JP2020075611A - Support structure of power steering device - Google Patents

Abstract

To provide a support structure of a power steering device that is supported on a vehicle body frame member for supporting a vibration generator, which can suppress steering vibrations without addition of a new member.SOLUTION: In a support structure in which a gear box 11 of a hydraulic power steering device is supported through a plurality of rubber bushes on a first cross member 3 supporting a front differential, the plurality of rubber bushes include a first rubber bush 20 provided at a left-side end part in a vehicle width direction in the gear box 11, near a pinion shaft connected to a steering wheel and second and third rubber bushes provided at a right-side end part in the vehicle width direction in the gear box 11. A dynamic spring constant in a vehicle longitudinal direction and in a vehicle vertical direction in the first rubber bush 20 is set to be smaller than dynamic spring constants respectively in the vehicle longitudinal direction and in the vehicle vertical direction in the second and third rubber bushes.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a support structure for a power steering device, and more particularly to a support structure for a power steering device in which a gear box is supported by a vehicle body frame member that supports a vibration generator.

  A power steering device that includes a gear box that transmits the rotation of the steering wheel to the front wheels via a pinion and a rack and that assists the steering force of the steering wheel by the driver using hydraulic pressure or an electric motor has been conventionally known. Has been.

  As a support structure of such a power steering device, whether it is a hydraulic power steering device or an electric power steering device, a structure in which a gear box is supported by a vehicle body frame member via a plurality of bushes is general.

  In such a support structure, a plurality of bushes having the same spring constant are often used, but this may make it difficult to achieve the required characteristics.

  Therefore, for example, Patent Document 1 proposes that a mount-side structure of an electric power steering device has a spring constant of a steering-side mount portion higher (harder) than a spring constant of a motor-side mount portion. According to the patent document 1, the mount portion having a high spring constant, which is present near the pinion shaft to which the steering force is input, can stabilize the steering performance and is near the electric motor. It is said that the vibration noise of the electric motor can be reduced by the mount portion having a low spring constant.

JP, 2014-84079, A

  By the way, since the power steering device is arranged near the front wheels, the same vehicle body skeleton as a device (hereinafter also referred to as a vibration generator) that generates vibrations such as an engine and a front differential, which are also arranged near the front wheels. Although it is often supported by a member, such a support structure has the following problems.

  That is, in the support structure in which the gear box is supported by the body frame member supporting the vibration generator through the plurality of bushes having the same spring constant, the vibration body vibrates to cause the body frame to move at a speed higher than a predetermined speed. It is known that when a force is applied to a member, the gear box vibrates. In particular, when the engine or the like is in a predetermined operating state, the gearbox vibrates greatly due to the vibration of the vibration generator, and the vibration is transmitted to the pinion shaft, intermediate shaft, column shaft, etc. Finally, there is a problem that the steering wheel gripped by the driver is rocked back and forth (steering vibration occurs).

  In this respect, the above-mentioned Patent Document 1 uses mounts (bushings) having different spring constants, but does not consider the vibration of the gearbox due to the vibration generator, so can the steering vibration be suppressed? I'm not sure. This is because even if the mount portion with a low spring constant suppresses the vibration generated by the power steering device itself, which is an electric motor, the mount portion with a high spring constant exists near the pinion shaft, so that the vibration caused by the vibration generator is generated. This is because it is easy to transmit to the gear box near the pinion shaft.

  Therefore, it is conceivable to provide a mass damper on a member on the vibration transmission path such as an intermediate shaft or a column shaft, but this causes a problem that the vehicle body weight increases and the manufacturing cost increases.

  The present invention has been made in view of the above points, and an object of the present invention is to add a new member in a support structure of a power steering device that is supported by a vehicle body frame member that supports a vibration generator. The purpose of the present invention is to provide a technique for suppressing steering vibration caused by a vibration generator.

  In order to achieve the above object, in the support structure for a power steering device according to the present invention, a plurality of rubber bushes have characteristics in a predetermined direction so that it is difficult for vibrations caused by the vibration generator to be transmitted to the gearbox at least near the pinion. I try to make a difference.

  Specifically, the present invention is directed to a support structure of a power steering device in which a gearbox of the power steering device is supported by a vehicle body frame member supporting a vibration generator via a plurality of rubber bushes.

  The support structure includes, in the plurality of rubber bushes, a first rubber bush provided at an end portion on one side in the vehicle width direction of the gear box, which is close to a pinion connected to a steering wheel, and the pinion. A second rubber bush provided on the other end of the gear box in the vehicle width direction on the other side, and a dynamic spring in the vehicle longitudinal direction and the vehicle vertical direction in the first rubber bush. The constants are set to be smaller than the dynamic spring constants of the second rubber bush in the vehicle front-rear direction and the vehicle up-down direction, respectively.

  If the spring characteristics of the rubber bush provided at one end of the gear box in the vehicle width direction and the spring characteristics of the rubber bush provided at the other end in the vehicle width direction are made approximately the same, vibration will be input. In doing so, it is known that the one end and the other end are displaced in the same direction, in other words, both ends of the gear box are in the same phase in a vibration mode. In addition, in a support structure in which the gearbox is supported by the body frame member together with the vibration generator, when the fast vibration is input from the vibration generator, the gearbox often vibrates. In particular, the vibration frequency of the vibration generator and the gearbox There is a case where the gear box vibrates largely up and down when the resonance frequency of the same is matched. Therefore, in the support structure in which both ends of the gearbox are supported by the vehicle body frame member supporting the vibration generator through the rubber bushes having substantially the same spring characteristics, the vibration mode in which both ends of the gearbox are displaced in phase It is probable that a relatively large steering vibration occurred due to the upper and lower resonances of the gear box.

  Here, if the spring characteristics of all rubber bushes are changed uniformly, the resonance point of the gearbox including the rubber bush can be shifted, but both ends of the gearbox are supported via rubber bushes with the same spring characteristics. As described above, the vibration mode in which both ends of the gear box are displaced in phase does not change. In addition, when the dynamic spring constant of the rubber bush increases, the vibration from the vibration generator is easily transmitted to the gear box via the rubber bush, which may worsen the steering vibration.

  Therefore, according to the present invention, the spring characteristic of the first rubber bush closer to the pinion whose vibration is desired to be further suppressed is relatively small, and specifically, the dynamic spring in the vehicle front-rear direction and the vehicle vertical direction in the first rubber bush is relatively small. The constants are set to be smaller than the dynamic spring constants of the second rubber bush in the vehicle longitudinal direction and the vehicle vertical direction, respectively.

  This makes it possible to suppress the resonance of the gearbox by shifting the resonance point of the entire gearbox including the rubber bush with respect to the fast vibration generated by the vibration generator. Not only that, by providing a characteristic difference between the first rubber bush and the second rubber bush with respect to the dynamic spring constants in the vehicle front-rear direction and the vehicle up-down direction that affect the roll vibration around the vehicle front-rear direction axis. It is possible to cancel the vibrations by displacing both ends of the gear box in opposite phases (displacement of one end and the other end in opposite directions). Moreover, since the dynamic spring constant of the first rubber bush provided at the one end in the vehicle width direction of the gear box, which is close to the pinion connected to the steering wheel, is relatively small, at least the steering wheel is provided. On the near side, it is difficult for the vibration from the vibration generator to be transmitted to the gear box, so that the steering vibration can be further suppressed.

  As described above, according to the present invention, it is possible to suppress the shaking of the entire gear box, particularly, the shaking of the gear box on the side closer to the steering wheel, and thereby, without adding a new member such as a mass damper, Steering vibration can be suppressed.

  In addition, in the present invention, the “vibration generator” means, for example, one that generates drive system vibration such as an engine or a differential.

  As described above, according to the support structure of the power steering device of the present invention, it is possible to suppress steering vibration caused by the vibration generator without adding a new member.

It is a top view which shows typically the support structure of the hydraulic power steering apparatus which concerns on embodiment of this invention. It is a top view which shows typically a hydraulic power steering apparatus and a 1st cross member. It is a front view showing typically a hydraulic power steering device and the 1st cross member. FIG. 4 is a sectional view taken along the line AA of FIG. 3. FIG. 4 is a sectional view taken along the line BB of FIG. 3. It is a figure which shows a 1st rubber bush typically, the same figure (a) is a longitudinal cross-sectional view, and the same figure (b) is a horizontal cross-sectional view. It is a figure which shows a 2nd rubber bush typically, the same figure (a) is a longitudinal cross-sectional view, and the same figure (b) is a horizontal cross-sectional view. It is a figure which illustrates the vibration mode of a gear box typically. It is a figure which shows the simulation test result typically, The figure (a) is a graph figure which shows the relationship between the frequency and the vibration level in the edge part of the vehicle width direction left side of a gear box, and the figure (b) shows. It is a figure which shows the vibration mode of an example, and FIG.6 (c) is a figure which shows the vibration mode of a comparative example. It is a figure which illustrates typically the vibration mode of the gearbox in the conventional support structure, the figure (a) is a front view, and the figure (b) is a side view.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  In each drawing, arrow X indicates the vehicle front-rear direction, arrow Y indicates the vehicle width direction, and arrow Z indicates the vehicle up-down direction. Further, reference numeral Fr indicates the vehicle front-rear direction front side, reference numeral Rr indicates the vehicle front-rear direction rear side, reference numeral Rh indicates the vehicle width direction right side, reference numeral Lf indicates the vehicle width direction left side, reference numeral Up indicates the vehicle vertical direction upper side, reference numeral Dw. Indicates the lower side of the vehicle in the vertical direction. Further, in FIG. 8, FIG. 10A and FIG. 10B, the state before the vibration is applied is shown in white and the state when the vibration is applied is shown in black.

-Overall structure-
FIG. 1 is a plan view schematically showing a support structure of a hydraulic power steering device 10 according to this embodiment. In this support structure, as shown in FIG. 1, a gear box 11 of a hydraulic power steering device 10 includes a plurality of rubber bushes on a first cross member (body frame member) 3 supporting a front differential (vibration generator) 8. It is supported via 20, 30, 40 (see FIG. 5, FIG. 6, etc.).

  More specifically, the vehicle 1 in which the hydraulic power steering device 10 is mounted is a frame vehicle in which a cabin is supported by a frame serving as a skeleton via a body mount, and extends in the vehicle front-rear direction as shown in FIG. It is provided with a pair of left and right side rails 2, 2 and a first cross member 3 and a second cross member 7 which are bridged in the vehicle width direction with respect to the pair of left and right side rails 2, 2. The front differential 8 connected to the front end portion of the propeller shaft 9 includes a bracket 8a and a bracket 8c extending rearward from the first cross member 3, and a bracket 8b extending forward from the second cross member 7 to form a first cross. It is supported by the member 3 and the second cross member 7. The hydraulic power steering device 10 is supported by the first cross member 3 supporting the front differential 8 by attaching the gear box 11 to the first cross member 3 via the three rubber bushes 20, 30, 40. ing.

-Hydraulic power steering device-
2 is a plan view schematically showing the hydraulic power steering device 10 and the first cross member 3, FIG. 3 is a front view, and FIG. 4 is a sectional view taken along the line AA of FIG. FIG. 5 is a sectional view taken along the line BB of FIG. The hydraulic power steering device 10 is a rack and pinion type hydraulic power steering device, and includes a gear box 11, a pinion shaft 14, a rack bar (not shown), a tie rod 15, a dust boot 16, and hydraulic tubes 17, 18. And are equipped with.

  The gear box 11 includes a rack housing 12 extending in the vehicle width direction, and a valve housing 13 formed at an end of the rack housing 12 on the left side in the vehicle width direction. Inside the rack housing 12, a rack bar extending in the vehicle width direction is accommodated so as to be slidable in the vehicle width direction. The rack housing 12 also serves as a cylinder tube of a hydraulic cylinder, and has first and second oil chambers (not shown) partitioned by a piston (not shown) fixed to the outer periphery of the rack bar. .. The rack housing 12 is formed with first and second ports 12a and 12b which communicate with the first and second oil chambers, respectively. Further, dust boots 16 are attached to both ends of the rack housing 12.

  Further, a first portion for attaching the gear box 11 to the first cross member 3 in which a through hole 61a extending in the vehicle front-rear direction is formed in a lower portion of the valve housing 13 at an end portion on the left side in the vehicle width direction of the rack housing 12. The mounting portion 61 is integrally provided. On the other hand, a second mounting portion 71 for mounting the gear box 11 to the first cross member 3 is formed in a lower portion of the rack housing 12 on the right side in the vehicle width direction and has a through hole 71a extending in the vehicle front-rear direction. It is provided integrally. Further, a third attachment portion 81 for attaching the gear box 11 to the first cross member 3 is formed in an upper portion of the right end portion of the rack housing 12 in the vehicle width direction, the through hole 81a extending in the vehicle front-rear direction being formed. It is provided integrally.

  A pinion shaft 14 is inserted in the valve housing 13. Further, in the valve housing 13, an inlet port 13a connected to a pump (not shown), an outlet port 13b connected to a tank (not shown), and the first and the first via the hydraulic tubes 17 and 18. First and second cylinder ports 13c and 13d connected to the two ports 12a and 12b, respectively, and an oil passage (not shown) that connects them are formed. Further, the valve housing 13 is provided with a valve (not shown) connected to the pinion shaft 14 so as to rotate together with the pinion shaft 14, and the pinion shaft 14 and the valve rotate relative to each other so that the ports 13a, 13b, The hydraulic pressure supplied to the first and second oil chambers is controlled by changing the opening degree of the oil passage communicating with 13c and 13d.

  Both ends of the rack bar are connected to one end of the tie rod 15 in the dust boot 16 via ball joints (not shown). The other end of the tie rod 15 is connected to a knuckle arm (not shown) that supports a front wheel (not shown). On the other hand, the pinion shaft (pinion) 14 is connected to the steering wheel 50 via an intermediate shaft 52 for adjusting an angle, a column shaft 51, etc. (see FIG. 8). The pinion teeth formed on the lower end of the pinion shaft 14 mesh with the rack teeth formed on the rack bar in the gear box 11.

  With the configuration described above, when the driver operates the steering wheel 50, the rotation of the steering wheel 50 is converted into a linear movement of the rack bar in the vehicle width direction due to the engagement of the pinion teeth and the rack teeth, and the tie rod 15 and the knuckle. The left and right front wheels are steered via the arm. At this time, the relative rotation of the pinion shaft 14 and the valve causes the opening of the oil passage that communicates the inlet port 13a with one oil chamber and the oil passage that communicates the outlet port 13b with the other oil chamber. And the opening degree of the oil passage that connects the inlet port 13a and the other oil chamber and the oil passage that connects the outlet port 13b and the one oil chamber to each other decreases. A steering assist force is generated to the left or right.

-Mounting structure-
The hydraulic power steering device 10 configured as described above is provided with a first rubber bush 20 provided at an end portion on the left side (one side) in the vehicle width direction of the gear box 11, which is close to the pinion shaft 14 connected to the steering wheel 50. And a second rubber bush 30 and a third rubber bush 40, which are provided at an end portion of the gear box 11 on the right side (the other side) in the vehicle width direction, which is far from the pinion shaft 14, and which have a closed cross-section hollow shape. It is supported by one cross member 3.

  More specifically, as shown in FIG. 2 and FIG. 3, the first cross member 3 includes a left-side inclined portion 4 that extends upward as it goes to the left side in the vehicle width direction, and an upside as it goes to the right side in the vehicle width direction. A right-side inclined portion 5 extending obliquely is formed, and upper ends of the left-side inclined portion 4 and the right-side inclined portion 5 are connected to the pair of left and right side rails 2, 2.

  As shown in FIG. 4, the left inclined portion 4 having a hollow closed section is provided with a through hole 4a having a circular cross section through which a bolt 62 can be inserted in a front portion thereof, and a collar 63 can be inserted into a rear portion thereof. A through hole 4b having a circular cross section is formed concentrically with the through hole 4a. On the other hand, as shown in FIG. 5, the right-side inclined portion 5 having a hollow closed cross-section has a through hole 5a having a circular cross section through which a bolt 72 can be inserted, and a collar 73 at the rear portion. A through hole 5b having a circular cross section that can be inserted is formed concentrically with the through hole 5a.

  Further, as shown in FIGS. 3 and 5, a bracket 6 having a hollow cross-section with the upper surface of the right inclined portion 5 is attached to the right inclined portion 5. As shown in FIG. 5, the bracket 6 is formed with a through hole 6a having a circular cross section through which a bolt 82 can be inserted in a front portion and a through hole having a circular cross section through which a collar 83 can be inserted in a rear portion. 6b is formed concentrically with the through hole 6a.

  As shown in FIG. 4, the first rubber bush (first rubber bush) 20 is composed of a front first rubber bush 21 and a rear first rubber bush 25. The first front rubber bush 21 includes an inner cylinder 22, an outer cylinder 23 that surrounds the outer circumference of the inner cylinder 22 and has a flange portion 23 a, and a substantially cylindrical rubber elastic body 24 that connects the two members 22 and 23. There is. Similarly, the rear first rubber bush 25 also includes an inner cylinder 26, an outer cylinder 27 having a flange portion 27a, and a rubber elastic body 28.

  In the first rubber bush 20, the front first rubber bush 21 is inserted from the front side and the rear first rubber bush 25 is inserted from the rear side into the through hole 61a of the first mounting portion 61 of the gear box 11. Thus, the first attachment portion 61 is attached to the gear box 11 so as to be sandwiched in the vehicle front-rear direction by the flange portions 23a and 27a. An end portion on the left side in the vehicle width direction of the gear box 11 is provided with a bolt 62 inserted into the inner cylinders 22 and 26 of the first rubber bush 20 in a collar 63 and a through hole 4a which are inserted into the through hole 4b of the left side inclined portion 4. The first cross member 3 is supported in a cantilevered state by inserting and tightening a nut 64 screwed to the tip of the bolt 62 protruding forward from the through hole 4a.

  The lower second rubber bush (second rubber bush) 30 is composed of a front second rubber bush 31 and a rear second rubber bush 35, as shown in FIG. Like the front first rubber bush 21, the front and rear second rubber bushes 31, 35 include inner cylinders 32, 36, outer cylinders 33, 37 having flange portions 33a, 37a, and rubber elastic bodies 34, 38. And are provided respectively. The second rubber bush 30 has flange portions 33a and 37a by inserting the front and rear second rubber bushes 31 and 35 from the front and the rear into the through hole 71a of the second mounting portion 71 of the gear box 11, respectively. It is attached to the gear box 11 so as to sandwich the second attachment portion 71 in the front and rear. In the lower part of the right end of the gear box 11 in the vehicle width direction, the bolt 72 inserted into the inner cylinders 32 and 36 of the second rubber bush 30 is inserted into the through hole 5b of the right inclined portion 5 and the collar 73 and the through hole. The nut 74 is inserted into the through hole 5a and is screwed onto the tip of the bolt 72 protruding forward from the through hole 5a, whereby the nut is supported in a cantilevered state by the first cross member 3.

  As shown in FIG. 5, the third rubber bush (second rubber bush) 40 includes a front third rubber bush 41 and a rear third rubber bush 45. Like the front first rubber bush 21, the front and rear third rubber bushes 41, 45 include inner cylinders 42, 46, outer cylinders 43, 47 having flange portions 43a, 47a, and rubber elastic bodies 44, 48. And are provided respectively. The third rubber bush 40 has flange portions 43a and 47a by inserting the front and rear third rubber bushes 41 and 45 from the front and the rear into the through hole 81a of the third mounting portion 81 of the gear box 11, respectively. It is attached to the gear box 11 so as to sandwich the third attachment portion 81 in the front and rear. The upper portion of the right end portion of the gear box 11 in the vehicle width direction is provided with a bolt 82 inserted into the inner cylinders 42 and 46 of the third rubber bush 40 in the collar 83 and the through hole 6a inserted into the through hole 6b of the bracket 6. The first cross member 3 is supported in a cantilevered state by inserting and tightening a nut 84 screwed onto the tip of a bolt 82 protruding forward from the through hole 6a.

-Spring characteristics-
Next, the spring characteristics of the first to third rubber bushes 20, 30, 40 will be described, but prior to this, in order to facilitate the present invention, a conventional support structure for a power steering device will be described. The conventional support structure is the same as that of the present embodiment except for the spring characteristic of the rubber bush, and thus redundant description will be omitted.

  FIG. 10 is a diagram schematically illustrating a vibration mode of the gear box 111 in the conventional support structure, FIG. 10 (a) is a front view, and FIG. 10 (b) is a side view. Note that in FIG. 10, the displacement of each part is exaggerated in order to make the diagram easy to see.

  When the rear end of the propeller shaft vibrates vertically as the engine (not shown) is driven, the front differential connected to the front end of the propeller shaft also vibrates vertically. In this case, in the conventional support structure in which the gear box 111 is supported by the cross member supporting the front differential through the plurality of rubber bushes having the same spring constant, the front differential vibrates at a speed higher than a predetermined speed. It is known that the gear box 111 vibrates when a force is applied to the cross member. In particular, when the engine or the like is in a predetermined operation state (for example, a state where the engine speed is about to be accelerated at 1000 (rpm) to 2000 (rpm)), as shown in FIG. The gearbox 111 vibrates greatly up and down due to the vibration, and as shown in FIG. 10B, the vibration is transmitted while oscillating the intermediate shaft 152, the column shaft 151, and the like, and finally the operation is performed. There is a problem of swinging the steering wheel 150 held by a person back and forth (steering vibration occurs). The reason why such steering vibration occurs is considered to be as follows.

  First, in the gear box 111, if the spring characteristic of the rubber bush at the left end in the vehicle width direction and the spring characteristic of the rubber bush at the right end in the vehicle width direction are made approximately the same, theoretically, when vibration is input, Moreover, the left and right ends are easily displaced in the same direction. Therefore, even if the swinging of the cross member is slightly different between the left and right due to the deviation of the arrangement of the front differential with respect to the cross member, as shown in FIG. 10 (a), both ends of the gear box 111 are displaced in the same phase. It becomes a mode. Further, in the support structure in which the gearbox 111 is supported by the cross member together with the front differential, when the engine or the like is in a predetermined operating state, the vibration frequency of the front differential and the resonance frequency of the gearbox 111 coincide with each other, and the resonance causes the gearbox 111 to resonate. It is considered that the box 111 vibrates up and down greatly.

  That is, in the conventional support structure in which both ends of the gear box 111 are supported by the cross member supporting the front differential through the rubber bushes having the same spring characteristics, the vibration mode in which both ends of the gear box 111 are displaced in phase It is considered that, due to the upper and lower resonances of the gear box 111, a relatively large steering vibration is generated.

  Here, if the spring characteristics of all the rubber bushes are uniformly changed, the resonance point of the gear box 111 including the rubber bushes can be shifted, but both ends of the gear box 111 are inserted through the rubber bushes having the same spring characteristics. The vibration mode in which both ends of the gear box 111 are displaced in phase does not change as long as they are supported. Further, if the dynamic spring constant of the rubber bush is increased, the vibration from the front differential can be easily transmitted to the gear box 111 via the rubber bush, so that the steering vibration may be deteriorated.

  Therefore, in the present embodiment, the first rubber bush 20 and the second and third rubber bushes 30 and 40 are provided so that the vibration caused by the front differential 8 is difficult to be transmitted to the gear box 11 at least near the pinion shaft 14. A characteristic difference is given in a predetermined direction. Specifically, in the support structure of the hydraulic power steering device 10 according to the present embodiment, the dynamic spring constants of the first rubber bush 20 in the vehicle front-rear direction and the vehicle up-down direction are set to the second and third rubber bushes 30, 40. Are set to be smaller than the dynamic spring constants of the vehicle front-rear direction and the vehicle up-down direction. Hereinafter, this configuration will be described in detail.

  6A and 6B are diagrams schematically showing the first rubber bush 20, where FIG. 6A is a vertical sectional view and FIG. 6B is a lateral sectional view. Further, FIG. 7 is a diagram schematically showing the second rubber bush 30, where FIG. 7A is a vertical sectional view and FIG. 7B is a lateral sectional view. Since the third rubber bush 40 has the same configuration as the second rubber bush 30, the description thereof will be omitted. 6 (a) and 7 (a) are longitudinal sectional views developed along the chain line aa in FIG. 6 (b) and FIG. 7 (b), respectively.

  As can be seen by comparing FIGS. 6A and 7A, the inner cylinders 22 and 26 of the first rubber bush 20 and the inner cylinders 32 and 36 of the second rubber bush 30 have the same shape and size. While the outer cylinders 23 and 27 and the rubber elastic bodies 24 and 28 of the first rubber bush 20 are formed, the outer cylinders 33 and 37 and the rubber elastic bodies 34 and 38 of the second rubber bush 30 are formed in the vehicle. The length dimension in the front-back direction is set to be short.

  In this way, by relatively shortening the length dimension of the rubber elastic bodies 24 and 28 in the vehicle front-rear direction, the dynamic spring constant of the first rubber bush 20 in the vehicle front-rear direction (for example, 5100 (N / mm)). Is nearly half smaller than the dynamic spring constant of the second and third rubber bushes 30 and 40 in the vehicle front-rear direction (for example, 8800 (N / mm)). As described above, the dynamic spring constant of the first rubber bush 20 in the vehicle front-rear direction is relatively small, that is, has a soft characteristic, so that the first rubber bush 20 is applied at a speed equal to or higher than a predetermined speed in the vehicle front-rear direction. It becomes difficult to transmit the force (vibration) of.

  Similarly, by making the lengths of the rubber elastic bodies 24 and 28 in the vehicle front-rear direction relatively short, the dynamic spring constant of the first rubber bush 20 in the vehicle up-down direction (for example, 6000 (N / mm)) is also obtained. The dynamic spring constants of the second and third rubber bushes 30 and 40 in the vertical direction of the vehicle (for example, 10400 (N / mm)) are smaller by almost half. As described above, by making the dynamic spring constant of the first rubber bush 20 in the vertical direction of the vehicle relatively small, that is, having a soft characteristic, the first rubber bush 20 is applied in the vertical direction of the vehicle at a speed higher than a predetermined speed. It is difficult to transmit the force (vibration) of.

  When the length of the rubber elastic bodies 24 and 28 in the vehicle front-rear direction is relatively shortened, the spring constant of the first rubber bush 20 in the vehicle width direction is also relatively reduced. By adjusting the thickness of 24, 28, etc., the static spring constant (for example, 1000 (N / mm)) in the vehicle width direction of the first rubber bush 20 can be adjusted to the vehicle of the second and third rubber bushes 30, 40. The static spring constant in the width direction (for example, 1050 (N / mm)) is maintained. As described above, by maintaining the static spring constant of the first rubber bush 20 in the vehicle width direction to be relatively high, that is, having a hard characteristic, the first rubber bush 20 can slowly apply a force in the vehicle width direction. It is difficult to deform, ensuring stable steering.

  According to the support structure of the present embodiment that uses the first to third rubber bushes 20, 30, and 40 with different spring characteristics set as described above, with respect to the fast vibration generated by the front differential 8 when the engine is driven, It is possible to suppress the resonance of the gear box 11 by shifting the resonance point of the entire gear box 11 including the first to third rubber bushes 20, 30, 40.

  Not only the characteristics of the first rubber bush 20 and the second and third rubber bushes 30 and 40 differ in dynamic spring constants in the vehicle front-rear direction and the vehicle up-down direction that affect roll vibration around the vehicle front-rear direction axis. 8, the both ends of the gear box 11 are displaced in opposite phases (the left end and the right end in the vehicle width direction are displaced in opposite directions) to cancel out the vibrations, as shown in FIG. You can

  Moreover, since the dynamic spring constant of the first rubber bush 20 provided at the left end of the gear box 11 in the vehicle width direction, which is close to the pinion shaft 14 connected to the steering wheel 50, is relatively small, at least On the side closer to the steering wheel 50, it is possible to make it difficult to transmit the vibration from the front differential 8 to the gear box 11.

  Together with these, as can be seen by comparing FIG. 8 and FIG. 10 (a), the vertical vibration of the gear box 11 is made smaller than that of the conventional support structure, and the intermediate shaft 52 and the column shaft 51 are reduced. It is possible to reliably suppress the front-back sway of the steering wheel 50, that is, the steering vibration by suppressing the deformation and vibration of the steering wheel.

  In addition, by maintaining the static spring constant of the first rubber bush 20 in the vehicle width direction relatively high, the first rubber bush 20 is less likely to be deformed by a slowly applied force (vibration) in the vehicle width direction. Therefore, the steering response can be stabilized. However, if the first rubber bush 20 is hard in the vehicle width direction, for example, vibration when a small stone or the like is stepped on by the front wheels is likely to be transmitted to the steering wheel 50. This point is shown in FIGS. 6 (a) and 7 (a). As shown in (), by providing the currants 24a, 28a, 34a, 38a in the vehicle width direction of each rubber elastic body 24, 28, 34, 38, it is possible to control the vibration transmitted from the front wheels.

  As described above, according to the support structure of the hydraulic power steering apparatus 10 according to the present embodiment, the vibration of the entire gear box 11 is kept close to that of the steering wheel 50 while maintaining the conventional required characteristics (for example, steering response). It is possible to suppress the swing of the gear box 11 on the side, and thus it is possible to suppress the steering vibration without adding a new member such as a mass damper.

  FIG. 9 is a diagram schematically showing a simulation test result, and FIG. 9A is a graph diagram showing a relationship between a frequency and a vibration level at an end portion on the left side in the vehicle width direction of the gear box. ) Is a diagram showing a vibration mode of the example, and FIG. 7C is a diagram showing a vibration mode of the comparative example. Note that these are obtained by performing a simulation test by CAE (Computer Aided Engineering). The example is the support structure of the present embodiment, and the comparative example is the support structure in which the spring characteristics of the three rubber bushes are set to be the same as the spring characteristics of the second rubber bush 30. Further, in FIG. 9A, the solid line represents the embodiment and the broken line represents the comparative example, and in FIGS. 9B and 9C, the solid line represents the gear box before vibration is applied, and the broken line represents It shows the gearbox when vibration is applied.

  As is clear from a comparison between FIG. 9B and FIG. 9C, in the conventional support structure, both ends of the gear box 111 are in the vibration mode in which they are displaced in the same phase. It was confirmed that in the supporting structure of No. 2, both ends of the gear box 11 can be changed to a vibration mode in which the two phases are displaced in opposite phases.

  In addition, according to the support structure of the present embodiment, as shown in FIG. 9A, the engine speed of around 1000 (rpm) to 2000 (rpm) corresponds to a state where the acceleration is about 150 (Hz). It was confirmed that it is possible to significantly reduce the vibration level (dB) in the frequency range as compared with the conventional support structure (see the hatched portion in FIG. 9A).

(Other embodiments)
The present invention is not limited to the embodiments, and can be implemented in various other forms without departing from the spirit or the main characteristics.

  In the above embodiment, the case where the support structure of the present invention is applied to the hydraulic power steering device 10 has been described, but the present invention is not limited to this, and the support structure of the present invention is applied to, for example, an electric power steering device or an electric hydraulic power steering device. You may.

  Further, in the above embodiment, the case where the support structure of the present invention is applied to the frame vehicle 1 has been described, but the present invention is not limited to this, and the support structure of the present invention may be applied to, for example, a monocoque vehicle.

  Further, in the above-described embodiment, the dynamic spring constant of the first rubber bush 20 is made relatively small by relatively shortening the length dimension of the rubber elastic bodies 24, 28 in the vehicle front-rear direction. However, the dynamic spring constant of the first rubber bush 20 may be relatively reduced by relatively lowering the hardness of the rubber elastic bodies 24 and 28, for example.

  Further, in the above-described embodiment, the right end portion of the gear box 11 in the vehicle width direction is supported via the two rubber bushes 30 and 40, but the invention is not limited to this. You may make it support via one rubber bush.

  Further, in the above embodiment, the static spring constant in the vehicle width direction of the first rubber bush 20 is made equal to the static spring constant in the vehicle width direction of the second and third rubber bushes 30 and 40. However, the static spring constant of the first rubber bush 20 in the vehicle width direction and the static spring constant of the second and third rubber bushes 30 and 40 in the vehicle width direction may be significantly different.

  As described above, the above embodiments are merely examples in all respects, and should not be limitedly interpreted. Furthermore, all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

  According to the present invention, steering vibration caused by the vibration generator can be suppressed without adding a new member. It is extremely beneficial to apply.

3 First cross member (body frame member)
8 Front differential (vibration generator)
10 Hydraulic Power Steering Device 11 Gear Box 14 Pinion Shaft (Pinion)
20 1st rubber bush (1st rubber bush)
30 Second Rubber Bush (Second Rubber Bush)
40 Third Rubber Bush (Second Rubber Bush)
50 steering wheel

Claims (1)

A gearbox of the power steering device is a support structure for the power steering device, wherein the vehicle body frame member supporting the vibration generator is supported via a plurality of rubber bushes.
The plurality of rubber bushes include a first rubber bush provided at an end portion on one side in the vehicle width direction of the gear box, which is close to a pinion connected to a steering wheel, and a portion of the gear box that is far from the pinion. A second rubber bush provided at the other end in the vehicle width direction is included,
The dynamic spring constants of the first rubber bush in the vehicle front-rear direction and the vehicle up-down direction are set smaller than the dynamic spring constants of the second rubber bush in the vehicle front-rear direction and the vehicle up-down direction, respectively. Characteristic power steering device support structure.

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