The present disclosure relates to damper devices including an input element, an output element, an outer elastic body that transmits torque between the input element and the output element, and an inner elastic body that is placed inward of the outer elastic body and that transmits torque between the input element and the output element, and starting devices including the damper device.
Conventionally, a damper device including a dynamic damper having a third elastic body that is coupled to any one of rotary elements forming the damper device and a mass body that is coupled to the third elastic body is known as this type of damper device (see, e.g., Patent Document 1). In this damper device, the third elastic body of the dynamic damper is disposed radially outward or inward of first and second elastic bodies that transmit torque between the input element and the output element, or is disposed between the first elastic body and the second elastic body in the radial direction.
[Patent Document 1] International Publication WO 2011/076168
However, in the case where the third elastic body of the dynamic damper is disposed at a different radial position from the first and second elastic bodies that transmit torque between the input element and the output element as in the conventional damper device, the outside diameter of the damper device is increased, making it difficult to make the entire device compact.
It is a primary object of the present disclosure to suppress an increase in outside diameter of a damper device including a dynamic damper and thus make the entire device compact.
A damper device according to the present disclosure is a damper device including an input element, an output element, an outer elastic body that transmits torque between the input element and the output element, and an inner elastic body that is disposed inward of the outer elastic body and that transmits torque between the input element and the output element, and includes: a dynamic damper that has a third elastic body coupled to any one of rotary elements forming the damper device and a mass body coupled to the third elastic body, and that applies vibration of an opposite phase to the rotary element to dampen vibration, wherein the third elastic body is disposed so as to be located next to the outer elastic body in a circumferential direction.
This damper device includes the dynamic damper that has the third elastic body coupled to any one of the rotary elements and the mass body coupled to the third elastic body, and that applies vibration of the opposite phase to the rotary element to dampen vibration. The third elastic body of the dynamic damper is disposed so as to be located next to the outer elastic body in the circumferential direction, and overlaps the outer elastic body in both axial and radial directions of the damper device. This can suppress an increase in outside diameter of the damper device and can make the entire device compact as compared to the case where the third elastic body of the dynamic damper is disposed radially outward or inward of the outer elastic body and the inner elastic body or between the outer elastic body and the inner elastic body in the radial direction. Moreover, since the third elastic body of the dynamic damper is disposed near an outer periphery of the damper device so as to be located next to the outer elastic body in the circumferential direction, this can suppress an excessive increase in rigidity of the outer elastic body and the third elastic body and reduce rigidity of the inner elastic body, and can thus further improve damping performance of the damper device including the dynamic damper.
A distance between an axis of the damper device and an axis of the outer elastic body may be equal to a distance between the axis of the damper device and an axis of the third elastic body. This can more satisfactorily suppress an increase in outside diameter of the damper device.
The axis of the outer elastic body and the axis of the third elastic body may be included in a same plane orthogonal to the axis of the damper device. This can also suppress an increase in axial length of the damper device, and can therefore make the entire device more compact.
The damper device may further include: an intermediate element that transmits power from the outer elastic body to the inner elastic body, and the input element may have an input-side contact portion that contacts the outer elastic body, and the third elastic body may be coupled to the intermediate element.
The inner elastic body may include a first inner elastic body and a second inner elastic body that are disposed so as to adjoin each other. The damper device may further include: a first intermediate element that transmits power from the outer elastic body to the first inner elastic body; and a second intermediate element that transmits power from the first inner elastic body to the second inner elastic body. The third elastic body may be coupled to the first intermediate element.
The damper device may further include: an intermediate element that transmits power from the outer elastic body to the inner elastic body. The intermediate element may have a plurality of intermediate-side contact portions that can contact the outer elastic body and the third elastic body. The outer elastic body may be supported from both sides by two of the intermediate-side contact portions in a mounted state of the damper device. Both ends of the third elastic body may respectively contact the intermediate-side contact portions in the mounted state of the damper device.
The input element may have a plurality of input-side contact portions that contact the outer elastic body, and the outer elastic body may be supported from both sides by two of the input-side contact portions in the mounted state of the damper device.
The damper device may further include: an intermediate element that transmits power from the outer elastic body to the inner elastic body. The input element may have an input-side contact portion that contacts the outer elastic body. The intermediate element may have an intermediate-side contact portion that can contact the outer elastic body and the third elastic body. A coupling member having a plurality of elastic body contact portions provided so as to contact both ends of the third elastic body may be fixed to the mass body of the dynamic damper. At least one of a distance between the axis of the damper device and the input-side contact portion, a distance between the axis of the damper device and the intermediate-side contact portion, and a distance between the axis of the damper device and the elastic body contact portion is different from the remaining two distances. The input-side contact portion, the intermediate-side contact portion, and the elastic body contact portions of the coupling member are thus disposed at different distances from the axis of the damper device, whereby strokes of the outer elastic body and the third elastic body can be satisfactorily ensured.
The input-side contact portion of the input element may be located next to the intermediate-side contact portion of the intermediate element in a radial direction of the damper device, and the intermediate-side contact portion of the intermediate element may be located next to the elastic body contact portion of the coupling member in the radial direction of the damper device.
The distance between the axis of the damper device and the elastic body contact portion may be larger than the distance between the axis of the damper device and the intermediate-side contact portion.
The distance between the axis of the damper device and the input-side contact portion, the distance between the axis of the damper device and the intermediate-side contact portion, and the distance between the axis of the damper device and the elastic body contact portion may be different from each other.
The intermediate element may include a first plate member having an annular guide portion that guides the outer elastic body, and a second plate member having the intermediate-side contact portion and coupled to the first plate member. The input-side contact portion of the input element may protrude inside the annular guide portion through an opening formed in the first plate member, and may contact the outer elastic body at a position radially inward of the intermediate-side contact portion of the second plate member. The elastic body contact portion of the coupling member may contact the end of the third elastic body at a position radially outward of the intermediate-side contact portion. The input-side contact portion of the input element, the intermediate-side contact portion of the intermediate element, and the elastic body contact portions of the coupling member are thus placed from the inside toward the outside in this order. The input element, the intermediate element, and the coupling member therefore do not interfere with each other when rotating, and the strokes of the outer elastic body and the third elastic body can be more satisfactorily ensured.
The input element may include a first input member having an elastic body surrounding portion that surrounds and guides the outer elastic body, and a second input member having the input-side contact portion and coupled to the first input member. The elastic body contact portion of the coupling member may protrude inside the elastic body surrounding portion through an opening formed in the first input member, and may contact the end of the third elastic body at a position radially inward of the input-side contact portion of the second input member. The intermediate element may be disposed between the first input member and the second input member such that the intermediate-side contact portion can contact the outer elastic body and the third elastic body at a position radially inward of the elastic body contact portion of the coupling member. The intermediate-side contact portion of the intermediate element, the elastic body contact portions of the coupling member, and the input-side contact portion of the input element are thus placed from the inside toward the outside in this order. The input element, the intermediate element, and the coupling member therefore do not interfere with each other when rotating, and the strokes of the outer elastic body and the third elastic body can be more satisfactorily ensured.
The outer elastic body may be an arc coil spring, and the inner elastic body may be a linear coil spring.
The third elastic body may be a linear coil spring.
The damper device and the dynamic damper may satisfy 0.90×f≤fdd≤1.10×f, where “f” represents a resonance frequency of the damper device, and “fdd” represents a resonance frequency of the dynamic damper.
The damper device may further include: a centrifugal pendulum vibration absorbing device coupled to any one of the rotary elements included in the damper device.
The damper device and the dynamic damper may satisfy 1.0≤Los/Lds≤10.0, where “Los” represents a circumferential length of the outer elastic body in the mounted state of the damper device, and “Lds” represents a circumferential length of the third elastic body in the mounted state of the damper device.
A starting device according to the present disclosure is a starting device including any of the above damper devices, a pump impeller, and a turbine runner that together with the pump impeller forms a hydraulic transmission device, and wherein the dynamic damper has a coupling member that has a plurality of elastic body contact portions provided so as to contact both ends of the third elastic body, and that is fixed to the turbine runner, and the mass body of the dynamic damper is formed at least by the turbine runner and the coupling member. Since the turbine runner is used also as the mass body of the dynamic damper, a more compact starting device including a damper device can be achieved.
Another starting device according to the present disclosure is a starting device including any of the above damper devices, a pump impeller, and a turbine runner that together with the pump impeller forms a hydraulic transmission device, and wherein the dynamic damper has a dedicated mass body that is different form the turbine runner. The dynamic damper thus may have a dedicated mass body as in this starting device.
Modes for carrying out the present disclosure will be described below with reference to the accompanying drawings.
The pump impeller 4 has a pump shell 40 tightly fixed to the front cover 3, and a plurality of pump blades 41 disposed on the inner surface of the pump shell 40. The turbine runner 5 has a turbine shell 50 and a plurality of turbine blades 51 disposed on the inner surface of the turbine shell 50. The inner periphery of the turbine shell 50 is fixed to a turbine hub 52 via a plurality of rivets. The turbine hub 52 is rotatably supported by the damper hub 7, and movement of the turbine hub 52 in the axial direction of the starting device 1 is restricted by the damper hub 7 and a snap ring mounted on the damper hub 7.
The pump impeller 4 and the turbine runner 5 face each other, and a stator 6 that adjusts the flow of hydraulic oil (working fluid) from the turbine runner 5 to the pump impeller 4 is coaxially placed between the pump impeller 4 and the turbine runner 5. The stator 6 has a plurality of stator blades 60, and the rotational direction of the stator 6 is set to only one direction by a one-way clutch 61. The pump impeller 4, the turbine runner 5, and the stator 6 form a torus (annular flow path) in which hydraulic oil is circulated, and function as a torque converter (hydraulic transmission device) having a function to amplify torque. In the starting device 1, the stator 6 and the one-way clutch 61 may be omitted, and the pump impeller 4 and the turbine runner 5 may function as a fluid coupling.
The lockup clutch 8 performs a lockup operation of coupling the front cover 3 to the turbine hub 7 via the damper device 10 and cancels the lockup. The lockup clutch 8 has a lockup piston 80 that is placed in the front cover 3 at a position near the inner wall surface on the engine side (the right side in the figure) of the front cover 3 and that is fitted on the damper hub 7 so as to be slidable in the axial direction and rotatable. As shown in
Hydraulic oil that is supplied from the hydraulic control device to the pump impeller 4 and the turbine runner 5 (torus) can flow into the lockup chamber 89. Accordingly, if the pressure in a hydraulic transmission chamber 9 defined by the front cover 3 and the pump shell 40 of the pump impeller 4 and the pressure in the lockup chamber 89 are kept equal to each other, the lockup piston 80 does not move toward the front cover 3, and the lockup piston 80 does not frictionally engage with the front cover 3. On the other hand, if the pressure in the lockup chamber 89 is reduced by the hydraulic control device, not shown, the lockup piston 80 moves toward the front cover 3 due to the pressure difference and frictionally engages with the front cover 3. The front cover 3 is thus coupled to the damper hub 7 via the damper device 10.
As shown in
In the present embodiment, the outer springs SP1 are arc springs (arc coil springs) each made of a metal material wound so as to have an axis extending in an arc shape when not subjected to a load. This can further reduce rigidity (reduce the spring constant) of the outer springs SP1 and can further reduce rigidity (increase the stroke) of the damper device 10. In the present embodiment, the first and second inner springs SP21, SP22 are coil springs (linear coil springs) each made of a metal material wound in a helical shape so as to have an axis extending straight when not subjected to a load. The first and second inner springs SP21, SP22 have higher rigidity (spring constant) than the outer springs SP1. The rigidity (spring constant) of the first inner springs SP21 may be either the same as or different from that of the second inner springs SP22. Arc springs may be used as the first and second inner springs SP21, SP22.
The drive member 11 has an annular fixed portion 11a that is fixed to the lockup piston 80 of the lockup clutch 8 via a plurality of rivets, and a plurality of spring contact portions (input-side contact portions) 11b extended in the axial direction from the outer periphery of the fixed portion 11a toward the pump impeller 4 and the turbine runner 5. The drive member 11 is fixed to the lockup piston 80 so as to be placed in an outer peripheral region in the hydraulic transmission chamber 9. The first intermediate member 12 includes an annular first plate member 13 that is placed on the front cover 3 (the lockup piston 80) side, and an annular second plate member 14 that is placed on the pump impeller 4 side or on the turbine runner 5 side and that is coupled (fixed) to the first plate member 13 via a rivet.
As shown in
The annular guide portion 13a of the first plate member 13 is formed so as to surround one side (the right side in
The second plate member 14 that is coupled (fixed) to the first plate member 13 has a plurality of spring guide portions (spring support portions) 14a formed inward of the annular guide portion 13a of the first plate member 13 and each guiding a corresponding one of the outer springs SP1, a plurality of (in the present embodiment, four) spring contact portions (intermediate-side contact portions) 14b formed outward of the spring guide portions 14a and extended in the axial direction toward the front cover 3, a plurality of spring guide portions (spring support portions) 14c formed so as to face the spring guide portions 13c of the first plate member 13, and a plurality of spring guide portions (spring support portions) 14d formed so as to face the spring guide portions 13d of the first plate member 13. As shown in
As shown in
As shown in
The driven member 16 is disposed between the first plate member 13 and the second plate member 14 of the first intermediate member 12 and is fixed to the damper hub 7 by welding etc. As shown in
The dynamic damper 20 includes a plurality of (in the present embodiment, two coil springs) third springs (third elastic bodies) SP3 as coil springs (linear coil springs) or arc springs (arc coil springs), and a coupling member 21 that is coupled to the third springs SP3 and that together with the turbine runner 5 and the turbine hub 52 forms a mass body. As used herein, the term “dynamic damper” refers to a mechanism that applies vibration of an opposite phase to a vibrating body at a frequency (engine speed) corresponding to the resonance frequency of the vibrating body to dampen vibration (vibration of the resonance frequency of the damper device 10), and the dynamic damper is formed by coupling the springs and the mass body such that the springs and the mass body are not included in a torque transmission path for the vibrating body. The dynamic damper can be operated at a desired frequency by adjusting the rigidity of the springs and the weight of the mass body.
The coupling member 21 of the dynamic damper 20 has an annular fixed portion 22 that is fixed to the turbine shell 50 of the turbine runner 5, and a plurality of (in the present embodiment, four) spring contact portions (elastic body contact portions) 23 extended from the fixed portion 22. The fixed portion 22 of the coupling member 21 is fixed to an outer peripheral region of the back surface (the surface on the front cover 3 side) of the turbine shell 50 by welding etc. The plurality of spring contact portions 23 are formed symmetrically with respect to the axis of the damper device 10 (the starting device 1) such that every two (a pair of) spring contact portions 23 are located close to each other. For example, two spring contact portions 23 that are paired with each other face each other at an interval according to the natural length of the third spring SP3. A single third spring SP3 is disposed between two spring contact portions 23 that are paired with each other. That is, in the mounted state of the damper device 10, each of the plurality of spring contact portions 23 contacts an end of a corresponding one of the third springs SP3, and each third spring SP3 is supported at its both ends by a corresponding pair of spring contact portions 23.
As shown in
As described above, the third springs SP3 of the dynamic damper 20 are disposed near the outer periphery of the damper device 10 so as to be located next to the outer springs SP1 in the circumferential direction. This can suppress an increase in outside diameter of the damper device 10 and can make the entire device more compact as compared to the case where the third springs SP3 are disposed radially outward or inward of the outer springs SP1 and the first and second inner springs SP21, SP22 or between the outer springs SP1 and the first and second inner springs SP21, SP22 in the radial direction. In the present embodiment, as shown in
The damper device 10 and the dynamic damper 20 are configured such that the ratio A of the circumferential length of the outer spring SP1 to the circumferential length of the third spring SP3, as given by A=Los/Lds, satisfies 1.0≤A≤10.0, more preferably 1.0≤A≤7.0, where “Los” represents the circumferential length of the outer spring SP1 in the mounted state of the damper device 10 (including the dynamic damper 20), “Lds” represents the circumferential length of the third spring SP3 in the mounted state of the damper device 10. Setting the ratio A to a value in this range regardless of the number of outer springs SP1 and the number of third springs SP3 can suppress an increase in outside diameter of the damper device 10, and can achieve proper rigidity of the outer springs 51 and the third springs SP3 and thus practically very satisfactorily improve damping performance of the damper device 10 including the dynamic damper 20.
The circumferential length of the outer spring SP1 and the circumferential length of the third spring SP3 in the mounted state of the damper device 10 refer to the length of the axis extending in an arc shape at least between a pair of spring contact portions in the case of arc springs, and refer to the length of the axis extending straight or in an arc shape at least between a pair of spring contact portions in the case of coil springs. The circumferential length of the outer spring SP1 and the circumferential length of the third spring SP3 in the mounted state of the damper device 10 can therefore be represented by the angle formed by the radius connecting one end of the axis of the outer spring SP1 or the third spring SP3 and the axis of the damper device 10 in the mounted state and the radius connecting the other end of the axis of the outer spring SP1 or the third spring SP3 and the axis of the damper device 10 in the mounted state, namely by the central angle. In the present embodiment, the central angle θ1 (see
Operation of the starting device 1 configured as described above will be described below with reference to
As can be seen from
As can be seen from
In the damper device 10, the third springs SP3 of the dynamic damper 20 are disposed near the outer periphery of the damper device 10 so as to be located next to the outer springs SP1 in the circumferential direction. This can suppress an excessive increase in rigidity (spring constant) of the outer springs SP1 and the third springs SP3 and reduce rigidity (spring constant) of the first and second inner springs SP21, SP22, and can thus further improve damping performance of the damper device 10 including the dynamic damper 20. In the starting device 1, fluctuations in torque that is applied to the front cover 3 can therefore be more satisfactorily dampened (absorbed) by the damper device 10 when the lockup operation is being performed by the lockup clutch 8.
When the lockup operation is being performed, the pump impeller 4 and the turbine runner 5 (the hydraulic transmission device) are not involved in transmission of torque between the front cover 3 and the input shaft IS of the transmission. As shown in
As described above, the damper device 10 of the starting device 1 includes the dynamic damper 20 having the third springs SP3 that are coupled to the first intermediate member 12 as a rotary element and the mass body that is coupled to the third springs SP3. The third springs SP3 of the dynamic damper 20 are disposed near the outer periphery of the damper device 10 so as to be located next to the outer springs SP1 in the circumferential direction. This can suppress an increase in outside diameter of the damper device 10 and can make the entire device more compact as compared to the case where the third springs SP3 of the dynamic damper 20 are disposed radially outward or inward of the outer springs SP1 and the first and second inner springs SP21, SP22 or between the outer springs SP1 and the first and second inner springs SP21, SP22 in the radial direction. This can also suppress an excessive increase in rigidity (spring constant) of the outer springs SP1 and the third springs SP3 and reduce rigidity (spring constant) of the first and second inner springs SP21, SP22, and can thus further improve damping performance of the damper device including the dynamic damper 20.
Making the distance r1 between the axis of the damper device 10 and the axis of the outer spring SP1 equal to the distance r3 between the axis of the damper device 10 and the axis of the third spring SP3 as in the above embodiment can more satisfactorily suppress an increase in outside diameter of the damper device 10. Moreover, causing the axes of the outer springs SP1 and the axes of the third springs SP3 to be included in the same plane PL orthogonal to the axis of the damper device 10 can also suppress an increase in axial length of the damper device 10. Thus, it is possible to make the entire device more compact. The distance r1 between the axis of the damper device 10 and the axis of the outer spring SP1 need not necessarily be exactly the same as the distance r3 between the axis of the damper device 10 and the axis of the third spring SP3. The distances r1, r3 may be slightly different from each other due to design tolerance etc. Similarly, the axes of the outer springs SP1 and the axes of the third springs SP3 need not necessarily be completely included in the same plane. The axes of the outer springs SP1 and the axes of the third springs SP3 may be slightly shifted in the axial direction from the plane due to design tolerance etc.
Moreover, in the damper device 10, the spring contact portions (input-side contact portions) 11b of the drive member 11 protrude inside the annular guide portion 13a of the first plate member through the openings 13b formed in the first plate member 13 of the first intermediate member 12, and contact the outer springs SP1 at positions radially inward of the spring contact portions (intermediate-side contact portions) 14b of the second plate member 14. Each of the plurality of spring contact portions 23 of the coupling member 21 contacts the end of a corresponding one of the third springs SP3 at a position radially outward of the spring contact portions 14b of the first intermediate member 12. That is, in the above embodiment, the distance between the axis of the damper device 10 and the spring contact portion (input-side contact portion) 11b (e.g., the distance from the axis to the centerline in the thickness direction of the spring contact portion), the distance between the axis of the damper device 10 and the spring contact portion (intermediate-side contact portion) 14b, and the distance between the axis of the damper device 10 and the spring contact portion (elastic body contact portion) 23 are different from each other.
The spring contact portion 11b of the drive member 11, the spring contact portion 14b of the first intermediate member 12, and the spring contact portion 23 of the coupling member 21 are thus placed from the inside toward the outside in this order. The drive member 11, the first intermediate member 12, and the coupling member 21 therefore do not interfere with each other when rotating, and sufficiently long strokes of the outer springs SP1 and the third springs SP3 can be ensured. The spring contact portion 11b, the spring contact portion 14b, and the spring contact portion 23 need not necessarily be placed from the inside toward the outside in this order so as to be separated from each other in the radial direction. Depending on the strokes required for the outer springs SP1 and the third springs SP3, two of the spring contact portion 11b, the spring contact portion 14b, and the spring contact portion 23 may be placed radially outward or radially inward of the remaining one spring contact portion. That is, any one of the distance between the axis of the damper device 10 and the spring contact portion (input-side contact portion) 11b, the distance between the axis of the damper device 10 and the spring contact portion (intermediate-side contact portion) 14b, and the distance between the axis of the damper device 10 and the spring contact portion (elastic body contact portion) 23 may be different from the remaining two distances.
In the mounted state of the damper device 10, both ends of each third spring SP3 are supported by a corresponding pair of (two) spring contact portions 23 of the coupling member 21, and contact corresponding ones of the spring contact portions 14b of the second plate member 14. However, the present disclosure is not limited to this. The number of third springs SP3 of the dynamic damper 20 may be increased as appropriate, the coupling member 21 may have spring contact portions each contacting ends of adjoining two of the third springs SP3, and every two third springs SP3 adjoining each other with such a spring contact portion therebetween may be supported from both sides by a spring contact portion such as an intermediate member. This can eliminate backlash resulting from manufacturing tolerance, which tends to be caused in the case of supporting each third spring SP3 by at least a pair of spring contact portions. Namely, this can eliminate a gap between the end of the third spring SP3 and the spring contact portion. The dynamic damper 20 can therefore be made to operate more smoothly.
In the starting device 1B including such a multi-plate hydraulic lockup clutch 8B, the fixed portion 11a of the drive member 11 of the damper device 10 is coupled to or is formed integrally with the clutch drum 82. In the starting device 1B, hydraulic oil (lockup pressure) is supplied from the hydraulic control device, not shown, to the lockup chamber (engagement oil camber) 89 that is defined by the lockup piston 80B and the flange member 85. The lockup piston 80B can thus be moved in the axial direction so as to press the first and second friction engagement plates 83, 84 toward the front cover 3, whereby the lockup clutch 8B can be engaged (fully engaged or slip-engaged). The starting device 1B can also provide the functions and effects provided by the damper device 10.
The second input member 112 has a plurality of spring guide portions (spring support portions) 112a each formed inside the spring surrounding portion 111a of the first input member 111 to guide a corresponding one of the outer springs SP1, and a plurality of spring contact portions (input-side contact portions) 112b extending in the axial direction toward the pump impeller 4 and the turbine runner 5. In the damper device 10C of
Moreover, in the damper device 10C, arc springs are used as a plurality of inner springs SP20, and the second intermediate member 15 of the damper device 10 is therefore omitted. This can further reduce rigidity (reduce the spring constant) of the inner springs SP20 and can reduce rigidity (increase the stroke) of the damper device 10C. Each of a first plate member 13C and a second plate member 14C of an intermediate member (intermediate element) 12C of the damper device 10C has spring contact portions (not shown) each contacting an end of a corresponding one of the inner springs SP20, and the driven member 16 has spring contact portions (not shown) each contacting an end of a corresponding one of the inner springs SP20.
In the damper device 10C, the second plate member 14C of the intermediate member (intermediate element) 12C is disposed between the first input member 111 and the second input member 112 such that the spring contact portions (intermediate-side contact portions) 14b can contact the ends of the outer springs SP1 and the ends of the third springs SP3 in the spring surrounding portion 111a of the first input member 111. The spring contact portions 23 of the coupling member 21 of the dynamic damper 20 protrude inside the spring surrounding portion 111a through openings 111b formed in the first input member 111, and each spring contact portion 23 contacts an end of a corresponding one of the third springs SP3 at a position radially outward of the spring contact portion 14b of the second plate member 14C. Moreover, each spring contact portion 112b of the second input member 112 (the drive member 11C) contacts an end of a corresponding one of the outer springs SP1 at a position radially outward of the spring contact portion 23 of the coupling member 21. That is, the distance between the axis of the damper device 10C and the spring contact portion (intermediate-side contact portion) 14b, the distance between the axis of the damper device 10C and the spring contact portion (elastic body contact portion) 23, and the distance between the axis of the damper device 10C and the spring contact portion (input-side contact portion) 112b are different from each other.
The spring contact portion 14b of the intermediate member 12C, the spring contact portion 23 of the coupling member 21, and the spring contact portion 112b of the drive member 11C are thus placed from the inside toward the outside in this order. The drive member 11, the first intermediate member 12, and the coupling member 21 therefore do not interfere with each other when rotating, and sufficiently long strokes of the outer springs SP1 and the third springs SP3 can be ensured. The spring contact portion 14b, the spring contact portion 23, and the spring contact portion 112b need not necessarily be placed from the inside toward the outside in this order so as to be separated from each other in the radial direction. Depending on the strokes required for the outer springs SP1 and the third springs SP3, two of the spring contact portion 14b, the spring contact portion 23, and the spring contact portion 112b may be placed radially outward or radially inward of the remaining one spring contact portion. That is, any one of the distance between the axis of the damper device 10C and the spring contact portion (intermediate-side contact portion) 14b, the distance between the axis of the damper device 10C and the spring contact portion (elastic body contact portion) 23, and the distance between the axis of the damper device 10C and the spring contact portion (input-side contact portion) 112b may be different from the remaining two distances.
In the starting device 1C of
In the centrifugal pendulum vibration absorbing device 25, each pendulum mass body 24 is formed by a support shaft (roller) that is rollably inserted through a corresponding one of a plurality of guide holes formed at predetermined intervals in the mass body support portion 13s, which are, e.g., elongated holes having a substantially arc shape, and two metal plates (weights) that are fixed to both ends of the support shaft. The configuration of the centrifugal pendulum vibration absorbing device 25 is not limited to this. The centrifugal pendulum vibration absorbing device 25 may be configured so as to rotate together with the drive member 11C (input element) of the damper device 10C and the driven member (output element) 16.
The damper device 10C of the starting device 1C configured as described above can also provide functions and effects similar to those of the above damper device 10. In the centrifugal pendulum vibration absorbing device 25 coupled to the damper device 10C, the plurality of pendulum mass bodies 24 swing in the same direction with respect to the first plate member 13C (the intermediate member 12C) as a support member that supports each pendulum mass body 24, according to rotation of the first plate member 13C. The centrifugal pendulum vibration absorbing device 25 thus applies to the intermediate member 12C of the damper device 10 vibration having a phase in the opposite direction to vibration of the intermediate member 12C. In the starting device 1C, vibration of the intermediate member (intermediate element) 12C that tends to vibrate between the outer springs SP1 and the inner springs SP20 can thus be absorbed (dampened) by the centrifugal pendulum vibration absorbing device 25 and the overall vibration level of the damper device 10 can be reduced when the lockup operation is being performed by the lockup clutch 8.
In the above damper devices 10, 10C, the outer springs SP and the first and second inner springs SP21, SP22 or the inner springs SP20 operate in series via the first and second intermediate members 12, 15 or the intermediate member 12C. However, the damper devices 10, 10C may be configured such that the outer springs SP and the first and second inner springs SP21, SP22 or the inner springs SP20 operate in parallel. That is, the damper devices 10, 10C may be configured either as series damper devices having a drive member, an intermediate member, and a driven member as rotary elements or as parallel damper devices having a drive member, an intermediate member, and a driven member as rotary elements. In the starting devices 1, 1B, 1C, and 1D, the mass body of the dynamic damper 20 is formed by the turbine runner 5 and the coupling member 21. However, the dynamic damper 20 may have a dedicated mass body that is different from the turbine runner 5.
It should be understood that the present disclosure is not limited in any way to the above embodiments, and various modifications can be made. The above modes for carrying out the disclosure are merely shown as specific forms and are not intended to be limiting.
The present disclosure is applicable, for example, to manufacturing fields of damper devices and starting devices including the same, etc.
Number | Date | Country | Kind |
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2013-203458 | Sep 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/074902 | 9/19/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/046076 | 4/2/2015 | WO | A |
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