JP5864480B2 - Fluid transmission device - Google Patents

Description

  The present invention relates to a fluid transmission device.

  The fluid transmission device is a device that once converts rotational power generated by a driving force from a driving source into fluid kinetic energy, and then converts the rotational power again into rotational power and transmits it to a driven shaft. As one type of such a fluid transmission device, a torque converter used in a vehicle such as an automobile is known. In a typical torque converter, the engine corresponds to a drive source, and the input shaft of the transmission corresponds to a driven shaft.

  In order to reduce the torque fluctuation transmitted from the engine to the transmission, the torque converter has a built-in damper mechanism. In order to effectively reduce the torque fluctuation, the elastic constant of an elastic body such as a spring constituting the damper mechanism may be lowered. To lower the elastic constant, it is effective to lengthen the elastic body. Therefore, a torque converter in which two damper mechanisms are connected in series is known (for example, see Patent Document 1).

  In order to ensure the durability of the damper mechanism, it is effective to limit an excessive load input to the elastic body. Therefore, a stopper mechanism may be provided so that the amount of contraction of the elastic body does not exceed a set value.

Japanese Patent No. 4559558

  However, in the torque converter of Patent Document 1, a dedicated member is required to connect the two damper mechanisms. Moreover, a dedicated member is required to provide the stopper mechanism. As a result, the number of parts is greatly increased, causing problems such as an increase in cost and an increase in weight.

  In view of the above, an object of the present invention is to provide a fluid transmission device capable of connecting two damper mechanisms and providing a stopper mechanism without significantly increasing the number of parts.

The present invention includes a pump impeller that rotates around a central axis by a driving force from a driving source, a turbine runner that rotates around the central axis by a flow of fluid generated by the rotation of the pump impeller, and a rotation of the turbine runner. An output member that transmits to the drive shaft, a lockup piston that is coupled to the pump impeller by a lockup clutch, and a first damper mechanism and a second damper mechanism that are interposed between the lockup piston and the output member. a fluid transmission device including, the first damper mechanism has a first holding portion of the plurality arranged along the circumferential direction of the central axis, first retaining coupled to the lock-up piston A member, a plurality of transmission members connected to the turbine runner, and the first holding unit and the transmission member; A plurality of first elastic bodies formed on the first holding member, and a plurality of first restricting portions that are engaged with the transmission member and restrict movement of the transmission member in the circumferential direction around the central axis. The second damper mechanism has a plurality of second holding portions arranged along a circumferential direction around the central axis, and is connected to the turbine runner via a connecting member, and the first holding member And a plurality of second elastic members respectively held between the second holding portion and the plurality of holding portions formed on the output member, and the output member. A plurality of second restricting portions that are formed and engage with the connecting member to restrict movement of the connecting member in the circumferential direction around the central axis.

  According to the present invention, the plurality of transmission members constituting the first damper mechanism are coupled to the turbine runner, and the second holding member constituting the second damper mechanism is coupled to the turbine runner via the plurality of coupling members. ing. In other words, the first damper mechanism and the second damper mechanism are coupled using the turbine runner, the plurality of transmission members, and the plurality of coupling members.

  Further, according to the present invention, the amount of contraction of the first elastic body is regulated from the plurality of first regulating portions formed on the first holding member and the plurality of transmission members respectively engaged with the first regulating portions. A stopper mechanism is configured. Moreover, the stopper mechanism which regulates the shrinkage | contraction amount of a 2nd elastic body is comprised from the some 2nd control part formed in the output member, and the some connection member which each engages with these 2nd control parts.

  Of the members for connecting the first damper mechanism and the second damper mechanism, the turbine runner is an essential member for the fluid transmission device, and the transmission member is also a member for holding the first elastic body, The connecting member is also a member for regulating the amount of contraction of the second elastic body.

  On the other hand, among the members constituting the two stopper mechanisms, the transmission member and the connecting member are also members for connecting the first damper mechanism and the second damper mechanism.

  Since the members are shared in this way, it is possible to connect the two damper mechanisms and provide the two stopper mechanisms without increasing the number of parts. Therefore, the number of parts does not increase significantly, and it is possible to prevent an increase in cost, an increase in weight, and the like.

Sectional drawing which shows the upper half of the torque converter which concerns on embodiment of the fluid transmission apparatus of this invention. The top view which shows the state which looked at the 1st damper mechanism from the turbine runner side to the cover side from the axial direction. The partially broken top view which shows the state which looked at the 2nd damper mechanism from the turbine runner side to the cover side from the axial direction. The graph which shows the characteristic of the twist angle and torque of a damper mechanism.

(Configuration of torque converter)
A configuration of the torque converter 10 according to the embodiment of the fluid transmission device of the present invention will be described.

  As shown in FIG. 1, the torque converter 10 includes three types of impellers, that is, a pump impeller 11, a turbine runner 12, a stator 13, and a cover 14. An annular path for circulating hydraulic oil is formed by the pump impeller 11, the turbine runner 12, and the stator 13.

  The torque converter 10 further includes a lock-up clutch 20 disposed between the turbine runner 12 and the cover 14 and two damper mechanisms 30 and 40.

  The pump impeller 11 is fixed to the cover 14 by welding. The cover 14 is connected to a driving shaft (engine crankshaft) (not shown) to which a driving force of a driving source such as an engine (not shown) is transmitted, and rotates around the central axis O as the driving shaft rotates.

  The turbine runner 12 is disposed so as to face the pump impeller 11, and has a fluid inflow port disposed in the vicinity of the fluid discharge port of the pump impeller 11. The stator 13 deflects the flow of hydraulic oil that flows into the pump impeller 11 from the turbine runner 12.

  The pump impeller 11 includes an outer pump shell 11a formed in a bowl shape, an inner pump core ring 11b, and a plurality of pump blades 11c whose base ends are fixed to the pump core ring 11b.

  The outer peripheral end of the pump shell 11 a is fixed to the cover 14. The inner peripheral end of the pump shell 11 a is fixed to the pump hub 15. Accordingly, the pump impeller 11 is formed in an annular shape and is configured to rotate around the central axis O.

  An output shaft (not shown) is disposed in the pump hub 15 so as to be rotatable around the central axis O. The output shaft is connected to an input shaft of a transmission (not shown) that is a driven shaft.

  The axial direction of the torque converter 10 is a direction in which the central axis O extends, and is also simply referred to as “axial direction” hereinafter. The circumferential direction of the torque converter 10 is a circumferential direction around the central axis O, and is hereinafter simply referred to as “circumferential direction”.

  The turbine runner 12 includes an outer turbine shell 12a formed in a bowl shape, an inner turbine core ring 12b, and a plurality of turbine blades 12c whose base ends are fixed to the turbine core ring 12b.

  The stator 13 is disposed so as to be sandwiched between the pump impeller 11 and the turbine runner 12.

  The stator 13 includes an inner core side ring 13a, an outer shell side ring 13b, and a plurality of stator blades 13c whose base end portions are fixed to the core side ring 13a. Each stator blade 13c is fixed to the outer peripheral surface of the core side ring 13a, and extends radially outward.

  The stator 13 is supported via a one-way clutch 17 by a fixed shaft that is supported by a housing so as not to rotate, although not shown. Further, thrust bearings 18 are arranged between the pump hub 15 and the core side ring 13a and between the turbine hub 16 and the core side ring 13a in the axial direction.

  The lockup clutch 20 includes an input side plate 21, a friction plate 22, and a hydraulic circuit (not shown) disposed between the cover 14 and the turbine runner 12. The input side plate 21 corresponds to the lockup piston of the present invention.

  The input side plate 21 is formed in a disk shape, and is supported on the outer peripheral surface of the turbine hub 16 so as to be slidable in the axial direction, and rotatably supported on the outer peripheral surface of the turbine hub 16 about the central axis O.

  The friction plate 22 is fixed to the surface on the cover 14 side of the radially outer portion of the input side plate 21. When the friction plate 22 is brought into contact with the cover 14, the input side plate 21 rotates integrally with the cover 14.

  The hydraulic circuit changes the hydraulic pressure inside the torque converter 10 to slide the input side plate 21 in the axial direction.

  Specifically, when the hydraulic pressure in the chamber on the left side of the input side plate 21 is lowered by the hydraulic circuit, the hydraulic pressure on the right side of the input side plate 21 becomes relatively high, and the input side plate 21 moves in the left direction in the figure. At this time, when the hydraulic pressure difference is increased, the friction plate 22 comes into contact with the cover 14, the cover 14 and the input side plate 21 rotate integrally, and the lockup clutch 20 is engaged.

  On the other hand, when the hydraulic pressure in the left chamber of the input side plate 21 is increased by the hydraulic circuit, the input side plate 21 moves to the right in the figure. At this time, the friction plate 22 does not come into contact with the cover 14, and the cover 14 and the input side plate 21 can freely rotate with each other, and the lockup clutch 20 is released.

  Thus, the lockup clutch 20 can be engaged and disengaged by changing the left and right hydraulic pressure of the input side plate 21 by the hydraulic circuit.

  The two damper mechanisms 30 and 40 are interposed between the input side plate 21 and the turbine hub 16. The first damper mechanism 30 is disposed on the radially outer side, and the second damper mechanism 40 is disposed on the radially inner side.

  As shown in FIGS. 1 and 2, the first damper mechanism 30 includes a first holding plate 31 positioned on the turbine runner 12 side from the input side plate 21, a plurality of transmission claws 32 connected to the turbine runner 12, A plurality of first springs 33 and a first stopper mechanism 34 are provided. The first holding plate 31 corresponds to the first holding member of the present invention, the transmission claw 32 corresponds to the transmission member of the present invention, and the first spring 33 corresponds to the first elastic body of the present invention.

  The first holding plate 31 is formed in a disk shape and is fixed to the input side plate 21 by rivets 35. The first holding plate 31 includes a plurality of accommodating portions 31a at the radially outer edge portion thereof. The accommodating part 31a is formed so as to be recessed toward the turbine runner 12 side. In the input side plate 21, a housing portion 21 a is formed at a position facing the housing portion 31 a of the first holding plate 31 so as to be recessed toward the cover 14.

  One first spring 33 is accommodated in each of the spaces formed by the two opposing accommodating portions 31a and 21a. The first spring 33 is a coil spring made of a metal material spirally wound so as to have an axial center extending in an arc shape.

  In the first holding plate 31, first holding portions 31 b that hold the first springs 33 are formed at intervals in the circumferential direction. The first holding portion 31b is formed as a claw portion extending straight from the portion fixed to the input side plate 21 to the outside in the radial direction, and the first spring 33 and the side surface of the claw portion come into contact with each other. 1 Spring 33 is held. The first holding part 31b corresponds to the first holding part of the present invention. And the notch part 31c is formed in the outer periphery of the accommodating part 31a of the circumferential direction both sides of the 1st holding | maintenance part 31b.

  The base ends of the plurality of transmission claws 32 are fixed to the outer surface on the radially outer side of the turbine shell 12a by welding at intervals in the circumferential direction. The claw portion 32 a at the tip of each transmission claw 32 protrudes toward the input side plate 21 and abuts against the other end of the first spring 33. Specifically, the claw portion 32a is inserted into a gap between the inner peripheral surface of the outer peripheral edge of the input side plate 21 and the outer peripheral end surface of the first holding portion 31b of the first holding plate 31. The cutout portions 31c on both sides are configured to be movable in the circumferential direction.

  Thus, both ends of the first spring 33 are in contact with the first holding portion 31b of the first holding plate 31 or the transmission claw 32, respectively.

  As shown in FIG. 2, when all the transmission claws 32 are located on the radially outer side of the first holding portion 31 b, the first spring 33 has both ends in the circumferential direction at the first holding portion 31 b of the first holding plate 31. And it is in contact with the transmission claw 32 and is in a neutral state.

  For example, when the input side plate 21 and the turbine runner 12 rotate relative to each other and the transmission claw 32 rotates counterclockwise with respect to the first holding plate 31, the input side plate 21 and the turbine runner 12 are positioned on the left side of the first holding portion 31b. The first spring 33 is pushed by the transmission claw 32 with which the right end abuts and becomes shorter than the neutral state. On the other hand, the first spring 33 located on the right side of the first holding portion 31b is kept in a state where the left end is separated from the transmission claw 32 but is in contact with the first holding portion 31b.

  At this time, torque is transmitted from the input side plate 21 to the transmission claw 32 via the first spring 33, and this torque is transmitted to the turbine runner 12. In this way, torque is transmitted from the input side plate 21 to the turbine runner 12.

  When the input side plate 21 and the transmission claw 32 are relatively rotated, the first spring 33 is pressed and contracted. If the first spring 33 is compressed too much, the first spring 33 cannot return to the neutral length due to excessive plastic deformation, and the performance of absorbing the torque fluctuation of the drive source decreases.

  Therefore, in the present embodiment, the movement of the transmission claw 32 that compresses and contracts the first spring 33 is restricted within the range of the notch 31c. This reliably prevents the first spring 33 from being compressed too much.

  The circumferential length of the notch 31c is the maximum relative rotation angle between the input side plate 21 and the first holding plate 31 so that the first spring 33 obtained in advance through experiments or the like is within an angle range in which the first spring 33 is not plastically deformed. It may be set so as to regulate.

  As shown in FIGS. 1 and 3, the second damper mechanism 40 includes two second holding plates 41 positioned on the turbine hub 16 side from the first holding plate 31, an output side plate 42, and a plurality of second plates. And a spring 43. The second holding plate 41 corresponds to the second holding member of the present invention, the output side plate 42 corresponds to the output member of the present invention, and the second spring 43 corresponds to the second elastic body of the present invention.

  The two second holding plates 41 are fixed by rivets 45 at their outer end portions. Further, the two second holding plates 41 sandwich the output side plate 42 between the inner end portions thereof, and the plate-like end portion where the turbine shell 12a of the turbine runner 12 is extended is on the turbine runner 12 side. Are fixed by rivets 46 respectively inserted into a plurality of through holes 42 a formed in the output side plate 42.

  The through-holes 42a are formed in an arc shape at intervals in the circumferential direction inside the output side plate 42 in the radial direction. The rivet 46 corresponds to the connecting member of the present invention.

  The output side plate 42 is fixed to the turbine hub 16 by welding. Accordingly, the two second holding plates 41 rotate integrally with the turbine runner 12, the two second holding plates 41 and the output side plate 42 can rotate with each other, and the output side plate 42 is a turbine hub. 16 and rotate together.

  The two second holding plates 41 are configured symmetrically in the axial direction. The two second holding plates 41 are each formed with a notch 41a at a radially intermediate portion with a circumferential interval. The output side plate 42 is formed with a notch 42b at a radially outer portion with a circumferential interval.

  The second spring 43 is accommodated in an accommodating portion defined by the notch portion 42b and two notch portions 41a located on both sides in the axial direction, and is circumferentially formed by the two second holding plates 41 and the output side plate 42. It is held so as to be pinched. The second spring 43 is a coil spring made of a metal material spirally wound so as to have a linear axis.

  In this manner, both ends of the second spring 43 are in contact with either the circumferential end surface of the notch 41a or the circumferential end surface of the notch 42b.

  As shown in FIG. 3, when the second spring 43 is in a neutral state, both ends of the second spring 43 are in contact with the circumferential end surface 41b of the notch 41a and the circumferential end surface 42c of the notch 42b, respectively. Yes. The circumferential end surface 41b of the notch 41a corresponds to the second holding portion of the present invention, and the circumferential end surface 42c of the notched portion 42b corresponds to the holding portion of the present invention.

  For example, when the turbine runner 12 and the turbine hub 16 rotate relative to each other and the output side plate 42 rotates counterclockwise with respect to the two second holding plates 41, the second spring 43 moves to the left end. Is in contact with the circumferential end surface 41b of the notch 41a of the second holding plate 41, and its right end is in contact with the circumferential end surface 42c of the notch 42b of the output side plate 42, which is shorter than the neutral state.

  At this time, torque is transmitted from the turbine runner 12 to the output side plate 42 via the second spring 43, and this torque is transmitted to the turbine hub 16. In this way, torque is transmitted from the turbine runner 12 to the turbine hub 16. Then, torque is transmitted from the turbine hub 16 to the input shaft of the transmission via the output shaft.

  When the turbine runner 12 and the turbine hub 16 rotate relative to each other, the second spring 43 is compressed. If the second spring 43 is compressed too much, the second spring 43 cannot return to the neutral length due to excessive plastic deformation, and the performance of absorbing the torque fluctuation of the drive source is reduced.

  Therefore, in the present embodiment, the range of movement of the rivet 46 fixed to the turbine runner 12 is limited to the through hole 42 a formed in the output side plate 42 fixed to the turbine hub 16, whereby the turbine runner 12 is moved. The relative rotation of the turbine hub 16 is restricted. This reliably prevents the second spring 43 from being compressed too much. As described above, the second stopper mechanism 44 includes the through hole 42 a formed in the output side plate 42 and the rivet 46. The through hole 42a corresponds to the second restricting portion of the present invention.

  The length in the circumferential direction of the through hole 42a is set to a maximum relative relationship between the two second holding plates 41 and the output side plate 42 so that the second spring 43 is obtained in an angle range in which the second spring 43 is not plastically deformed. What is necessary is just to set so that a rotation angle may be controlled.

(Torque converter operation)
Next, the operation of the torque converter 10 configured as described above will be described.

  When the lock-up clutch 20 is released (when the friction plate 22 and the cover 14 are separated), the torque of the drive source is transmitted in the order of the cover 14, the pump impeller 11, the turbine runner 12, and the turbine hub 16, It is transmitted to the input shaft of the transmission (not shown) via the output shaft.

  When the lock-up clutch 20 is engaged (when the friction plate 22 and the cover 14 are in contact), the drive source transmitted to the cover 14 depending on the magnitude of the torque input to the damper mechanisms 30 and 40. The path through which the torque is transmitted to the input shaft of the transmission (hereinafter referred to as “torque transmission path”) changes.

  As shown in FIG. 4, when the torque input to the damper mechanisms 30 and 40 is small (low torque region), the torsion angle of the damper mechanisms 30 and 40 is small, and when the torque is large (high torque region), the torsion is performed. The angle increases. 4, the case where the two damper mechanisms 30 and 40 are combined is indicated by a solid line, the case where only the first damper mechanism 30 is provided is indicated by a dotted line, and the case where only the second damper mechanism 40 is provided is indicated by a two-dot chain line. Thus, the twist angle changes depending on the magnitude of the torque.

  When the torque transmitted to the cover 14 is small, the torque of the drive source transmitted to the cover 14 is the input side plate 21, the first holding plate 31, the first spring 33, the transmission claw 32, the turbine runner 12, and the second holding. The plate 41, the second spring 43, the output side plate 42, and the turbine hub 16 are transmitted in this order and transmitted to the input shaft of the transmission.

  At this time, the first holding plate 31 pushes the first spring 33 whose one end is in contact with the first holding portion 31 b of the first holding plate 31 connected to the input side plate 21. As a result, torque is transmitted from the input side plate 21 to the first spring 33 via the first holding plate 31.

  Then, the transmission claw 32 that is in contact with the other end of the first spring 33 is pushed by the first spring 33. Thereby, torque is transmitted from the first spring 33 to the turbine runner 12 via the transmission claw 32.

  Then, the second spring 43 having one end abutted against the two second holding plates 41 connected to the turbine runner 12 is pushed by the second holding plate 41. As a result, torque is transmitted from the turbine runner 12 to the second spring 43 via the two second holding plates 41.

  Then, the output side plate 42 that is in contact with the other end of the second spring 43 is pushed by the second spring 43. As a result, torque is transmitted from the second spring 43 to the turbine hub 16 via the output side plate 42.

  On the other hand, when the torque transmitted to the cover 14 is large and the movement of the transmission claw 32 is restricted by the notch 31c of the first holding plate 31, the torque of the drive source transmitted to the cover 14 is the input side plate 21, The first holding plate 31, the transmission claw 32, the turbine runner 12, the second holding plate 41, the second spring 43, the output side plate 42, and the turbine hub 16 are transmitted in this order and transmitted to the input shaft of the transmission.

  When the torque transmitted to the cover 14 is large, the first spring 33 held at both ends by the first holding portion 31b and the transmission claw 32 of the first holding plate 31 is compressed. As a result, the transmission claw 32 comes into contact with the end of the cutout portion 31 c of the first holding plate 31. Therefore, the first holding plate 31 directly pushes the transmission claw 32, and torque is directly transmitted from the first holding plate 31 to the transmission claw 32 without the first spring 33.

  The torque transmission path after the turbine runner 12 to which the transmission claw 32 is fixed is the same as when the torque is small.

  Further, when the torque transmitted to the cover 14 is large and the movement of the rivet 46 is restricted by the through hole 42 a formed in the output side plate 42, the torque of the drive source transmitted to the cover 14 is the input side plate 21. The first holding plate 31, the first spring 33, the transmission claw 32, the turbine runner 12, the second holding plate 41, the output side plate 42, and the turbine hub 16 are transmitted in this order, and transmitted to the input shaft of the transmission. .

  The torque transmission path before the turbine runner 12 is the same as when the torque is small.

  When the torque transmitted to the turbine runner 12 is large, the second springs 43 held between the notches 41 a of the two second holding plates 41 and the notches 42 b of the output side plate 42 are compressed. Accordingly, the rivet 46 that couples the two second holding plates 41 to the turbine runner 12 comes into contact with the end of the through hole 42 a formed in the output side plate 42. Accordingly, the two second holding plates 41 directly push the output side plate 42, and torque is directly transmitted from the two second holding plates 41 to the output side plate 42 without the second spring 43. Is done.

  As described above, according to the present embodiment, the transmission claw 32 that is the output member of the first damper mechanism 30 is fixed to the turbine runner 12, and the second damper mechanism 40 has two second members that are input members. The two holding plates 41 are connected to the turbine runner 12 by rivets 46. That is, the first damper mechanism 30 and the second damper mechanism 40 are connected via the turbine runner 12 using the transmission claws 32 and the rivets 46. Thereby, the turbine runner 12 functions as an inertia mass body of the two damper mechanisms 30 and 40.

  According to the present embodiment, the two damper mechanisms 30 and 40 are connected in series via the turbine runner 12. And as described in the said patent document 1, without using the turbine runner 12, the exclusive member which connects the two damper mechanisms 30 and 40 directly is not provided.

  Furthermore, according to the present embodiment, the first spring 33 restricts excessive contraction of the first spring 33 from the notch 31c formed in the first holding plate 31 and the transmission claw 32 engaged with the notch 31c. A stopper mechanism 34 is configured. The second stopper mechanism 44 that restricts excessive contraction of the second spring 43 is constituted by a through hole 42a formed in the output side plate 42 and a rivet 46 that engages with the through hole 42a.

  Of the members for connecting the first damper mechanism 30 and the second damper mechanism 40, the turbine runner 12 is an essential member for the torque converter 10, and the transmission claw 32 holds the first spring 33. The rivet 46 is also a member for regulating an excessive contraction amount of the second spring 43. On the other hand, the transmission claw 32 and the rivet 46 are also members for connecting the first damper mechanism 30 and the second damper mechanism 40.

  Since the members are shared in this way, it is possible to connect the two damper mechanisms 30 and 40 and provide the two stopper mechanisms 34 and 44 without increasing the number of parts. And the shape of the notch 31c formed in the 1st holding plate 31 and the through-hole 42a formed in the output side plate 42 are simple shapes.

  Therefore, the number of parts is not increased so much and only a simple process needs to be added. Therefore, it is possible to prevent the torque converter 10 from being increased in cost and weight.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to this.

  For example, the shape of the first spring 33 and the second spring 43 may be either an arc shape or a straight shape.

DESCRIPTION OF SYMBOLS 10 ... Torque converter (fluid transmission device) 11 ... Pump impeller 12 ... Turbine runner 13 ... Stator 14 ... Cover 15 ... Pump hub 16 ... Turbine hub 20 ... Lock-up clutch 21 ... Input side plate (lock) Up piston), 21a ... accommodating part, 22 ... friction plate, 30 ... first damper mechanism, 31 ... first holding plate (first holding member), 31a ... accommodating part, 31b ... first holding part, 31c ... notch part (First regulating part), 32 ... transmission claw (transmission member), 32a ... claw part, 33 ... first spring (first elastic body), 34 ... first stopper mechanism, 40 ... second damper mechanism, 41 ... first 2 holding member, 41a ... notch part, 41b ... circumferential end surface of the notch part (second holding part), 42 ... output side plate (output member), 42a ... through hole (second regulating part), 2b ... notch, the circumferential end faces of 42c ... notch (holding portion), 43 ... second spring (second elastic member), 44 ... second stopper mechanism, 46 ... Rivet (connecting member), O ... center axis.

Claims (1)

A pump impeller that rotates around a central axis by a driving force from a driving source;
A turbine runner that rotates about the central axis by a flow of fluid generated by rotation of the pump impeller;
An output member for transmitting rotation of the turbine runner to a driven shaft;
A lockup piston coupled to the pump impeller by a lockup clutch;
A fluid transmission device comprising a first damper mechanism and a second damper mechanism interposed between the lock-up piston and the output member,
The first damper mechanism is
A plurality of first holding portions arranged along a circumferential direction around the central axis, and a first holding member connected to the lock-up piston;
A plurality of transmission members coupled to the turbine runner;
A plurality of first elastic bodies respectively held between the first holding portion and the transmission member;
A plurality of first restricting portions that are formed on the first holding member and engage with the transmission member to restrict movement of the transmission member in the circumferential direction around the central axis;
The second damper mechanism is
A plurality of second holding portions arranged along a circumferential direction around the central axis, connected to the turbine runner via a connecting member, and independent from the first holding member; Members,
A plurality of second elastic bodies respectively held between the second holding portion and a plurality of holding portions formed on the output member;
A fluid transmission device comprising: a plurality of second restricting portions that are formed on the output member and engage with the connecting member to restrict movement of the connecting member in the circumferential direction around the central axis.

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