JP5494973B2 - Vehicle suspension system - Google Patents

Description

  The present invention relates to a vehicle suspension device, and more particularly to a wheel alignment adjustment structure.

  2. Description of the Related Art Conventionally, in an automobile suspension system, an elastic bush that couples an arm and a vehicle body in a vibration-proof manner is used at a vehicle body side coupling portion of an arm that supports a wheel with respect to the vehicle body. For example, as described in Patent Document 1, an arm is provided with an elastic bushing in which an elastic member made of a rubber-like elastic body is fixed to the outer periphery of a trunk portion of a core member having attachment holes to the vehicle body at both ends by vulcanization molding. There is known a structure that is press-fitted and fixed to the mounting cylinder part and that both ends of the core member of the elastic bush are directly fastened to the vehicle body by bolts. In the elastic bush having such a configuration, since the core member of the elastic bush is directly fastened to the vehicle body, for example, the rigidity of the connecting portion is ensured as compared with the elastic bush connected to the vehicle body via a bracket. can do. Further, since no bracket is required, the number of parts can be reduced, and the cost and weight can be reduced. Furthermore, since no bracket is used, space can be saved.

JP 2003-294084 A

However, since the elastic bushing of Patent Document 1 does not have a mechanism for adjusting the alignment of the wheels, it is difficult to apply the elastic bushing to a support portion at a location that affects the alignment adjustment.
The present invention has been made to solve such a problem, and an object of the present invention is to provide a vehicle suspension system including an elastic bushing that can easily adjust alignment with a simple configuration. There is.

  In order to achieve the above object, in the vehicle suspension apparatus according to claim 1, in the vehicle suspension apparatus in which the arm supporting the wheel is connected to the vehicle body via the elastic bush, the elastic bush has a cylindrical inner shape. A bush main body comprising a cylinder, a cylindrical outer cylinder that is provided outside the inner cylinder and connected to the arm, and an elastic member that is fixed and integrally provided between the inner cylinder and the outer cylinder; A pair of mounting portions that are inserted into the inner cylinder of the bush body so as to be movable in the axial direction and have cylindrical support portions formed with screw portions on the outer periphery, and are fixed to the vehicle body at both ends. Formed in a disc shape having a mounting shaft for supporting the bush body on the vehicle body and an inner diameter portion through which the support portion of the mounting shaft is inserted, and disposed on both side ends of the inner cylinder of the bush body Of the bush body A pair of stoppers for restricting displacement in the direction, and screwed to the threaded portion of the mounting shaft, and the bushing body is mounted by sandwiching the inner cylinder of the bushing body from both sides in the axial direction via the pair of stoppers A pair of nuts fixed to the shaft are provided, and the fixing position of the bushing body with respect to the mounting shaft can be adjusted in the axial direction by changing the screwing position of the pair of nuts.

Furthermore, in the suspension system of a vehicle according to claim 1, before Symbol elastomeric bushing has a hollow cylindrical shape, wherein with the mounting shaft is inserted therein, with said inner cylinder of said bushing body to the outside can be rotated A first adjustment having a cylindrical portion to be inserted and a first adjustment disc portion formed in a disc shape eccentric to the center of the cylindrical portion at one end of the cylindrical portion and abutting against a side surface of the stopper A pair of a member and the first adjusting disk portion is provided, and has a disk shape having a fitting portion that is fitted to the other end portion of the cylindrical portion while being eccentric from the center of the cylindrical portion. A second adjustment member having a second adjustment disk portion that contacts the side surface of the stopper in a state of being fitted to the cylindrical portion and moves in a rotation direction in synchronization with the first adjustment member. And the inner cylinder of the bush body is opposed to the bush body. The cylindrical portion is an oval hollow shape that is movable in the radial direction, and the pair of stoppers is an oval whose inner diameter portion is matched to the oval shape of the inner cylinder, and the bush body On the other side that is not on the side in contact with the inner cylinder, there is formed a restricting portion that is provided on both sides in the longitudinal direction of the inner diameter portion and that abuts on the periphery of the first or second adjusting disc portion to restrict the position. And rotating the first adjustment disc portion and the second adjustment disc portion about the attachment shaft, thereby setting the relative position of the bush body and the attachment shaft to the longitudinal direction of the inner cylinder. It can be adjusted in the direction.

  According to the first aspect of the present invention, the threaded portion is formed on the outer periphery of the mounting shaft that is inserted into the inner cylinder of the bushing body connected to the arm and fixed to the vehicle body, and a pair of nuts are screwed from both sides of the inner cylinder of the bushing body. The bush main body is fixed to the mounting shaft by being sandwiched together, and the fixing position of the bush main body with respect to the mounting shaft can be adjusted in the axial direction by changing the screwing position of the pair of nuts.

As a result, the position of the arm connected to the bushing body is moved in the width direction of the vehicle body (the axial direction of the mounting shaft) by adjusting the fastening position by loosening the nut and making the fixing position of the bushing body fixed to the mounting shaft variable. The alignment can be adjusted.
Therefore, it is not necessary to loosen or remove the coupling between the elastic bush and the vehicle body, that is, the coupling between the arm and the vehicle body, and the alignment can be easily adjusted by simply moving the nut fastening position. be able to. In addition, since the nut is regularly moved according to the screw pitch of the screw portion, fine adjustment can be easily performed.

Thus, according to the first aspect of the present invention, there is provided a suspension device including an elastic bush capable of fine alignment adjustment with a simple configuration with reduced cost without significantly changing the structure of the elastic bush. Can do.
Further, in the invention of claim 1, wherein the resilient bushing further mounting shaft is inserted therein, the cylindrical portion inner cylinder of the bushing body to the outside is inserted rotatably, and eccentric with respect to the center of the cylindrical portion A first adjustment member having a first adjustment disk portion that contacts the side surface of one stopper, and is fitted to the other end portion of the cylindrical portion while being eccentric with respect to the center of the cylindrical portion, and the other comprising a second adjustment disc portion of the disc-shaped abuts against the side surface of the stopper, it comprises a first dynamic ku synchronization with the rotational direction adjusting member second adjusting member, and the inner cylinder of the further bushing body a hollow oval to allow movement between the inner diameter portions of the pair of stoppers cylindrical portion in a radial direction relative to the bushing body, also on the side of the pair of stoppers, a first or longitudinal sides of the inner diameter portion A rule for regulating the position by contacting the peripheral edge of the second adjusting disc Has a section, by rotating the first adjusting disk portion and a second adjusting disk portion around the mounting shaft, the longitudinal of the ellipse of the inner cylinder relative position between the bushing and the mounting shaft It can be adjusted in the direction.

  Thus, by rotating the first adjustment disc portion and the second adjustment disc portion around the attachment shaft, the relative position between the bush body and the attachment shaft can be adjusted in the longitudinal direction of the inner cylinder. Therefore, by rotating the first and second adjustment members, the pair of stoppers are pushed by the peripheral edges of the first adjustment disc portion and the second adjustment disc portion and moved in the radial direction of the longitudinal length of the inner diameter portion. At the same time, the bush main body fitted to the pair of stoppers is moved in the longitudinal direction of the oval inner cylinder (the radial direction of the longitudinal length of the inner cylinder). That is, the bush body can be moved in the radial direction with respect to the mounting shaft fixed to the vehicle body.

  Therefore, the arm can be moved not only in the axial direction of the bushing body (the left-right direction of the vehicle body) but also in the radial direction of the bushing body (for example, in the longitudinal direction of the vehicle body or in the vertical direction). It can be carried out.

1 is a schematic configuration diagram of a vehicle suspension device according to an embodiment of the present invention. It is sectional drawing which follows the AA line in FIG. 1 which paid its attention to the structure which achieves the 1st alignment of this invention. It is a disassembled perspective view of the elastic bush of FIG . It is the schematic of the attachment axis | shaft of FIG. It is the schematic of the bush main body of FIG. It is the schematic of the stopper of FIG. It is a schematic explanatory drawing at the time of the first alignment adjustment in the vehicle body width direction in the present invention. It is sectional drawing which follows the AA line in FIG. 1 which paid its attention to the structure which achieves the 2nd alignment of this invention. It is a disassembled perspective view of the elastic bush of FIG . It is the schematic of the attachment axis | shaft of FIG. It is the schematic of the adjustment cylinder member of FIG. It is the schematic of the adjustment board member of FIG. It is the schematic of the bush main body of FIG. It is the schematic of the stopper of FIG. It is a schematic explanatory drawing at the time of the second alignment adjustment in the longitudinal direction of the vehicle body in the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, a schematic configuration of a vehicle suspension apparatus according to the present invention will be described.
FIG. 1 is a schematic configuration diagram of a vehicle suspension device according to an embodiment of the present invention. In the figure, the arrow “front” indicates the vehicle body front direction, and the arrow “lateral” indicates the vehicle body width direction.
As shown in FIG. 1, the vehicle suspension apparatus of the present embodiment includes an elastic bush 10 (10 ′) that elastically supports an arm 30 that supports a wheel (not shown) on a side member 20 constituting a vehicle body (not shown ) . Attached.

Specifically, an outer cylinder 13 ( described later ) of the bush 10 (10 ′) is press-fitted into a support hole 31 ( described later ) provided in the arm 30, and the bush 10 (10 ′) is fixed to the arm 30. In addition, the bush 10 (10 ′) is fixed to the vehicle body with bolts 40 on the side member 20. In this way, the arm 30 is fixed to the vehicle body via the bush 10 (10 ′) .
Hereinafter, the detailed structure of the elastic bushing 10 according to the first alignment in the width direction of the vehicle body of the present invention will be described.
[First alignment ]
Figure 2 shows a cross-sectional view taken along line A-A in FIG. FIG. 3 is an exploded perspective view of the elastic bush. FIG. 4 shows a schematic diagram of the mounting shaft. FIG. 5 shows a schematic view of the bush body, in which FIG. 5 (a) shows a cross-sectional view and FIG. 5 (b) shows a side view. FIG. 6 shows a schematic diagram of the stopper.

  As shown in FIGS. 2 and 3, the elastic bush 10 includes a mounting shaft 11 that is a support shaft, an outer tube 13, an elastic member 14, and an inner tube 15, and is a cylindrical bush supported by the mounting shaft 11. The main body 12, the bush main body 12 is sandwiched from both sides of the inner cylinder 15, and a pair of stoppers 16 for restricting the axial displacement of the bush main body 12 (elastic member 14), and the bush main body 12 are sandwiched via the pair of stoppers 16. And a pair of nuts 17 fixed to the mounting shaft 11.

  As shown in FIG. 4, the attachment shaft 11 is a metal rod-like member in which flat plate-like attachment portions 11 a are formed at both ends and a central portion is a columnar support portion 11 b. Further, fastening holes 11c for inserting bolts 40 for attachment to the side members 20 are formed in the attachment portions 11a at both ends. Further, the support portion 11b is formed with an insertion portion 11d inserted through the inner cylinder 15 of the bush body 12 and a convex rotation prevention portion 11e on the outer side that prevents the inner cylinder 15 from rotating. Furthermore, screw portions 11f and 11g that are screwed into the nut 17 are formed at both ends of the support portion 11b.

As shown in FIG. 5, the bush main body 12 is integrally provided between the cylindrical inner cylinder 15, the outer cylinder 13 provided in a cylindrical shape outside the inner cylinder 15, and the inner cylinder 15 and the outer cylinder 13. The elastic member 14 is made up of.
The outer cylinder 13 is formed of a metal cylindrical shape so as to cover the outer peripheral surface of the elastic member 14, and is press-fitted into a support hole 31 formed in the arm 30 and connected to the arm 30. The inner cylinder 15 is a metal cylindrical shape having a hollow bore 15a, the outer peripheral edge of its both ends are formed in a convex shape radially outward. The inner diameter portion 15 a is formed with an inner diameter that allows the insertion portion 11 d of the attachment shaft 11 to move in the axial direction of the attachment shaft 11. Further, the inner diameter portion 15 a is formed with a concave anti-rotation groove 15 b corresponding to the rotation prevention portion 11 e of the mounting shaft 11 that prevents the inner cylinder 15 from rotating. The elastic member 14 is formed by fixing a rubber-like elastic body to the inner periphery of the outer cylinder 13 and the outer periphery of the inner cylinder 15 by vulcanization molding.

  As shown in FIG. 6, the pair of stoppers 16 have a thin metal disk shape, and an inner diameter portion of an inner diameter at which the insertion portion 11 d of the attachment shaft 11 can move in the axial direction of the attachment shaft 11 is located at the center of the disc. 16a is formed. Further, similarly to the inner cylinder 15, the inner diameter portion 16 a is formed with a concave rotation prevention groove 16 b corresponding to the rotation prevention portion 11 e of the mounting shaft 11 that prevents the stopper 16 from rotating.

And the components which comprise these elastic bushes 10 are assembled as follows.
As shown in FIGS. 2 and 3, the bush main body 12 is inserted into the insertion portion 11d of the mounting shaft 11 so that the rotation prevention groove 15b of the inner cylinder 15 is fitted into the rotation prevention portion 11e of the insertion portion 11d. Further, a pair of stoppers 16 are fitted on both sides of the inner cylinder 15 of the bushing body 12 inserted through the mounting shaft 11 so that the rotation preventing portion 11e of the insertion portion 11d of the mounting shaft 11 and the rotation preventing groove 16b are correspondingly fitted. Is inserted as follows. Further, a pair of nuts 17 are inserted from both ends of the mounting shaft 11 and screwed into the threaded portions 11 f and 11 g of the mounting shaft 11. The bush body 12 is fixed to the mounting shaft 11 by the inner cylinder 15 being held between the pair of nuts 17 via the pair of stoppers 16. Further, the bolt 40 is inserted into the fastening hole 11c of the mounting shaft 11, and the mounting shaft 11 is fixed to the side member 20 by fastening the bolt 40 to the welding nut 21 previously welded to the side member 20, and the arm 30 is elastic. It is connected to the side member via the bush 10.

The following describes operations and effects according to the first alignment of the thus constructed vehicles of the suspension.
7A and 7B are schematic explanatory diagrams at the time of the first alignment adjustment in the vehicle body width direction, where FIG. 7A shows before alignment adjustment and FIG. 7B shows after alignment adjustment. In the figure, the arrow “front” indicates the vehicle body front direction, and the arrow “lateral” indicates the vehicle body width direction.

The arm 30 is connected to the bush body 12 by press-fitting the outer cylinder 13 of the bush body 12. Then, the inner cylinder 15 of the bushing body 12 mounting shaft 11 fixed to the side members 20 by bolts 40 is inserted, the bushing body 12 is sandwiched between a pair of nuts 17 through the pair of stoppers 16 attached It is fixed to the shaft 11 (FIG. 7A). At the time of alignment adjustment, one of the pair of nuts 17 is loosened, and one nut 17 is moved, for example, by the amount of nut movement in the figure. Then, the other nut 17 is moved in the same manner as the one nut 17. Thus a pair of stoppers 16 arranged on both sides of the bushing body 12 and the bushing body 12 is moved to one side with the other nut 17. At this time, the arm 30 connected to the bush body 12 is moved together. Further, by tightening the other nut 17, the bush body 12 is re-fixed via the stopper 16 and the arm 30 is fixed. That is, the arm 30 can be moved by the amount of movement of the arm in the drawing by moving the bushing body 12 by the amount of movement of the nut (FIG. 7B).

Thus, the fastening position of the pair of nuts 17 provided in the elastic bushing 10 is adjusted, and the fixing position of the bushing body 12 with respect to the mounting shaft 11, that is, the fixing position of the arm 30 is set in the vehicle body width direction (the axis of the mounting shaft 11 Direction), the first alignment of the wheels can be adjusted.
As described above, with the above-described structure, it is not necessary to remove the coupling between the elastic bush 10 and the side member 20, that is, the coupling between the arm 30 and the side member 20 during the first alignment adjustment, and the fastening position of the nut 17 is moved. It is possible to easily adjust the first alignment of the wheels by a simple operation. In addition, since the nut 17 is regularly moved according to the screw pitch of the screw portions 11f and 11g of the mounting shaft 11, fine adjustment can be easily performed.

In addition, by providing the mounting shaft 11 with the screw portions 11f and 11g and using the stopper 16 and the nut 17 as described above, the structure of the elastic bush 10 can be reduced without changing the structure of the elastic bush 10 with a simple configuration . A suspension device including an elastic bush capable of adjusting one alignment can be provided.
[Second alignment ]
In addition to the first alignment described above, the vehicle suspension device of the present invention can also perform a second alignment of the wheels in the longitudinal direction of the vehicle body. This second alignment will be described below.

To enable the second alignment arm 30 described above is also movable in the longitudinal direction of the vehicle, it will be explained with the structure of the movable arm 30 in the front-rear direction below.
FIG. 8 shows a cross-sectional view along the line AA in FIG. 1 as in FIG . FIG. 9 is an exploded perspective view of the elastic bush. FIG. 10 shows a schematic diagram of the mounting shaft. FIG. 11 is a schematic view of the adjustment cylinder member, in which (a) is a cross-sectional view and (b) is a side view. FIG. 12 is a schematic view of the adjustment plate member. FIG. 13 shows a schematic view of the bush main body 12, in which (a) shows a cross-sectional view and (b) shows a side view. FIG. 15 is a schematic view of the stopper, in which (a) is a cross-sectional view and (b) is a side view.

As shown in FIGS. 8 and 9, the elastic bush 10 ′ includes a mounting shaft 11 ′ that is a support shaft, a cylindrical bush body 12 that includes an outer cylinder 13 ′, an elastic member 14 ′, and an inner cylinder 15 ′. When, 'bushing body Nde write sandwiched from both sides of the 12 (elastic member 14' the inner tube 15 a bushing body 12 'and the inner cylinder 15' a pair of stoppers 16 for restricting the axial displacement of) one located on one side of the 'abuts on, the one side of the stopper 16' of the stopper 16 regulating cylinder member with which 'the mounting shaft 11 the bushing body 12 (inner cylinder 15)' to move in the longitudinal direction of the vehicle body (the first adjustment member ) and 18, the adjustment sleeve member 18 ends in fitted with a 'abut against the adjusting tube member 18 a stopper 16 of the other side in conjunction with' other stopper 16 bush body 12 (inner cylinder 15 ') moves in the longitudinal direction of the vehicle body relative to the mounting shaft 11 'bets The mounting shaft 11 is configured such that the leveling member (second adjusting member) 19 and the bush main body 12 (inner cylinder 15 ′) are sandwiched between the pair of stoppers 16 ′, the adjusting cylinder member 18 and the adjusting plate member 19. It is comprised with a pair of nut 17 fixed to '.

  As shown in FIG. 10, the mounting shaft 11 ′ is a metal bar-shaped member in which flat plate-shaped mounting portions 11 a ′ are formed at both ends and the center portion is a cylindrical support portion 11 b ′. Further, fastening holes 11c 'for inserting bolts 40 for attachment to the side member 20 are formed in the attachment portions 11a' at both ends. Further, an insertion portion 11 d ′ that is inserted through the adjustment cylinder member 18 is formed in the support portion 11 b ′. Further, screw portions 11 f ′ and 11 g ′ screwed with the nut 17 are formed at both ends of the support portion 11 b ′.

As shown in FIG. 11, the adjustment cylinder member 18 includes a cylindrical portion 18a formed in a hollow cylindrical shape, and an adjustment disk portion (first first) protruding in a radial shape at one end of the cylindrical portion 18a. Adjustment disk portion) 18b. The cylindrical portion 18a has an inner diameter set so that the support portion 11b 'of the mounting shaft 11' is rotatably inserted, and an outer diameter is rotatably inserted into the inner diameter portion 15a 'of the inner cylinder 15' of the bush body 12. Is set to be. Further, a rotation synchronization groove 18c that is concave in the center direction and extends in the axial direction is formed in the outer diameter portion of the cylindrical portion 18a. The adjustment disc portion 18b has a disc shape with a predetermined outer diameter and is formed so as to be eccentric from the center of the cylindrical portion 18a. Adjusting disk portion 18b is in the state assembled shown in FIG. 8, and is configured to abut a side face of the 'opposite side of the stopper 16 and the side contacting' the inner cylinder 15 of the bushing body 12. The adjusting disk portion 18b is a member that acts on a restricting portion 16f ′ of a stopper 16 ′, which will be described later, and adjusts the forward / backward movement amount of the bush body 12 via the topper 16 ′.

As shown in FIG. 12, the adjustment plate member 19 is a metal thin plate member, and an adjustment disk portion (second adjustment disk portion) having a disk shape with the same predetermined outer diameter as that of the adjustment disk portion 18b. 19a and a fitting portion 19b that is formed in the adjustment disc portion 19a and is fitted to the cylindrical portion 18a of the adjustment cylinder member 18. The fitting portion 19b has a disc shape that is eccentric from the center of the adjustment disc portion 19a, and the amount of eccentricity is the same as the eccentric amount of the adjustment disc portion 18b with respect to the cylindrical portion 18a of the adjustment cylinder member 18. Is set to That is, the adjustment disc member 19a is set to be in the same eccentric state as the adjustment disc portion 18b with respect to the cylinder portion 18a in a state where the adjustment plate member 19 is fitted to the cylinder portion 18a of the adjustment cylinder member 18. Yes. The adjustment disc portion 19a is in the assembled state shown in FIG. 8, and is configured to abut a side face of the 'opposite side of the stopper 16 and the side contacting' the inner cylinder 15. Further, the inner diameter portion 19b, rotation synchronization pawl 19c forming a convex shape toward the center side at a position corresponding rotational synchronization grooves 18c to the rotational direction is formed on the outer diameter of the cylindrical portion 18a of the adjusting tube member 18 Is formed. By fitting the rotation synchronization claw 19c of the adjustment plate member 19 in accordance with the rotation synchronization groove 18c of the adjustment cylinder member 18, the eccentric directions of the adjustment disk portion 19a and the adjustment disk portion 18b are adjusted and the adjustment plate member 19 is The adjustment cylinder member 18 is rotated in synchronization. The adjustment disc portion 19a is a member that acts on a restricting portion 16f ′ of a stopper 16 ′, which will be described later, and adjusts the amount of forward and backward movement of the bush body 12 via the stopper 16 ′, similarly to the adjustment disc portion 18b.

As shown in FIG. 13, the bush main body 12 includes a cylindrical inner cylinder 15 ′, an outer cylinder 13 ′ provided in a cylindrical shape outside the inner cylinder 15 ′, and an inner cylinder 15 ′ and an outer cylinder 13 ′. It is comprised from elastic member 14 'provided integrally among them.
The outer cylinder 13 ′ is a metal cylindrical shape and is formed so as to cover the outer peripheral surface of the elastic member 14 ′. The outer cylinder 13 ′ is press-fitted into a support hole 31 formed in the arm 30 and connected to the arm 30.

The inner cylinder 15 ′ has a hollow metal cylinder shape. The inner diameter portion 15a ′ of the inner cylinder 15 ′ is formed in an ellipse that is long in the front-rear direction of the vehicle body, and the cylindrical portion 18a of the adjustment cylinder member 18 moves along the longitudinal direction (vehicle body front-rear direction) of the inner diameter portion 15a ′. The shape can be inserted through. In other words, the inner cylinder 15 ′ is movable in the longitudinal direction of the vehicle body, which is the longitudinal direction of the inner diameter part 15 a ′, with respect to the cylindrical part 18 a of the adjustment cylinder member 18. Further, the inner cylinder 15 'axial end portions of the stopper 16''is formed as a, these fitting portions 15c' fitting portion 15c to be fitted with the outer peripheral positioning forming a concave shape toward the center in the A groove 15d 'is formed.

The elastic member 14 'is formed by attaching a rubber-like elastic body to the inner periphery of the outer cylinder 13' and the outer periphery of the inner cylinder 15 'by vulcanization molding.
As shown in FIG. 14, the pair of stoppers 16 'is a metal disk-shaped thin plate. In addition, an oblong inner diameter portion 16a ′ is formed at the center of the stopper 16 ′ in the longitudinal direction of the vehicle body in accordance with the shape of the inner diameter portion 15a ′ of the inner cylinder 15 ′ of the bush main body 12, and this inner diameter portion 16a. The cylindrical portion 18a of the adjustment cylinder member 18 can be inserted into and can be moved in the front-rear direction. Further, a fitting portion 16c ′ having an inner diameter capable of fitting with the fitting portion 15c ′ of the inner cylinder 15 ′ is formed on one end face of the stopper 16 ′. Further, the fitting portion 16c ', the inner cylinder 15' positioning pawl 16d which forms a convex shape toward the center so as to correspond to the 'positioning groove 15d formed in the outer periphery of' the fitting portion 15c in the 'is formed ing. Further, the other end surface of the stopper 16 ′ (the surface not in contact with the inner cylinder 15 ′) is in contact with the peripheral edges of the adjustment disk portions 18b and 19a having a predetermined outer diameter formed on the adjustment cylinder member 18 and the adjustment plate member 19. A pair of restricting portions 16f ′ that are in contact and restrict the position are formed. The restricting portion 16f ′ is a stepped portion extending in the vertical direction of the vehicle body, that is, in a direction perpendicular to the longitudinal direction (vehicle body longitudinal direction) of the inner diameter portion 16a ′, and is predetermined on the front and rear sides (both sides in the longitudinal direction) of the inner diameter portion 16a. It is provided in a pair with an interval of. That is, the other end surface of the stopper 16 ′ is in a state in which grooves having a predetermined interval extending in the vertical direction are formed by the pair of restricting portions 16f ′.

Incidentally, regulation Seito member 18 and adjustment plate adjusting disk portion 18b of the member 19, each of 19a, in a state of being fitted between the 'pair of regulating portions 16f of the' corresponding side of the stopper 16, the stopper 16 Is abutted against .
Parts constituting the elastic bushing 10 'is assembled as follows. As shown in FIGS. 8 and 9, the insertion portion 11 d ′ of the attachment shaft 11 ′ is rotatably inserted into the inner diameter portion of the cylindrical portion 18 a of the adjustment cylinder member 18. Furthermore, from the other end of the adjusting cylinder member 18 opposite to the adjusting disc portion 18b of the adjusting cylinder member 18, 'one of the stopper 16 of the' regulating portion 16f 'and the adjustment circle of the pixel pair of stoppers 16 is fitted to a position where contact with the adjusting disk portion 18b to the outer diameter of the cylindrical portion 18a of the plate portion 18b and the tone in correspondence with Seito member 18. The adjustment disk portion 18b of the adjustment cylinder member 18 is in a state of being fitted between the pair of restriction portions 16f ′ of the one stopper 16 ′. Further, from the other end of the adjustment cylinder member 18, the inner cylinder 15 ′ of the bush main body 12 is fitted into the outer diameter portion of the cylinder portion 18 a of the adjustment cylinder member 18. Then, the positioning claw 16d ′ of the one stopper 16 ′ and the positioning groove 15d ′ of the inner cylinder 15 ′ are made to correspond to each other, and the fitting part 15c ′ of the inner cylinder 15 ′ is fitted to the fitting part 16c ′ of the one stopper 16 ′. Are fitted. Then, the Awa fitted to the outer diameter of the cylindrical portion 18a of the adjusting cylinder member 18 'the other stopper 16 of the' a pair of stopper 16 from the other end of the adjusting cylinder member 18. Then, 'the fitting portion 16c of the' other stopper 16, the other 'positioning groove 15d of' stopper 16 'positioning pawl 16d' of the inner cylinder 15 and the 'fitting portion 15c' of the inner cylinder 15 in correspondence Fitted. Further, adjustment johnsongrass in correspondence with the position of the rotation synchronization groove 18c of the cylindrical portion 18a and the rotating synchronous claw 19c of the member 19 in the adjustment cylinder member 18, the adjustment plate member 19 is adjusted from the other end of the adjusting tube member 18 The cylindrical member 18 is fitted to the outer diameter portion of the cylindrical portion 18a , whereby the inner diameter portion 19b of the adjustment plate member 19 and the outer diameter portion of the cylindrical portion 18a are fitted to each other . The adjusting disk portion 19a of the adjustment plate member 19 is abutted against the other stopper 16 'in a state of fitted between a' pair of regulating portions 16f of the 'other stopper 16. Further, a pair of nuts 17 are fitted into the mounting shaft 11 ′ from both ends of the mounting shaft 11 ′, and screwed into the screw portions 11f ′ and 11g ′ of the mounting shaft 11 ′ . Thereby , the bush main body 12 is fixed to the mounting shaft 11 ′ in a state where the inner cylinder 15 ′ is sandwiched between the pair of stoppers 16 ′ via the adjustment cylinder member 18 and the adjustment plate member 19. Then, the bolt 40 is inserted into the fastening hole 11 c ′ of the mounting shaft 11 ′, and the mounting shaft 11 ′ is fixed to the side member 20 by fastening the bolt 40 and the welding nut 21 previously welded to the side member 20. .

Hereinafter, a description of the operation and effects of the second alignment in the vehicles of the suspension system of the present invention configured as described above.
FIGS. 15A and 15B are schematic explanatory diagrams at the time of the second alignment adjustment in the longitudinal direction of the vehicle body. FIG. 15A shows before alignment adjustment, and FIG. 15B shows after alignment adjustment. In the figure, the arrow “front” indicates the vehicle body front direction, and the arrow “up” indicates the vehicle body upward direction.

The arm 30 is connected to the bush body 12 by press-fitting the outer cylinder 13 ′. The bush body 12 is fixed to a mounting shaft 11 ′ fixed to the side member 20 by a bolt 40 with a pair of nuts 17 through a pair of stoppers 16 ′, an adjustment cylinder member 18, and an adjustment plate member 19. (FIG. 15A). When the second alignment is adjusted by moving the arm 30 in the longitudinal direction of the vehicle body, the pair of nuts 17 are loosened, and one or both of the adjustment disc portion 18b of the adjustment cylinder member 18 and the adjustment disc portion 19a of the adjustment plate member 19 are adjusted. Are rotated in the same direction around the cylindrical portion 18a (mounting shaft 11 '). For example, when the adjustment cylinder member 18 is moved by the rotation amount in the drawing, the arm 30 is moved by the arm movement amount in the drawing together with the bushing body 12 (FIG. 15B). The second alignment is adjusted by adjusting the amount of movement. Then, if the nut 17 is tightened to re-fix the bushing body 12, the second alignment adjustment is completed.

  More specifically, for example, when the adjustment cylinder member 18 and the adjustment plate member 19 are rotated by the amount of rotation in the drawing, the adjustment disk portions 18b and 19a of the adjustment cylinder member 18 and the adjustment plate member 19 become cylinders of the adjustment cylinder member 18. The adjustment disk portions 18b and 19a are formed eccentrically with respect to the cylindrical portion 18a. Therefore, the adjustment disk portions 18b and 19a are rotated eccentrically, and the adjustment disk portions 18b and 19a are rotated. Thus, the restricting portion 16f on the vehicle body rearward side of the stopper 16 'is pushed in the vehicle rearward direction. The stopper 16 ′ and the inner cylinder 15 ′ of the bushing body 12 are fixed by a fitting portion 16c ′ and a fitting portion 15c ′. Furthermore, the inner diameter portion 15a ′ of the inner cylinder 15 ′ and the inner diameter portion 16a of the stopper 16 ′. Since 'is formed as an ellipse in the longitudinal direction of the vehicle body, the bushing body 12 is moved in the vehicle body rearward direction along the longitudinal direction of the inner diameter portion 15a' of the inner cylinder 15 '. As the bush body 12 moves, the arm 30 connected to the bush body 12 is moved in the rear direction of the vehicle body by an arm movement amount corresponding to the rotation amount of the adjustment cylinder member 18 or the adjustment plate member 19. Of course, if the adjusting cylinder member 18 or the adjusting plate member 19 is rotated in the front direction of the vehicle body in the direction opposite to the rotation amount of FIG.

As described above, the second alignment can be adjusted by moving the arm 30 in the longitudinal direction of the vehicle body by adjusting the position of the bushing body 12 in the longitudinal direction.
Further, as is clear from the above description , the fixing position of the bush body 12 to the mounting shaft 11 ′ by the pair of nuts 17 is varied in the axial direction, and the fixing position of the arm 30 in the vehicle body width direction is moved. It is also possible to adjust the first alignment.

Also, during the adjustment of the second alignment , the pair of nuts 17 are loosened without removing the arm 30 from the vehicle body, and the adjustment cylinder member 18 or the adjustment plate member 19 is rotated to fix the arm 30 in the longitudinal direction of the vehicle body. The second alignment in the longitudinal direction of the vehicle body can be adjusted without removing the arm 30 from the vehicle body.
In the embodiment , the inner diameter portion 15a ′ of the inner cylinder 15 ′ of the bush main body 12 and the inner diameter portion 16a ′ of the stopper 16 ′ are elongated in the longitudinal direction of the vehicle body. However, the present invention is not limited to this. An ellipse that is long in the vertical direction of the vehicle body may be used. In this case, the restriction portion 16f ′ of the stopper 16 ′ is formed above and below the inner diameter portion 16a ′, and the position of the arm 30 can be moved in the vertical direction of the vehicle body.

As described above, in the embodiment of FIG. 8, in addition to the first alignment adjustment , the second alignment adjustment in the radial direction of the bushing body 12 can be performed in addition to the position of the arm 30. Can be done finely.

10 ' elastic bush
11 ' mounting shaft
12 bush body
13 ' outer cylinder
14 ' elastic member
15 ' inner cylinder
16 ' stopper
16f Restriction part 17 Nut 18 Adjustment cylinder member (1st adjustment member)
19 Adjustment plate member (second adjustment member)

Claims (1)

In a vehicle suspension device in which an arm supporting a wheel is connected to a vehicle body via an elastic bush,
The elastic bush is
A cylindrical inner cylinder, a cylindrical outer cylinder that is provided outside the inner cylinder and connected to the arm, and an elastic member that is fixed and integrally provided between the inner cylinder and the outer cylinder. The bush body,
The bush body has a cylindrical support portion that is inserted into the inner cylinder of the bush body so as to be movable in the axial direction and has a threaded portion on the outer periphery, and a pair of attachment portions that are fixed to the vehicle body are formed at both ends. A mounting shaft for supporting the bush body on the vehicle body;
A pair of discs having an inner diameter portion through which the support portion of the mounting shaft is inserted, and disposed on both side ends of the inner cylinder of the bush body to regulate axial displacement of the bush body. A stopper,
A pair of nuts that are screwed into the threaded portion of the mounting shaft and sandwich the inner cylinder of the bushing body from both sides in the axial direction through the pair of stoppers, and fix the bushing body to the mounting shaft;
By changing the screwing position of the pair of nuts, the fixing position of the bushing body with respect to the mounting shaft can be adjusted in the axial direction ,
The elastic bush is
A hollow cylindrical shape is formed, and the mounting shaft is inserted inside, and a cylindrical portion into which the inner cylinder of the bush main body is rotatably inserted, and at one end of the cylindrical portion, the cylindrical portion A first adjustment member formed in a disc shape eccentric to the center and having a first adjustment disc portion that contacts the side surface of the stopper;
A pair of the first adjusting disc portion and a disc shape having a fitting portion fitted to the other end portion of the cylindrical portion in a state of being eccentric from the center of the cylindrical portion, the cylinder A second adjusting member that has a second adjusting disk portion that is in contact with the side surface of the stopper in a state of being fitted to a portion and that moves in a rotating direction in synchronization with the first adjusting member,
The inner cylinder of the bush body has an elliptical hollow shape that allows the cylindrical portion to move in the radial direction with respect to the bush body,
The pair of stoppers is an ellipse in which the inner diameter portion is matched to the oval shape of the inner cylinder, and the other side surface of the bushing body that is not on the side in contact with the inner cylinder is arranged in the longitudinal direction of the inner diameter section. A restricting portion that is provided on both sides and is in contact with the periphery of the first or second adjusting disc portion to restrict the position is formed.
The relative position between the bush body and the mounting shaft is adjusted in the longitudinal direction of the inner cylinder by rotating the first adjusting disk portion and the second adjusting disk portion about the mounting shaft. A suspension system for a vehicle, characterized in that it is possible .

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