KR101494946B1 - Vibration damping apparatus - Google Patents

Abstract

The stiffness in the axial direction is suppressed while the rigidity in the circumferential direction of the holding plate is kept high. A hold plate 3 fixed to the lock-up piston 2 of the torque converter 100 and rotating integrally with the lock-up piston 2, a driven plate 4, a holding plate 3 and a driven plate 4 in the rotational direction and having an inner diameter side spring 6 and an outer diameter side spring 5 arranged in the circumferential direction around the central axis X, In the holding plate 3, the spring holding portion 35 having the holding hole 36 of the inner diameter side spring 6 is extended from the ring-shaped fixed portion 31 to the inner diameter side with the lock-up piston 2 And the spring holding portion 35 is connected to the holding portion 36 on both sides of the holding hole 36 in the circumferential direction around the center axis X to the holding hole 36, (40) is provided.

Description

[0001] VIBRATION DAMPING APPARATUS [0002]

The present invention relates to a vibration damping device for a torque converter.

Patent Document 1 discloses a vibration damping device for damping vibration of a power generated by an engine.

As shown in FIG. 8, the vibration damping device 200 of the patent document 1 includes a hold plate 202 fixed to the lock-up piston 201 and to which the rotational driving force of the engine is inputted, A spring 203 (an outer diameter side spring 204, an inner diameter side spring 205) arranged along the circumferential direction of rotation while elastically connecting the plate 203, the hold plate 202 and the driven plate 203 in the rotating direction, .

In the vibration damping device 200, when the lock-up piston 201 is coupled to the cover converter 206 to be in the lock-up state, the rotational drive force of the engine is transmitted to the hold plate 202 connected to the lock- And the rotational driving force inputted to the hold plate 202 is transmitted to the driven plate 202 via the spring (the outer diameter side spring 204 and the inner diameter side spring 205) provided on the outer diameter side and the inner diameter side of the holding plate 202, And is transmitted to the main body 203 side.

Since the hold plate 202 is connected to the lock-up piston 201 by the rivet R on the inner diameter side, the lock plate 202 is brought into the lock-up state. When the rotational driving force of the engine is directly inputted to the hold plate 202 , A torsional stress is applied to the connection portion of the holding plate 202 by the rivet (R). Therefore, the holding plate 202 needs to have a circumferential rigidity to withstand torsional stress.

The engagement of the lock-up piston 201 with the cover converter 206 is performed by displacing (curving) the lock-up piston 201 toward the cover converter by the hydraulic pressure applied to the lock-up piston 201 (See arrows in the figure).

However, if the stiffness of the holding plate 202 is high, the curvature of the lock-up piston 201 is hindered, and it is difficult to quickly fasten the lock-up piston 201 to the cover converter 206. Therefore, the holding plate 202 preferably has low stiffness in the curved direction (axial direction) of the lock-up piston 201.

Thus, in order to smoothly perform the lock-up in the vibration damping device 200, it is necessary to suppress the stiffness in the axial direction while maintaining the rigidity in the circumferential direction of the hold plate 202 at a high level.

In the case of Patent Document 1, as shown in FIG. 8B, a piercing hole 208 is formed on the outer diameter side of the support hole 207 of the hold plate 202 for supporting the inner diameter side spring 205 , And the rigidity of the holding plate 202 in the axial direction is lowered.

Japanese Patent Application Laid-Open No. 2010-007717

However, since the stiffness of both sides of the support hole 207 is not reduced only by forming the piercing hole 208 on the outer diameter side of the support hole 207 as in Patent Document 1, The rigidity in the axial direction could not be sufficiently lowered.

Therefore, it is required that the stiffness in the axial direction is suppressed while maintaining the stiffness of the holding plate in the circumferential direction at a high level, so that quick locking of the lock-up piston to the cover converter is possible.

The present invention relates to a torque converter comprising a hold plate fixed to a lock-up piston of a torque converter and rotating around a central axis integrally with a lock-up piston, a driven plate connected to a turbine of the torque converter and rotated about the central axis, A vibration damping device comprising a spring arranged in a circumferential direction around a central axis and elastically connecting a holding plate and a driven plate in a rotating direction,

A spring retaining portion protruding from the fixed portion of the holding plate to the lock-up piston toward the inner diameter side and having a retaining hole formed therein for retaining the spring;

And through holes formed on both sides of the holding hole along the central axis of the spring are formed.

The stiffness in the axial direction can be weakened at the portion where the spring holding portion of the holding plate is formed, so that the holding plate is a member having excellent flexibility which is easily bent in the axial direction.

Brief Description of the Drawings Fig. 1 is a view for explaining a torque converter equipped with a vibration damping device according to an embodiment. Fig.
2 is a view for explaining a vibration damping device according to an embodiment;
3 is a view for explaining a holding plate according to the embodiment;
4 is an enlarged view of a part of a holding plate according to the embodiment.
5 is a view for explaining a driven plate according to the embodiment;
6 is a view for explaining an equalizer according to the embodiment;
7 is an enlarged view of a spring holding portion of the holding plate according to the embodiment;
8 is a view for explaining a vibration damping device according to a conventional example;

Hereinafter, embodiments of the present invention will be described.

Fig. 1 is a view for explaining a vibration damping device 1 in the torque converter 100. Fig.

2 (a) is a plan view, (b) is an AA sectional view in (a), and (c) is a BB sectional view in (a) .

2 (a), approximately 1/3 of the lower right portion is a plan view in the state where the driven plate 4 is present, and approximately 1/3 of the lower left portion is omitted in the drawing of the driven plate 4 And approximately one third of the upper side is a cross-sectional view in which the vibration damping device 1 is cut on a plane orthogonal to the rotation center axis X. In Fig.

1 and 2, the vibration damping device 1 is provided inside the torque converter 100 and comprises a holding plate 3, a driven plate 4, a spring (an outer diameter side spring 5), an inner diameter side spring 6), and an equalizer 7.

When the torque converter 100 is in the lockup state in which the lockup piston 2 is fastened to the cover converter 101 and the rotational driving force of the engine is directly inputted to the transmission mechanism side, Is prevented from directly propagating to the transmission mechanism unit side.

Each component of the vibration damping device 1 will be described below.

Fig. 3 is a view for explaining the holding plate 3, and Fig. 3 (a) is a plan view and Fig. 3 (b) is a sectional view taken along the line A-A in Fig. 4 (a) is an enlarged view of a part of the hold plate 3, and FIG. 4 (b) is a cross-sectional view taken along the line A-A in FIG.

[Hold plate]

2, the holding plate 3 is fixed to a surface of the lock-up piston 2 opposite to the cover converter 101, and is provided so as to rotate integrally with the lock-up piston 2. As shown in Fig.

As shown in Fig. 3, the holding plate 3 is a molded body of a ring-shaped plate member viewed in the axial direction, and a ring-shaped fixing portion 31 is provided on the inner diameter side thereof.

The fixing portion 31 is provided with a rivet hole 31a penetrating through the fixing portion 31 in the thickness direction thereof and the holding plate 3 is fitted with a rivet R through which the rivet hole 31a is inserted , And is fixed to the lock-up piston (2).

In the embodiment, the rivet holes 31a are provided in nine places in total in the circumferential direction around the central axis X at predetermined intervals, and these are the virtual circle Im1 ).

At the outer periphery of the fixing portion 31, contact portions 34 extending outward in the radial direction are provided at three positions in a circumferential direction around the central axis X at predetermined intervals.

The contact portion 34 has a shape in which the width of the contact portion 34 is increased along the circumferential direction as it is spaced from the central axis X. The outer circumferences of the contact portions 34 are located radially outward of the fixed portion 31 And is connected to the flange portion 33 positioned.

The later-described outer diameter side spring 5 comes into contact with the contact portion 34 from the circumferential direction (see Fig. 2). The contact portion 34 has a curved shape in cross section in order to secure a contact surface with the outer diameter side spring 5.

Specifically, as shown in Figs. 3 (b) and 4 (b), the contact portion 34 is curved so as to bulge in the direction away from the lock-up piston 2 The inner diameter side curved portion 34a and the outer diameter side curved portion 34b curved to bulge in the direction approaching the lock-up piston 2 and a direction away from the lock-up piston 2 in parallel with the central axis X And a shape along the periphery of the outer diameter side spring 5 on the lock-up piston 2 side.

The distal end side of the linear portion 34c extending in the direction away from the lock-up piston 2 is curved outward in the radial direction and its tip end is integrally connected to the inner periphery of the flange portion 33. [

The flange portion 33 is positioned on the transmission mechanism side (the side away from the lock-up piston 2) with respect to the fixed portion 31 and extends along the substantially orthogonal direction of the central axis X b).

The flange portion 33 has a ring shape viewed in the axial direction and extends in parallel with the flange portion 71 of the equalizer 7 described later and is spaced apart from the lock-up piston 2 of the equalizer 7 And the movable range in the direction indicated by the arrow.

The wall portion 33a extending in the direction away from the lock-up piston 2 bends the outer diameter side of the flange portion 33 in the direction away from the lock-up piston 2 at the outer periphery of the flange portion 33 Respectively. The peripheral wall portion 33a is provided over the entire circumference of the outer periphery of the flange portion 33 in the circumferential direction around the center axis X (see Fig. 3 (a)), A flange portion 33 which is in contact with the contact portion 34 and an outer diameter side of the holding plate 3 including the contact portion 34. [ The peripheral wall portion 33a is formed to have substantially the same outer diameter as the cylindrical portion 2c provided on the outer periphery of the lock-up piston 2 (see Fig. 4 (b)).

At the inner periphery of the flange portion 33, an outer restricting portion 33b extending radially inward is provided. 4 (b), the outer limiting portion 33b extends along the outer periphery viewed from the axial direction of the outer diameter side spring 5 in the direction away from the lock-up piston 2, Up piston 5 in the direction away from the lock-up piston 2. The lock-

3, the fixing portion 31, the contact portion 34, and the opening portion 32 surrounded by the flange portion 33 are located on the outer diameter side of the fixing portion 31 as seen in plan view.

The outer diameter side spring 5 disposed in the accommodation space S (see FIG. 3 (b)) formed between the hold plate 3 and the lock-up piston 2 is located in the opening 32.

The opening 32 is formed to have a predetermined length in the circumferential direction around the center axis X. In the embodiment, a total of three openings 32 are provided at regular intervals.

The opening 32 is formed over an angular range W in which two outer diameter side springs 5a and 5b arranged in the circumferential direction as viewed from the central axis X can be accommodated (See Fig. 3 (a)].

On the inner diameter side of the opening portion 32, an inner limiting portion 31b is provided which is cut and bent. 3 (a), the inner limiting portion 31b is bent in the front direction (the direction away from the lock-up piston), and the inner limiting portion 31b is disposed in the inner diameter direction As shown in FIG.

This inner limiting portion 31b is formed in two parts in the circumferential direction to avoid a position overlapping with the outer side in the radial direction of the rivet hole 31a as viewed from the central axis X. In Fig. The inner limiting portion 31b is formed in a shape of arc along the imaginary circle Im2 about the central axis X as shown in Fig.

As shown in Fig. 2, the outer diameter side spring 5 located in the opening 32 as viewed in plan view is constituted by a pair of split springs 5a and 5b, A retainer 8 is inserted and attached to an end portion on the side of the contact portion 34 in the longitudinal direction.

One end of each of the split springs 5a and 5b is in contact with the contact portion 34 of the holding plate 3 through the retainer 8 in the circumferential direction and the other end is in contact with the supporter 72 of the equalizer 7 And are in contact from the circumferential direction.

The outer diameter side spring 5 is held in such a state that its both ends are gripped by the abutting portions 34 and 34 adjacent to each other in the circumferential direction around the central axis X, Are arranged along the circumferential direction.

3, a spring holding portion 35 for holding the inner diameter side spring 6 is formed on the inner diameter side of the fixed portion 31 by bulging toward the center axis X side.

The spring retaining portion 35 is formed in a positional relationship overlapping the contact portion 34 as seen from the center axis X. In the embodiment, the spring retaining portion 35 is provided at three positions in the circumferential direction around the central axis X at predetermined intervals.

4A, a holding hole 36 for holding the inner diameter side spring 6 is formed in the spring holding portion 35. As shown in Fig. The holding hole 36 has a width W1 in the circumferential direction approximately equal to the axial length of the inner diameter side spring 6 and the inner diameter side spring 6 disposed in the holding hole 36 has a width Are held by the rims 36a and 36a of the holding holes 36. [0064] As shown in Fig.

The retaining holes 36 are provided with regulating portions 37, 38 which are cut and bent and formed on the rims of the inner and outer diameters.

The restricting portion 37 is bent in a direction away from the lock-up piston 2, and the restricting portion 38 is bent toward the lock-up piston 2 side. In the embodiment, the restricting portions 37 and 38 restrict the movement of the inner diameter side spring 6 in the inner diameter direction and the outer diameter direction.

The width W2 of the restricting portions 37 and 38 in the circumferential direction around the center axis X is shorter than the width W1 of the holding hole 36. [

In the embodiment, the inner diameter side spring 6 is compressed in the axial direction of the inner diameter side spring 6 by the opening 43 (see FIG. 5) of the later-mentioned driven plate 4. Therefore, in order to prevent the expansion and contraction of the inner diameter side spring 6 in the axial direction by the restricting portion 37, only the central portion in the longitudinal direction of the inner diameter side spring 6, (37, 38).

Both sides of the holding hole 36 in the spring holding portion 35 are grip portions 39 for holding both end portions of the inner diameter side spring 6. In order to secure a contact surface with the inner diameter side spring 6, the grip portion 39 has a curved shape as viewed in cross section.

As shown in Fig. 4 (b), the grip portion 39 is curved so as to bulge in the direction approaching the lock-up piston 2 as viewed from the end face, and the lock- The apex 39a located in the vicinity of the piston 2 is positioned substantially at the center in the radial width W3 of the holding hole 36. [

[Driven plate]

5A is a plan view, FIG. 5B is an AA sectional view in FIG. 5A, and FIG. 5C is an enlarged view of a region B in FIG. to be.

2, the driven plate 4 is located on the side opposite to the lock-up piston 2 of the holding plate 3, and the driven plate 4 and the holding plate 3 are located on the outer peripheral side of the spring bearing The portion 45 and the contact portion 34 are provided so as to overlap each other in the axial direction.

As shown in Fig. 5 (a), the driven plate 4 is a molded body of a ring-shaped plate member viewed in the axial direction, and a ring-shaped mounting portion 41 is provided on the inner diameter side.

In the vibration damping device 1, the mounting portion 41 is provided in a direction orthogonal to the central axis X, and a mounting hole 41a is formed in the mounting portion 41. [ The mounting holes 41a are formed by passing through the mounting portions 41 in the thickness direction, and a plurality of mounting holes 41 are provided at predetermined intervals in the circumferential direction around the central axis X. [

In the embodiment, a total of six mounting holes 41a are formed. By means of rivets (not shown) inserted into the mounting holes 41a, the driven plate 4 is connected to the turbine of the torque converter have.

The outer diameter side of the mounting portion 41 is a curved portion 42 curved to bulge toward the lock-up piston 2. An opening 43 is formed in the curved portion 42 so as to penetrate the curved portion 42 in the thickness direction have.

In the embodiment, the apex portion 42a of the curved portion 42 located at the side of the lock-up piston 2 is formed so as to be located substantially in the middle in the radial width W4 of the opening 43, 43 are provided in the circumferential direction around the central axis X at a predetermined interval.

In the state in which the driven plate 4 is embedded in the vibration damping device 1, the apex portion 42a of the apex portion 42a of the bending portion 42 (See Fig. 5 (c)).

On the outer periphery of the driven plate 4, spring receiving portions 45 extending outward in the radial direction are provided at three positions in a circumferential direction around the central axis X at predetermined intervals.

The spring receiving portion 45 has a shape in which the width in the circumferential direction is widened as it is spaced from the central axis X as seen from the plane and the outer diameter side spring 5 is brought into contact with the circumferential direction.

The spring receiving portion 45 is provided on the side of the lockup piston 2 so as to prevent interference with the contact portion 34 of the holding plate 3 and to secure a contact surface with the outer diameter side spring 5, And has a curved shape.

Specifically, as shown in Figs. 5 (b) and 5 (c), the spring-receiving portion 45 includes, in order from the inner diameter side, an inner diameter side curved to bulge in a direction away from the lock- And a linear portion 45b extending in a direction orthogonal to the center axis X. The linear portion 45b has a central portion viewed from the axial direction of the outer diameter side spring 5 The shape of the spring receiving portion 45 is set so as to traverse.

[Equalizer]

6A is a plan view of the equalizer 7 as viewed in the axial direction, FIG. 6B is a sectional view taken along the line AA in FIG. 6A, C, and (d) is a cross-sectional view taken along the line BB in (a).

2 (b), the equalizer 7 is located between the lock-up piston 2 and the holding plate 3 in the axial direction of the central axis X, and the lock- And the holding plate 3 so as to be rotatable relative to each other.

The equalizer 7 has a ring-shaped main body portion 70, a flange portion 71 and a support portion 72 extending from the main body portion 70 toward the inner diameter side in the axial direction.

A flange portion 71 which is bent outward in the radial direction and extends in a direction orthogonal to the central axis X is formed on the side opposite to the lock-up piston 2 in the main body portion 70.

The outer diameter side spring 5 moved radially outwardly by the centrifugal force is brought into contact with the inner peripheral surface 70a of the main body portion 70 and the main body portion 70 is in contact with the outer diameter side spring 5 In order to prevent deformation due to receiving stress, the flange portion 71 is provided in the main body portion 70 to secure the strength.

The support portion 72 supports the other ends of the split springs 5a and 5b and extends inward in the radial direction at the end of the body portion 70 on the side of the lock-up piston 2.

In the embodiment, three support portions 72 are formed at regular intervals in the circumferential direction around the central axis X, and the pair of split springs 5a and 5b are arranged in the circumferential direction around the central axis X It is installed to connect.

6 (c), the support portion 72 extends radially inward from the end on the side of the lock-up piston 2 and then is bent in a direction away from the lock-up piston 2, And the distal end side thereof is bent toward the inner diameter side. Therefore, the support portion 72 is curved so as to cross the central portion of the outer diameter side spring 5 viewed from the axial direction, from the lock-up piston 2 side.

In the embodiment, the movement of the equalizer 7 to the transmission side is regulated by the flange portion 33 of the holding plate 3, and the movement to the engine side is regulated by the lock-up piston 2.

The movement of the equalizer 7 in the inner diameter direction (central axis X) side is basically restricted by the outer diameter side spring 5 and the movement in the outer diameter direction is restricted by the cylindrical portion 2c.

1, when the number of revolutions of the engine reaches a predetermined number of revolutions, the lock-up piston 2 is urged toward the engine by the hydraulic pressure, and the torque converter 100 Up state in which the friction lining 2b of the lock-up piston 2 is fastened to the cover converter 101. [

In the lockup state, the rotational driving force of the engine is directly inputted to the holding plate 3 through the lock-up piston 2, so that the holding plate 3 is rotated about the central axis X, with respect to the driven plate 4 Rotate relatively.

At this time, since the contact surface 45c (see FIG. 5A) of the spring receiving portion 45 of the driven plate 4 is in contact with the outer diameter side spring 5 from the axial direction, the holding plate 3 And relatively rotates with respect to the driven plate 4 while compressing the outer diameter side spring 5 in the peripheral direction by the spring receiving portion 45. [

As a result, the rotational drive force input to the hold plate 3 is input to the driven plate 4 via the outer-diameter spring 5, so that the input rotational drive force is transmitted to the turbine hub and transmission .

2 (a), the rim 43a of the opening 43 of the driven plate 4 and the holding hole 36 of the spring holding portion 35 of the holding plate 3 are engaged with each other, 36 are arranged with a phase difference of an angle? In the circumferential direction around the central axis X. [

Thus, immediately after the transfer of the rotational driving force from the holding plate 3 to the driven plate 4 is started, only the outer diameter side spring 5 is compressed.

When the holding plate 3 rotates relative to the driven plate 4 by an angle of? With the increase of the rotational driving force (torque) Compression starts.

Therefore, the rotational driving force is finally input to the driven plate 4 via the outer-diameter-side spring 5 and the inner-diameter-side spring 6.

The main parts of the holding plate 3 in the vibration damping device 1 will be described below.

7 is an enlarged view showing the vicinity of the spring holding portion 35 of the holding plate 3 in an enlarged manner.

7, the spring holding portion 35 of the holding plate 3 extends from the ring-shaped fixed portion 31 of the holding plate 3 to the inner diameter side (toward the central axis X) Respectively.

The fixing portion 31 is provided with a rivet hole 31a at a predetermined interval in the circumferential direction around the central axis X and the spring holding portion 35 is formed by And extends radially inwardly between the rivet holes 31a and 31a.

The spring retaining portion 35 has a shape in which the width W5 in the circumferential direction is narrowed toward the inner diameter side (central axis X) as seen in plan view, (36) are formed.

The retaining hole 36 is formed to penetrate the spring retaining portion 35 in the thickness direction and both ends of the inner diameter side spring 6 in the longitudinal direction (axial direction) And is supported by a circumferential edge 36a.

The restricting portion 37 bent and bent in a direction away from the lock-up piston 2 and the restricting portion 37 bent in a direction approaching the lock-up piston 2 are formed on the inner diameter side and the outer diameter side of the retaining hole 36 A gear restricting portion 38 is provided.

The base portion of the restricting portion 37 and the connecting portion 36b of the holding hole 36 are formed in a circular arc shape in order to alleviate stress concentration when viewed from the top.

The penetrating portion 40 is formed on the outer diameter side of the holding hole 36 so as to be symmetrical with a virtual line Im3 connecting the center axis X and the middle in the circumferential direction of the holding hole 36, Respectively.

The penetrating portion 40 is formed with a predetermined length W6 along the circumferential direction around the central axis X. [ The end portion of the penetrating portion 40 on the side of the virtual line Im3 is formed so as to extend radially outward of the holding hole 36. The penetrating portion 40 extends from the radially outer side of the holding hole 36, (36).

The outer periphery 40b of the penetration portion 40 is formed so as to follow an imaginary circle Im5 about the center axis X. [ The imaginary circle Im5 is an imaginary circle whose diameter is smaller than the imaginary circle Im6 passing through the rim of the inner diameter side of the rivet hole 31a.

In the embodiment, the holding plate 3 is fixedly connected to the lock-up piston 2 by a rivet R through which a rivet hole 31a is inserted (refer to FIG. 2 (b)). Up piston 2 and the holding plate 3 when the torque converter 100 is brought into the lock-up state and the rotational driving force of the engine is inputted from the lock-up piston 2 to the holding plate 3, A torsional stress is applied.

This stress acts in the circumferential direction of the rivet R (rivet hole 31a) connecting the lock-up piston 2 and the holding plate 3.

7, a torsional stress is generated in the circumferential direction around the central axis X in an area between the imaginary circle Im6 passing through the rim of the inner diameter side of the rivet hole 31a and the imaginary circle Im7 passing through the rim of the outer diameter side .

Therefore, when the penetrating portion 40 is formed in the circumferential direction of the rivet hole 31a and reaches the region sandwiched between the imaginary circle Im6 and the imaginary circle Im7, the rigidity against the torsional stress of the holding plate 3 is lowered.

Therefore, in the embodiment, the position of the outer peripheral edge 40b is set so that the penetrating portion 40 is formed on the inner diameter side of the virtual circle Im6 (the rivet hole 31a).

The inner periphery 40a of the penetration portion 40 is formed so as to follow the imaginary circle Im4 centered on the central axis X. [

The imaginary circle Im4 is an imaginary circle passing radially outward beyond the contact point P on the outer diameter side of the rim 36a of the inner diameter side spring 6 and the holding hole 36. When the penetrating portion 40 is not formed Is smaller than the imaginary circle Im8 passing through the outer circumferential edge 36c (indicated by an imaginary line in the figure) of the holding hole 36 of the holding hole 36. [

It is necessary to secure the width in the radial direction for forming the holding hole 36 in the holding plate 3 when the penetrating portion 40 is provided outside the holding hole 36 in the radial direction. It is necessary to secure the rigidity in the circumferential direction of the rivet as described above. In this case, the retaining hole 36 (spring retaining portion 35) is moved inward in the radial direction, As shown in FIG. In this case, the working diameter of the inner diameter side spring 6 (diameter from the central axis X) is limited, and the capacity for the torque input is reduced.

The inner circumferential edge 40a of the penetrating portion 40 is formed so as to correspond to the outer circumferential edge 36c of the holding hole 36 in the case where the penetrating portion 40 is not formed In the radial direction. The imaginary line Im3 of the penetrating portion 40 is formed so that the penetrating portion 40 is connected to the holding hole 36 on the outer side in the radial direction with respect to the contact point P on the outer diameter side of the inner diameter side spring 6 and the rim 36a. Is in communication with the holding hole 36 from an oblique direction on the outer side in the radial direction of the holding hole 36. [

This is because when the penetrating portion 40 is in contact with the holding hole 36 on the inner diameter side with respect to the contact point P, gripping of the inner diameter side spring 6 in the grip portion 39 is inhibited.

Thus, since the holding hole 36 is not moved toward the inner diameter side of the holding plate 3 in order to form the penetrating portion 40, the working diameter of the inner diameter side spring 6 is limited, The capacity is prevented from becoming small.

The penetrating portion 40 is a long hole whose basic shape extends along the circumferential direction around the center axis X and the tip end 40c in the direction away from the holding hole 36 is a spring retaining portion 35, To the approximate center of the holding portions 39 on both sides of the holding hole 36 in the holding hole 36. As shown in Fig.

In the holding plate 3, a continuous portion (continuous portion) extending continuously from the center axis X to the outside in the radial direction enhances the rigidity of the holding plate 3 against bending in the axial direction.

In the case of the holding plate 3 shown in Fig. 7, the contact portion 34 is located radially outward of the spring holding portion 35 with the fixing portion 31 interposed therebetween as viewed from the central axis X .

Therefore, for example, when the penetrating portion 40 is not formed, the range of the width W7 from the grip portion 39 to the contact portion 34 is extended radially outward as viewed from the central axis X It becomes an extended continuous portion.

In this case, the rigidity against the bending in the axial direction of the holding plate 3 is increased by the range of the width W7. As a result, the holding plate 3 is fixed to the central axis X ) In the axial direction (thrust direction).

In the embodiment, by providing the penetration portion 40 having the width W6 in the circumferential direction, the continuous portion extending from the grip portion 39 to the contact portion 34 in the radially outward direction is narrowed to the width W8 .

As a result, the rigidity against the bending in the axial direction of the holding plate 3 is weakened by the narrowed width of the continuous portion, as compared with the case where the penetrating portion 40 is not provided.

Since the penetration portion 40 is located in the middle of the continuous portion, the connection portion 31c between the inner diameter side (the grip portion 39) and the outer diameter side (the contact portion 34) is narrowed with the penetration portion 40 interposed therebetween And the inner diameter side (the grip portion 39) and the outer diameter side (the contact portion 34) are easily bent in the axial direction with the connection portion 31c as a boundary.

Therefore, also in this point, the stiffness of the lock-up piston 2 with respect to the bending in the axial direction of the holding plate 3 is weakened.

In the embodiment, the holding plate 3 is configured such that the inner diameter side (the grip portion 39) and the outer diameter side (the contact portion 34) are curved in the axial direction with the connection portion 31c as a boundary, The contact portion 40 is in the range from the rim 36a on both sides of the holding hole 36 to the both side ends 35a in the circumferential direction of the spring holding portion 35, In the range capable of retaining the strength to withstand the bending stress.

For example, when the thickness of the holding plate 3 is increased, the rigidity of the holding plate is increased. Therefore, by increasing the width W6 in the circumferential direction of the penetrating portion 40 as the plate thickness becomes longer, The rigidity of the holding plate is appropriately adjusted.

The width W6 in the circumferential direction of the penetrating portion 40 is set such that the tip end 40c of the penetrating portion 40 reaches the maximum of the spring holding portion 40c within a range in which the strength of the connecting portion 31c can be ensured 35 to the vicinities of both end portions 35a in the circumferential direction.

As described above, the holding plate 3 fixed to the lock-up piston 2 of the torque converter 100 and rotating around the central axis X integrally with the lock-up piston 2, A driven plate 4 connected to the turbine of the turbine 3 and rotating about the central axis X and a driven plate 4 for elastically connecting the holding plate 3 and the driven plate 4 in the rotational direction, Diameter side spring 6 and an outer diameter side spring 5 arranged in the circumferential direction and the rotational driving force of the engine inputted to the holding plate 3 is transmitted to the inner diameter side spring 6 and the outer diameter side spring 5 In the vibration damping device (1) to be transmitted to the driven plate (4)

In the holding plate 3, the spring holding portion 35 in which the holding hole 36 of the inner diameter side spring 6 is perforated is moved from the ring-shaped fixed portion 31 to the inner diameter side with the lock- And the spring holding portion 35 is provided with a holding hole 39 in the holding portion 39 on both sides of the holding hole 36 in the circumferential direction around the central axis X And the retaining hole 36 is formed along the center axis of the inner diameter side spring 6. The inner diameter side spring 6 has a through hole 40,

The range from the grip portion 39 on both sides of the holding hole 36 in the spring holding portion 35 to the fixing portion 31 on the outer side in the radial direction of the holding plate 3 is smaller than the center axis X, The rigidity (flexural strength) in the axial direction of the central axis X of the holding plate 3 is increased by the continuous portion.

With this configuration, the width in the circumferential direction of the continuous portion extending from the center axis X to the outside in the radial direction can be narrowed, so that the rigidity in the axial direction of the hold plate 3 can be reduced. As a result, since the holding plate 3 is a member having excellent flexibility which is easy to pivot in the axial direction, the stiffness against bending in the axial direction of the lock-up piston 2 to which the holding plate 3 is fixed can also be weakened.

Particularly, a contact portion 34 extending radially outward is provided on the opposite side of the spring holding portion 35 with the fixing portion 31 therebetween, and a continuous portion extending continuously outward in the radial direction as viewed from the central axis, In the range from the grip portion 39 of the spring holding portion 35 to the contact portion 34 via the fixing portion 31, the rigidity in the axial direction of the central axis X of the holding plate 3 The strength (bending strength) is further increased. Even in such a case, the stiffness in the axial direction of the holding plate 3 can be weakened, so that the stiffness of the lock-up piston 2 against bending in the axial direction is lowered.

The penetrating portion 40 of the grip portion 39 is formed so as to extend from the both sides of the holding hole 36 to the vicinity of the both side ends 35a in the circumferential direction of the spring holding portion 35, And the inner diameter side spring (6) is held by the support portion (39).

The space portion by the penetration portion 40 is intermittently provided in the middle of the continuous portion which is continuous in the radially outward side from the grip portion 39 on both sides of the holding hole 36 as viewed from the central axis X The rigidity of the holding plate 3 against bending in the axial direction can be reduced. As a result, the stiffness of the holding plate 3 in the axial direction is suppressed, so that the fastening of the lock-up piston 2 to the cover converter can be performed quickly.

The fixing portion 31 of the holding plate 3 is provided with a rivet hole 31a through which a rivet R for fastening the holding plate 3 to the lock-up piston 2 is inserted, X, and the penetrating portion 40 is provided on the inner diameter side with respect to the rivet hole 31a.

When the rotational driving force of the engine is inputted to the holding plate 3 from the lock-up piston 2, a torsional stress is applied between the lock-up piston 2 and the holding plate 3 and this torsional stress acts on the lock- I.e., the circumferential direction of the rivet (R), between the holding plate (2) and the holding plate (3). In the case of the holding plate 3, since the torsional stress acts on the circumferential direction of the rivet hole 31a of the rivet R, when the penetrating portion 40 is formed in the circumferential direction of the rivet hole 31a, The rigidity against the torsional stress of the torsion spring 3 is lowered.

By providing the through portion 40 on the inner diameter side of the rivet hole 31a as described above, rigidity in the circumferential direction of the holding plate 3 can be maintained at a high level, have.

More specifically, the penetrating portion 40 is formed so as to extend from both edges 36a of the holding hole 36 as seen from the central axis X toward the both side ends 35a of the spring holding portion 35 , The penetrating portion 40 is set in the range radially outward of the contact point P on the outer diameter side of the inner diameter side spring 6 in the holding hole 36 and on the inner diameter side of the rivet hole 31a Respectively.

With this configuration, it is not necessary to move the retaining hole 36 inward in the radial direction in order to install the penetrating portion 40, so that the inner diameter side spring 6 can be disposed as far as possible on the outer diameter side. In other words, since the operating diameter of the inner diameter side spring 6 does not need to be reduced in order to provide the penetrating portion 40, the capacity of the inner diameter side spring against torque input does not decrease. Therefore, in order to compensate for the decrease in the capacity of the torque input in the conventional case, it is necessary to provide a higher-performance spring. However, in the case of the vibration damping device 1 according to the embodiment, An inexpensive spring can be adopted.

The penetrating portion 40 is a long hole formed along the circumferential direction around the central axis X and the width of the long hole in the circumferential direction and the radial direction is set in accordance with the thickness of the holding plate .

With this configuration, the rigidity of the holding plate changes with the thickness of the plate. Therefore, by setting the widths of the long holes in the circumferential direction and the radial direction in accordance with the plate thickness, it is possible to suppress the deterioration of the rigidity of the holding plate 3 in the circumferential direction The rigidity in the axial direction is lowered, and the holding plate 3 can be easily bent in the axial direction.

The penetrating portion 40 is provided in contact with the holding hole 36 of the spring holding portion 35 in the embodiment described above. Instead of the penetrating portion, a notch communicating with the holding hole 36 may be provided, or a piercing hole may be formed, as long as it can weaken the stiffness of the portion extending to the outside of the direction.

Although the inner periphery 40a and the outer periphery 40b of the penetration portion 40 are formed so as to follow the imaginary circle Im4 and the imaginary circle Im5 respectively, good.

1: Vibration damping device
2: Lock-up piston
3: Hold plate
4: Driven plate
5: outer diameter side spring
6: Inner side spring
7: Equalizer
8: Retainer
31:
31a: rivet hole (insertion hole)
31b:
31c:
32: opening
33: flange portion
33a: peripheral wall portion
33b:
34:
35: spring holding portion
36: Retaining hole
37: Regulatory Department
38: Regulatory Department
39:
40:
41:
41a: mounting hole
42:
43: opening
45: spring bearing portion
70:
71: flange portion
72: Support
100: Torque converter
101: Cover Converter
P: contact point
R: Rivet (fastening member)
S: accommodation space
X: center axis (rotation center axis)

Claims (4)

A holding plate which is fixed to a lock-up piston of the torque converter and rotates around a central axis integrally with the lock-up piston,
A driven plate coupled to the turbine of the torque converter and rotating about the central axis,
And a spring arranged in the circumferential direction around the central axis and elastically connecting the holding plate and the driven plate in the rotating direction,
Wherein a contact portion of the spring with the outer diameter side spring of the holding plate and a grip portion protruding from the fixed portion of the lock-up piston toward the inner diameter side are provided at the same position in the radial direction and the both ends of the spring are always in contact with the grip portion A retaining hole having both end faces to be held thereon;
And a through hole which protrudes on opposite sides of the holding hole on both sides in the circumferential direction with respect to both end surfaces of the holding hole along the center axis of the spring, the through hole being radially outward of the holding hole And a through hole formed so as to communicate with both end surfaces of the holding hole and an outer diameter side contact point of the inner diameter side spring. The method according to claim 1,
Wherein the through hole communicates with the holding hole from both sides of the holding hole. 3. The method according to claim 1 or 2,
Wherein a plurality of insertion through holes for inserting a fastening member for fastening the hold plate to the lock-up piston are provided in the fixing portion of the holding plate at predetermined intervals in the circumferential direction,
And the through hole is provided on an inner diameter side with respect to the insertion through hole. 3. The method according to claim 1 or 2,
Wherein the through hole is an elongated hole formed along the circumferential direction and a width of the elongated hole in the circumferential direction is set to be longer as the plate thickness of the hold plate becomes thicker.

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