JP2021038762A - Damper gear - Google Patents

Abstract

To increase a torsional angle in a damper gear.SOLUTION: A damper gear includes: a pair of input plates 21, 22; a pair of intermediate plates 31, 32; outer peripheral springs 41; a spline hub 5; and arc springs 61. The intermediate plates 31, 32 are disposed in an axial space between the pair of input plates 21, 22 and may rotate relative to the input plates 21, 22. The outer peripheral springs 41 are disposed in a chamber C and elastically connect the input plates 21, 22 with the intermediate plates 31, 32 in a rotation direction. The spline hub 5 has a flange 52 disposed in an axial space between the pair of intermediate plates 31, 32. The arc springs 61 are disposed in the chamber C so as to operate serially with the outer peripheral springs 41 and elastically connect the intermediate plates 31, 32 with the spline hub 5 in the rotation direction.SELECTED DRAWING: Figure 1

Description

The present invention relates to a damper device.

The drive system of the vehicle is provided with a damper device for transmitting the power from the engine and damping the input rotational fluctuation. As a damper device of this type, a flywheel assembly as shown in Patent Document 1 has been proposed.

The flywheel assembly of Patent Document 1 has an input-side rotating member into which engine power is input, and an output plate arranged so as to be rotatable relative to the input-side rotating member. The input-side rotating member and the output plate are elastically connected in the rotational direction by a plurality of springs. Further, a spring seat is arranged between the input side rotating member and the intermediate plate and the spring, and between each spring.

JP-A-2015-86965

In the damper device, it is effective to widen the twist angle between the input side rotating member and the output plate in order to attenuate and absorb the vibration.

However, in the damper device of Patent Document 1, it is difficult to widen the twist angle, and the vibration cannot be sufficiently damped and absorbed.

An object of the present invention is to make it possible to widen the twist angle in a damper device by a compact configuration.

(1) The damper device according to the present invention includes a pair of disc-shaped input plates, a pair of disc-shaped intermediate plates, a plurality of outer peripheral elastic members, an output rotating member, and a plurality of inner circumferences. It is provided with a side elastic member. A pair of input plates are arranged so as to face each other at an axial distance and are fixed to each other. A pair of intermediate plates are arranged in an axial space surrounded by a pair of input plates so as to face each other at an axial interval, and are rotatable relative to the pair of input plates and can rotate with each other. It is fixed. The plurality of outer peripheral elastic members are arranged in an axial space surrounded by a pair of input plates, and elastically connect the pair of input plates and the pair of intermediate plates in the rotational direction. The output rotating member has flanges arranged in an axial space surrounded by a pair of intermediate plates and is rotatable relative to a pair of input plates and a pair of intermediate plates. The plurality of inner peripheral elastic members are arranged so as to operate in series with the plurality of outer peripheral elastic members in the radial direction of the plurality of outer peripheral elastic members in the axial space surrounded by the pair of input plates. A pair of intermediate plates and an output rotating member are elastically connected in the rotational direction.

In this device, a pair of intermediate plates are arranged between a pair of input plates and an output rotating member, and the outer peripheral side elastic member and the inner peripheral side elastic member operate in series by the intermediate plate. Therefore, the twist angle between the pair of input plates and the output rotating member can be widened. Further, the flanges of the output rotating members are arranged in the axial space surrounded by the pair of intermediate plates, and the pair of intermediate plates are arranged in the axial space surrounded by the pair of input plates. ing. Therefore, the entire device can be made compact.

(2) Preferably, a sealing mechanism for sealing the space surrounded by the pair of input plates on which the outer peripheral side elastic member and the inner peripheral side elastic member are arranged is further provided.

Here, since the space in which the outer peripheral side elastic member and the inner peripheral side elastic member are arranged is sealed by the sealing mechanism, a viscous fluid such as grease can be accommodated in this space.

(3) Preferably, the sealing mechanism is arranged between the pair of input plates and the pair of intermediate plates or output rotating members in the axial direction. And preferably, the sealing mechanism has an annular sealing member and a cone spring that urges the annular sealing member to one side in the axial direction.

(4) Preferably, the cone spring and the sealing member are arranged between one of the pair of input plates and one of the pair of intermediate plates in the axial direction. In this case, preferably, a friction member is arranged between one intermediate plate and the flange of the output rotating member. The friction member generates a hysteresis torque when one of the intermediate plates and the output rotating member rotate relative to each other.

(5) Preferably, the plurality of inner peripheral side elastic members are arc-shaped arc springs in a free state. In this case, the twist angle can be made wider.

(6) Preferably, a support member for supporting the outer peripheral portions of the plurality of arc springs with respect to the pair of intermediate plates is further provided.

Here, since a support member is provided between the outer peripheral portion of the arc spring and the intermediate plate, friction between the arc spring and the intermediate plate when the arc spring bends so as to bulge toward the outer peripheral side during operation. Hysteresis torque and wear due to contact can be suppressed.

(7) Preferably, a stopper mechanism for making the inner peripheral side elastic member non-adhesive when the pair of intermediate plates and the output rotating member are relatively rotated is further provided.

In particular, when the inner peripheral side elastic member is an arc spring, it is not preferable that the arc spring is brought into close contact with the arc spring during operation. Therefore, the stopper mechanism prevents the elastic members on the inner peripheral side from coming into close contact with each other.

(8) Preferably, the stopper mechanism has a first contact portion and a second contact portion. The first contact portion is provided on a pair of intermediate plates. The second contact portion is provided on the output rotating member, and comes into contact with the first contact portion when the pair of intermediate plates and the output rotating member rotate relative to each other by a predetermined angle.

Here, the stopper mechanism is realized by bringing the intermediate plate and the output rotating member into contact with each other. Therefore, the configuration can be simplified and the entire device can be made compact.

In the present invention as described above, in the damper device, the twist angle can be widened due to the compact configuration.

Sectional drawing of the damper apparatus according to one Embodiment of this invention. The external perspective view of the 1st input plate. The external perspective view of the first intermediate plate. Enlarged partial view of FIG. Front view of the outer peripheral damper portion and the inner peripheral damper portion. External perspective view of the spline hub. External perspective view of the inner peripheral damper part. Enlarged view of the sealing mechanism. Twist characteristic diagram.

[overall structure]
FIG. 1 is a cross-sectional view of a damper device 1 according to an embodiment of the present invention. OO in FIG. 1 is the rotation axis of the damper device 1, the engine is arranged on the left side of FIG. 1, and the transmission is arranged on the right side.

The damper device 1 is a device for transmitting torque from a member on the engine side to an input shaft on the transmission side, and has a function of absorbing and damping torsional vibration due to rotational fluctuation. The damper device comprises a first input plate 21 and a second input plate 22 (hereinafter, may be simply referred to as "input plates 21 and 22") constituting the input rotating body 2, and a third input rotating body 3. 1 Intermediate plate 31 and 2nd intermediate plate 32 (hereinafter, may be simply referred to as "intermediate plates 31, 32"), an outer peripheral side damper portion 4, a spline hub (an example of an output rotating member) 5, and the inside. A peripheral damper portion 6 and a sealing mechanism 7 are provided.

[Input plates 21 and 22]
The first input plate 21 and the second input plate 22 are different from each other except that the first input plate 21 has a tubular portion on the outer peripheral portion and the inner peripheral end portion extends inward in the radial direction. It has almost the same configuration. Therefore, the first input plate 21 will be mainly described below.

FIG. 2 shows an external perspective view of the first input plate 21. As shown in FIGS. 1 and 2, the first input plate 21 has a disk-shaped disk portion 211, a tubular portion 212, and a fixing portion 213.

A circular opening is formed in the central portion of the disc portion 211. The disk portion 211 has two outer peripheral side holding portions 2a and two outer peripheral side engaging portions 2b. The outer peripheral side holding portion 2a is formed in an arc shape. The two outer peripheral side engaging portions 2b are arranged at positions facing each other with the rotation shaft interposed therebetween, and are formed so as to be sandwiched between the two outer peripheral side holding portions 2a. The outer peripheral side engaging portion 2b is formed so as to project toward the transmission side in the axial direction. The tubular portion 212 is formed by extending the outer peripheral end of the disc portion 211 toward the transmission side. The fixing portion 213 is formed by bending the tip of the tubular portion 212 outward in the radial direction.

A plurality of assembly holes 2c are formed on the outer peripheral side of the central opening of the first input plate 21. Using this assembly hole 2c, the entire damper device is mounted on a member on the engine side.

The second input plate 22 is arranged so as to face the first input plate 21 at a distance in the axial direction. Further, the outer peripheral end portion of the second input plate 22 is fixed to the fixing portion 213 of the first input plate 21. Therefore, the second input plate 22 cannot rotate relative to the first input plate 21.

As described above, the second input plate 22 does not have a portion corresponding to the tubular portion 212 of the first input plate 21. Further, as shown in FIG. 1, the inner diameter d2 of the second input plate 22 is larger than the inner diameter d1 of the first input plate 21, and the outer diameter of the circle connecting the most radial outer portions of the plurality of assembly holes 2c. Even larger than d3.

Except for the above points, the second input plate 22 has the same configuration as the first input plate 21. That is, the second input plate 22 has two outer peripheral side holding portions 2a and an outer peripheral side engaging portion 2b at positions corresponding to the outer peripheral side holding portion 2a and the outer peripheral side engaging portion 2b of the first input plate 21, respectively. have.

With the above configuration, the chamber C surrounded by the input plates 21 and 22 is formed from the radial intermediate portion to the outer peripheral portion of the first input plate 21 and the second input plate 22. A viscous fluid such as grease is housed inside the chamber C.

[Intermediate plates 31, 32]
The intermediate plates 31 and 32 can rotate relative to the input plates 21 and 22. Then, it is arranged in the axial space (chamber C) surrounded by the input plates 21 and 22.

The first intermediate plate 31 and the second intermediate plate 32 have substantially the same configuration except that the first intermediate plate 31 has a sealing portion at the inner peripheral end portion. Therefore, the first intermediate plate 31 will be mainly described below.

FIG. 3 shows an external perspective view of the first intermediate plate 31. Further, FIG. 4 is an enlarged partial view of FIG. The first intermediate plate 31 has a disk portion 311 and a pair of intermediate engaging portions 312.

The disk portion 311 has two inner peripheral side holding portions 3a, two inner peripheral side engaging portions 3b, a washer support portion 3c, and a sealing portion 3d. The inner peripheral side holding portion 3a is formed in an arc shape. The outer peripheral wall of the inner peripheral side holding portion 3a functions as a washer support portion 3c. Further, two engaging holes 3e penetrating in the axial direction are formed in each inner peripheral side holding portion 3a. The two inner peripheral side engaging portions 3b are arranged at positions facing each other with the rotation shaft interposed therebetween, and are formed so as to be sandwiched between the two inner peripheral side holding portions 3a. The inner peripheral side engaging portion 3b is formed so as to project toward the transmission side in the axial direction. The seal portion 3d is formed in an annular shape at the inner peripheral end portion of the disk portion 311.

The pair of intermediate engaging portions 312 are arranged at positions facing each other with the rotation shaft interposed therebetween, and are formed so as to project outward in the radial direction from the disc portion 311. Further, the intermediate engaging portion 312 is formed so as to be offset toward the transmission side with respect to the disc portion 311. A stopper portion 3f (an example of the first contact portion) is formed at the inner peripheral end portion of the intermediate engaging portion 312.

As described above, the second intermediate plate 32 has the same configuration except that the seal portion 3d of the first intermediate plate 31 is not provided. That is, the second intermediate plate 32 has an inner peripheral side holding portion 3a, an inner peripheral side engaging portion 3b, a washer support portion 3c, and a disk portion 321 having an engaging hole 3e. Further, the second intermediate plate 32 has an intermediate engaging portion 322 having a stopper portion 3f.

The intermediate engaging portion 312 of the first intermediate plate 31 and the intermediate engaging portion 322 of the second intermediate plate 32 are fixed to each other by the rivet 33. Therefore, the first intermediate plate 31 and the second intermediate plate 32 cannot rotate relative to each other. As shown in FIG. 1, these intermediate engaging portions 312 and 322 are between the outer peripheral side engaging portion 2b of the first input plate 21 and the outer peripheral side engaging portion 2b of the second input plate 22 in the axial direction. Is located in.

The two spaces between the pair of intermediate engaging portions 312 and 322 in the circumferential direction function as the outer peripheral side accommodating portion 34 accommodating the outer peripheral side damper portion 4.

[Outer circumference damper part 4]
The outer peripheral side damper portion 4 is housed in the outer peripheral side accommodating portion 34 of the intermediate plates 31 and 32 in the chamber C, and is held by the outer peripheral side holding portions 2a of the input plates 21 and 22. The outer peripheral side damper portion 4 elastically connects the input plates 21 and 22 and the intermediate plates 31 and 32 in the rotational direction. As shown in FIG. 5, the outer peripheral side damper portion 4 has eight outer peripheral side springs 41, six intermediate spring seats 42, and four end spring seats 43.

The eight outer peripheral springs 41 are arranged side by side in the circumferential direction. An intermediate spring seat 42 is arranged between the adjacent outer peripheral springs 41, and the four outer peripheral springs 41 act in series. Two end spring seats 43 are arranged at the circumferential ends of the four outer peripheral springs 41. The end spring seat 43 is in contact with the outer peripheral side engaging portion 2b and the intermediate engaging portions 312 and 322.

The spring seats 42 and 43 are formed with tubular portions 42a and 43a into which the ends of the outer peripheral springs 41 are inserted. Then, when the input plates 21 and 22 and the intermediate plates 31 and 32 rotate relative to each other by a predetermined angle, the circumferential end faces of the tubular portions 42a and 43a of the adjacent spring seats 42 and 43 come into contact with each other, and the input plates 21 , 22 and the intermediate plates 31, 32 are restricted from relative rotation. That is, the outer peripheral side stopper mechanism is formed by the adjacent spring seats 42 and 43.

The same applies to the other four outer peripheral springs 41 not shown in FIG. That is, the other four outer peripheral springs 41 act in series via the intermediate spring seat 42. Further, an end spring seat 43 is arranged at the end of the other four outer peripheral springs 41 in the circumferential direction. The four outer peripheral springs 41 shown in FIG. 5 and the four outer peripheral springs 41 not shown in FIG. 5 act in parallel.

[Spline Hub 5]
As shown in FIGS. 1 and 6, the spline hub 5 has a boss 51 and a flange 52.

The boss 51 is formed in a tubular shape, and a spline hole 51a that engages with a shaft on the transmission side is formed on the inner peripheral surface.

The flange 52 extends radially outward from the outer peripheral surface of the boss 51, and includes the first intermediate plate 31 and the second intermediate plate 32 (to be exact, the disc portion 311 and the second intermediate plate 32 of the first intermediate plate 31). It is arranged between the axial directions of both plates 31 and 32 so as to be sandwiched by the disk portion 321 of the above. That is, the flange 52 is arranged in the space surrounded by the first intermediate plate 31 and the second intermediate plate 32. The flange 52 has two inner peripheral side accommodating portions 5a, two notches 5b (an example of a second contact portion), and a plurality of assembling holes 5c. Further, the flange 52 has a seal portion 5d wide in the axial direction between the inner peripheral side accommodating portion 5a and the assembly hole 5c in the radial direction.

The inner peripheral side accommodating portion 5a is arranged on the outer side in the radial direction of the assembly hole 5c. The inner peripheral side accommodating portion 5a is an opening penetrating in the axial direction and is formed in an arc shape. More specifically, the inner peripheral side accommodating portion 5a is arranged so as to face the inner peripheral side holding portions 3a of the intermediate plates 31 and 32.

The notch 5b is formed on the outer peripheral surface of the flange 52, and constitutes an inner peripheral side stopper mechanism. The inner peripheral side stopper mechanism will be described later.

The assembling hole 5c is arranged so as to overlap the assembling hole 2c of the first input plate 21 in the radial direction when viewed from the direction along the rotation axis.

As shown in FIG. 1, the end surface of the sealing portion 5d of the flange 52 on the engine side in the axial direction faces the sealing portion 3d of the first intermediate plate 31. Further, the end surface of the seal portion 5d on the transmission side in the axial direction faces the inner peripheral end portion of the second input plate 22.

[Inner circumference side damper part 6]
The inner peripheral side damper portion 6 is arranged inward in the radial direction of the outer peripheral side damper portion 4, and is arranged in the chamber C together with the outer peripheral side damper portion 4. The inner peripheral side damper portion 6 elastically connects the intermediate plates 31 and 32 and the spline hub 5 in the rotational direction. As shown in FIGS. 5 and 7, the inner peripheral side damper portion 6 has two arc springs 61 and four support washers 62 (an example of a support member). FIG. 7 is an external perspective view of the arc spring 61 and the support washer 62.

The arc spring 61 has an arc shape in a free state before incorporating these springs 61 into the device. The arc spring 61 is housed in the inner peripheral side accommodating portion 5a of the spline hub 5, and is held by the inner peripheral side accommodating portion 3a of the intermediate plates 31 and 32. The end faces of the arc spring 61 are the circumferential end face of the inner peripheral side accommodating portion 5a of the spline hub 5 and the circumferential end face of the inner peripheral side holding portion 3a (that is, the circumferential of the inner peripheral side engaging portion 3b). It is in contact with the end face in the direction). The rigidity of the arc spring 61 is lower than the rigidity of the outer peripheral spring 41.

As shown in FIGS. 4 and 7, the support washer 62 is arranged between the outer peripheral surface of the arc spring 61 and the washer support portion 3c of the intermediate plates 31 and 32. Each support washer 62 has a substantially semicircular main body 62a, a support protrusion 62b, and two engagement protrusions 62c.

The inner peripheral surface of the main body 62a has a shape along the outer peripheral surface of the arc spring 61. The support protrusion 62b projects radially outward from one end in the axial direction on the outer peripheral surface of the main body 62a. The support protrusions 62b are supported by the disc portions 311, 321 of the intermediate plates 31 and 32. The engaging protrusion 62c is formed so as to project axially from the side surface of the main body 62a. The engaging projection 62c is engaged with the engaging holes 3e of the corresponding intermediate plates 31 and 32.

With such a configuration, the support washer 62 prevents the outer peripheral surface of the arc spring 61 from coming into direct contact with the intermediate plates 31 and 32. Therefore, even if the arc spring 61 bends outward in the radial direction during operation, hysteresis torque and wear due to frictional contact between the arc spring 61 and the intermediate plates 31 and 32 can be eliminated.

Here, in order to regulate the relative rotation angle (twist angle) of the intermediate plates 31 and 32 and the spline hub 5 within a predetermined angle range, as shown in FIG. 5, the inner peripheral side stopper mechanism 64 (stopper) An example of the mechanism) is provided. The inner peripheral side stopper mechanism 64 is composed of a stopper portion 3f of the intermediate plates 31 and 32 and a notch 5b formed on the outer peripheral surface of the flange 52 of the spline hub 5.

More specifically, on the outer peripheral surface of the flange 52, two notches 5b that open to the outer peripheral side are formed over a predetermined angle range. Then, the stopper portions 3f of the intermediate plates 31 and 32 are inserted into the notch 5b. Therefore, when the intermediate plates 31 and 32 are twisted with respect to the spline hub 5 by a predetermined angle, the circumferential end face of the stopper portion 3f comes into contact with the end face of the notch 5b. As a result, the twisting angles of the intermediate plates 31 and 32 and the spline hub 5 are regulated within a predetermined angle range.

[Seal mechanism 7]
The chamber C is sealed by the sealing mechanism 7. Therefore, the viscous fluid such as grease contained in the chamber C is prevented from leaking from the chamber C.

As shown enlarged in FIG. 8, the sealing mechanism 7 is provided between the inner peripheral end portion of the first input plate 21 and the sealing portion 3d of the first intermediate plate 31. Further, the sealing mechanism 7 is provided between the inner peripheral end portion of the second input plate 22 and the axial end surface of the flange 52 of the spline hub 5. Further, the sealing mechanism 7 is provided between the sealing portion 3d of the first intermediate plate 31 and the axial end surface of the flange 52.

The seal mechanism 7 has two annular seal washers 71, two cone springs 72, and a friction member 73.

The seal washer 71 of the seal mechanism 7 on the engine side is in contact with the seal portion 3d of the first intermediate plate 31. The seal washer 71 is pressed against the seal portion 3d by the cone spring 72 provided between the seal washer 71 and the first input plate 21.

The seal washer 71 of the seal mechanism 7 on the transmission side is in contact with the side surface of the flange 52 on the transmission side. The seal washer 71 is pressed against the side surface of the flange 52 by a cone spring 72 provided between the seal washer 71 and the second input plate 22.

Further, the friction member 73 is arranged between the seal portion 3d of the first intermediate plate 31 and the side surface of the flange 52 on the engine side. Then, a cone spring 72 arranged on the engine side press-contacts the seal portion 3d with the side surface of the flange 52.

The seal washer 71 has a plurality of protrusions 71a protruding in the axial direction on the side surface. The protrusion 71a engages a hole formed in the corresponding input plates 21 and 22. Therefore, the seal washer 71 cannot rotate relative to the corresponding input plates 21 and 22.

As described above, the chamber C is sealed by the seal mechanism 7 composed of the seal washer 71, the cone spring 72, and the friction member 73.

The friction member 73 generates a predetermined hysteresis torque when the intermediate plates 31 and 32 and the spline hub 5 rotate relative to each other. That is, the friction member 73 also has a function for obtaining a hysteresis torque.

[motion]
The torque from the engine is input to the input plates 20 and 21 and transmitted to the intermediate plates 31 and 32 via the outer peripheral side damper portion 4. Then, it is transmitted from the intermediate plates 31 and 32 to the spline hub 5 via the inner peripheral side damper portion 6.

Specifically, since the arc spring 61 of the inner peripheral side damper portion 6 has lower rigidity than the outer peripheral side spring 41 of the outer peripheral side damper portion 4, the arc spring 61 is compressed before the outer peripheral side spring 41. After that, the outer peripheral spring 41 is compressed.

Then, when the twist angle (relative rotation angle) between the intermediate plates 31 and 32 and the spline hub 5 reaches a predetermined size, the inner peripheral side stopper mechanism 64 operates. Specifically, the end faces of the stopper portions 3f of the intermediate plates 31 and 32 come into contact with the end faces of the notches 5b of the spline hub 5. As a result, the compression of the arc spring 61 is stopped. Further, when the twist angle between the input plates 20 and 21 and the intermediate plates 31 and 32 becomes a predetermined size, the outer peripheral side stopper mechanism operates. Specifically, the end faces of the adjacent spring seats 42 and 43 come into contact with each other. As a result, the compression of the outer peripheral spring 41 is stopped.

FIG. 9A shows the twisting characteristics of the inner peripheral side damper portion 6, and FIG. 9B shows the twisting characteristics of the outer peripheral side damper portion 4. Further, FIG. 3C shows the torsional characteristics of the entire device. As is clear from FIG. 9C, the device as a whole has a low rigidity of the first stage in which the arc spring 61 is operating and a second stage in which the operation of the arc spring 61 is stopped and the outer peripheral spring 41 is operated. It has a two-stage torsional characteristic with high rigidity of the eyes.

Here, as the twist angle increases, the amount of compression of the springs 61 and 41 increases, and the outward deflection of the springs 61 and 41 increases. Therefore, the pressing force of the support washer 62 that supports the arc spring 61 against the intermediate plates 31 and 32 and the pressing force of the spring seats 42 and 43 against the input plates 20 and 21, respectively, increase. Therefore, as the twist angle increases, the hysteresis torque also gradually increases. Hysteresis torque is also generated by the repulsive force caused by the compression of the outer peripheral spring 41.

[Other Embodiments]
The present invention is not limited to the above embodiments, and various modifications or modifications can be made without departing from the scope of the present invention.

(A) In the above embodiment, the spring of the inner peripheral side damper portion 6 is an arc spring 61, but a linear coil spring may be used in a free state.

(B) The inner peripheral side stopper mechanism 64 is composed of the stopper portions 3f of the intermediate plates 31 and 32 and the notch 5b of the spline hub 5, but the configuration of the inner peripheral side stopper mechanism is not limited to this. A part of the intermediate plates 31 and 32 and a part of the spline hub 5 may be brought into contact with each other to regulate the relative rotation angle between the two.

(C) In the above embodiment, in the seal mechanism 7, the configuration on the engine side and the configuration on the transmission side are different, but both configurations may be the same.

1 Damper device 3e Stopper (first contact)
4 Outer peripheral damper part 5 Spline hub 5b Notch (second contact part)
6 Inner circumference side damper 7 Seal mechanism 21 and 22 Input plates 32, 32 Intermediate plate 41 Outer circumference spring 52 Flange 61 Arc spring 62 Support washer (support member)
64 Inner circumference side stopper mechanism 71 Seal washer 72 Cone spring 73 Friction member

Claims (8)

A pair of disc-shaped input plates that are arranged so as to face each other at an axial distance and are fixed to each other.
In the axial space surrounded by the pair of input plates, the discs are arranged so as to face each other at an axial interval, and can rotate relative to the pair of input plates and are fixed to each other. A pair of intermediate plates and
A plurality of outer peripheral elastic members arranged in an axial space surrounded by the pair of input plates and elastically connecting the pair of input plates and the pair of intermediate plates in the rotational direction.
An output rotating member having a flange arranged in an axial space surrounded by the pair of intermediate plates and capable of rotating relative to the pair of input plates and the pair of intermediate plates.
In the axial space surrounded by the pair of input plates, the plurality of outer peripheral elastic members are arranged in the radial direction so as to operate in series with the plurality of outer peripheral elastic members, and are intermediate between the pair. A plurality of inner peripheral elastic members that elastically connect the plate and the output rotating member in the rotational direction,
Damper device equipped with.
The damper device according to claim 1, further comprising a sealing mechanism for sealing a space surrounded by the pair of input plates on which the outer peripheral side elastic member and the inner peripheral side elastic member are arranged.
The sealing mechanism is arranged between the pair of input plates and the pair of intermediate plates or the output rotating member in the axial direction.
The sealing mechanism is
An annular seal member and
A cone spring that urges the annular seal member to one side in the axial direction,
Have,
The damper device according to claim 2.
The cone spring and the sealing member are arranged between one of the pair of input plates and one of the pair of intermediate plates in the axial direction.
A friction member which is arranged between the one intermediate plate and the flange of the output rotating member and generates a hysteresis torque when the one intermediate plate and the output rotating member rotate relative to each other is further provided.
The damper device according to claim 3.
The damper device according to any one of claims 1 to 4, wherein the plurality of elastic members on the inner peripheral side are arc springs having an arc shape in a free state.
The damper device according to claim 5, further comprising a support member that supports the outer peripheral portions of the plurality of arc springs with respect to the pair of intermediate plates.
The damper device according to any one of claims 1 to 6, further comprising a stopper mechanism for making the inner peripheral elastic member non-adhesive when the pair of intermediate plates and the output rotating member rotate relative to each other. ..
The stopper mechanism is
The first contact portion provided on the pair of intermediate plates and
A second contact portion provided on the output rotating member, which comes into contact with the first contact portion when the pair of intermediate plates and the output rotating member rotate relative to each other by a predetermined angle.
Have,
The damper device according to claim 7.

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