JP5955793B2 - Damper mechanism of torque transmission device - Google Patents

Description

  The present invention relates to a damper mechanism in a torque transmission device such as a lockup clutch of a torque converter and a clutch of a manual transmission.

Conventionally, for example, a lockup clutch of a torque converter is provided with a damper mechanism in order to suppress a shock generated during the engagement and vibration from the engine transmitted in the engaged state.
Such a damper mechanism mainly includes an input side spring holding plate, an output side driven plate, and a coil spring.
As shown in FIG. 10A, the spring holding plate 10 has a plurality of protrusions 11 protruding radially outward from a circular peripheral edge at equal intervals in the circumferential direction.
A coil spring 13 is compressed by a predetermined amount and disposed along the periphery between adjacent protrusions 11 as indicated by phantom lines, and abuts against the end faces of the protrusions 11 facing each other in the circumferential direction in a preloaded state. .
As shown in FIG. 10B, the driven plate 15 has a spring receiving portion 16 that protrudes outward from a circular peripheral edge in the same manner as the spring holding plate 10. The same number of spring receiving portions 16 as the protrusions 11 of the spring holding plate 10 are provided at equal intervals in the circumferential direction.

The spring holding plate 10 and the driven plate 15 are disposed so as to be rotatable relative to each other with their rotation axes coincided with each other. The spring receiving portion 16 of the driven plate 15 is set so that both end edges in the circumferential direction overlap with the end edges of the protruding portions 11 of the spring holding plate 10 when viewed from the axial direction.
When the spring holding plate 10 and the driven plate 15 are rotated relative to each other, the edge of the spring receiving portion 16 protruding between the two adjacent protruding portions 11 presses one end of the coil spring 13 and the other end of the coil spring 13 comes into contact. The coil spring 13 is compressed between the edge of the protruding portion 11 that is present. Thus, it is intended that the shock from the input side and the vibration of the engine at the time of lockup are absorbed, and direct transmission to the output side transmission mechanism portion is prevented.
Japanese Patent Laying-Open No. 2010-007717 also discloses a similar configuration.

JP 2010-007717 A

By the way, since the coil spring 13 held between the protrusions 11 is preloaded, the spring holder 16 and the driven plate 15 rotate relative to each other so that the spring receiver 16 compresses the coil spring 13. The torque must increase until the load on section 16 corresponds to the preload.
Here, in the conventional damper mechanism, the edge of the projection 11 of the spring holding plate 10 that is in contact with one end of the coil spring 13 and the spring receiving portion of the driven plate 15 that presses the one end of the coil spring 13 during relative rotation. The 16 edges are formed in parallel when viewed from the axial direction.
On the other hand, since the coil spring 13 is disposed in an arc shape between the protrusions 11, the length on the inner diameter side around the rotation axis is shorter than the length on the outer diameter side. This tendency becomes more prominent when the overall length of the coil spring 13 becomes longer while the recent demand for lower rigidity of the damper becomes stronger.
As a result, the inner diameter side of the coil spring 13 is compressed to be larger than the uniform nominal compression amount set on the center line (action line) of the coil diameter, resulting in a locally large load.

Since the edge of the spring receiving portion 16 is parallel to the edge of the protruding portion 11, when the spring holding plate 10 and the driven plate 15 are about to rotate relative to each other, the spring receiving portion 16 has an inner diameter side of the coil spring 13. A large load is applied. When a large load is applied to the spring receiving portion 16, the gradient of the torque change transmitted to the driven plate 15 at the start of relative rotation becomes large despite the need for low rigidity. Prevention has not been realized yet.
The above problem is not limited to the damper mechanism in the exemplified lockup clutch of the torque converter, but also to other damper mechanisms in general torque transmission devices.

  Accordingly, an object of the present invention is to provide a damper mechanism of a torque transmission device in which the gradient of torque change applied to the driven plate at the start of relative rotation between the spring holding plate and the driven plate is small, and an impact can be reliably prevented. .

The present invention
A spring holding plate coupled to the input side member and rotating around the central axis and having a plurality of contact portions in the circumferential direction;
A driven plate that is coupled to the output side member and rotates around the central axis and includes a plurality of spring receiving portions in the circumferential direction corresponding to the contact portion;
Both ends are supported by adjacent contact portions of the spring holding plate and are held in a preloaded state, and at the time of relative rotation of the spring holding plate and the driven plate, one end is pushed from the spring receiving portion to hold the spring holding plate and the driven plate. In a damper mechanism of a torque transmission device comprising a coil spring that is elastically connected,
The abutting edge of the spring receiving portion that pushes one end of the coil spring is protruded more radially outward from the central axis than the inner circumferential side toward the coil spring side with respect to the end edge of the abutting portion that supports one end of the coil spring. And has a circumferentially projecting end on the outer peripheral side from the coil center of the coil spring ,
The inclination angle of the abutment edge of the spring receiving portion with respect to the radial line passing through the center in the circumferential direction of the spring receiving portion is the local stress generated in the coil spring by the circumferential protruding end at the time of the maximum input torque. It was set in a range lower than the fatigue limit value .

  According to the present invention, at the beginning of relative rotation, the circumferentially protruding end pushes the outer diameter side of the coil spring having a low degree of compression, so that the gradient of change in the torque transmitted to the driven plate 4 is small and the impact is reduced. Is reliably prevented.

It is a figure which shows the main structures of the damper mechanism of embodiment. It is a figure which shows a spring holding plate. It is an enlarged view which shows the detail around a contact part. It is a figure which shows a driven plate. It is explanatory drawing which shows the relationship between the spring receiving part of a driven plate, and the contact part of a spring holding plate. It is a figure which shows an equalizer. It is a figure which shows the detail of the whole damper mechanism. It is explanatory drawing which shows operation | movement of a damper mechanism. It is a figure which shows the torque change transmitted to a driven plate. It is a figure which shows a prior art example.

Hereinafter, an embodiment in which the present invention is applied to a lockup clutch of a vehicle torque converter will be described.
Drawing 1 is a figure showing the main composition of the damper mechanism concerning an embodiment.
The damper mechanism 1 prevents a shock generated when the torque converter 100 fastens the lock-up piston 2 to the converter cover 101, and also prevents the vibration of the engine from directly propagating to the transmission mechanism side in the lock-up state. Provided.
The damper mechanism 1 is provided inside the torque converter 100, the central axis X is concentric with the power transmission shaft of the torque converter 100, and the main components are a spring holding plate 3, a driven plate 4, an outer diameter side spring 5, and an inner diameter side spring. 6 and an equalizer 7.
In FIG. 1, the right side is the engine side, and the left side is the speed change mechanism unit side.

The spring holding plate 3 is fixed to a surface of the lockup piston 2 opposite to the engine side, and is provided so as to rotate integrally with the lockup piston 2.
The driven plate 4 is located on the opposite side of the lock-up piston 2 with the spring holding plate 3 interposed therebetween, and can be rotated relative to the spring holding plate 3.
The equalizer 7 is positioned between the lock-up piston 2 and the spring holding plate 3 and is rotatable relative to the spring holding plate 3 and the driven plate 4.

Hereinafter, each component of the damper mechanism 1 will be described.
[Spring holding plate]
2A and 2B show the spring holding plate 3, wherein FIG. 2A is a front view and FIG. 2B is a cross-sectional view taken along line AA in FIG.
The spring holding plate 3 is a molded body of a ring-shaped plate member centered on the central axis X, and a region along the inner edge of the spring holding plate 3 serves as a ring-shaped fixing portion 31.
The fixing portion 31 is provided with rivet holes 31a at equal intervals in the circumferential direction, and the spring holding plate 3 is coupled to the lockup piston 2 by a rivet R inserted through the rivet hole 31a.
The spring holding plate 3 has three spring accommodating windows 32 at equal intervals in the circumferential direction, approximately in the middle of the ring width (radial direction). The spring accommodating window 32 has an arc-shaped elongated hole having a length W extending in the circumferential direction, and the outer diameter side spring 5 (see FIG. 3) is disposed therein.

A region between adjacent spring accommodating windows 32 corresponds to a protrusion of the spring holding plate in the conventional example, and the region indicated by hatching in FIG. The three contact portions 34 have a fan shape in which the width in the circumferential direction increases toward the outer side in the radial direction.
The outer diameter side spring 5 is compressed by a predetermined amount, and both ends thereof are in contact with both ends in the circumferential direction of the spring accommodating window 32, that is, the edge 34 d of the contact portion 34 in a preloaded state.
The outer diameter side spring 5 is composed of a pair of split springs 5a and 5b. A retainer 8 is inserted into the end of the split springs 5a and 5b on the abutting portion 34 side in the longitudinal direction (circumferential direction). Attached. The retainer 8 has a flat surface facing the end edge 34d of the abutting portion 34.
Further, a support portion 72 of an equalizer 7 described later is sandwiched between the split springs 5a and 5b.

3A and 3B show details around the abutting portion 34, where FIG. 3A is an enlarged partial front view, and FIG. 3B is a cross-sectional view taken along line BB in FIG.
The contact portion 34 has a shape curved in the axial direction in order to secure a contact area with the outer diameter side spring 5 (retainer 8).
Specifically, the abutting portion 34 is sequentially curved from the inner diameter side so as to bulge in a direction away from the lock-up piston 2, and in a direction approaching the lock-up piston 2 from the inner diameter-side curved portion 34a. The outer diameter side curved portion 34b curved so as to bulge, and the linear portion 34c extending in a direction away from the lockup piston 2 in parallel with the central axis X from the outer diameter side curved portion 34b. The coil has a shape along the periphery of the lockup piston 2 side.

The outer peripheral side of the spring accommodating window 32 is a ring-shaped flange portion 33 when viewed from the axial direction. The tip of the linear portion 34 c of the contact portion 34 is continuous with the flange portion 33.
The flange portion 33 includes a peripheral wall portion 33a extending in the radial direction and extending from the outer peripheral edge thereof in a direction away from the axial lockup piston 2 over the entire circumference. The outer diameter of the peripheral wall portion 33 a is substantially the same as the outer diameter of the cylindrical portion 2 c provided on the outer periphery of the lockup piston 2.

An outer regulating portion 33 b formed by extending the inner peripheral edge of the flange portion 33 radially inward and in a direction away from the lockup piston 2 is provided on the outer diameter side edge of the spring accommodating window 32.
Further, an inner regulating portion 31b (see FIG. 2B) formed by extending the outer peripheral edge of the fixed portion 31 in a direction away from the lockup piston 2 is provided on the inner diameter side edge of the spring accommodating window 32. .
The outer diameter side spring 5 is held by the spring accommodating window 32 by being surrounded by the inner regulating portion 31b and the outer regulating portion 33b, the lock-up piston 2, and the equalizer 7, and dropping is regulated.

As shown in FIGS. 2 and 3, from the fixed portion 31, three spring holding portions 35 for holding the inner diameter side spring 6 project in the inner diameter direction at the same circumferential position as each contact portion 34. .
The spring holding portion 35 is formed with a holding hole 36 for holding the inner diameter side spring 6.
In particular, as shown in FIG. 3, the holding hole 36 has a length W <b> 1 in a direction perpendicular to the radial line, and regions 39 b on both sides in the width direction are used as the gripping portions 39, and the edges 39 b of both gripping portions 39. , 39b abuts both ends of the inner diameter side spring 6 indicated by phantom lines.

A restricting portion 37 extending radially outward and in a direction away from the lockup piston 2 is provided at the inner diameter side edge of the holding hole 36, and a restricting portion 38 extending toward the lockup piston 2 side is provided at the outer diameter side edge. Yes.
The inner diameter side spring 6 is surrounded by the restricting portions 37 and 38 and the lock-up piston 2 and is held by the spring holding portion 35, and dropping is restricted.
The lengths W <b> 2 of the restricting portions 37 and 38 are shorter than the length W <b> 1 of the holding hole 36. This is because the inner diameter side spring 6 is compressed by an inner spring receiving portion 44 (see FIG. 4) of the driven plate 4 to be described later, so that interference with the inner spring receiving portion 44 is avoided.

The grip portion 39 has a curved shape in order to ensure a contact area with the inner diameter side spring 6.
That is, as shown in FIG. 3B, the gripping portion 39 is curved so as to bulge in a direction approaching the lockup piston 2, and is located closest to the lockup piston 2 in this curved portion. The apex 39a is positioned substantially at the center of the holding hole 36 in the radial width W3.

[Driven plate]
4A and 4B show the driven plate 4. FIG. 4A is a front view, FIG. 4B is a cross-sectional view taken along the line CC in FIG. 4A, and FIG. 4C is an enlarged view of a region D in FIG.
As shown in FIG. 4A, the driven plate 4 is a molded body of a ring-shaped plate member centered on the central axis X, and a region along the inner diameter edge thereof is used as a ring-shaped attachment portion 41. Yes.
The mounting portion 41 is provided with mounting holes 41a at equal intervals in the circumferential direction, and the driven plate 4 is coupled to the turbine of the torque converter 100 by a rivet (not shown) inserted through the mounting hole 41a.
On the outer periphery of the driven plate 4, three outer spring receiving portions 45 extending radially outward are provided at equal intervals in the circumferential direction.
The outer spring receiving portion 45 has a fan shape whose width in the circumferential direction increases toward the outer side in the radial direction, and when the driven plate 4 and the spring holding plate 3 rotate relative to each other, the circumferential edge of the outer spring receiving portion 45 abuts. The edge 45c contacts the outer diameter side spring 5 (retainer 8) held by the spring holding plate 3.

The outer spring receiving portion 45 has a curved shape in order to secure the contact area with the outer diameter side spring 5 while avoiding interference with the contact portion 34 of the spring holding plate 3 located on the lockup piston 2 side. have.
Specifically, as shown in FIGS. 4B and 4C, the outer spring receiving portion 45 is curved from the inner diameter side so as to bulge in the direction away from the lockup piston 2 in order from the inner diameter side. It consists of a part 45a and a linear part 45b extending radially outwardly orthogonal to the central axis X.
In particular, as shown in (c), in a state where the driven plate 4 is assembled with the spring holding plate 3, the linear portion 45 b is set so as to cross the coil center of the outer diameter side spring 5 in the radial direction.

As shown in FIG. 5, the outer spring receiving portion 45 and the contact portion 34 of the spring holding plate 3 are both fan-shaped, but the inclination of the contact edge 45 c with respect to the radial line passing through the circumferential center of the outer spring receiving portion 45 ( The angle α) is larger by a predetermined amount γ than the inclination (angle β) of the end edge 34d with respect to the radial line passing through the center in the circumferential direction of the contact portion 34, and the outer peripheral side is the circumferential protruding end P of the contact edge 45c.
In FIG. 5, for easy identification, the spring holding plate 3 (contact portion 34) is indicated by a broken line, and the driven plate 4 (outer spring receiving portion 45) is indicated by a solid line.
The outer diameter of the outer spring receiving portion 45 is slightly smaller than the inner diameter of the linear portion 34c of the contact portion 34 in the spring holding plate 3, but the maximum circumferential width S between the circumferential protruding ends P of the outer spring receiving portion 45 is The circumferential width of the contact portion 34 on the same circle as the virtual circle M around the central axis X having the maximum width S is set to be the same as the circumferential width of the contact portion 34 on the same circle. It may be slightly shorter than the circumferential width.
When the outer peripheral corner portion of the outer spring receiving portion 45 is not rounded, the virtual circle M on which the circumferential protruding end P is located passes through the outer periphery of the outer spring receiving portion 45. Regardless of whether or not the outer peripheral corners are rounded, the virtual circle M passes through the outer diameter side of the coil center line CL (see also FIG. 3) of the outer diameter side spring 5 held by the spring holding plate 3.

The substantially intermediate portion in the radial direction continuous to the attachment portion 41 is a curved portion 42 that curves so as to bulge toward the lockup piston 2 side. In particular, as shown in FIG. 4C, the apex portion 42 a closest to the lock-up piston 2 side of the bending portion 42 is positioned approximately in the middle of the radial width W <b> 4 of the opening 43.
The curved portion 42 is formed with an opening 43 that presents an arc-shaped elongated hole extending in the circumferential direction at the same circumferential position as each of the outer spring receiving portions 45. That is, the circumferential center position of the outer spring receiving portion 45 and the circumferential center position of the opening 43 are on the same radial line.
The circumferential length of the opening 43 is larger than the length W1 of the holding hole 36 of the spring holding plate 3.

A region indicated by hatching in FIG. 4A in the curved portion 42 is an inner spring receiving portion 44 having a radial width of the circumferential edge of the opening 43. That is, the end edge of the inner spring receiving portion 44 that faces the opening 43 is a contact edge 44a that contacts the inner diameter side spring 6 held in the holding hole 36 when the driven plate 4 and the spring holding plate 3 are relatively rotated by a predetermined amount. It becomes.
For this reason, the curved portion 42 (inner spring receiving portion 44) is set so that the apex portion 42 a crosses the coil center of the inner diameter side spring 6 in a state where the driven plate 4 is assembled with the spring holding plate 3.

[equalizer]
FIG. 6 shows an equalizer 7, (a) is a front view, (b) is a cross-sectional view taken along line EE in (a), (c) is an enlarged view of an F portion in (b), and (d) is ( It is GG sectional drawing in a).
The equalizer 7 extends a flange portion 71 radially outward from the end opposite to the lock-up piston 2 of the cylindrical main body portion 70 about the central axis X to the lock-up piston 2 side. The support portion 72 is configured to extend radially inward from the end edge at equal intervals in the circumferential direction.
The main body portion 70 of the equalizer 7 covers the outer diameter side of the spring accommodating window 32 in a state assembled with the spring holding plate 3.

In particular, as shown in FIG. 6 (c), the support portion 72 extends radially inward from the edge of the main body portion 70 on the lock-up piston 2 side, and is then bent in a direction away from the lock-up piston 2. Further, the tip is curved inward so as to cross the coil center of the outer diameter side spring 5.
The support portion 72 extends into the spring accommodating window 32 and is disposed between the divided springs 5a and 5b.
The equalizer 7 is restricted from moving in one axial direction by the lock-up piston 2, and is restricted from moving to the other by the flange portion 33 of the spring holding plate 3.
The radial movement of the equalizer 7 is regulated by the cylindrical portion 2 c of the lockup piston 2.

FIG. 7 shows details of the entire damper mechanism 1 in which the spring holding plate 3, the driven plate 4, the outer diameter side spring 5, the inner diameter side spring 6, and the equalizer 7 described above are assembled coaxially. The partially broken front view seen from the left, (b) is HH sectional drawing in (a), (c) is JJ sectional drawing in (a).
In FIG. 7A, approximately 1/3 in the lower right is a state in which the driven plate 4 is present, approximately 1/3 in the lower left is a state in which the driven plate 4 is removed, and approximately 1/3 in the upper portion is a spring. The holding plate 3 is also removed.
The driven plate 4 is assembled in such a positional relationship that the outer spring receiving portion 45 overlaps with the contact portion 34 of the spring holding plate 3 when viewed from the axial direction.
The contact edge 45 c of the outer spring receiving portion 45 is in contact with the retainer 8 of the outer diameter side spring 5 held at the spring accommodating window 32 of the spring holding plate 3 at its circumferential protruding end P.
The inner diameter side spring 6 held by the spring holding portion 35 of the spring holding plate 3 is located at the center in the circumferential direction of the opening 43 of the driven plate 4, and the contact edge 44 a of the inner spring receiving portion 44 at both ends of the opening 43. There is a gap of angle θ between the inner diameter side spring 6 and the inner diameter side spring 6.

When the vehicle enters a predetermined operation state, the lockup piston 2 is pushed to the engine side by hydraulic pressure, and the torque converter 100 enters a lockup state in which the friction lining 2b of the lockup piston 2 is fastened to the converter cover 101.
In the lock-up state, the rotational driving force (torque) of the engine is directly input to the spring holding plate 3 via the lock-up piston 2, so that the spring holding plate 3 rotates around the central axis X. The driven plate 4 follows the rotation of the spring holding plate 3 while the outer spring receiving portion 45 presses and contracts the outer diameter side spring 5.

At this time, the outer side spring receiving portion 45 is initially in contact with the retainer 8 on the outer diameter side from the coil center of the outer diameter side spring 5 at the circumferential protruding end P of the abutting edge 45c. As described above, the outer diameter side of the outer diameter side spring 5 is first supported by the abutting portion 34 (end edge 34d) of the spring holding plate 3 while the outer diameter side of the outer diameter side spring 5 is small. Press the side. Therefore, the input to the driven plate 4 at the beginning of lockup starts from a low torque value.
In FIG. 8, for easy identification, the spring holding plate 3 (contact portion 34) is indicated by a broken line, and the driven plate 4 (outer spring receiving portion 45) is indicated by a solid line.
Then, the spring holding plate 3 and the driven plate 4 are rotated relative to each other by an angle δ, and as shown in FIG. 8B, the contact edge between the end face of the retainer 8 of the outer diameter side spring 5 and the outer spring receiving portion 45. When 45c is in a parallel state, the outer diameter side spring 5 (retainer 8) is pushed over the entire surface facing the contact edge 45c from the outer diameter side to the inner diameter side of the coil. The retainer 8 of the side spring 5 is separated from the contact surface 34 d of the spring holding plate 3 and is supported only by the outer spring receiving portion 45. The other end of the outer diameter side spring 5 is supported by an adjacent contact portion 34 (not shown).

FIG. 9 shows a change in torque transmitted to the driven plate 4 with respect to the relative rotation angle.
In the comparative example (broken line) corresponding to the conventional example in which the abutting edge 45c of the outer spring receiving portion 45 and the end edge 34d of the abutting portion 34 are parallel in a stationary state when assembled, the outer spring receiving is started at the same time as the relative rotation starts. The part 45 receives all of the load larger than the nominal value of the preload including the inner diameter side where the compression amount of the outer diameter side spring 5 is large, and the torque increases with a large gradient. On the other hand, in the embodiment shown by the solid line, after gradually increasing from a low torque value to reach the angle δ, the torque value Tpl due to the nominal load of the preload of the outer diameter side spring 5 is reached.
As described above, since the gradient of the torque change is small, at the beginning of the relative rotation, the same effect is obtained as when the spring constant of the outer diameter side spring 5 is lowered or the overall length is lengthened, and the impact is reliably prevented.

Immediately after the transmission of the rotational driving force (torque) from the spring holding plate 3 to the driven plate 4 is started, only the outer diameter side spring 5 is compressed.
When the transmitted rotational driving force increases and the spring holding plate 3 rotates relative to the driven plate 4 by θ, the compression by the contact edge 44a of the inner spring receiving portion 44 of the inner diameter side spring 6 is reduced. Be started. Therefore, finally, the rotational driving force is transmitted to the driven plate 4 through the outer diameter side spring 5 and the inner diameter side spring 6.

As the difference γ between the inclination (angle α) of the contact edge 45c of the outer spring receiving portion 45 and the inclination (angle β) of the end edge 34d of the contact portion 34 increases, the gradient of torque change at the start of relative rotation increases. However, the rotation angle when receiving the maximum input torque increases due to the characteristics corresponding to the lowering of the spring constant of the outer diameter side spring 5 as described above. Moreover, depending on the inclination of the contact edge 45c, the outer diameter side of the outer diameter side spring 5 may be compressed more than the inner diameter side.
Therefore, the inclination (angle α) of the contact edge 45c of the outer spring receiving portion 45 is such that the local stress generated in the outer diameter side spring 5 at the time of the maximum input torque is lower than the fatigue limit value of the SN curve (stress-number of repetitions). It shall be set as a range.

In the present embodiment, the lock-up piston 2 corresponds to the input side member in the invention, and the turbine of the torque converter 100 corresponds to the output side member.
The outer spring receiving portion 45 corresponds to a spring receiving portion in the invention, and the outer diameter side spring 5 corresponds to a coil spring.

The embodiment is configured as described above, and both ends are supported by the adjacent abutting portions 34 of the spring holding plate 3 coupled to the lock-up piston 2, and the outer diameter side spring 5 is arranged in a preloaded state, and the torque converter In the damper mechanism in which the spring receiving portion 45 of the driven plate 4 coupled to the turbine 100 pushes one end of the outer diameter side spring 5 and elastically connects with the spring holding plate 3, the spring receiving portion 45 abuts. The edge 45c is inclined with respect to the edge 34d of the abutting portion 34 so that the radially outer peripheral side from the central axis X protrudes toward the outer diameter side spring 5 rather than the inner periphery side. Since the circumferentially protruding end P is provided on the outer circumferential side from the center, the circumferentially protruding end P is the outer diameter side where the degree of compression of the outer diameter side spring 5 is low at the beginning of relative rotation. Press result, the change gradient of the input torque to the driven plate 4 is small, the impact is prevented reliably.
(Effects corresponding to claim 1)

Since the spring receiving portion 45 has the inclined contact edges 45c on both sides in the circumferential direction, not only when the rotational driving force is positively input from the lockup piston 2 on the engine side, but also on the turbine on the transmission mechanism portion side. Even when reverse input is performed, the impact at the start of relative rotation between the spring holding plate 3 and the driven plate 4 is reliably prevented.
(Effects corresponding to claim 3)

Since the driven plate 4 has a ring shape, the spring receiving portion 45 protrudes from the outer periphery thereof, and the circumferential protruding end P is located on a circle passing through the outer periphery of the spring receiving portion 45 with the center axis X as the center. The circumferential projecting end P abuts on the outermost peripheral side of the outer diameter side spring 5 in particular, and the input torque to the driven plate 4 at the beginning of relative rotation can be made particularly low .
Further, since the outer diameter side spring 5 includes the retainer 8 having a flat surface facing the contact portion 34 at the end supported by the contact portion 34, the outer diameter side spring 5 between the contact portions 34 is provided. Regardless of the arrangement state, the circumferentially protruding end P of the spring receiving portion 45 abuts smoothly, and the outer diameter side spring 5 can be pushed stably .

The spring holding plate 3 of the embodiment forms a plurality of arc-shaped elongated hole spring accommodating windows 32 and the outer diameter side springs 5 are arranged, and the region between the adjacent spring accommodating windows 32 is abutting portion 34. However, the present invention is not limited to this, and similarly to the conventional example, the protruding portion may be protruded from the outer periphery of the spring holding plate to be a contact portion, and the outer diameter side spring may be disposed between the contact portions.
Further, in the embodiment, the edges on both sides in the circumferential direction of the spring receiving portion 45 are set as the contact edges 45c having a larger inclination than the end edge 34d of the contact portion 34, or the rotational driving force is input from the engine side or the speed change mechanism portion. The outer peripheral side of the outer diameter side spring 5 is pushed at the start of relative rotation regardless of whether it is input from the side, but the outer diameter side spring 5 is pushed when necessary, for example, when rotational driving force is input from the engine side. Only the side edge may be a contact edge 45c having a large inclination.

DESCRIPTION OF SYMBOLS 1 Damper mechanism 2 Lockup piston 2b Friction lining 2c Cylindrical part 3 Spring holding plate 4 Driven plate 5 Outer diameter side spring 5a, 5b Split spring 6 Inner diameter side spring 7 Equalizer 8 Retainer 31 Fixed part 31a Rivet hole 31b Inner restriction part 32 Spring Accommodating window 33 Flange portion 33a Peripheral wall portion 33b Outer restricting portion 34 Abutting portion 34a Inner diameter side bent portion 34b Outer diameter side bent portion 34c Linear portion 34d Edge 35 Spring holding portion 36 Holding hole 37, 38 Restricting portion 39 Holding portion 39a Vertex 39b Edge 41 Mounting portion 41a Mounting hole 42 Curved portion 42a Vertex portion 43 Opening portion 44 Inner spring receiving portion 44a Abutting edge 45 Outer spring receiving portion 45a Inner diameter side curved portion 45b Linear portion 45c Abutting edge 70 Main body portion 71 Flange part 72 Support part 10 Torque converter 101 converter cover 102 turbine P circumferential protruding end M virtual circle R rivet X central axis

Claims (5)

A spring holding plate coupled to the input side member and rotating around the central axis and having a plurality of contact portions in the circumferential direction;
A driven plate that is coupled to the output side member and rotates around a central axis and includes a plurality of spring receiving portions in the circumferential direction corresponding to the contact portion;
Both ends are supported by the adjacent contact portion of the spring holding plate and held in a preloaded state, and one end is pushed from the spring receiving portion when the spring holding plate and the driven plate are rotated relative to each other. And a damper mechanism of a torque transmission device comprising a coil spring that elastically connects the driven plate,
The abutting edge of the spring receiving portion that pushes the one end of the coil spring is radially inner from the central axis with respect to the edge of the abutting portion that supports the one end of the coil spring. with inclined such that the protruding into the coil spring side than has a circumferential projecting edge on the outer peripheral side of the coil center of the coil spring,
The inclination angle of the abutment edge of the spring receiving portion with respect to the radial line passing through the center in the circumferential direction of the spring receiving portion is the local stress generated in the coil spring by the circumferential protruding end at the time of the maximum input torque. A damper mechanism for a torque transmission device, wherein the damper mechanism is set in a range lower than a fatigue limit value .   2. The torque transmission device according to claim 1, wherein the inclined contact edge in the spring receiving portion is an end edge that presses the coil spring when a rotational driving force is positively input from the input side member. Damper mechanism.   The damper mechanism of the torque transmission device according to claim 1, wherein the inclined contact edge in the spring receiving portion is an end edge on both sides in the circumferential direction of the spring receiving portion. The driven plate has a ring shape, and the spring receiving portion protrudes outward from the outer periphery thereof,
4. The damper of a torque transmission device according to claim 1, wherein the circumferentially projecting end is located on a circle passing through the outer periphery of the spring receiving portion with the central axis as a center. 5. mechanism.   The torque transmission device according to any one of claims 1 to 4, wherein the coil spring includes a retainer having a flat surface facing the contact portion at an end supported by the contact portion. Damper mechanism.

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