter portion 22b of the output shaft 22 at equal intervals in the circumferential direction. One leaf spring 28 interposed between two cylindrical rollers 27 is inserted into a wedge clearance 26 formed between the cam surface 22e of the large diameter portion 22b and the cylindrical inner peripheral surface 23a of the outer ring 23. It is arranged.

  The cylindrical rollers 27 and the leaf springs 28 are arranged at equal intervals in the circumferential direction by column portions 15 c of the inner ring 15 having a function of transmitting the rotational torque input from the outer ring 14 to the output shaft 22. That is, the column portion 15c of the inner ring 15 functions as a cage by accommodating the cylindrical roller 27 and the leaf spring 28 in the pocket 15f and holding them at equal intervals in the circumferential direction.

  The large diameter portion 22 b of the output shaft 22 is provided with a protrusion 22 f for transmitting the rotational torque from the inner ring 15 to the output shaft 22. The protrusion 22f is inserted and disposed in a hole 15e formed in the enlarged diameter portion 15b of the inner ring 15 with a circumferential clearance.

  The outer ring 23, the cover 24, and the side plate 25 are formed on the outer peripheral edge portion of the side plate 25 by the notch concave portion 23 b formed on the outer peripheral edge portion of the outer ring 23 and the notched concave portion 24 a formed on the outer peripheral edge portion of the cover 24. By inserting and crimping the formed claw portion 25a, the side plate 25 is fixed to the outer ring 23 and the cover 24, and is integrated as a stationary member of the brake side clutch portion 12.

  An operation example of the lever side clutch portion 11 and the brake side clutch portion 12 having the above-described configuration will be described below.

  In the lever side clutch portion 11, when rotational torque is input to the outer ring 14 by lever operation, the cylindrical roller 16 engages with the wedge clearance 20 between the outer ring 14 and the inner ring 15. Due to the engagement of the cylindrical roller 16 in the wedge clearance 20, rotational torque is transmitted to the inner ring 15 and the inner ring 15 rotates. At this time, elastic force is accumulated in the centering springs 18 and 19 as the outer ring 14 and the cage 17 rotate.

  When there is no input of rotational torque by lever operation, the cage 17 and the outer ring 14 are returned to the neutral state by the elastic force of the centering springs 18 and 19. On the other hand, the inner ring 15 maintains the given rotational position as it is. Therefore, the inner ring 15 rotates in a jog by repeating the rotation of the outer ring 14, that is, by the pumping operation of the operation lever 43 (see FIG. 4).

  In the brake-side clutch portion 12, the cylindrical roller 27 engages with the wedge clearance 26 between the output shaft 22 and the outer ring 23 even when rotational torque is reversely input to the output shaft 22 by sitting on the seat, and the output shaft 22 Locked to the outer ring 23. In this way, the rotational torque reversely input from the output shaft 22 is locked by the brake side clutch portion 12 and the return of the rotational torque reversely input to the lever side clutch portion 11 is blocked. Thereby, the seat surface height of the seat is maintained.

  On the other hand, when the rotational torque from the lever side clutch portion 11 is input to the inner ring 15 by lever operation, the column portion 15 c of the inner ring 15 comes into contact with the cylindrical roller 27 and resists the elastic force of the leaf spring 28. Press. As a result, the cylindrical roller 27 is detached from the wedge clearance 26, and the locked state of the output shaft 22 is released by the separation of the cylindrical roller 27 from the wedge clearance 26, so that the output shaft 22 can rotate. When the locked state of the output shaft 22 is released, rotational friction is applied to the output shaft 22 by the friction ring 29.

  When the inner ring 15 further rotates, the clearance between the hole 15e of the enlarged diameter portion 15b of the inner ring 15 and the projection 22f of the large diameter portion 22b of the output shaft 22 is clogged, and the enlarged diameter portion 15b of the inner ring 15 becomes the projection 22f of the output shaft 22. Contact in the rotational direction. Thereby, the rotational torque from the lever side clutch part 11 is transmitted to the output shaft 22 via the protrusion 22f, and the output shaft 22 rotates. That is, when the inner ring 15 is jogged and rotated, the output shaft 22 is also jogged and rotated. Thereby, the seat surface height of the seat can be adjusted.

  The clutch unit 10 having the above-described structure is used by being incorporated in an automobile seat lifter unit 39 that adjusts the height of the seat 40 by lever operation. FIG. 4 shows a seat 40 installed in the passenger compartment of the automobile.

  As shown in FIG. 4, the seat 40 includes a seat 41 and a backrest 42, and the seat lifter 39 adjusts the height of the seat surface of the seat 41. The height of the seating seat 41 is adjusted by the operation lever 43 attached to the side plate 13 (see FIG. 1) of the lever side clutch portion 11 in the clutch unit 10.

  The sheet lifter unit 39 has the following structure. One end of each of the link members 45 and 46 is pivotally attached to the slide movable member 44 so as to be rotatable. The other ends of the link members 45 and 46 are pivotally attached to the seating seat 41, respectively. A sector gear 47 is integrally provided at the other end of the link member 45. The sector gear 47 meshes with the pinion gear 22 d of the output shaft 22 of the clutch unit 10.

  For example, when the seating surface of the seating seat 41 is lowered, the lever side clutch portion 11 is operated, that is, the operation lever 43 is swung downward to lock the brake side clutch portion 12 (see FIG. 1). Release the state. When the brake side clutch portion 12 is unlocked, the seating surface of the seating seat 41 can be smoothly lowered by applying an appropriate rotational resistance to the output shaft 22 by the friction ring 29 (see FIG. 1).

  By releasing the lock at the brake side clutch portion 12, the pinion gear 22d of the output shaft 22 of the brake side clutch portion 12 is rotated clockwise (in FIG. 4) with the rotational torque transmitted from the lever side clutch portion 11 to the brake side clutch portion 12. It rotates in the direction of the arrow. Then, the sector gear 47 that meshes with the pinion gear 22d swings counterclockwise (the arrow direction in FIG. 4), and both the link member 45 and the link member 46 are tilted to lower the seating surface of the seating seat 41.

  In this way, after adjusting the height of the seating surface of the seating seat 41, when the operation lever 43 is released, the operation lever 43 swings upward by the elastic force of the centering springs 18 and 19, and returns to its original position (neutral). Return to the state. When the operation lever 43 is swung upward, the seating surface of the seating seat 41 is raised by the reverse operation to that described above. When the operation lever 43 is released after the height of the seating seat 41 is adjusted, the operation lever 43 swings downward and returns to the original position (neutral state).

  The overall configuration of the clutch unit 10 in this embodiment is as described above. The friction ring 29 made of an elastic member such as resin, which is a characteristic configuration, will be described in detail below.

  As shown in FIG. 5, circular protrusions 29 a are arranged at equal intervals in the circumferential direction on the end surface of the friction ring 29 that applies rotational resistance to the output shaft 22 when the brake side clutch portion 12 is unlocked by lever operation. It is provided in the place. The friction ring 29 is fixedly attached to the side plate 25 by fitting the protrusions 29 a into the holes 25 b of the side plate 25.

  As shown in FIG. 6, the friction ring 29 attached and fixed to the side plate 25 has a structure in which a fitting margin is provided between the inner peripheral surface 29 b and the outer peripheral surface 22 c of the output shaft 22. When the friction ring 29 is assembled to the output shaft 22, the inner peripheral surface 29 b of the friction ring 29 is press-fitted into the outer peripheral surface 22 c of the output shaft 22. In the embodiment shown in FIG. 6, there is a gap between the outer peripheral surface 29 c of the friction ring 29 and the inner peripheral surface 22 h of the annular recess 22 g of the output shaft 22.

  When releasing the locked state of the output shaft 22 in the brake-side clutch portion 12 by lever operation, the inner peripheral surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22 due to the fitting margin between the friction ring 29 and the output shaft 22 The outer peripheral surface 22c of the output shaft 22 slides with respect to the inner peripheral surface 29b of the friction ring 29 by the friction force generated during Thereby, an appropriate rotational resistance (sliding torque) is applied to the output shaft 22. By applying this rotational resistance, the seating surface of the seating seat 41 can be adjusted smoothly.

  In this embodiment, a fitting allowance is provided between the inner peripheral surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22, so that the inner peripheral surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22 are provided. Can be brought into close contact with each other. Therefore, even if there is a gap between the inner peripheral surface 25 c of the side plate 25 and the outer peripheral surface 22 c of the output shaft 22, the lubricant leaks from the inside of the brake side clutch portion 12 or the brake side clutch portion 12 It is possible to prevent foreign matter from entering the inside from the outside.

  As a result, when the brake side clutch portion 12 is unlocked, it is possible to avoid the generation of abnormal noise or micro-vibration due to the sliding operation of the outer peripheral surface 22c of the output shaft 22 relative to the inner peripheral surface 29b of the friction ring 29. As a result, when the lever is operated to release the locked state of the brake side clutch portion 12, the operation feeling can be improved, and a comfortable lever operation for the user can be realized.

  FIG. 7 shows a friction ring 29 according to another embodiment of the present invention. The friction ring 29 shown in the figure integrally has a cylindrical portion 29 d having an inner peripheral surface 29 c extending in the axial direction of the output shaft 22.

  By providing such a cylindrical portion 29d, the area where the inner peripheral surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22 are in close contact with each other by the axial dimension of the cylindrical portion 29d is shown in FIG. It can be increased compared to the embodiment shown.

  Here, since the friction ring 29 is made of resin, the larger the fitting allowance between the friction ring 29 and the output shaft 22 is, the smaller the temporal force of the friction ring 29 is reduced by resin creep. Therefore, as in the embodiment shown in FIG. 7, by providing the friction ring 29 with a cylindrical portion 29d, the area where the inner peripheral surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22 are in close contact with each other is increased. Yes. Thereby, the fitting margin of the friction ring 29 and the output shaft 22 can be made small.

  In this way, by reducing the fitting margin between the friction ring 29 and the output shaft 22, it is possible to suppress a decrease in the tightening force due to resin creep in the friction ring 29. As a result, when the brake is released at the brake side clutch portion 12, the load that the cylindrical roller 27 separates from the wedge clearance 26 is reduced, or the output shaft 22 slides with respect to the friction ring 29 to generate abnormal noise or slight vibration. Can be further suppressed, and the lever operation feeling can be easily improved.

  In the embodiment of FIGS. 6 and 7 described above, the case where the fitting margin is provided between the inner peripheral surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22 has been described. The structure shown in FIGS. 8 and 9 is not limited to the above.

  8 is a modification of the friction ring 29 in the embodiment of FIG. 6, and FIG. 9 is a modification of the friction ring 29 in the embodiment of FIG. 8 and 9, the same parts as those in FIGS. 6 and 7 are denoted by the same reference numerals, and the duplicate description is omitted.

  In the embodiment shown in FIGS. 8 and 9, a fitting allowance is provided between the inner peripheral surface 29 b of the friction ring 29 and the outer peripheral surface 22 c of the output shaft 22, and the outer peripheral surface 29 c of the friction ring 29 and the output shaft 22 are It is set as the structure which provided the fitting allowance between 22 h of inner peripheral surfaces of the annular recessed part 22g.

  By adopting such a structure, the inner surface 29b of the friction ring 29 and the outer peripheral surface 22c of the output shaft 22 are in close contact with each other in the inner surface of the outer peripheral surface 29c of the friction ring 29 and the annular recess 22g of the output shaft 22. It is possible to add an area in close contact with the peripheral surface 22h. By increasing the contact area between the friction ring 29 and the output shaft 22, the fitting allowance between the friction ring 29 and the output shaft 22 can be further reduced.

  By reducing the fitting margin between the friction ring 29 and the output shaft 22, it is possible to further suppress the decrease in the tightening force due to the resin creep in the friction ring 29. As a result, when the brake is released at the brake-side clutch portion 12, the load that the cylindrical roller 27 separates from the wedge clearance 26 is reduced, or the output shaft 22 slides against the friction ring 29. The occurrence of vibration can be further suppressed, and the lever operation feeling can be easily improved.

  The present invention is not limited to the above-described embodiments, and can of course be implemented in various forms without departing from the gist of the present invention. It includes the equivalent meanings recited in the claims and the equivalents recited in the claims, and all modifications within the scope.

10 Clutch unit 11 Input side clutch (lever side clutch)
12 Output side clutch (brake side clutch)
22 Output member (output shaft)
22c outer peripheral surface 22g annular recess 22h inner peripheral surface 25 stationary member (side plate)
29 Braking member (friction ring)
29b Inner peripheral surface 29c Outer peripheral surface 29d Cylindrical part 39 Sheet lifter part

Claims (5)

An input side clutch unit that controls transmission and cutoff of input rotational torque, and an output side clutch that transmits rotational torque from the input side clutch unit to the output side and blocks rotational torque that is reversely input from the output side And consists of
The output-side clutch portion is a stationary member that is constrained to rotate, a shaft-shaped output member that outputs rotation, and a sliding torque that is attached and fixed to the stationary member and is generated by a fitting margin with the output member. And a ring-shaped braking member that imparts rotational resistance to the output member, and a fitting unit is provided between the inner peripheral surface of the braking member and the outer peripheral surface of the output member.   The clutch unit according to claim 1, wherein the braking member is made of an elastic member.   The clutch unit according to claim 1 or 2, wherein the braking member has a cylindrical portion whose inner peripheral surface extends in the axial direction of the output member.   The clutch unit according to any one of claims 1 to 3, wherein the output member has an annular recess, and a fitting margin is provided between an inner peripheral surface of the annular recess of the output member and an outer peripheral surface of the braking member. .   The clutch unit as described in any one of Claims 1-4 in which the said input side clutch part and the said output side clutch part are integrated in the seat lifter part for motor vehicles.

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