JP2014009704A - Power transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power transmission device capable of absorbing minute displacement between shafts in a circumferential direction and an axial direction.SOLUTION: The power transmission device comprises: a shaft member 2; a drive plate 10 rotating integrally with the shaft member 2; input side plates 17, 18 in which rotation power of the drive plate 10 is inputted; a torque variation absorbing device 3 for absorbing a variation torque generated between it and an output side plate 23 outputting the rotation power; and a fluid transmission device 4 having output side members 45-48 outputting the rotation power by receiving the rotation power from input side members 40-44 in which the rotation power of the output side plate 23 is inputted via fluid. The shaft member 2 has a recess 2b indented in an axial direction at an end, and the input side plate 17 has a cylinder section 17f borne movably in the axial direction inside the recess 2b. A bearing member 29 is mounted to inside of the cylinder section 17f, and the input side plate 17 has a hole section 17h opened inside a tip of the cylinder section 17f.

Description

  The present invention relates to a power transmission device having a torque fluctuation absorber and a torque converter in a power transmission path between two shafts.

  Conventionally, in a power transmission device having a torque fluctuation absorber and a torque converter in a power transmission path between an engine crankshaft and a transmission input shaft, the torque fluctuation absorber and the torque converter are coaxial with respect to the crankshaft. Some have been devised to keep.

  For example, in Patent Document 1, a protrusion (14 in FIG. 1 in Patent Document 1) formed on a disk (15 in FIG. 1 in Patent Document 1) of a torsion damper (30 in FIG. 1 of Patent Document 1) is driven. Torsion damper (torque fluctuation absorbing device) with respect to drive shaft (corresponding to crankshaft) by partially engaging with a central hole (19 in FIG. 1 of Patent Document 1) of a shaft (11 in FIG. Is positioned coaxially, and the engine side end of the driven shaft (21 in FIG. 1 of Patent Document 1) is inserted into the inside of the projecting portion via the pilot bearing (22 in FIG. 1 of Patent Document 1). Thus, a drive shaft (corresponding to a torque converter) is coaxially positioned with respect to the drive shaft and the torsion damper. Moreover, in patent document 1, the center hub (26 of FIG. 1 of patent document 1) of the torsion damper is connected (spline engagement) to the driven shaft.

JP 2004-116780 A

  The following analysis is given by the inventor.

  However, in Patent Document 1, since there is a backlash (gap between spline teeth) in the circumferential direction at the spline-engaged portion between the central hub of the torsion damper and the driven shaft, the spline is caused by vibration in a small torque region such as idling. There is a possibility that sound between teeth is generated.

  Moreover, in the structure of patent document 1, since the driven shaft is supported by the protrusion part formed in the disk of the torsion damper via the pilot bearing, when the torque converter is arranged on the output side, the torque converter When ballooning (a phenomenon in which the shell expands due to internal pressure) is deformed, the entire torque converter is displaced toward the transmission (axial direction) with the pilot bearing as a base point. As a result, the rotating member of the torque converter may be greatly displaced and interfere with other parts.

  The main subject of this invention is providing the power transmission device which can absorb the small displacement of the circumferential direction between an axis | shaft and an axial direction.

  In one aspect of the present invention, in the power transmission device, a shaft member that is rotatably arranged, a drive plate that rotates integrally with the shaft member, an input side plate that receives rotational power of the drive plate, An output side plate that outputs rotational power, a torque fluctuation absorbing device that absorbs fluctuation torque generated between the input side plate and the output side plate, and the rotational power of the output side plate. An input side member, and an output side member that outputs rotational power by receiving rotational power from the input side member via a fluid, and the shaft member at the end The input side plate has a cylindrical portion that is supported so as to be axially movable inside the concave portion, and the inner side of the cylindrical portion has a concave portion that is recessed in the axial direction. A bearing member is mounted and has a hole portion opened inside the tip of the cylindrical portion, and the input side member has a center piece that is supported so as to be axially movable inside the bearing member. And the center piece can be inserted so as not to interfere with the hole.

  In the power transmission device of the present invention, the shaft member has another cylindrical portion protruding in the axial direction at the end portion, and the drive plate is disposed on an outer periphery of the other cylindrical portion, and the cylindrical portion Is preferably supported so as to be axially movable inside the recess including the inside of the other cylindrical part.

  In the power transmission device of the present invention, it is preferable that an axial contact length between the concave portion and the cylindrical portion is set to be shorter than an axial protruding length of the cylindrical portion.

  In the power transmission device of the present invention, a bolt for fastening the drive plate to the shaft member from the torque fluctuation absorber side may be provided, and the input side plate may have an opening for accommodating the head of the bolt. preferable.

  According to the present invention, the cost of the apparatus can be reduced by integrally forming the cylindrical portion supported by the concave portion of the shaft member in the input side plate. Moreover, since the heavy torque fluctuation absorber is directly centered on the shaft member, the unbalance after the torque fluctuation absorber is assembled to the shaft member can be reduced. Furthermore, the axial length of the entire apparatus can be shortened by inserting the cylindrical portion of the input side plate inside the concave portion of the shaft member.

  Further, according to the present invention, by installing the bearing member inside the cylindrical portion of the input side plate near the center of the rotating shaft, the size of the bearing member can be reduced (smaller diameter), and the cost of the apparatus can be reduced. be able to. Further, since the torque converter is supported via the bearing member with respect to the torque fluctuation absorber, the shaft deviation between the torque converter and the torque fluctuation absorber does not occur during the mounting work on the vehicle. Furthermore, even if the torque converter is deformed by ballooning, the center piece of the torque converter can move in the axial direction with respect to the bearing member, and even if the center piece moves in the axial direction, it can be inserted without touching the hole. Therefore, there is no conflict with the input side plate, the entire torque converter is not displaced to the transmission side (axial direction), and the components of the torque converter do not interfere with other parts.

It is sectional drawing between XX 'of FIG.2 and FIG.3 which showed typically the structure of the power transmission device containing the torque fluctuation absorber which concerns on Example 1 of this invention. It is the top view seen from the arrow A of FIG. 1 which showed typically the structure of the torque fluctuation absorber which concerns on Example 1 of this invention. It is the partially notched top view seen from the arrow B of FIG. 1 which showed typically the structure of the torque fluctuation absorber which concerns on Example 1 of this invention. It is an expanded sectional view near the bearing which showed typically the composition of the torque fluctuation absorber concerning Example 1 of the present invention. It is an expanded sectional view of the vicinity of the seal member schematically showing the configuration of the torque fluctuation absorber according to Embodiment 1 of the present invention.

[Outline of Embodiment]
In the power transmission device according to the embodiment of the present invention, a shaft member (2 in FIG. 1) that is rotatably arranged, a drive plate (10 in FIG. 1) that rotates integrally with the shaft member, and the drive plate An input side plate (17, 18 in FIG. 1) to which rotational power is input and an output side plate (23 in FIG. 1) to output the rotational power, and the input side plate and the output side plate A torque fluctuation absorber (3 in FIG. 1) that absorbs the fluctuation torque generated between them, an input side member (40 to 44 in FIG. 1) to which the rotational power of the output side plate is input, and the input side member An output side member (45 to 48 in FIG. 1) that outputs the rotational power by receiving the rotational power of the fluid via the fluid, and the shaft member, Concave part (Fig. 2b), and the input side plate has a cylindrical portion (17f in FIG. 1) supported so as to be axially movable inside the concave portion, and a bearing member (in FIG. 1). 29) and has a hole (17h in FIG. 1) opened inside the tip of the cylindrical portion, and the input side member is axially movable inside the bearing member. It has a center piece (40a in FIG. 1) to be supported, and the center piece can be inserted so as not to touch the hole.

  Note that, in the present application, where reference numerals are attached to the drawings, these are only for the purpose of helping understanding, and are not intended to be limited to the illustrated embodiments. Hereinafter, embodiments will be described with reference to the drawings.

  A power transmission apparatus according to Embodiment 1 of the present invention will be described with reference to the drawings. 1 is a cross-sectional view taken along a line XX ′ in FIGS. 2 and 3 schematically showing a configuration of a power transmission device including a torque fluctuation absorber according to Embodiment 1 of the present invention. FIG. 2 is a plan view seen from an arrow A in FIG. 1 schematically showing the configuration of the torque fluctuation absorber according to Embodiment 1 of the present invention. FIG. 3 is a partially cutaway plan view seen from an arrow B of FIG. 1 schematically showing the configuration of the torque fluctuation absorber according to Embodiment 1 of the present invention. FIG. 4 is an enlarged cross-sectional view of the vicinity of the bearing schematically showing the configuration of the torque fluctuation absorber according to Embodiment 1 of the present invention. FIG. 5 is an enlarged cross-sectional view of the vicinity of the seal member schematically showing the configuration of the torque fluctuation absorber according to Embodiment 1 of the present invention.

  Referring to FIG. 1, a power transmission device 1 is a device that transmits rotational power of an engine (not shown, an internal combustion engine) to a transmission (not shown). In the power transmission device 1, a torque fluctuation absorber 3 and a torque converter 4 are arranged in series in a power transmission path between the crankshaft 2 of the engine and the input shaft 6 of the transmission. The crankshaft 2 and the input shaft 6 are arranged coaxially on the rotating shaft 7.

  The crankshaft 2 is an output shaft of the engine (see FIGS. 1 and 4). In the crankshaft 2, the side member 11, the drive plate 10, and the side member 12 are fastened (connected) by bolts 13 on the transmission side (left side in FIG. 1). The crankshaft 2 has a cylindrical portion 2a that protrudes toward the transmission on the surface on the transmission side (left side in FIG. 1). The cylindrical portion 2 a is inserted inside the annular side member 11, the drive plate 10, and the side member 12, and positions the side member 11, the drive plate 10, and the side member 12 so as to be coaxial with the rotation shaft 7. do.

  The crankshaft 2 has a recessed portion 2b that is recessed toward the engine side (right side in FIG. 1) in the axial direction at a portion inside the cylindrical portion 2a. The cylindrical portion 17f of the side plate 17 is inserted (beared) into the concave portion (including the inside of the cylindrical portion 2a) so as to be axially movable and rotatable and non-radially movable (radial movement is restricted). As a result, the side plate 17 is centered with respect to the crankshaft 2. The axial contact length 62 of the portion where the concave portion 2b (including the cylindrical portion 2a) contacts the cylindrical portion 17f is set shorter than the axial protruding length 63 of the cylindrical portion 2a (or the cylindrical portion 17f). (See FIG. 4). The contact length 62 is preferably 1 mm or more and 4 mm or less, more preferably 2 mm or more and 3 mm or less. The distal end portion (portion on the transmission side in the axial direction) of the cylindrical portion 2a is spaced apart from the side plate 17 in the axial direction (see the gap 61 in FIG. 4). The concave portion 2b is spaced apart from the cylindrical portion 17f (including the convex portion 17g) of the side plate 17 in the axial direction (see the gap 60 in FIG. 4). Thereby, the axial movement of the side plate 17 with respect to the crankshaft 2 is ensured.

  The torque fluctuation absorber 3 is an apparatus that absorbs (suppresses) the fluctuation torque generated between the engine and the transmission (see FIGS. 1 to 3). The torque fluctuation absorber 3 is arranged in a power transmission path between the crankshaft 2 and the torque converter 4 (front cover 40). The torque fluctuation absorber 3 has a damper portion that absorbs fluctuation torque by an elastic force (spring force). The torque fluctuation absorber 3 includes, as main components, a drive plate 10, side members 11 and 12, bolts 13, a block member 14, a welded portion 15, bolts 16, side plates 17, and side plates. 18, welded portion 19, cap 20, ring gear 21, welded portion 22, center plate 23, seal member 24, ring member 25, side member 26, rivet 27, bolt 28, and bearing. 29, a block member 30, a welded portion 31, sheet members 32 and 33, an outer coil spring 34, and inner coil springs 35 and 36.

  The drive plate 10 is an annular and disk-shaped plate for transmitting (inputting) the rotational power from the crankshaft 2 to the torque fluctuation absorber 3 (see FIGS. 1, 4, and 5). The drive plate 10 is positioned so as not to move in the radial direction by the cylindrical portion 2a of the crankshaft 2 while being sandwiched between the side member 11 and the side member 12 at the radially inner portion. Fastened (connected) to the crankshaft 2. As a result, the drive plate 10 rotates integrally with the crankshaft 2. The drive plate 10 is fastened to the corresponding block member 14 by a plurality of bolts 16 at a radially outer portion.

  The side member 11 is an annular and plate-like member for stabilizing the seating surface of the head of the bolt 13 and improving the durability of the drive plate 10 (see FIGS. 1 and 4). The side member 11 is disposed between the head of the bolt 13 and the drive plate 10, is positioned so as not to move in the radial direction by the cylindrical portion 2 a of the crankshaft 2, and includes a plurality of bolts 13 together with the drive plate 10 and the side member 12. Is fastened (connected) to the crankshaft 2.

  The side member 12 is an annular and plate-like member for improving the durability of the drive plate 10 against vibration or the like (see FIGS. 1 and 4). The side member 12 is disposed between the drive plate 10 and the crankshaft 2, is positioned so as not to move in the radial direction by the cylindrical portion 2 a of the crankshaft 2, and is cranked by a plurality of bolts 13 together with the drive plate 10 and the side member 11. Fastened (connected) to the shaft 2.

  The bolt 13 is a member for fastening (connecting) the drive plate 10 and the side members 11 and 12 to the crankshaft 2 (see FIG. 1). The head of the bolt 13 is disposed inside the opening 17 e of the side plate 17 so as not to contact the side plate 17. Thereby, the axial direction dimension of an apparatus can be shortened.

  The block member 14 is a block-shaped member for fastening the drive plate 10 with bolts 16 (see FIGS. 1, 2, and 5). The block member 14 is attached to a recess 17d formed in a portion between the accommodating portions 17a (portions that accommodate the coil springs 34, 35, and 36) adjacent to each other in the circumferential direction of the side plate 17. In other words, the block member 14 is arrange | positioned in the position which overlaps with the accommodating part 17a in the circumferential direction. The block member 14 is welded and fixed to the side plate 17 by a welded portion 15 at a radially outer portion and a radially inner portion. The block member 14 has a female screw portion 14 a that is screwed into the bolt 16 at a position corresponding to the bolt 16. The block member 14 rotates integrally with the drive plate 10 and the side plate 17 when the drive plate 10 is fastened (connected) by the bolt 16.

  The welded portion 15 is a portion for fixing the block member 14 to the side plate 17 by welding (see FIGS. 1, 2, and 5). The welded portion 15 fixes the radially outer portion and the radially inner portion of the block member 14 to the side plate 17.

  The bolt 16 is a member for fastening (engaging) the drive plate 10 to the block member 14 (see FIGS. 1 and 5).

  The side plate 17 is an annular member (see FIGS. 1 to 5). The side plate 17 is arranged on the outer periphery of the center plate 23 or on the engine side. The side plate 17 has a hole 17b through which the bolt 28 is passed during assembly. A cap 20 that closes the entire hole 17b is attached to the hole 17b. The side plate 17 has a bag-shaped accommodation portion 17a for accommodating the sheet members 32, 33 and the coil springs 34, 35, 36 at the radially outer portion, and the coil springs 34, 35, 36, the sheet member. Supports the centrifugal force of 32 and 33 and the component force in the radial direction during coil compression. The accommodating portion 17a can be brought into contact with and separated from the sheet members 32 and 33 at the end face in the circumferential direction, and the sheet members 32 and 33 are not twisted between the side plates 17 and 18 and the center plate 23. Are in close contact with each other or have some backlash, and contact with one of the sheet members 32 and 33 when the side plates 17 and 18 and the center plate 23 are twisted. The side plate 17 has a concave portion 17d on the surface on the drive plate 10 side of a portion between the accommodating portions 17a adjacent in the circumferential direction. The concave portion 17d is a portion for mounting the block member 14. The concave portion 17d can be formed by shaving or press molding. A block member 14 attached to the recess 17 d is fixed to the side plate 17 by a welded portion 15. The side plate 17 is formed so as to cover the radially outer side of the outer coil spring. The side plate 17 is inserted inside the annular ring gear 21 at the outer peripheral surface, and the ring gear 21 is fixed by the welded portion 22. The side plate 17 is in close contact with the side plate 18 at the end on the torque converter 4 side and is fixed to the side plate 18 by a welded portion 19.

  The side plate 17 has a cylindrical portion 17f that extends radially inwardly to the inside of the cylindrical portion 2a of the crankshaft 2 and protrudes toward the crankshaft 2 at the radially inner end. The cylindrical portion 17f is inserted (beared) into the concave portion 2b (including the inside of the cylindrical portion 2a) of the crankshaft 2 so as to be axially movable, rotatable, and radially unmovable. An outer ring of a bearing 29 is mounted and fixed inside the cylindrical portion 17f. The side plate 17 has a convex portion 17g protruding radially inward on the inner peripheral surface of the tip portion of the cylindrical portion 17f. The convex portion 17g is used to position the outer ring of the bearing 29 attached and fixed inside the cylindrical portion 17f in the axial direction. The side plate 17 has a hole portion 17h that is open on the inner side of the distal end portion of the cylindrical portion 17f (the radially inner side of the convex portion 17g). The hole 17h is for inserting the center piece 40a of the front cover 40, and is set so as not to contact the center piece 40a. The hole 17h is opened to allow the center piece 40a to move in the axial direction by ballooning, thereby preventing grease leakage in the bearing 29.

  The side plate 17 has an opening 17 e at a site corresponding to the head of the bolt 13. The opening 17e is a space for accommodating the head of the bolt 13 and prevents the head of the bolt 13 and the side plate 17 from conflicting. Thereby, the axial direction dimension of an apparatus can be shortened. The side plate 17 is spaced apart from the head of the bolt 13 (including a flange-like portion or washer) in the radial direction and the axial direction at the opening 17e and the peripheral edge thereof.

  The side plate 17 has a stepped portion 17c over the entire circumference at a portion between the hole portion 17b and the opening portion 17e in the radial direction. The step portion 17c regulates the radial movement so that the ring member 25 and the center plate 23 can rotate on the radially outer surface. The side plate 17 is in contact with the ring member 25 so as to be slidable in the rotational direction on a surface radially outward from the stepped portion 17c. Is pressed against the ring member 25. Thereby, the clearance gap between the side plate 17 and the center plate 23 in the spring accommodation chamber 58 which accommodates the coil springs 34, 35, and 36 can be sealed.

  The side plate 18 is an annular member (see FIGS. 1, 3, and 5). The side plate 18 is disposed on the torque converter side of the torque fluctuation absorber 3. The side plate 18 is disposed radially outward from the annular block member 30 at a predetermined interval. The side plate 18 has a radially outer portion in close contact with the side plate 17 over the entire circumference, and is fixed to the side plate 17 by a welded portion 19. As a result, the side plate 18 rotates integrally with the side plate 17, and the internal lubricant does not leak from the joint portion of the side plates 17, 18. The side plate 18 has a bag-shaped accommodation portion 18a for accommodating the sheet members 32, 33 and the coil springs 34, 35, 36 at an intermediate portion. The accommodating portion 18a can be brought into contact with and separated from the sheet members 32 and 33 at the end face in the circumferential direction, and the sheet members 32 and 33 are not twisted between the side plates 17 and 18 and the center plate 23. Are in close contact with each other or have some backlash, and contact with one of the sheet members 32 and 33 when the side plates 17 and 18 and the center plate 23 are twisted. The side plate 18 has a convex portion 18b that protrudes continuously toward the center plate 23 in the circumferential direction at a portion radially inward of the accommodating portion 18a, and extends over the entire periphery of the seal member 24 at the convex portion 18b. And are slidably pressed. The gap between the side plate 18 and the center plate 23 in the spring accommodating chamber 58 that accommodates the coil springs 34, 35, 36 is completely covered by the seal member 24.

  The welded portion 19 is a portion where a portion where the side plate 17 and the side plate 18 are in close contact with each other is welded and fixed (see FIGS. 1 and 5).

  The cap 20 is a member that seals (closes) the entire hole portion 17b of the side plate 17, and is mounted (press-fitted) into the hole portion 17b (see FIG. 1). The cap 20 can prevent foreign matters such as dust, dust, water, and mud from entering the spring accommodating chamber 58 from the engine side. Instead of the cap 20, an adhesive film, an adhesive sheet, a waterproof and moisture-permeable material, etc. that can be attached by covering the entire hole 17 b from the outside may be used.

  The ring gear 21 is a ring-shaped gear having a gear on the outer peripheral surface (see FIGS. 1 to 3 and FIG. 5). The ring gear 21 meshes with an output gear (not shown) of a starter motor (not shown). The ring gear 21 is attached to the outer peripheral portion of the side plate 17 and is fixed to the side plate 17 by a welded portion 22.

  The welded portion 22 is a portion where the ring gear 21 is fixed to the side plate 17 by welding (see FIGS. 1 and 2).

  The center plate 23 is an annular member (see FIGS. 1 and 3 to 5). The center plate 23 is disposed radially inward from the connecting portion of the side plates 17 and 18 at a predetermined interval. The center plate 23 extends radially inward from the position of the block member 30. The center plate 23 is disposed on the outer periphery of the stepped portion 17 c of the side plate 17. The center plate 23 is rotatable and restricted in radial movement at the inner peripheral end by the radially outer surface of the stepped portion 17 c of the side plate 17. Sealing members 24 and side members 26 disposed on both sides of the radially inner portion are fixed to the center plate 23 by a plurality of rivets 27. As a result, the center plate 23 rotates integrally with the seal member 24. The center plate 23 is fastened (engaged) to the block member 30 by a bolt 28 together with the seal member 24 and the side member 26. As a result, the center plate 23 rotates integrally with the front cover 40 of the torque converter 4 via the block member 30. The center plate 23 has notched window portions 23a for accommodating the sheet members 32 and 33 and the coil springs 34, 35, and 36 at the outer peripheral portion. The window portion 23a can be brought into contact with and separated from the sheet members 32 and 33 at the end face in the circumferential direction, and the sheet members 32 and 33 are not twisted between the side plates 17 and 18 and the center plate 23. Are in close contact with each other or have some backlash, and contact with one of the sheet members 32 and 33 when the side plates 17 and 18 and the center plate 23 are twisted.

  The center plate 23 has a convex portion 23b that protrudes toward the side plate 18 at the radially inner portion of the window portion 23a. As for the convex part 23b, when the side plates 17 and 18 have moved to the engine side (the right side in FIG. 5), the side plate 18 (the part between the accommodating parts 18a (between the circumferential directions)) does not contact the center plate 23. It becomes a stopper for doing so. Therefore, the axial gap length 71 between the tip of the convex portion 23 b and the seal member 24 is equal to the portion (spring receiving portion) between the accommodating portions 18 a (between the circumferential directions) of the side plate 18 and the center plate 23. Is set to be shorter than the gap length 70 in the axial direction.

  The seal member 24 is an annular and plate-like member (see FIGS. 1, 3, and 5). For the seal member 24, for example, a thin metal or resin plate can be used. The seal member 24 is sandwiched between the center plate 23 and the block member 30 at a radially inner portion, and continuously adhered to the center plate 23 together with the side member 26 by the rivets 27 in the circumferential direction. It is fixed by caulking, and is fastened (engaged) to the block member 30 together with the center plate 23 and the side member 26 by bolts 28. The seal member 24 is separated from the center plate 23 at the radially outer portion, and is in close contact with the convex portion 18b of the side plate 18 in the circumferential direction so as to be slidable (preferably , Press contact with a preload). Thus, the gap between the side plate 18 and the center plate 23 in the spring accommodating chamber 58 that accommodates the coil springs 34, 35, 36 can be completely covered (blocked, separated), and the spring accommodating chamber 58 is sealed. (Lubricant leakage prevention / foreign matter entry prevention).

  The ring member 25 is an annular and plate-like member (see FIGS. 1 and 4). The ring member 25 is made of a material that has a lower coefficient of friction than the side plate 17 and the center plate 23 in direct contact with each other, for example, a resin material. The ring member 25 is disposed on the outer periphery of the radially outer surface of the stepped portion 17c of the side plate 17, and the radial movement is restricted by the stepped portion 17c. The ring member 25 is slidably sandwiched between the side plate 17 and the center plate 23. As a result, the gap between the side plate 17 and the center plate 23 in the spring accommodating chamber 58 that accommodates the coil springs 34, 35, and 36 can be covered (blocked, separated), and the spring accommodating chamber 58 is sealed (lubricated). It is possible to prevent chemical leakage and foreign matter entry.

  The side member 26 is an annular and plate-like member (see FIGS. 1, 2 and 5). The side member 26 is caulked and fixed to the center plate 23 together with the seal member 24 by a rivet 27, and is fastened (engaged) to the block member 30 together with the center plate 23 and the seal member 24 by bolts 28.

  The rivet 27 is a connecting member for connecting (caulking and fixing) the seal member 24 and the side member 26 to the center plate 23 (see FIGS. 1, 3, and 5). In addition to the bolt 28, the seal member 24 is fixed to the center plate 23 in advance by a rivet 27, thereby preventing the seal member 24 from falling off (displacement) and reducing the float between the center plate 23 and the seal member 24. The lubricant can be prevented from entering the gap between the center plate 23 and the seal member 24.

  The bolt 28 is a fastening member for fastening the center plate 23, the seal member 24, and the side member 26 to the block member 30 (see FIGS. 1 and 3).

  The bearing 29 is a bearing for rotatably mounting the center piece 40a of the front cover 40 to the cylindrical portion 17f of the side plate 17 (see FIGS. 1 and 4). The bearing 29 is disposed radially inward of the PCD (Pitch Circle Diameter) of the bolt 13 (so-called crank bolt). The bearing 29 is arranged such that the inner ring is axially movable and rotatable with respect to the outer peripheral surface of the center piece 40 a of the front cover 40, and is not radially movable (the radial movement is restricted), and the outer ring is a cylinder of the side plate 17. It is press-fitted and fixed inside the portion 17f. The bearing 29 is positioned in the axial direction inside the cylindrical portion 17 f of the side plate 17 by the convex portion 17 g of the side plate 17. Instead of the bearing 29, a sliding bearing such as a bush may be used.

  The block member 30 is an annular block-shaped member for fastening (engaging) the center plate 23 with bolts 28 (see FIGS. 1 and 5). The block member 30 is welded and fixed to the front cover 40 of the torque converter 4 by a welded portion 31 at a radially outer portion and a radially inner portion. The block member 30 has a female screw portion that is screwed into the bolt 28 at a position corresponding to the bolt 28. The block member 30 rotates integrally with the center plate 23 and the front cover 40 when the seal member 24, the center plate 23, and the side member 26 are fastened (engaged) by the bolts 28. The block member 30 has a recess that accommodates the head (caulking portion) of the rivet 27.

  The welded portion 31 is a portion for fixing the block member 30 to the front cover 40 of the torque converter 4 by welding (see FIG. 1). The welded portion 31 fixes the radially outer portion and the radially inner portion of the block member 30 to the front cover 40.

  The sheet member 32 is accommodated in the accommodating portions 17a and 18a of the side plates 17 and 18 in the spring accommodating chamber 58 and the window portion 23a of the center plate 23, and is in the circumferential direction of the accommodating portions 17a and 18a and the window portion 23a. This is a member disposed between the end surface of the outer coil spring and one end of the outer coil spring 34 (see FIG. 3). Resin can be used for the sheet member 32 in order to reduce wear of the outer coil spring 34. The seat member 32 has a portion press-fitted inside one end of an inner coil spring 35 disposed inside the outer coil spring 34, and fixes one end of the inner coil spring 35 by press-fitting.

  The sheet member 33 is accommodated in the accommodating portions 17a and 18a of the side plates 17 and 18 in the spring accommodating chamber 58 and the window portion 23a of the center plate 23, and the other in the circumferential direction of the accommodating portions 17a and 18a and the window portion 23a. This is a member disposed between the end surface of the outer coil spring 34 and the other end of the outer coil spring 34 (see FIG. 3). Resin can be used for the seat member 33 in order to reduce wear of the outer coil spring 34. The seat member 33 has a portion press-fitted inside the other end of the inner coil spring 36 disposed inside the outer coil spring 34, and fixes the other end of the inner coil spring 36 by press-fitting.

  The outer coil spring 34 is accommodated in the accommodating portions 17a and 18a of the side plates 17 and 18 in the spring accommodating chamber 58 and the window portion 23a of the center plate 23, and is in contact with the sheet members 32 and 33 disposed at both ends. (See FIGS. 1 and 3). The outer coil spring 34 contracts when torsion occurs between the side plates 17 and 18 and the center plate 23. In the outer coil spring 34, an inner coil spring 35 is disposed on the circumferential side of the sheet member 32, and an inner coil spring 36 is disposed on the circumferential side of the sheet member 33. When the torsion occurs between the side plates 17, 18 and the center plate 23, the outer coil spring 34 comes into close contact before both the inner coil spring 35 and the inner coil spring 36 come into close contact. The outer coil spring 34 serves as a stopper that regulates torsion between the side plates 17, 18 and the center plate 23 when the outer coil spring 34 comes into close contact with the side plates 17, 18 and the center plate 23. The outer coil spring 34 is set to have a smaller spring constant than the inner coil springs 35 and 36. The outer coil spring 34 comes into close contact after the inner coil spring 35 comes into close contact when the torsion occurs between the side plates 17 and 18 and the center plate 23.

  The inner coil spring 35 is a coil spring disposed on the side of the circumferential seat member 32 inside the outer coil spring 34 (see FIGS. 1 and 3). At one end of the inner coil spring 35, a portion of the sheet member 32 is press-fitted inside and fixed to the sheet member 32. The other end of the inner coil spring 35 is separated from one end of the inner coil spring 36 when no twist is generated between the side plates 17, 18 and the center plate 23, and the side plate 17, When a torsion occurs between the center plate 23 and the center plate 23 to reach a predetermined torsion angle, it contacts one end of the inner coil spring 36, and contracts when a torsion occurs further than the predetermined torsion angle. The inner coil spring 35 is set to have a spring constant larger than that of the outer coil spring 34 and smaller than that of the inner coil spring 36. The inner coil spring 35 comes into close contact before the outer coil spring 34 comes into close contact when the torsion occurs between the side plates 17 and 18 and the center plate 23.

  The inner coil spring 36 is a coil spring disposed on the side of the sheet member 33 in the circumferential direction inside the outer coil spring 34 (see FIG. 3). The other end portion of the inner coil spring 36 is fixed to the sheet member 33 by press-fitting a portion of the sheet member 33 inside. One end of the inner coil spring 36 is separated from the other end of the inner coil spring 35 when no twist is generated between the side plates 17, 18 and the center plate 23, and the side plate 17, When a torsion occurs between the center plate 23 and the center plate 23 to reach a predetermined torsion angle, the other end of the inner coil spring 35 is brought into contact with and contracts when further torsion occurs beyond the predetermined torsion angle. The inner coil spring 36 has a larger spring constant than the outer coil spring 34 and the inner coil spring 35. When the torsion occurs between the side plates 17 and 18 and the center plate 23, the inner coil spring 36 does not come into close contact before the outer coil spring 34 comes into close contact.

  The torque converter 4 is a fluid transmission device that generates a torque amplifying action by a rotational difference between the pump impeller 42 on the input side and the turbine runner 46 on the output side, utilizing the mechanical action of the fluid in the fluid working chamber ( (See FIG. 1). The torque converter 4 is disposed on a power transmission path between the torque fluctuation absorber 3 and the input shaft 6. The torque converter 4 includes a single-plate lockup clutch 5 that directly connects the pump impeller 42 and the turbine runner 46 when there is a small difference in rotational speed to eliminate the rotational speed difference between the crankshaft 2 and the input shaft 6. . The torque converter 4 is supported by the center piece 40a of the front cover 40 on the input side so as to be rotatable and axially movable with respect to the cylindrical portion 17f of the side plate 17 of the torque fluctuation absorber 3 via the bearing 29. Yes. The torque converter 4 includes a front cover 40, a pump shell 41, a pump impeller 42, a shaft 43, a pump core 44, a turbine shell 45, a turbine runner 46, a turbine core 47, and a turbine as main components. It has a hub 48, a stator 49, a one-way clutch 50, a shaft 51, a plate member 52, a lock-up piston 53, and a friction material 54.

  The front cover 40 is a disk-shaped member disposed on the engine side (the right side in FIG. 1) of the torque converter 4 (see FIG. 1). The front cover 40 is formed in a shape that extends radially outward from the rotary shaft 7 and has an outer peripheral portion extending to the transmission side (left side in FIG. 1). The outer peripheral end of the front cover 40 is fixed in close contact with the outer peripheral end of the pump shell 41 by welding. The front cover 40 rotates integrally with the pump shell 41. In the space surrounded by the front cover 40 and the pump shell 41, components such as a pump impeller 42 and a turbine runner 46 of the torque converter 4 are arranged, and an automatic transmission fluid (ATF) as a working fluid is enclosed. Has been. The front cover 40 receives rotational power from the engine via the crankshaft 2 and the torque fluctuation absorber 3. In the front cover 40, a block member 30 in the torque fluctuation absorber 3 is welded to a surface on the engine side (right side in FIG. 1) by a welding portion 31. The front cover 40 can be frictionally engaged with the friction material 54 of the lockup clutch 5 on the surface on the transmission side (left side in FIG. 1). The front cover 40 is set (formed) so as not to contact the side plates 17 and 18 and the bearing 29 of the torque fluctuation absorber 3 in the axial direction.

  In the front cover 40, a rod-shaped center piece 40a is fixed on the rotary shaft 7 on the surface on the engine side (right side in FIG. 1). The center piece 40 a is inserted inside the inner ring of the bearing 29 so as to be movable in the axial direction, rotatable, and immovable in the radial direction (radial movement is restricted), and the side plate 17 of the torque fluctuation absorber 3 is interposed via the bearing 29. The cylindrical portion 17f is supported so as to be rotatable and axially movable. The center piece 40a is inserted so as not to touch the hole 17h of the side plate 17, and is separated from the crankshaft 2 in the axial direction.

  The pump shell 41 is an annular member that constitutes a space for circulating the ATF (see FIG. 1). The pump shell 41 is welded with its outer peripheral end in close contact with the outer peripheral end of the front cover 40 and with its inner peripheral end in close contact with the shaft 43. The pump shell 41 rotates integrally with the front cover 40 and the shaft 43. The pump shell 41 is mounted with a plurality of pump impellers 42 on the surface (inner surface) on the engine side (right side in FIG. 1), and rotates integrally with the pump impeller 42.

  The pump impeller 42 is a blade member on the pump side (see FIG. 1). The pump impeller 42 is disposed so as to face the turbine runner 46. The pump impeller 42 has an outer end attached to the pump shell 41 and an inner end attached to the pump core 44. The pump impeller 42 rotates integrally with the pump shell 41 and the pump core 44. The pump impeller 42 is formed in a shape that pushes out the ATF flowing from the stator 49 toward the turbine runner 46 side when the pump shell 41 rotates in one direction.

  The shaft 43 is a cylindrical shaft member rotatably supported by a case (not shown) that covers the outer periphery of the torque converter 4 and the torque fluctuation absorber 3 or the transmission side (see FIG. 1). The shaft 43 is in close contact with the inner peripheral end of the pump shell 41 and is welded, and rotates integrally with the pump shell 41. The shaft 43 is arranged on the outer periphery of the shaft 51 at a predetermined interval.

  The pump core 44 is an annular member to which inner end portions of a plurality of pump impellers 42 are attached (see FIG. 1).

  The turbine shell 45 is an annular member that constitutes a space for circulating the ATF (see FIG. 1). The turbine shell 45 is fixed to the turbine hub 48 by a plurality of rivets at the inner peripheral portion. The turbine shell 45 rotates integrally with the turbine hub 48. The turbine shell 45 is mounted with a plurality of turbine runners 46 on the transmission side (left side in FIG. 1), and rotates together with the turbine runner 46. In the turbine shell 45, a plate member 52 is fixed by welding on the surface (outer surface) on the engine side (right side in FIG. 1).

  The turbine runner 46 is a blade member on the turbine side (see FIG. 1). The turbine runner 46 is disposed so as to face the pump impeller 42. The turbine runner 46 has an outer end attached to the turbine shell 45 and an inner end attached to the turbine core 47. The turbine runner 46 rotates integrally with the turbine shell 45 and the turbine core 47. The turbine runner 46 is formed in such a shape as to rotate by receiving the ATF pushed out from the rotating pump impeller 42 and to discharge the ATF toward the stator 49. The turbine runner 46 can rotate independently of the pump impeller 42.

  The turbine core 47 is an annular member to which inner end portions of the plurality of turbine runners 46 are attached (see FIG. 1).

  The turbine hub 48 is a member having a flange portion extending radially outward from a cylindrical hub portion (see FIG. 1). In the turbine hub 48, the turbine shell 45 is fixed by a plurality of rivets at the outer peripheral portion of the flange portion. The turbine hub 48 is spline engaged with the input shaft 6 of the transmission so as to be axially movable and non-rotatable on the inner peripheral side of the hub portion. The turbine hub 48 rotates integrally with the turbine shell 45 and the input shaft 6. On the outer peripheral surface of the hub portion of the turbine hub 48, a cylindrical portion of the inner peripheral portion of the lockup piston 53 is disposed so as to be slidable in the axial direction. The sliding surfaces of the turbine hub 48 and the lockup piston 53 are sealed.

  The stator 49 is a member having a plurality of blades for rectifying the flow of ATF returning from the turbine runner 46 to the pump impeller 42 (see FIG. 1). The stator 49 is disposed at a position closer to the inside in the radial direction between the pump impeller 42 and the turbine runner 46. The stator 49 acts to change the flow direction of ATF flowing from the turbine runner 46 to the pump impeller 42. The stator 49 is attached to a case (not shown) of a transmission (not shown) via a one-way clutch 50 and a shaft 51, and can rotate only in one direction.

  The one-way clutch 50 is a clutch that can rotate only in one direction (see FIG. 1). As the one-way clutch 50, a structure using a roller, a sprag, or a ratchet mechanism can be used. The one-way clutch 50 is disposed between the shaft 43 and the turbine hub 48 in the axial direction, and is disposed between the stator 49 and the shaft 51 in the radial direction. In the one-way clutch 50, the outer ring is fixed to the stator 49, and the inner ring is spline engaged with the shaft 51 so as to be axially movable and non-rotatable.

  The shaft 51 is a cylindrical shaft member that is non-rotatably attached to a case (not shown) of a transmission (not shown) (see FIG. 1). The shaft 51 is spline engaged with the inner ring of the one-way clutch 50 so as to be axially movable and non-rotatable. The shaft 51 is arranged inside the cylindrical shaft 43 at a predetermined interval. The shaft 51 is arranged on the outer periphery of the input shaft 6 of the transmission, and supports the input shaft 6 rotatably via a bush.

  The plate member 52 is an annular member fixed to the outer surface of the turbine shell 45 by welding (see FIG. 1). The plate member 52 is spline-engaged with the lockup piston 53 so as to be axially movable and non-rotatable. The plate member 52 rotates integrally with the turbine shell 45 and the lockup piston 53.

  The lock-up piston 53 is an annular piston for directly connecting the pump impeller 42 and the turbine runner 46 when the rotational speed difference is small (see FIG. 1). The lockup piston 53 includes an oil chamber 56 disposed between the lockup piston 53 and the front cover 40 in a space surrounded by the front cover 40 and the pump shell 41, and the lockup piston 53 and the pump shell 41. And an oil chamber 57 disposed between the two. The lock-up piston 53 has an annular friction material 54 fixed to a surface of the outer peripheral portion on the front cover 40 side, and rotates integrally with the friction material 54. The lockup piston 53 rotates integrally with the crankshaft 2 via the friction material 54, the front cover 40, and the torque fluctuation absorber 3 when the friction material 54 frictionally engages with the front cover 40. The lock-up piston 53 is spline-engaged with the plate member 52 at its outer peripheral end so as to be axially movable and non-rotatable. The lockup piston 53 rotates integrally with the input shaft 6 of the transmission via the plate member 52, the turbine shell 45, and the turbine hub 48. The lock-up piston 53 is arranged so as to be slidable in the axial direction with respect to the outer peripheral surface of the cylindrical hub portion of the turbine hub 48, and is sealed by a sliding surface with the turbine hub 48. The lockup piston 53 is pressed toward the front cover 40 when the oil pressure in the oil chamber 56 is lower than the oil pressure in the oil chamber 57, and the friction material 54 and the front cover 40 are frictionally engaged. The lock-up piston 53 moves away from the front cover 40 when the oil pressure in the oil chamber 56 is higher than the oil pressure in the oil chamber 57, and releases the frictional engagement between the friction material 54 and the front cover 40. . The oil pressure in the oil chambers 56 and 57 is controlled by a hydraulic circuit (not shown), and the oil pressure in the oil chamber 56 is made lower than the oil pressure in the oil chamber 57 (the crankshaft 2 and the input shaft). 6 is eliminated), and the lockup state is released by making the oil pressure in the oil chamber 56 higher than the oil pressure in the oil chamber 57.

  The friction material 54 is an annular member that is fixed to the lock-up piston 53 (or the front cover 40 is acceptable) and that can be frictionally engaged with the front cover 40 (see FIG. 1).

  The input shaft 6 is an input shaft of the transmission (see FIG. 1). The input shaft 6 is disposed on the inner side of the shaft 51, and supports the shaft 51 rotatably through a bush. The input shaft 6 is spline-engaged so as to be axially movable and non-rotatable on the inner peripheral side of the hub portion of the turbine hub 48, and rotates integrally with the turbine hub 48.

  According to the first embodiment, the cylindrical portion 17f that is supported by the concave portion 2b of the crankshaft 2 is integrally formed on the side plate 17, so that the cost of the apparatus can be reduced. Further, since the heavy torque fluctuation absorber 3 is directly centered on the crankshaft 2, the unbalance after the torque fluctuation absorber 3 is assembled to the crankshaft 2 can be reduced. Furthermore, since the cylindrical portion 17f of the side plate 17 is inserted inside the concave portion 2b of the crankshaft 2, the axial length of the entire apparatus can be shortened.

  Further, according to the first embodiment, by installing the bearing 29 on the radially inner side of the PCD of the bolt 13 (crank bolt), the size of the bearing 29 can be reduced (smaller diameter), and the cost of the apparatus can be reduced. Can do. In addition, since the torque converter 4 (center piece 40a) is supported via the bearing 29 with respect to the torque fluctuation absorber 3 (side plate 17), the torque converter 4 and the torque fluctuation absorber 3 are Axis misalignment does not occur. Furthermore, even if the torque converter 4 is deformed by ballooning, the center piece 40a can move in the axial direction with respect to the bearing 29. Even if the center piece 40a moves in the axial direction, it does not conflict with the side plate 17 or the crankshaft 2. Thus, the entire torque converter 4 is not displaced toward the transmission side (in the axial direction), and components of the torque converter 4 do not interfere with other parts.

  Further, according to the first embodiment, the axial contact length 62 of the portion where the concave portion 2b (including the inside of the cylindrical portion 2a) of the crankshaft 2 and the cylindrical portion 17f of the torque fluctuation absorber 3 are in contact with each other is shortened. Thus, it is possible to suppress the oscillation of vibration (eccentricity) at the end of the crankshaft 2 from being transmitted to the torque fluctuation absorber 3. As a result, the inertia of the swinging direction of the end of the crankshaft 2 is reduced, the excitation force to the crank journal (the shaft portion between the cranks in the engine) is also reduced, and NV (noise vibration) from the engine to the body is reduced. Improved characteristics. The engine output torque is transmitted to the torque fluctuation absorber 3 through the soft drive plate 10.

  Further, according to the first embodiment, the opening 17e is provided in the side plate 17 so that the head of the bolt 13 (crank bolt) is accommodated in the opening 17e, so that the axial direction can be shortened. Thus, the space near the rotating shaft 7 in which the reduction in the axial direction is relatively difficult can be used effectively, and the mountability is improved.

  Further, according to the first embodiment, since the axially inner portion of the center plate 23 is in contact with the side plate 17 via the ring member 25, the hysteresis of the damper characteristic of the torque fluctuation absorber 3 is reduced. it can. As a result, the damping performance of the damper is improved.

  Further, according to the first embodiment, in the torque fluctuation absorber 3, the axial gap length 71 between the tip of the convex portion 23 b and the seal member 24 is set between the accommodating portions 18 a of the side plates 18 (circumferential direction). Between the crankshaft 2 and the input shaft 6 of the transmission is tilted by setting the length to be shorter than the axial gap length 70 between the portion (spring receiving portion) and the center plate 23. In such a case (for example, swing deformation or misalignment of the crankshaft 2), the inclination of the shaft can be absorbed between the torque fluctuation absorber 3 and the torque converter 4. Even when a pulling force from the torque converter 4 side to the transmission side is applied, the convex portion 23b and the seal member 24 first come into contact with each other, so that the twisting operation of the torque fluctuation absorber 3 is not adversely affected. As a result, stable damper performance can be obtained in the torque fluctuation absorber 3.

  Furthermore, according to the first embodiment, the center plate 23 connected to the torque converter 4 via the block member 30 extends radially inward from the block member 30, so that the rigidity of the center plate 23 is increased. In addition, the ballooning deformation of the torque converter 4 can be reduced. The smaller the inner diameter of the center plate 23, the higher the rigidity and the greater the effect.

  It should be noted that the embodiments and examples may be changed and adjusted within the scope of the entire disclosure (including claims and drawings) of the present invention and based on the basic technical concept. Various combinations or selections of various disclosed elements (including each element of each claim, each element of each embodiment or example, each element of each drawing, etc.) are included within the scope of the claims of the present invention. Is possible. That is, the present invention naturally includes various variations and modifications that could be made by those skilled in the art according to the entire disclosure including the claims and the drawings, and the technical idea.

1 Power transmission device 2 Crankshaft (shaft member)
2a Cylindrical part (other cylindrical part)
2b Concave part 3 Torque fluctuation absorber 4 Torque converter (fluid transmission)
DESCRIPTION OF SYMBOLS 5 Lockup clutch 6 Input shaft 7 Rotating shaft 10 Drive plate 11, 12 Side member 13 Bolt 14 Block member 14a Female thread part 15 Welded part 16 Bolt 17 Side plate (input side plate)
17a Housing part 17b Hole part 17c Step part 17d Concave part 17e Opening part 17f Cylindrical part 17g Convex part 17h Hole part 18 Side plate (input side plate)
18a accommodating portion 18b convex portion 19 welded portion 20 cap 21 ring gear 22 welded portion 23 center plate (output side plate)
23a Window part 23b Convex part 24 Seal member 25 Ring member 26 Side member 27 Rivet 28 Bolt 29 Bearing (bearing member)
30 Block member 31 Welded portion 32, 33 Sheet member 34 Outer coil spring 35, 36 Inner coil spring 40 Front cover (input side member)
40a Centerpiece 41 Pump shell (input side member)
42 Pump impeller (input side member)
43 Shaft 44 Pump core (input side member)
45 Turbine shell (output side member)
46 Turbine runner (output side member)
47 Turbine core (output side member)
48 Turbine hub (output side member)
49 Stator 50 One-way clutch 51 Shaft 52 Plate member 53 Lock-up piston 54 Friction material 56, 57 Oil chamber 58 Spring accommodating chamber 60, 61 Gap 62 Contact length 63 Projection length 70, 71 Gap length

Claims (4)

A shaft member arranged rotatably,
A drive plate that rotates integrally with the shaft member;
A torque that includes an input side plate to which the rotational power of the drive plate is input and an output side plate that outputs the rotational power, and absorbs a fluctuation torque generated between the input side plate and the output side plate. A fluctuation absorber;
A fluid transmission device comprising: an input side member to which rotational power of the output side plate is input; and an output side member that outputs rotational power by receiving the rotational power from the input side member via a fluid;
With
The shaft member has a recess that is recessed in the axial direction at the end,
The input side plate has a cylindrical portion that is supported so as to be axially movable inside the concave portion, a bearing member is mounted on the inner side of the cylindrical portion, and on the inner side of the distal end portion of the cylindrical portion. Having an open hole,
The input side member has a center piece that is supported so as to be axially movable inside the bearing member;
The centerpiece can be inserted so as not to touch the hole. The shaft member has another cylindrical portion protruding in the axial direction at the end,
The drive plate is arranged on the outer periphery of the other cylindrical portion,
The power transmission device according to claim 1, wherein the cylindrical portion is supported so as to be movable in an axial direction inside the concave portion including an inner side of the other cylindrical portion.   The power transmission device according to claim 1 or 2, wherein a contact length in the axial direction between the concave portion and the cylindrical portion is set to be shorter than a protruding length in the axial direction of the cylindrical portion. . A bolt for fastening the drive plate to the shaft member from the torque fluctuation absorber side;
The power transmission device according to any one of claims 1 to 3, wherein the input side plate has an opening that accommodates a head portion of the bolt.

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