JP5350702B2 - Lock-up device and fluid power transmission device - Google Patents

Description

  The present invention relates to a lockup device used in a fluid type power transmission device.

  As a fluid power transmission device, for example, a torque converter including a lock-up device is known. The lockup device is a mechanism for mechanically coupling the front cover to the turbine, and is disposed in a space between the turbine and the front cover. Power is directly transmitted from the front cover to the turbine by the lockup device.

  A conventional lock-up device has a piston and a damper mechanism. The piston is arranged so as to be movable in the axial direction, and slides with the front cover when pressed against the front cover. The damper mechanism includes a pair of retaining plates, a hub flange, and a plurality of springs that elastically connect the retaining plate and the hub flange in the rotational direction. The retaining plate holds the spring so as to be elastically deformable in the rotational direction, and rotates integrally with the piston. The hub flange is disposed between the pair of retaining plates and is fixed to the turbine.

When the piston is pressed against the front cover by hydraulic pressure, torque input to the front cover is transmitted to the turbine via the piston and damper mechanism. At this time, the torsional vibration is absorbed and attenuated by the damper mechanism (see, for example, Patent Document 1).
Japanese Patent No. 2006-29553

  This type of lock-up device may employ a damper mechanism having two-stage characteristics. For example, the damper mechanism includes a retaining plate fixed to a piston, a first spring held by the retaining plate, an intermediate plate capable of supporting the end of the first spring in the rotational direction, and an intermediate plate. A second spring, and an output plate capable of supporting the end of the second spring in the rotational direction.

  For example, in the first stage of torsional characteristics, the first spring and the second spring are compressed in series via the intermediate plate, and in the second stage, only the second spring is compressed. Thereby, a two-stage characteristic can be realized in the damper mechanism of the lockup device.

  The second stage stopper mechanism is realized by a retaining plate and an output plate. Specifically, a plurality of first protrusions protruding inward in the radial direction are formed on the inner peripheral portion of the retaining plate. An opening is formed in the intermediate plate. A plurality of second protrusions protruding outward in the radial direction and inserted into the opening of the intermediate plate are formed on the outer peripheral portion of the output plate. When the second protrusion comes into contact with the edge portion of the opening, the relative rotation between the intermediate plate and the output plate is stopped, and the compression of the second spring is stopped. When the first protrusion and the second protrusion are in contact with each other in the rotation direction, the relative rotation between the retaining plate and the output plate is stopped, and the compression of the first and second springs is stopped.

  However, in this damper mechanism, the positional relationship between the opening of the intermediate plate and the accommodating portion in which the second spring is accommodated is not described in detail. Since the housing portion has a window hole, the strength of the intermediate plate may be reduced by the opening and the housing portion. However, a configuration for suppressing the strength reduction of the intermediate plate is disclosed in Patent Document 1. Not.

  The subject of this invention is providing the lockup apparatus which can suppress the fall of intensity | strength.

A lockup device according to the present invention is a device for mechanically connecting an input rotator to an output rotator, and includes a piston, an output member, an intermediate member, a plurality of first elastic members, and a plurality of A second elastic member. The piston is provided so as to be pressed against the input rotating body by the action of hydraulic pressure. The output member is fixed to the output rotating body. The intermediate member is rotatably arranged with respect to the piston and the output member. The first elastic member elastically connects the piston and the intermediate member in the rotation direction. The second elastic member elastically connects the intermediate member and the output member in the rotation direction. The output member includes an output member main body having a plurality of storage portions that store the second elastic member, and a protruding portion that protrudes radially outward from the output member main body. The intermediate member has an opening in which the center of the rotation direction is disposed between the rotation directions of the adjacent accommodating portions into which the protrusions are inserted. The intermediate member includes a first intermediate member, a second intermediate member that is disposed radially inward of the first elastic member and between the first intermediate member and the piston and is fixed to the first intermediate member. ,have. The opening is formed in the second intermediate member, the output member is disposed between the first intermediate member and the second intermediate member in the axial direction, and at least one of the first intermediate member and the second intermediate member is It has at least one support protrusion that protrudes toward the output member in the axial direction and supports the output member in the axial direction.

  In this lockup device, since the rotation direction center of the opening of the intermediate member is disposed between the rotation directions of the adjacent accommodating portions, it is possible to suppress the strength of the intermediate member from being reduced by the opening and the accommodating portion. Thereby, this lockup device can suppress a decrease in strength.

  In the lockup device according to the present invention, it is possible to suppress a decrease in strength.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<Overall configuration of torque converter>
A torque converter 1 as a fluid type power transmission device will be described with reference to FIGS. FIG. 1 is a schematic vertical sectional view of the torque converter 1. FIG. 2 is a schematic vertical sectional view of the lockup device 6. 3, an engine (not shown) is arranged on the left side of FIG. 1, and a transmission (not shown) is arranged on the right side of FIG. A line OO shown in FIG. 1 is a rotation axis of the torque converter 1.

  The torque converter 1 is a device for transmitting power from an engine crankshaft (not shown) to an input shaft of a transmission, and mainly includes a front cover 2 (an example of an input rotating body) to which power is input, An impeller 3, a turbine 4 (an example of an output rotating body), a stator 5, and a lockup device 6 are provided.

  An impeller 3 is fixed to the front cover 2, and a fluid chamber is formed by the front cover 2 and the impeller 3. The turbine 4 is disposed so as to face the impeller 3 in the fluid chamber. The turbine 4 includes a turbine shell 41, a plurality of turbine blades 42 fixed to the turbine shell 41, and a turbine hub 43 fixed to the turbine shell 41 by rivets 44. The turbine hub 43 is connected to an input shaft of a transmission (not shown). The stator 5 is a mechanism for adjusting the flow of hydraulic oil from the turbine 4 to the impeller 3, and is disposed between the impeller 3 and the turbine 4.

<Configuration of lock-up device>
The lockup device 6 is a device for mechanically connecting the front cover 2 and the turbine 4 as necessary, and is disposed between the front cover 2 and the turbine 4 as shown in FIG. As shown in FIG. 2, the lock-up device 6 includes a piston 61, a holding plate 62 (an example of a holding member), an output plate 67 (an example of an output member), an intermediate plate 63 (an example of an intermediate member), Eight first coil spring sets 65 (an example of a first elastic member) and eight second coil spring sets 66 (an example of a second elastic member) are provided.

(1) Piston The piston 61 is a member for switching the connection between the front cover 2 and the turbine 4 and is provided to be pressed against the front cover 2 by the action of hydraulic pressure. Specifically, the piston 61 is supported by the turbine hub 43 of the turbine 4 so as to be axially movable and relatively rotatable. On the side of the piston 61 on the engine side (the side opposite to the intermediate plate 63), an annular friction facing 71 and a balance weight 70 disposed between the rotation directions of adjacent first rivets 72 (described later) are provided. It is fixed.

(2) Holding plate The holding plate 62 is a member for supporting the end portion of the first coil spring set 65 (more specifically, the spring seat 65c attached to the end portion of the first coil spring set 65) in the rotation direction. Yes, and fixed to the piston 61 by eight first rivets 72 (an example of a first fixing member). Specifically, the holding plate 62 has eight input support portions 62b. The input support portion 62b is disposed between the ends of the first coil spring set 65, and rotates in the direction of rotation with the end of the first coil spring set 65 (more specifically, the spring seat 65c of the first coil spring set 65). Can be contacted.

(3) Intermediate plate The intermediate plate 63 is disposed so as to be rotatable with respect to the piston 61 and the output plate 67. Specifically, the intermediate plate 63 includes a first intermediate plate 64, a second intermediate plate 68 fixed to the first intermediate plate 64, and eight pieces that fix the second intermediate plate 68 to the first intermediate plate 64. And a second rivet 73.

  The first intermediate plate 64 includes a first intermediate plate body 64a disposed radially inward of the first coil spring set 65, and an output claw 64b (an example of a drive claw) extending radially outward from the first intermediate plate body 64a. And eight first support protrusions 64p. The first intermediate plate body 64 a has an intermediate tapered surface 64 d formed so as to face the first coil spring set 65. The output claw 64b can contact the spring seat 65c of the first coil spring set 65 in the rotation direction. The intermediate tapered surface 64d is inclined with respect to the axial direction.

  The first support protrusions 64p are formed by embossing, for example, and are arranged at an equal pitch in the rotation direction. The first support protrusion 64p protrudes toward the axial transmission side (output plate 67 side), and supports the output plate 67 in the axial direction.

  The first intermediate plate 64 has a first inner tapered surface 64 c formed so as to face the turbine 4. The first inner tapered surface 64c is inclined with respect to the axial direction.

  The second intermediate plate 68 is disposed radially inward of the first coil spring set 65 and between the first intermediate plate 64 and the piston 61 in the axial direction. Specifically, the second intermediate plate 68 includes a second intermediate plate main body 68a, eight second storage portions 68e (an example of a storage portion), eight openings 68b, and lateral sides of the openings 68b in the rotation direction. The eight abutting portions 68c disposed on the right side and the eight second supporting projections 68p.

  The thickness of the second intermediate plate 68 is different from the thickness of the first intermediate plate 64. Specifically, as shown in FIGS. 3 to 5, the thickness of the second intermediate plate 68 is thinner than the thickness of the first intermediate plate 64.

  The opening 68 b is formed in the second intermediate plate 68. A protrusion 67b is inserted into the opening 68b. The rotation direction center C1 (FIG. 2) of the opening 68b is disposed between the rotation directions of the adjacent second accommodating portions 68e. The number of openings 68b is the same as the number of second accommodating portions 68e. The outer diameter of the opening 68b is larger than the outer diameter of the protrusion 67b. The second support protrusion 68p protrudes toward the axial transmission side (output plate 67 side), and supports the output plate 67 in the axial direction.

  The contact portion 68c is a plate-like portion and is inclined with respect to the axial direction. Specifically, the contact portion 68c is inclined so that the inner diameter decreases from the first intermediate plate 64 side to the piston 61 side. In the present embodiment, the angle between the axial direction and the contact portion 68c is about 45 degrees. The abutting portion 68c can abut on the protruding portion 67b in the rotation direction.

  The second support protrusions 68p are formed by embossing, for example, and are arranged at an equal pitch in the rotation direction. The second support protrusion 68p is disposed on the opposite side of the output plate 67 from the first support protrusion 64p. That is, the output plate 67 is sandwiched in the axial direction by the first support protrusion 64p and the second support protrusion 68p.

  The second intermediate plate 68 further has a second inner tapered surface 68d formed to face the piston 61. The second inner tapered surface 68d is inclined with respect to the axial direction.

(4) Output Plate The output plate 67 is a member connected to the turbine 4 so as to be able to rotate integrally with the turbine 4, and is fixed to the turbine hub 43 by eight third rivets 74. The output plate 67 has an output plate body 67a having eight second housing portions 68e for housing the second coil spring set 66, a projecting portion 67b projecting radially outward from the output plate body 67a, and projecting in the axial direction. And eight support portions 67c.

  The output plate 67 is disposed between the first intermediate plate 64 and the second intermediate plate 68 in the axial direction. The output plate 67 is supported in the axial direction by the first support protrusion 64p and the second support protrusion 68p.

  The support portion 67c supports the intermediate plate 63 (more specifically, the first intermediate plate 64) in the radial direction. The support portions 67c are arranged at an equal pitch in the rotation direction, and are formed by, for example, pressing.

  The output plate 67 further has a hole 67e through which the third rivet 74 passes and the portion on the piston 61 side is tapered. The hole 67e has a tapered surface 67f on the engine side (piston 61 side). The taper surface 67f is in contact with the third head 74a of the third rivet 74. That is, a part of the third head 74a is accommodated in the hole 67e. For this reason, the third head 74 a hardly protrudes from the output plate 67 in the axial direction.

  Further, the piston 61 has a thin portion 61e having a reduced axial thickness at a position facing the third rivet 74 in the axial direction. It can be said that the thin portion 61e is formed by an annular recess 61f provided on the transmission side.

(5) First coil spring set The first coil spring set 65 is a member for elastically connecting the piston 61 and the output plate 67 in the rotational direction, and is supported mainly by the holding plate 62 so as to be elastically deformable in the rotational direction. Has been. Movement of the first coil spring set 65 outward in the radial direction is restricted by the holding plate 62. A pair of spring seats 65 c is attached to the end of the first coil spring set 65.

  The first coil spring set 65 includes a first parent spring 65a and a first child spring 65b. The first child spring 65b is disposed inside the first parent spring 65a. As shown in FIG. 2, since the free length L12 of the first child spring 65b is shorter than the free length L11 of the first parent spring 65a, a two-stage characteristic can be realized by the first coil spring set 65 (described later).

(6) Second Coil Spring Set The second coil spring set 66 is a member for elastically connecting the intermediate plate 63 to the output plate 67 and is supported by the intermediate plate 63 so as to be elastically deformable in the rotational direction. In the present embodiment, the second coil spring set 66 is disposed radially inward from the first coil spring set 65. The number of second coil spring sets 66 is the same as the number of first coil spring sets 65.

  The second coil spring set 66 includes a second parent spring 66a and a second child spring 66b. The second child spring 66b is disposed inside the second parent spring 66a. Unlike the case of the first coil spring set 65, the free length L22 of the second child spring 66b is the same as the free length L21 of the second parent spring 66a. For this reason, the second parent spring 66a and the second child spring 66b are always compressed in parallel.

(7) First rivet and second rivet The first rivet 72 is a member for fixing the holding plate 62 to the piston 61, and a first body 72a penetrating the holding plate 62 and the piston 61 in the axial direction; A first head 72b disposed on the output rotating body side of the first body 72a and having a larger outer diameter than the first body 72a, and a first head disposed on the opposite side of the first body 72a from the first head 72b. And a caulking portion 72c. The first caulking part 72c has an outer diameter larger than that of the first body part 72a, but is smaller than that of the first head part 72b.

  The second rivet 73 is a member for connecting the first intermediate plate 64 and the second intermediate plate 68, and a second body portion 73 a penetrating the first intermediate plate 64 and the second intermediate plate 68 in the axial direction; A second head 73b disposed on the output rotating body side of the second body 73a and having a larger outer diameter than the second body 73a, and a second disposed on the opposite side of the second body 73a from the second head 73b. And a crimping portion 73c. The second caulking portion 73c has an outer diameter larger than that of the second body portion 73a and smaller than that of the second head portion 73b. The outer diameter of the second body portion 73a is smaller than the outer diameter of the first body portion 72a.

  When viewed from the axial direction, the second rivet 73 is disposed at a position that does not overlap the first rivet 72 between the rotation directions of the adjacent first rivets 72 even when the lockup device 6 is operated. The first rivet 72 is disposed so as to overlap at least a part of the second rivet 73 in the rotation direction. In other words, the intermediate plate 63 is arranged quite close to the piston 61 and the holding plate 62.

  Further, the same number of second rivets 73 as the first rivets 72 (eight in the present embodiment) are provided. The number of first coil spring sets 65 is the same as the number of first rivets 72. In a state where no power is applied to the piston 61, the second rivet 73 is disposed at substantially the same rotational position as the output claw 64b.

<Torsion characteristics>
As described above, the piston 61, the first coil spring set 65, and the intermediate plate 63 form the first damper portion D1. The intermediate plate 63, the second coil spring set 66, and the output plate 67 form a second damper portion D2.

  Here, the torsional characteristics of the damper mechanism of the lockup device 6 will be described with reference to FIG. FIG. 6 shows the torsional characteristics of the damper mechanism of the lockup device 6.

  As shown in FIG. 6, in this lockup device 6, the maximum torsional torque of the second damper part D2 is set smaller than the torsional torque when the compression of the first child spring 65b of the first damper part D1 is started. ing. Specifically, the first damper portion D1 and the second damper portion D2 operate in series up to point A in FIG. More specifically, the first parent spring 65a and the second coil spring set 66 are compressed in series. For this reason, in the first stage of torsional characteristics (range from the origin to point A), torsional characteristics with low torsional rigidity can be obtained. At the point A, the projecting portion 67b and the contact portion 68c are contacted in the rotation direction, so that the operation of the second damper portion D2 stops.

  In the second stage of torsional characteristics (range from point A to point B), only the first parent spring 65a of the first damper portion D1 is compressed, so that the torsional rigidity is slightly higher than in the first stage. When the twist angle reaches point B, the first parent spring 65a and the first child spring 65b of the first damper portion D1 are compressed in parallel. For this reason, the torsional rigidity is further increased in the third stage of the torsional characteristics (range from point B to point C).

  Thus, since the maximum torsional torque of the second damper part D2 is set smaller than the torsional torque when the compression of the first child spring 65b of the first damper part D1 is started, the torsion angle is relatively wide. Can be secured.

<Operation of torque converter>
When the front cover 2 and the impeller 3 are rotating, the hydraulic oil flows from the impeller 3 to the turbine 4, and power is transmitted from the impeller 3 to the turbine 4 through the hydraulic oil. The power transmitted to the turbine 4 is transmitted to an input shaft (not shown) via the turbine hub 43.

  When the rotational speed of the input shaft becomes substantially constant, power transmission via the lockup device 6 is started. Specifically, the piston 61 moves to the engine side due to a change in hydraulic pressure, and the friction facing 71 is pressed against the front cover 2. As a result, the piston 61 rotates integrally with the front cover 2, and power is transmitted from the front cover 2 to the holding plate 62 via the piston 61.

  When power is transmitted to the holding plate 62, a first coil spring set 65 and a second coil spring set 66 (more specifically, a first parent spring 65a and a second coil spring set 66 between the holding plate 62 and the output plate 67). ) Are compressed in series through the intermediate plate 63 in the rotational direction. When the relative rotation between the piston 61 and the output plate 67 proceeds, the protruding portion 67b of the output plate 67 moves in the rotation direction in the opening 68b, and the protruding portion 67b contacts the contact portion 68c in the rotation direction. As a result, the relative rotation between the output plate 67 and the intermediate plate 63 stops, and the operation of the second damper portion D2 stops.

  When the relative rotation between the piston 61 and the output plate 67 further proceeds, the compression of the first parent spring 65a is continued between the piston 61 and the intermediate plate 63. When the length of the first parent spring 65a becomes the same as the free length L12 of the first child spring 65b, the first parent spring 65a and the first child spring 65b are compressed in parallel. When the first coil spring set 65 is completely compressed and the lines are in close contact with each other, the operation of the first damper portion D1 is stopped, and power is directly transmitted from the front cover 2 to the turbine 4.

<Features>
The features of the lockup device 6 described above are summarized below.

(1)
In this lockup device 6, since the rotation direction center C1 of the opening 68b of the intermediate plate 63 is disposed between the rotation directions of the adjacent second storage portions 68e, the intermediate plate 63 is formed by the opening 68b and the second storage portion 68e. It can suppress that the intensity | strength of this falls. As a result, the lockup device 6 can suppress a decrease in strength.

(2)
In this lockup device 6, since the number of the openings 68b is the same as the number of the second accommodating portions 68e, the openings 68b and the second accommodating portions 68e can be efficiently formed in the second intermediate plate 68. A decrease in strength of the intermediate plate 68 can be suppressed.

(3)
In this lockup device 6, since the outer diameter of the opening 68b is larger than the outer diameter of the protrusion 67b, the protrusion 67b does not interfere with the opening 68b when the intermediate plate 63 and the output plate 67 are assembled in the axial direction. Thereby, in this lockup device 6, assembly property can be improved.

(4)
In this lockup device 6, since the plate-like contact portion 68c is inclined with respect to the axial direction, the contact portion 68c and the contact portion 68c are compared with the case where the contact portion 68c is not inclined with respect to the axial direction. It becomes easy to ensure a wide contact area with the protrusion 67b. Thereby, abrasion of the contact part 68c and the protrusion part 67b can be suppressed.

  In particular, in this embodiment, even if the plate thickness of the second intermediate plate 68 is reduced, a wide contact area between the contact portion 68c and the protruding portion 67b can be ensured.

(5)
Since the opening 68b is formed in the second intermediate plate 68, it is necessary to bend the periphery of the opening 68b of the second intermediate plate 68 in the axial direction in order to insert the protruding portion 67b. For this reason, the axial dimension of the second intermediate plate 68 tends to increase.

  However, in this lockup device 6, since the second intermediate plate 68 is disposed on the piston 61 side of the first intermediate plate 64 on the radially inner side of the first coil spring set 65, the radius of the first coil spring set 65 is set. The increase in the axial dimension of the second intermediate plate 68 can be absorbed by using the space inside the direction. That is, the lockup device 6 can suppress an increase in axial dimension.

(6)
In this lockup device 6, the thickness of the first intermediate plate 64 is different from the thickness of the second intermediate plate 68, so that the first intermediate plate 64 and the second intermediate plate 68 have the same thickness. The axial dimension of the entire intermediate plate 63 can be shortened.

  In particular, in this embodiment, since the plate thickness of the second intermediate plate 68 is smaller than the plate thickness of the first intermediate plate 64, the axial dimension of the entire intermediate plate 63 can be shortened.

  Further, since the first intermediate plate 64 having a large thickness is provided with an output claw 64b capable of coming into contact with the end of the first coil spring set 65 in the rotation direction, the output is output to the second intermediate plate 68 having a small thickness. The strength of the output claw 64b can be increased as compared with the case where the claw 64b is provided.

(7)
In the lockup device 6, since the first intermediate plate body 64a has an intermediate tapered surface 64d formed so as to face the first coil spring set 65, the first coil spring set 65 is provided with the first intermediate plate body 64a. Interference with can be suppressed.

(8)
In the lockup device 6, the first intermediate plate 64 has the first support protrusion 64 p that supports the output plate 67 in the axial direction, and the second support protrusion 68 p that supports the output plate 67 in the axial direction. Since the second intermediate plate 68 has, the contact area between the intermediate plate 63 and the output plate 67 can be reduced. Thereby, the frictional resistance generated between the intermediate plate 63 and the output plate 67 can be reduced, and the generation of a large hysteresis torque can be prevented.

(9)
In the lockup device 6, since the support protrusion is disposed between the rotation directions of the adjacent second holding portions, the support protrusion can be formed on a relatively wide flat plate-like portion. Thereby, the moldability of a support protrusion can be improved.

(10)
In the lockup device 6, the second rivet 73 is disposed at a position that does not overlap the first rivet 72 between the rotation directions of the adjacent first rivets 72 when viewed from the axial direction. The plate 63 can be arranged close to the axial direction. Thereby, the axial direction dimension of the lockup apparatus 6 can be shortened.

(11)
In the lockup device 6, since the first rivet 72 is disposed so as to overlap with at least a part of the second rivet 73 in the rotation direction, the dimension in the axial direction can be further shortened.

(12)
In the lockup device 6, since the number of the first coil spring sets 65 is the same as the number of the first rivets 72, the strength around the portion holding the first coil spring sets 65 can be efficiently increased.

(13)
In this lockup device, since the second rivet 73 is disposed at substantially the same rotational position as the output claw 64b in a state where no power is applied to the piston 61, the strength around the output claw 64b to which power is transmitted. Can be improved efficiently.

(14)
In this lockup device, since the outer diameter of the second barrel portion 73a is smaller than the outer diameter of the first barrel portion 72a, the intermediate plate 63 can be reduced in weight.

(15)
In the lockup device 6, the first intermediate plate 64 has the first inner tapered surface 64 c formed so as to face the turbine 4, and therefore the first intermediate plate 64 interferes with the turbine shell 41. The first intermediate plate 64 can be disposed close to the turbine 4 while preventing the above. That is, the axial dimension of the entire lockup device 6 can be shortened.

(16)
In this lockup device 6, since the second intermediate plate 68 has the second inner tapered surface 68d formed so as to be inclined with respect to the axial direction and opposed to the piston 61, the second intermediate plate 68 is a turbine. 4, the second intermediate plate 68 can be disposed close to the piston 61 while preventing interference with the piston 4. That is, the axial dimension of the entire lockup device 6 can be shortened.

(17)
In the lockup device 6, since the output plate 67 has the hole 67e having the tapered surface 67f on the piston 61 side, the third head 74a of the third rivet 74 can be accommodated in the hole 67e. Thereby, it can suppress that the 3rd rivet 74 protrudes from the output plate 67, and the axial direction dimension of the lockup apparatus 6 whole can be shortened.

(18)
In the lockup device 6, the piston 61 has a thin portion 61 e with a reduced axial thickness at a position facing the third rivet 74 in the axial direction, and therefore the piston 61 interferes with the third rivet 74. It is possible to dispose the piston 61 close to the output plate 67 while preventing this. That is, the axial dimension of the entire lockup device 6 can be shortened.

(19)
In this lock-up device 6, the balance weight 70 is disposed between the rotation directions of the adjacent first rivets 72, so that the balance weight 70 has the same thickness as the first caulking portion 72 c of the first rivet 72. Can be prevented from projecting to the piston 61 side from the first caulking portion 72c. Thereby, it can suppress that the axial direction dimension of the lockup apparatus 6 increases with the balance weight 70. FIG.

  Further, since the balance weight 70 is fixed to the engine side surface of the piston 61 (the side surface opposite to the intermediate plate 63), the work of attaching the balance weight 70 becomes easy.

(20)
In this lockup device 6, since the free length of the first child spring 65b is shorter than the free length of the first parent spring 65a, when the first coil spring set 65 is compressed, the first parent spring 65a is first compressed, Next, the first child spring 65b and the first parent spring 65a are compressed in parallel. For this reason, a two-stage characteristic can be realized with a simple configuration, and the angle of torsional characteristics can be widened.

(21)
The lockup device 6 has a simple configuration because the maximum torque of the second damper portion D2 is set to be smaller than the torque when the first child spring 65b of the first damper portion D1 starts to be compressed. Thus, a three-stage characteristic can be realized. Thereby, it is possible to widen the torsional characteristics with a simple configuration.

(22)
In the lockup device 6, since the intermediate plate 63 is supported in the radial direction by the eight support portions 67c, the posture of the intermediate plate 63 with respect to the output plate 67 is stabilized. As a result, the operation of the intermediate plate 63 is stabilized, and the vibration damping performance of the lockup device 6 is stabilized.

(23)
In the lockup device 6, since the support portion 67c is formed by press working, vibration damping performance can be stabilized while suppressing an increase in manufacturing cost.

<Other embodiments>
The specific configuration of the present invention is not limited to the above-described embodiment, and various modifications and changes can be made without departing from the scope of the invention.

(1)
The quantity of each part is not limited to the above-mentioned embodiment.

(2)
For example, in the above-described embodiment, the number of openings 68b is the same as the number of second accommodating portions 68e, but the number of openings 68b may be smaller than the number of second accommodating portions 68e. In this case, the strength reduction of the intermediate plate 63 can be further suppressed.

(3)
In the above-described embodiment, the number of openings 68b is the same as the number of second accommodating portions 68e, but the number of openings 68b may be smaller than the number of second accommodating portions 68e. In this case, the strength of the second intermediate plate 68 can be increased as compared with the above-described embodiment, but the number of the contact portions 68c is reduced, so that the load applied to the protrusions 67b and the contact portions 68c is increased.

(4)
The number of support portions 67c is not limited to the above-described embodiment. The support part 67c should just be provided in two or more places.

(5)
In the above-described embodiment, the first intermediate plate 64 has eight first support protrusions 64p, and the second intermediate plate 68 has eight second support protrusions 68p. It is sufficient that at least one of the second intermediate plate 68 has a support protrusion.

  Further, the number of support protrusions is not limited to the above-described embodiment. The number of the first support protrusions 64p may be one or more, and the number of the second support protrusions 68p may be one or more. If the first support protrusions 64p and the second support protrusions 68p are provided at a plurality of locations, the posture of the output plate 67 with respect to the intermediate plate 63 is easily stabilized.

(6)
In the above-described embodiment, the outer diameter of the second body portion 73a is smaller than the outer diameter of the first body portion 72a, but the outer diameter of the second body portion 73a is the same as the outer diameter of the first body portion 72a. Also good.

(7)
In the above-described embodiment, the number of the first coil spring sets 65 is the same as the number of the second coil spring sets 66, but the number of the first coil spring sets 165 is the same as the lock-up device 106 shown in FIGS. The number may be larger than the number of second coil spring sets 166. Specifically, as shown in FIGS. 7 and 8, the lockup device 106 includes ten first coil spring sets 165 and eight second coil spring sets 166. Even in this case, the same effects as those of the lockup device 6 described above can be obtained.

(8)
Although the hole 67e of the output plate 67 has a tapered surface 67f, if the third head 74a of the third rivet 74 is accommodated in the hole 67e, the hole 67e may have a counterbore shape. Good.

(9)
The maximum torque of the second damper part D2 may be the same as the torque when the compression of the first child spring 65b of the first damper part D1 is started. In this case, as shown in FIG. 9, the points A and B of the torsional characteristics shown in FIG. 6 are at the same position on the graph. Even in this case, the torsion angle can be set relatively large.

(10)
In the above-described embodiment, the torque converter 1 is described as an example of the fluid power transmission device. However, the fluid power transmission device may be a fluid coupling that does not include the stator 5.

Torque converter vertical cross section Top view of the lock-up device III-III sectional view of FIG. Sectional view of the lock-up device (upper half of Fig. 3) Cross-sectional view of the lock-up device (lower half of Fig. 3) Torsional characteristic diagram of lock-up device Top view of lock-up device (another embodiment) VIII-VIII sectional view of FIG. 7 (another embodiment) Torsional characteristic diagram of lock-up device (another embodiment)

Explanation of symbols

1 Torque converter (an example of a fluid power transmission device)
2 Front cover (example of input rotating body)
3 Impeller 4 Turbine (an example of output rotor)
5 Stator 6 Lock-up device 61 Piston 62 Holding plate (an example of a holding member)
63 Intermediate plate (an example of an intermediate member)
64 1st intermediate plate (an example of the 1st intermediate member)
64a First intermediate plate body 64b Output claw (an example of a driving claw)
64c 1st inside taper surface 64d Intermediate taper surface 64e 1st accommodating part 64p 1st support protrusion 65 1st coil spring set (an example of the 1st elastic member)
65a First parent spring 65b First child spring 66 Second coil spring set (an example of a second elastic member)
66a Second parent spring 66b Second child spring 67 Output plate (an example of an output member)
67a Output plate body 67b Protruding portion 67c Supporting portion 67e Hole 67f Tapered surface 68 Second intermediate plate (an example of a second intermediate member)
68a 2nd intermediate plate main body 68b Opening 68c Contact part 68d 2nd inner side taper surface 68e 2nd accommodating part (an example of an accommodating part)
68p 2nd support protrusion

Claims (27)

A lockup device for mechanically coupling an input rotator to an output rotator,
A piston provided to be pressed against the input rotating body by the action of hydraulic pressure;
An output member fixed to the output rotating body;
An intermediate member disposed rotatably with respect to the piston and the output member;
A plurality of first elastic members that elastically connect the piston and the intermediate member in a rotational direction;
A plurality of second elastic members that elastically connect the intermediate member and the output member in the rotational direction;
The output member has an output member main body, and a protruding portion that protrudes radially outward from the output member main body,
The intermediate member has a plurality of storage portions that store the second elastic member, and an opening in which the center of the rotation direction is disposed between the rotation directions of the adjacent storage portions into which the protrusions are inserted , and
The intermediate member is a first intermediate member and a second intermediate member disposed radially between the first elastic member and between the first intermediate member and the piston and fixed to the first intermediate member. An intermediate member,
The opening is formed in the second intermediate member;
The output member is disposed between axial directions of the first intermediate member and the second intermediate member,
At least one of the first intermediate member and the second intermediate member has at least one support protrusion that protrudes toward the output member in the axial direction and supports the output member in the axial direction.
Lock-up device. The number of the openings is the same as the number of the accommodating portions or less than the number of the accommodating portions.
The lockup device according to claim 1. The outer diameter of the opening is larger than the outer diameter of the protrusion,
The lockup device according to claim 1 or 2. The intermediate member further includes a plate-like contact portion that is disposed on the side of the opening in the rotation direction and that can contact the protruding portion in the rotation direction.
The contact portion is inclined with respect to the axial direction;
The lockup device according to any one of claims 1 to 3. The plate thickness of the first intermediate member is different from the plate thickness of the second intermediate member.
The lockup device according to claim 1 . The plate thickness of the second intermediate member is smaller than the plate thickness of the first intermediate member.
The lockup device according to claim 5 . The first intermediate member includes a first intermediate member body disposed radially inward of the first elastic member, an end portion of the first elastic member extending in a radial direction from the first intermediate member body, and a rotation direction. A driving claw capable of abutting on,
The lockup device according to claim 6 . The first intermediate member main body has an intermediate tapered surface that is formed on an outer peripheral portion so as to face the first elastic member and is inclined with respect to the axial direction.
The lockup device according to claim 7 . The second intermediate member includes a plurality of second holding portions that hold the second elastic member, and the support protrusions that are disposed between the rotation directions of the adjacent second holding portions.
The lockup device according to claim 1 . A holding member that is fixed to the piston and holds the first elastic member; and a plurality of first fixing members that fix the holding member to the piston;
The intermediate member is provided in the same number as the first fixing member, and further includes a plurality of second fixing members that fix the second intermediate member to the first intermediate member,
When viewed from the axial direction, the second fixing member is disposed at a position that does not overlap the first fixing member between the rotation directions of the adjacent first fixing members.
The lockup device according to claim 1 . The first fixing member is disposed so as to overlap with at least a part of the second fixing member in the rotation direction.
The lockup device according to claim 10 . The number of the first elastic members is the same as the number of the first fixing members.
The lockup device according to claim 10 or 11 . The first fixing member is disposed on the output rotating body side of the first body part and has a larger outer diameter than the first body part. The first body part penetrates the holding member and the piston in the axial direction. One head and a first caulking portion that is disposed on the opposite side of the first torso from the first torso and has a larger outer diameter than the first torso and a smaller outer diameter than the first head; Have
The second fixing member is disposed on a side of the output rotating body of the second body part, the second body part passing through the first intermediate member and the second intermediate member in the axial direction, and more than the second body part. A second head having a large outer diameter and a second head disposed on the opposite side of the second body from the second head and having an outer diameter larger than that of the second body and smaller than the second head. 2 crimping parts,
The lockup device according to any one of claims 10 to 12 . The first intermediate member includes a first intermediate member body disposed radially inward of the first elastic member, an end portion of the first elastic member extending in a radial direction from the first intermediate member body, and a rotation direction. And a driving claw capable of contacting the
In a state where no power is applied to the piston, the second fixing member is disposed at substantially the same rotational direction position as the drive claw.
The lockup device according to any one of claims 10 to 13 . The outer diameter of the second body part is the same as or smaller than the outer diameter of the first body part,
The lockup device according to any one of claims 10 to 14 . The first intermediate member has a first tapered surface formed on an inner peripheral portion so as to be inclined with respect to the axial direction and face the output rotating body.
The lockup device according to claim 1 . The second intermediate member has a second tapered surface formed on an inner peripheral portion so as to be inclined with respect to the axial direction and to face the piston.
The lockup device according to claim 1 . The number of the first elastic members is the same as the number of the second elastic members or more than the number of the second elastic members.
The lockup device according to any one of claims 1 to 17 . A lockup device for mechanically coupling an input rotator to an output rotator,
A piston provided to be pressed against the input rotating body by the action of hydraulic pressure;
An output member fixed to the output rotating body;
An intermediate member disposed rotatably with respect to the piston and the output member;
A plurality of first elastic members that elastically connect the piston and the intermediate member in a rotational direction;
A plurality of second elastic members that elastically connect the intermediate member and the output member in the rotational direction;
The output member has an output member main body, and a protruding portion that protrudes radially outward from the output member main body,
The intermediate member has a plurality of storage portions that store the second elastic member, and an opening in which the center of the rotation direction is disposed between the rotation directions of the adjacent storage portions into which the protrusions are inserted, and
A third fixing member for fixing the output member to the output rotating body;
The output member has a hole through which the third fixing member passes and a portion on the piston side has a tapered shape or a counterbore shape .
Russia Kkuappu apparatus. The piston has a thin portion with a reduced axial thickness at a position facing the third fixing member in the axial direction.
The lockup device according to claim 19 . An adjustment member disposed between the rotation directions of the first fixing members fixed to the side surface of the piston and adjacent thereto;
The lockup device according to any one of claims 10 to 13 . The adjusting member is fixed to a side surface of the piston opposite to the intermediate member;
The lockup device according to claim 21 . The first elastic member includes a first parent spring, and a first child spring that is disposed inside the first parent spring and has a shorter free length than the first parent spring,
The second elastic member includes a second parent spring and a second child spring that is disposed inside the second parent spring and has the same free length as the second parent spring.
The lockup device according to any one of claims 1 to 22 . A first damper portion is formed by the piston, the first elastic member, and the intermediate member,
A second damper portion is formed by the intermediate member, the second elastic member, and the output member,
The maximum torsion torque of the second damper portion is set to be equal to or less than the torsion torque when the compression of the first child spring of the first damper portion is started.
24. The lockup device according to claim 23 . The output member further includes a plurality of support portions protruding in an axial direction from the output member main body,
The intermediate member is supported in the radial direction by the plurality of support portions.
The lockup device according to any one of claims 1 to 24 . The support part is formed by press working.
The lockup device according to claim 25 . A front cover that functions as the input rotating body;
A turbine functioning as the output rotating body;
A lockup device according to any of claims 1 to 26 ;
A fluid type power transmission device.

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