The present invention relates to a clutch unit having a lever-side clutch portion for transmitting rotational torque from an input side to an output side thereof and a brake-side clutch portion for transmitting rotational torque from the input side to the output side and interrupting torque reversely input from the output side.
In general, in a clutch unit using engagement elements such as cylindrical rollers or balls, a clutch portion is arranged between an input-side member and an output-side member. Further, in the clutch portion, the engagement elements such as cylindrical rollers or balls are engaged and disengaged with respect to wedge gaps formed between the input-side member and the output-side member, thereby controlling transmission and interruption of the input torque.
The applicant of the present invention has previously proposed a clutch unit incorporated into, for example, an automobile seat-lifter section which vertically adjusts a seat through lever operation. This clutch unit is provided with a lever-side clutch portion for transmitting rotational torque from the input side to the output side and a brake-side clutch portion for transmitting rotational torque from the input side to the output side and interrupting torque reversely input from the output side (see, for example, Patent Literature 1).
As illustrated in
Note that, in the figures, reference numeral 113 represents a lever-side side plate fixed to the lever-side outer ring 114 by swaging and constituting the input-side member together with the lever-side outer ring 114, and reference numeral 131 represents a washer mounted to an output shaft 122 through the intermediation of a wave washer 130.
Meanwhile, as illustrated in
Note that, there is provided a larger diameter portion 115c extending from an axial end portion of the inner ring 115 in a radially outer direction and bending in an axial direction. In order to cause the larger diameter portion 115c to function as a retainer for retaining the cylindrical rollers 127 at predetermined circumferential intervals, pockets 115e for accomodating the cylindrical rollers 127 and plate springs 128 are equiangularly formed. In the figures, reference numerals 124 and 125 respectively represent a cover and a brake-side side plate constituting the stationary-side member together with the brake-side outer ring 123, and the brake-side outer ring 123 and the cover 124 are integrally fixed to each other with the brake-side side plate 125 by swaging. Reference numeral 128 represents a plate spring of, for example, an N-shaped sectional configuration arranged between the cylindrical rollers 127 of each pair, and reference numeral 129 represents a friction ring serving as a braking member mounted to the brake-side side plate 125.
[PTL1] JP 2009-210114 A
By the way, the conventional clutch unit disclosed in Patent Literature 1 has the following structure. Specifically, the stationary-side member includes the brake-side outer ring 123, the cover 124, and the brake-side side plate 125, and the brake-side outer ring 123 and the cover 124 are integrally fixed to each other with the brake-side side plate 125 by swaging. The conventional clutch unit also has the following structure. Specifically, when the lever-side outer ring 114 is rotated through lever operation, the outer centering spring 119 accumulates an elastic force obtained by torque input from the lever-side outer ring 114, and restores the lever-side outer ring 114 to a neutral state with the accummulated elastic force through releasing of the input torque. The outer centering spring 119 is provided between the lever-side outer ring 114 and the cover 124 constituting the stationary-side member together with the brake-side outer ring 123. The outer centering spring 119 is held in abutment on the cover 124.
In a case of the clutch unit having the above-mentioned structure, when the lever-side outer ring 114 is rotated through lever operation, the outer centering spring 119 accumulates an elastic force obtained by the torque input from the lever-side outer ring 114 and then increases in diameter. Then, at the time of lever operation of restoring a lever from a full stroke to a neutral position, the outer centering spring 119, which slides on the cover 124, may climb onto an inclined portion 124g of the cover 124 (see
Further, as illustrated in
Therefore, it is an object of the present invention to provide a clutch unit capable of forestalling occurrence of noises caused at the time of lever operation by contact of the outer centering spring with the lever-side outer ring and by an unstable behavior of the outer centering spring.
A clutch unit according to the present invention comprises: a lever-side clutch portion provided on an input side, for controlling transmission and interruption of rotational torque to an output side through lever operation; and a brake-side clutch portion provided on the output side, for transmitting torque input from the lever-side clutch portion to the output side and for interrupting torque reversely input from the output side.
The lever-side clutch portion according to the present invention comprises: an input-side member to be rotated through the lever operation; and an elastic member provided between a stationary-side member restricted in rotation and the input-side member, for accumulating an elastic force obtained by torque input from the input-side member and for restoring the input-side member to a neutral state with the accumulated elastic force through releasing of the torque input from the input-side member. The stationary-side member comprises an inclined portion which abuts on the elastic member and swells to the elastic member side. The inclined portion is formed into a shape for controlling an amount of axial movement of the elastic member when the elastic member is restored to an initial state through the releasing of the torque input from the input-side member. Here, it is desired that the shape for controlling the amount of axial movement of the elastic member when the elastic member is restored to the initial state through the releasing of the torque input from the input-side member be formed on a rounded corner surface situated at an outermost diameter of the inclined portion or on an inclined surface extending radially inward from the outermost diameter of the inclined portion.
According to the present invention, the inclined portion is formed into the shape for controlling the amount of axial movement of the elastic member when the elastic member is restored to the initial state through releasing of the torque input from the input-side member. Thus, at the time of lever operation of restoring a lever from a full stroke to a neutral position, it is possible to prevent the elastic member, which slides on the stationary-side member, from climbing onto the inclined portion of the stationary-side member, and to avoid contact of the elastic member with the input-side member. Accordingly, it is possible to prevent occurrence of noises.
The lever-side clutch portion according to the present invention comprises: an input-side member to be rotated through the lever operation; and an elastic member provided between a stationary-side member restricted in rotation and the input-side member, for accumulating an elastic force obtained by torque input from the input-side member and for restoring the input-side member to a neutral state with the accumulated elastic force through releasing of the torque input from the input-side member. The elastic member comprises a C-shaped and band-like plate spring which comprises a pair of lock portions formed by bending both ends thereof to a radially outer side. One of the pair of lock portions and another of the pair of lock portions are formed at positions that are identical in a band-plate width direction. Here, it is desired that the one of the pair of lock portions and the another of the pair of lock portions be formed at center positions in the band-plate width direction or at both side positions in the band-plate width direction.
According to the present invention, the elastic member comprises the C-shaped and band-like plate spring which comprises the pair of lock portions formed by bending both the ends thereof to the radially outer side, and one of the pair of lock portions and another of the pair of lock portions are formed at positions that are identical in the band-plate width direction. Thus, each end of the elastic member is shaped to be symmetric with respect to a center line in a band-plate peripheral direction, and hence it is possible to prevent a moment force generated at the time of application of input torque. Accordingly, a behavior of the elastic member is stabilized, which can prevent occurrence of noises.
The brake-side clutch portion according to the present invention comprises: an output-side member from which torque is output; a stationary-side member restricted in rotation; a coupling member to which the torque is input from the lever-side clutch portion; and a plurality of pairs of engagement elements accommodated in pockets of the coupling member, for controlling transmission of the torque input from the coupling member and interruption of torque reversely input from the output-side member through engagement with and disengagement from wedge gaps formed between the stationary-side member and the output-side member. Any one of width dimensions of the pockets and outer diameter dimensions of the plurality of pairs of engagement elements are set different from one another.
According to the present invention, the width dimensions of the pockets are set different from one another or the outer diameter dimensions of the plurality of pairs of engagement elements are set different from one another. Thus, when the engagement elements are disengaged from the wedge gaps so as to release a locked state of the output-side member, not all the engagement elements are disengaged from the wedge gaps at the same time, but all the engagement elements are disengaged from the wedge gaps in a step-by-step manner. With this operation, even in a case where high load is applied to the output-side member, when the locked state of the output-side member is released, it is possible to avoid concentration of contact pressure, which is generated between the engagement elements due to high load applied to the output-side member, on the engagement element disengaged from the wedge gap last. Accordingly, it is possible to suppress concentration of the contact pressure generated between the engagement elements, and to prevent occurrence of noises at the moment at which the engagement elements are flipped.
According to the present invention, as means for making a difference among the width dimensions of the pockets, the following structure is desired: pockets having small widths and pockets having large widths are arranged alternately in a peripheral direction. With this structure, when the locked state of the output-side member is released, the engagement elements accommodated in the pockets having small widths are disengaged from the wedge gaps prior to the engagement elements accommodated in the pockets having large widths. Thus, all the engagement elements can be disengaged from the wedge gaps substantially one side at a time in a step-by-step and balanced manner, and concentration of the contact pressure generated between the engagement elements is suppressed easily.
According to the present invention, as means for making a difference among the outer diameter dimensions of the plurality of pairs of engagement elements, the following structure is desired: engagement elements having small diameters and engagement elements having large diameters are arranged alternately in a peripheral direction. With this structure, when the locked state of the output-side member is released, the engagement elements having small diameters are disengaged from the wedge gaps prior to the engagement elements having large diameters. Thus, all the engagement elements can be disengaged from the wedge gaps substantially one side at a time in a step-by-step and balanced manner, and concentration of the contact pressure generated between the engagement elements is suppressed easily.
In a case where the coupling member according to the present invention comprises seven or more pockets, it is desired that the seven or more pockets comprise three pockets having large widths and four or more pockets having small widths. With this structure, when the locked state of the output-side member is released, the engagement elements accommodated in the four or more pockets having small widths are disengaged from the wedge gaps, and then the engagement elements accommodated in the minimum necessary three remaining pockets having large widths are disengaged from the wedge gaps. As a result, concentration of the contact pressure generated between the engagement elements is suppressed easily.
In a case where the coupling member according to the present invention comprises seven or more pockets, it is desired that the seven or more pockets accommodate three pairs of engagement elements having large diameters and four or more pairs of engagement elements having small diameters. With this structure, when the locked state of the output-side member is released, the four or more pairs of engagement elements are disengaged from the wedge gaps, and then the minimum necessary three remaining pairs of engagement elements are disengaged from the wedge gaps. As a result, concentration of the contact pressure generated between the engagement elements is suppressed easily.
The brake-side clutch portion according to the present invention comprises: an output-side member from which torque is output; a stationary-side member restricted in rotation; a plurality of pairs of engagement elements arranged in wedge gaps between the stationary-side member and the output-side member, for controlling transmission of the torque input from the lever-side clutch portion and interruption of the torque reversely input from the output side through engagement and disengagement between the stationary-side member and the output-side member; and an elastomer member inserted between the engagement elements of each pair, for imparting a repulsive force to the engagement elements of each pair.
According to the present invention, the elastomer member, which is inserted between the engagement elements of each pair, for imparting the repulsive force to the engagement elements of each pair, can easily increase load applied to the engagement elements. Accordingly, even in a case where high load is applied to the output-side member, when the locked state of the output-side member is released, it is possible to forestall the situation that the elastomer member is to flip the engagement elements, and it is possible to inhibit occurrence of noises.
It is desired that the elastomer member according to the present invention have an outside dimension larger than a gap between the engagement elements of each pair, and be inserted in an elastically deformed state between the engagement elements of each pair. With this structure, an elastic restoring force of the elastomer member acts as a repulsive force to be imparted to the engagement elements, and hence the repulsive force is easily imparted to the engagement elements.
It is desired that the elastomer member according to the present invention have a columnar shape or a quadrangular prism shape, and have an axial dimension equal to or smaller than axial dimensions of the engagement elements of each pair. With this structure, owing to such a simple shape, a function of the elastomer member can be exerted. When the elastomer member has the axial dimension equal to or smaller than the axial dimensions of the engagement elements of each pair, the function of the elastomer member can be exerted reliably, which is effective.
It is desired that the elastomer member according to the present invention be made of any one of a thermosetting elastomer and an elastically deformable resin material. This selection of any one of the thermosetting elastomer and the elastically deformable resin material enables easy manufacture of the elastomer member, which is effective.
In the clutch unit according to the present invention, the lever-side clutch portion and the brake-side clutch portion are incorporated in an automobile seat-lifter section. Thus, the clutch unit is suited for use in an automobile. In this case, the clutch unit has a configuration in which the input-side member is connected to an operation lever and the output-side member is coupled to a link mechanism of the automobile seat-lifter section.
According to the present invention, the inclined portion is formed into the shape for controlling the amount of axial movement of the elastic member when the elastic member is restored to the initial state through releasing of the torque input from the input-side member. Thus, at the time of lever operation of restoring a lever from a full stroke to a neutral position, it is possible to prevent the elastic member, which slides on the stationary-side member, from climbing onto the inclined portion of the stationary-side member, and to avoid contact of the elastic member with the input-side member. Accordingly, it is possible to prevent occurrence of noises.
Further, the elastic member comprises the C-shaped and band-like plate spring which comprises the pair of lock portions formed by bending both the ends thereof to the radially outer side, and one of the pair of lock portions and another of the pair of lock portions are formed at positions that are identical in the band-plate width direction. Thus, each end of the elastic member is formed into a symmetric shape, and hence it is possible to prevent such a moment force as to pivot the another of the pair of lock portions about a fulcrum set on the one of the pair of lock portions at the time of application of input torque. Accordingly, a behavior of the elastic member is stabilized, which can prevent occurrence of noises.
As a result, it is possible to provide a clutch unit with high reliability. In a case where the clutch unit is incorporated into the automobile seat-lifter section, lever operation of adjusting a seat vertically is performed satisfactorily, and hence comfortable lever operation can be realized for a passenger.
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The clutch unit X is incorporated into an automobile seat-lifter section (see
As illustrated in
As illustrated in
Next, detailed description is made of main components of the lever-side clutch portion 11 and the brake-side clutch portion 12 which are provided in the clutch unit X.
a and 6b illustrate the lever-side side plate 13 of the lever-side clutch portion 11. In the lever-side side plate 13, a hole 13a into which the output shaft 22 and the inner ring 15 are inserted is formed in a center portion thereof, and a plurality of (five, for example) claw portions 13b are provided in a protruding manner on an outer peripheral portion thereof. Those claw portions 13b are bent and molded in an axial direction so as to have bisected distal ends. Then, the claw portions 13b are inserted into cutout recessed portions 14e (see
a to 7c illustrate the lever-side outer ring 14. The lever-side outer ring 14 is obtained by molding a plate-like material into a cup-shape through press working, and comprises a hole 14b formed in a center portion 14c, through which the output shaft 22 and the inner ring 15 are inserted. On an inner periphery of a cylindrical portion 14d extending from the center portion 14c in the axial direction, a plurality of cam surfaces 14a are equiangularly formed (see
On an outer peripheral portion of the lever-side outer ring 14, a plurality of (three, for example) claw portions 14f and 14g are provided in a protruding manner and bent and molded in the axial direction. Of those claw portions 14f and 14g, the one claw portion 14f is locked by being inserted and arranged between two lock portions 19a (see
The plurality of (five in the figure) cutout recessed portions 14e into which the claw portions 13b (see
a and 8b illustrate the inner ring 15. The inner ring 15 is provided with the outer peripheral surface 15a formed on an outer diameter of a cylindrical portion 15b into which the output shaft 22 is inserted, the wedge gaps 20 (see
At the time of application of torque input from the lever-side outer ring 14 in the inner centering spring 18, one of the lock portions 18a is engaged with one of the end surfaces 17c of the retainer 17, and the other of the lock portions 18a is engaged with the claw portion 24b of the cover 24. Thus, the inner centering spring 18 is pressed and extended in accordance with rotation of the lever-side outer ring 14 so as to accumulate an elastic force. At the time of releasing the torque input from the lever-side outer ring 14, the retainer 17 is restored to a neutral state with the elastic restoring force.
a illustrates an example of the outer centering spring 19. The outer centering spring 19 is a C-shaped and band plate-like spring comprising the pair of lock portions 19a formed by bending both the ends thereof to a radially outer side, and is situated on a radially outer side of the inner centering spring 18 (see
In the outer centering spring 19, when the torque input from the lever-side side plate 13 is applied through lever operation so as to rotate the lever-side outer ring 14, one of the lock portions 19a is engaged with the claw portion 14f of the lever-side outer ring 14, and the other of the lock portions 19a is engaged with the claw portion 24d of the cover 24, respectively. Thus, the outer centering spring 19 is pressed and extended in accordance with the rotation of the lever-side outer ring 14 so as to accumulate an elastic force. After the outer center spring 19 is increased in diameter, when the torque input from the lever-side outer ring 14 is released, the lever-side outer ring 14 is restored to a neutral state with the elastic restoring force.
Unlike in the conventional outer centering spring 119 (see
Note that, it is only necessary that each end of the outer centering spring 19 be shaped to be symmetric with respect to the center line in the band-plate peripheral direction, and hence, for example, an outer centering spring 19′ as illustrated in
a and 13b and
A plurality of (six, for example) flat cam surfaces 22a are equiangularly formed on an outer peripheral surface of the larger diameter portion 22d, and the two cylindrical rollers 27 and the plate spring 28 are arranged in each wedge gap 26 (see
a and 15b illustrate the brake-side outer ring 23, and
The clutch unit X has the following structure. Specifically, the outer centering spring 19 is arranged between the cover 24 and the lever-side outer ring 14, and the outer centering spring 19 abuts on the cover 24 on the radially outer side of the inclined portion 24g of the cover 24. Here, at the time of lever operation of restoring a lever from a full stroke to a neutral position, the outer centering spring 19, which slides on the cover 24, climbs onto the inclined portion 24g of the cover 24 and thus comes into contact with the opposing lever-side outer ring 14. As a result, slight noises may occur. Accordingly, the inclined portion 24g of the cover 24 is formed into a shape for controlling an amount of axial movement of the outer centering spring 19 when the outer centering spring 19 is restored to an initial state by releasing of input torque.
That is, according to the embodiment illustrated in
Further, as another embodiment, as illustrated in
A plurality of (three) cutout recessed portions 23a are formed on an outer periphery of the brake-side outer ring 23. Correspondingly to the cutout recessed portions 23a, a plurality of (three) cutout recessed portions 24a are similarly formed on an outer periphery of the cover 24. As illustrated in
The claw portions 25a of the brake-side side plate 25 are inserted into the cutout recessed portions 23a and 24a. By swaging the claw portions 25a of the brake-side side plate 25, the brake-side outer ring 23 and the cover 24 are coupled to each other and integrated with the brake-side side plate 25, to thereby form the stationary-side member. Swaging of the claw portions 25a of the brake-side side plate 25 is performed by increasing outward the distance between bisected distal end portions 25a1 of each of the claw portions 25a with use of a swage (not shown) (see
The wedge gaps 26 are formed between the inner peripheral surface 23b of the brake-side outer ring 23 and the cam surfaces 22a of the output shaft 22 (see
Two pairs of the lock portions 24e and 24f are formed by stepping on the outer periphery of the cover 24 (see
On the outer periphery of the brake-side sideplate 25, one flange portion 25e and two flange portions 25f are provided as clutch mounting portions with respect to the seat-lifter section (see
a to 18c illustrate the friction ring 29 made of a resin. On an end surface of the friction ring 29, the plurality of circular protrusions 29a are equiangularly formed. By press-fitting and engaging the protrusions 29a into the holes 25c of the brake-side side plate 25, the friction ring 29 is fixed to the brake-side side plate 25 (see
In the case of press-fitting of the protrusions 29a, an engagement state with the holes 25c can be achieved due to elastic deformation of the protrusions 29a made of a resin material. By adopting a press-fit engagement structure of the protrusions 29a and the holes 25c, it is possible to prevent the friction ring 29 from falling off from the brake-side side plate 25 due to handling during transportation or the like. As a result, it is possible to increase handling properties at the time of assembly.
The friction ring 29 is press-fitted to an inner peripheral surface 22e of the annular recessed portion 22b formed in the larger diameter portion 22d of the output shaft 22 with fastening allowance (see
On the outer peripheral surface 29c of the friction ring 29, there are equiangularly formed a plurality of recessed groove-like slits 29b (see
In other words, it is possible to reduce a setting range of rotational resistance imparted by the frictional force generated between the outer peripheral surface 29c of the friction ring 29 and the inner peripheral surface 22e of the annular recessed portion 22b of the output shaft 22, and hence to appropriately and easily set the degree of the rotational resistance. Further, the slits 29b serve as grease pools, and hence it is possible to suppress abrasion of the outer peripheral surface 29c of the friction ring 29 due to sliding with respect to the inner peripheral surface 22e of the annular recessed portion 22b of the output shaft 22.
Description is made on operation of the lever-side clutch portion 11 and the brake-side clutch portion 12 of the clutch unit X structured as described above.
In the lever-side clutch portion 11, when the input torque is applied to the lever-side outer ring 14, the cylindrical rollers 16 are engaged into the wedge gaps 20 between the lever-side outer ring 14 and the inner ring 15. The inner ring 15 is rotated with torque transmitted to the inner ring 15 through the intermediation of the cylindrical rollers 16. Simultaneously, an elastic force is accumulated in both the centering springs 18 and 19 in accordance with the rotation of the lever-side outer ring 14 and the retainer 17. When the input torque is interrupted, the lever-side outer ring 14 and the retainer 17 are restored to a neutral state with the elastic force of both the centering springs 18 and 19. Meanwhile, the inner ring 15 is maintained at the fixed rotational position. Accordingly, the inner ring 15 is rotated in an inching manner with repetitive rotation of the lever-side outer ring 14, in other words, pumping operation of the operation lever.
In the brake-side clutch portion 12, when reverse-input torque is input to the output shaft 22, the plate spring 28 imparts a repulsive force to the cylindrical rollers 27 of each pair, and thus the cylindrical rollers 27 are engaged into the wedge gap 26 between the output shaft 22 and the brake-side outer ring 23 so as to lock the output shaft 22 with respect to the brake-side outer ring 23. Therefore, the torque reversely input from the output shaft 22 is locked by the brake-side clutch portion 12 so as to interrupt back-flow of the torque reversely input to the lever-side clutch portion 11.
Meanwhile, the torque input from the lever-side outer ring 14 is input to the inner ring 15 through the intermediation of the lever-side clutch portion 11. When the inner ring 15 is brought into abutment on the cylindrical rollers 27 and presses the cylindrical rollers 27 against the elastic force of the plate springs 28, the cylindrical rollers 27 are disengaged from the wedge gaps 26 and a locked state of the output shaft 22 is released. As a result, the output shaft 22 is allowed to be rotated. When the inner ring 15 is further rotated, clearances between the holes 15d of the inner ring 15 and the protrusions 22f of the output shaft 22 are narrowed, and the inner ring 15 is brought into abutment on the protrusions 22f of the output shaft 22 in a rotational direction. As a result, the torque input from the inner ring 15 is transmitted to the output shaft 22 through the intermediation of the protrusions 22f, and the output shaft 22 is rotated.
Here, in a case where high load is applied to the output shaft 22, contact pressure generated between the cylindrical rollers 27 is increased. As a result, when the cylindrical rollers 27 are disengaged from the wedge gap 26 so as to release a locked state of the output shaft 22, as illustrated in
In the clutch unit according to the above-mentioned embodiment, all the pockets 15e are set to have the same circumferential width dimensions, the pockets 15e being formed equiangularly in the larger diameter portion 15c of the inner ring 15, for accommodating the cylindrical rollers 27 and the plate springs 28. However, as well as the width dimensions of the pockets 15e, an inner diameter dimension of the brake-side outer ring 23, a roundness of the inner diameter of the brake-side outer ring 23, outer diameter dimensions of the cylindrical rollers 27, and a cam surface dimension of the output shaft 22 vary. Accordingly, when the cylindrical rollers 27 are disengaged from the wedge gaps 26 so as to release the locked state of the output shaft 22, it may be difficult to disengage all the cylindrical rollers 27 from the wedge gaps 26 at the same time.
As described above, in a case where it is difficult to disengage all the cylindrical rollers 27 from the wedge gaps 26 at the same time, when the cylindrical rollers 27 are disengaged from the wedge gaps 26 so as to release the locked state of the output shaft 22, the contact pressure, which is generated between the cylindrical rollers 27 due to high load applied to the output shaft 22, is concentrated on the cylindrical roller 27 that is disengaged from the wedge gap 26 last. As a result, the cylindrical rollers 27 are flipped, and hence the plate springs 28 are more likely to buckle. Accordingly, it is extremely difficult to restore each of the cylindrical rollers 27 to an initial position, and noises are more likely to occur at the moment at which the cylindrical rollers 27 are flipped.
In this context, when the locked state of the output shaft 22 is released, in order to suppress concentration of the contact pressure generated between the cylindrical rollers 27, and to prevent occurrence of noises at the moment at which the cylindrical rollers 27 are flipped, in the clutch unit according to this embodiment, as illustrated in
Besides setting of the width dimensions W1 of the pockets 15e1 to be different from the width dimensions W2 of the pockets 15e2 as in this embodiment, as another embodiment, as illustrated in
As described above, the pockets 15e1 having small widths and the pockets 15e2 having large widths are arranged alternately in the peripheral direction, or the cylindrical rollers 27a having small diameters and the cylindrical rollers 27b having large diameters are arranged alternately in the peripheral direction, and thus the following operation is provided. Specifically, even in a case where high load is applied to the output shaft 22, when the locked state of the output shaft 22 is released, it is possible to avoid concentration of the contact pressure, which is generated between the cylindrical rollers 27 (27a, 27b) due to high load applied to the output shaft 22, on the cylindrical roller 27 (27a, 27b) that is disengaged from the wedge gap 26 last. Accordingly, it is possible to suppress concentration of the contact pressure generated between the cylindrical rollers 27 (27a, 27b), and to prevent occurrence of noises at the moment at which the cylindrical rollers (27a, 27b) are flipped.
Note that, in the above-mentioned embodiments, description is made of a case where six pockets 15e1 and 15e2 (15e) are provided. In a case where the larger diameter portion 15c of the inner ring 15 functioning as the retainer comprises seven or more pockets 15e1 and 15e2 (15e), the following structure is adopted.
In the structure in which the width dimensions W1 of the pockets 15e1 are set different from the width dimensions W2 of the pockets 15e2, in a case where eight pockets 15e1 and 15e2 are provided as in an embodiment illustrated in
Further, in the structure in which the outer diameter dimensions D1 of the cylindrical rollers 27a are set different from the outer diameter dimensions D2 of the cylindrical rollers 27b, in a case where eight pockets 15e are provided as in an embodiment illustrated in
In the above-mentioned embodiments, the output shaft 22 is locked by an elastic force of the plate spring 28, and the locked state of the output shaft 22 is released against the elastic force of the plate spring 28. Because of a shape, a plate thickness, and the like of the plate spring 28, spring load of the plate spring 28 has limitations with respect to load applied to the cylindrical rollers 27. Therefore, in a case where load applied to the cylindrical rollers 27 is increased, it is necessary to prepare means other than the plate spring 28.
In this context, when the locked state of the output shaft 22 is released, in order to forestall the situation that the cylindrical rollers 27 are flipped and thus the plate springs 28 may buckle, and to prevent occurrence of noises caused by vibration at the moment at which the cylindrical rollers 27 are flipped, instead of the plate springs 28 used in the above-mentioned embodiments, as illustrated in
The elastomer member 28a has an outer diameter dimension larger than a gap between the cylindrical rollers 27 of each pair, and is inserted in an elastically deformed state between the cylindrical rollers 27 (see
Further, the elastomer member 28a has a columnar shape and an axial dimension equal to or smaller than axial dimensions of the cylindrical rollers 27. Owing to a simple shape such as the columnar shape, a function of the elastomer member 28a, i.e., a function of imparting the repulsive force to the cylindrical rollers 27 can be exerted. Further, when the axial dimension of the elastomer member 28a is set equal to or smaller than the axial dimensions of the cylindrical rollers 27, the elastomer member 28a can reliably exert the function of imparting the repulsive force to the cylindrical rollers 27 without interfering with other components.
As described above, the output shaft 22 is locked by the elastic force of the elastomer member 28a, and the locked state of the output shaft 22 is released against the elastic force of the elastomer member 28a. In this embodiment, compared to the plate spring 28 (see
As a result, even in a case where high load is applied to the output shaft 22, when the cylindrical rollers 27 are disengaged from the wedge gaps 26 so as to release the locked state of the output shaft 22, the following operation is provided. Specifically, as illustrated in
Note that, the elastomer member 28a is made of any one of a thermosetting elastomer and an elastically deformable resin material. This selection of anyone of the thermosetting elastomer and the elastically deformable resin material enables easy manufacture of the elastomer member 28a. Further, as illustrated in
The clutch unit X provided with the structure as described above in detail is used while being incorporated into, for example, an automobile seat-lifter section.
a is a conceptual view of a structural example of the seat-lifter section 41. One ends of link members 41c and 41d are pivotally mounted to a slide movable member 41b1 of a seat slide adjuster 41b. The other ends of the link members 41c and 41d are pivotally mounted to the sitting seat 40a. The other end of the link member 41c is pivotally mounted to a sector gear 41f through intermediation of a link member 41e. The sector gear 41f is pivotally mounted to the sitting seat 40a, and pivotable about a fulcrum 41f1. The other end of the link member 41d is pivotally mounted to the sitting seat 40a.
The clutch unit X described above in this embodiment is fixed to an appropriate position of the sitting seat 40a. Fixation of the clutch unit X to the sitting seat 40a is fixation by swaging to a seat frame (not shown) of the sitting seat 40a, in which the three flange portions 25e and 25f of the brake-side side plate 25 are subjected to plastic deformation in such a manner that the distal end portions of the cylindrical portions 25i and 25j are increased in diameter outward.
Meanwhile, the operation lever 41a made of, for example, a resin is coupled to the lever-side side plate 13 of the lever-side clutch portion 11, and the pinion gear 41g meshing with the sector gear 41f as a rotary member is provided to the output shaft 22 of the brake-side clutch portion 12. As illustrated in
In
In this manner, when the operation lever 41a is released after adjustment of the height H of the sitting seat 40a, the operation lever 41a pivots clockwise with the elastic force of the two centering springs 18 and 19, and returns to the original position (restores to the neutral state). Note that, when the operation lever 41a is pivoted clockwise (downward), the seat surface of the sitting seat 40a is lowered through operation in an opposite direction as that in the case described above. Further, when the operation lever 41a is released after adjustment of the height, the operation lever 41a pivots counterclockwise and returns to the original position (restores to the neutral state).
The present invention is not limited to the above-mentioned embodiments. As a matter of course, the present invention may be carried out in various modes without departing from the spirit of the present invention. The scope of the present invention is defined by claims, and includes the meaning of an equivalent of the claims and all the modifications within the claims.
Number | Date | Country | Kind |
---|---|---|---|
2010-057370 | Mar 2010 | JP | national |
2010-165085 | Jul 2010 | JP | national |
2010-170924 | Jul 2010 | JP | national |
Number | Date | Country | |
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Parent | 13576434 | Aug 2012 | US |
Child | 14707394 | US |