JP2020006843A - Steering device - Google Patents

Abstract

To suppress the wear of a boot.SOLUTION: In a boot 5, a bellows part 53 in which a protrusion and a recess are alternately continued is formed while being fixed to a housing 10 side and a tie rod 89 side, and the bellows part 53 has a small-diameter part 53c whose inside diameter DbC is smaller than the other portion in the middle of an axial direction being the tie rod 89 side rather than a ball joint 3 in a neutral position of a rack 88b.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a steering device.

  2. Description of the Related Art In a vehicle, a steering device is provided as a device for transmitting an operation performed by a driving operator on a steering wheel to wheels. In a rack and pinion type steering device, a pinion is connected to a steering shaft to which rotation of a steering wheel is transmitted, and the rack meshes with the pinion. The rack extends in the left-right direction of the vehicle, is supported by a housing together with a pinion, and each end is provided to penetrate the housing and is connected to left and right wheels. The rack changes the direction of the wheels by moving in the left-right direction of the vehicle according to the rotation of the pinion accompanying the rotation of the steering wheel. The rack is provided with a ball joint attached to each end, and tie rods extend in the left-right direction of the vehicle and are connected to the wheels via the ball joints. The ball joint is covered with boots. The boot has a bellows shape so that it can expand and contract with the movement of the rack and bend as the tie rod swings via a ball joint. Ethylene propylene rubber and olefin-based elastomers have been employed as commonly used boot materials.

  Such a boot of a rack-and-pinion type steering device is described in, for example, Patent Document 1. The boot disclosed in Patent Literature 1 has a small inner diameter only at a central portion corresponding to a ball joint at a neutral position of a steering device to facilitate deformation.

Japanese Utility Model Publication No. 60-23249

  In the boot described in Patent Document 1, since the inner diameter is reduced only in the central portion corresponding to the ball joint, friction occurs between the inner peripheral surface of the boot and the ball joint, and the boot is used for a long time. , Boots may wear out.

  Also, the boot is curved along the swing direction of the tie rod by swinging the tie rod, but from the ball joint, on the housing side, the opposite side of the swing direction of the tie rod is dented and deformed so as to approach the ball joint, The entire boot may be curved in an S-shape. In this case, friction between the inner peripheral surface of the boot and the ball joint is likely to occur.

  The present disclosure has been made in view of the above problems, and has as its object to provide a steering device that can suppress wear of boots.

  In order to achieve the above object, a steering device according to an embodiment of the present disclosure includes a cylindrical housing, a rack that extends through the housing, and is provided to be movable in an axial direction, and an end of the rack. A ball joint to be arranged, a tie rod provided swingably with respect to the rack via the ball joint, and a boot covering the ball joint, wherein the boot is fixed to the housing side and the tie rod side. A bellows portion in which the convex portion and the concave portion are alternately connected while the bellows portion is formed, and the bellows portion is located at the neutral position of the rack, and is located at a position closer to the tie rod side than the ball joint in the axial direction. It has a small diameter part with a small inside diameter.

  Thereby, when the tie rod swings so as to be inclined in the radial direction with respect to the axial direction of the rack at the neutral position of the rack, the small-diameter portion deforms more than the other portions, and bends more on the tie rod side than the ball joint. Therefore, the situation where the boot slides on the outer peripheral surface of the ball joint can be reduced. When the tie rod does not swing or is extremely small, the other portion of the small-diameter portion is unlikely to be deformed, so that the position of the entire boot is largely prevented from changing due to vibration during traveling of the vehicle. When the rack extends to the tie rod side from the neutral position, the other portion of the small diameter portion is unlikely to be deformed, and the small diameter portion is largely deformed, so that the inflection point of the ball joint does not exceed the small diameter portion. For this reason, even if the tie rod swings in this state, the small diameter portion of the boot is more greatly deformed than the other portions, and the boot bends on the tie rod side of the ball joint, so that the boot slides on the outer peripheral surface of the ball joint. The situation can be reduced. When the rack is reduced toward the housing from the neutral position, the ball joint moves within a range of another portion of the small diameter portion on the housing side. For this reason, even if the tie rod swings in this state, the small diameter portion of the boot is more greatly deformed than the other portions, and the boot is bent on the tie rod side of the ball joint, so that the boot slides on the outer peripheral surface of the ball joint. Contact situations can be reduced. Further, since the other portion of the small-diameter portion on the housing side is unlikely to be deformed, when the rack is reduced to the housing side from the neutral position, the boot is suppressed from being pinched by the ball joint and the housing. As a result, the steering device can suppress wear of the boot.

  As a desirable mode of the above-mentioned steering device, the inside diameter and the outside diameter of the small diameter portion are formed smaller than the other portions.

  Thereby, as a whole, the small diameter portion is more easily deformed than the other portions, and the other portions are harder to be deformed, so that the boot is less likely to slide on the outer peripheral surface of the ball joint. Can be reduced. As a result, the steering device can further suppress the wear of the boot.

  As a desirable mode of the above steering device, the small diameter portion is formed to have the smallest inner diameter in the axial direction of the bellows portion.

  Thereby, as for the boot, as a whole, the small diameter portion is most easily deformed in the axial direction of the bellows portion, so that the situation where the boot slides on the outer peripheral surface of the ball joint can be further reduced. As a result, the steering device can further suppress the wear of the boot.

  As a desirable mode of the above-mentioned steering device, an inside diameter of the small diameter part is formed smaller than an outside diameter of the ball joint.

  Thereby, the boot is more likely to bend on the tie rod side than the ball joint, and the other portions are less likely to be deformed. Therefore, the situation where the boot slides on the outer peripheral surface of the ball joint can be further reduced. As a result, the steering device can suppress wear of the boot.

  According to the steering device of the present disclosure, wear of the boot can be suppressed.

FIG. 1 is a schematic diagram of the steering device of the present embodiment. FIG. 2 is a cross-sectional view of the steering gear box of the present embodiment. FIG. 3 is an enlarged sectional view of one end of the steering gear box of the present embodiment. FIG. 4 is an enlarged sectional view of one end of the steering gear box of the present embodiment. FIG. 5 is an enlarged cross-sectional view of one end of a steering gear box according to a modification. FIG. 6 is an enlarged cross-sectional view of one end of a steering gear box according to a modification.

  Hereinafter, the present invention will be described in detail with reference to the drawings. The present invention is not limited by the following embodiments for carrying out the invention (hereinafter, referred to as embodiments). The components in the following embodiments include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those that are in the so-called equivalent range. Furthermore, components disclosed in the following embodiments can be appropriately combined.

(Embodiment)
FIG. 1 is a schematic diagram of the steering device of the present embodiment. As shown in FIG. 1, the steering device 80 includes a steering wheel 81, a steering shaft 82, a universal joint 84, an intermediate shaft 85, a universal joint 86, a pinion shaft 87, a pinion 88a, a rack 88b, A tie rod 89. The steering device 80 is connected with a steering wheel 81, a steering shaft 82, a universal joint 84, an intermediate shaft 85, a universal joint 86, a pinion shaft 87, a pinion 88a, a rack 88b, and a tie rod 89 in this order.

  As shown in FIG. 1, the steering wheel 81 is connected to one end of a steering shaft 82. The other end of the steering shaft 82 is connected to the universal joint 84. The universal joint 84 is connected to one end of the intermediate shaft 85. The other end of the intermediate shaft 85 is connected to the universal joint 86. The universal joint 86 is connected to one end of the pinion shaft 87. The other end of the pinion shaft 87 is connected to the pinion 88a. The pinion 88a meshes with the rack 88b. The rack 88b is connected to the tie rod 89. The tie rod 89 is connected to wheels via a link mechanism (not shown). Therefore, when the steering wheel 81 is rotated by an operator driving the vehicle, this rotational motion is transmitted to the steering shaft 82, the universal joint 84, the intermediate shaft 85, the universal joint 86, the pinion shaft 87, and the pinion 88a in this order. .

  The pinion 88a transmits the rotational motion transmitted from the pinion shaft 87 to the rack 88b. The rack 88b is arranged so that the axial direction, which is the direction in which the rack 88b extends, extends along the vehicle width direction, and is provided so as to be movable in the vehicle width direction. Is converted into a linear motion. Accordingly, when the rack 88b moves in the axial direction, the tie rod 89 moves, and the angle, that is, the direction of the wheel changes via a link mechanism (not shown).

  In the following description, the axial direction of the rack 88b is simply described as the axial direction. The direction orthogonal to the axial direction is described as a radial direction. The axis of the rack 88b is described as a rotation axis, and a direction along a circumference around the rotation axis is described as a circumferential direction.

  As shown in FIG. 1, the steering device 80 further includes an electric motor 93, a torque sensor 94, a vehicle speed sensor 95, and an ECU (Electronic Control Unit) 90. The electric motor 93, the torque sensor 94, and the vehicle speed sensor 95 are electrically connected to the ECU 90.

  The electric motor 93 is, for example, a brushless motor. The electric motor 93 may be a motor including a brush (slider) and a commutator (commutator). The electric motor 93 is fixed to, for example, a housing 10 described below. The power of the electric motor 93 is transmitted to the rack 88b, and moves the rack 88b in the axial direction. Due to the torque generated by the electric motor 93, the force required for the operator to move the rack 88b is reduced. That is, the steering device 80 of the present embodiment employs a rack assist type.

  The torque sensor 94 is attached to, for example, the pinion 88a. Torque sensor 94 outputs the steering torque transmitted to pinion 88a to ECU 90 by CAN (Controller Area Network) communication. The vehicle speed sensor 95 detects a traveling speed (vehicle speed) of a vehicle body on which the steering device 80 is mounted. The vehicle speed sensor 95 is provided on the vehicle body and outputs the vehicle speed to the ECU 90 through CAN communication.

  The ECU 90 controls the operation of the electric motor 93. The ECU 90 acquires signals from each of the torque sensor 94 and the vehicle speed sensor 95. Power is supplied to the ECU 90 from a power supply 99 (for example, a battery mounted on a vehicle) with the ignition switch 98 turned on. The ECU 90 calculates an auxiliary steering command value based on the steering torque and the vehicle speed. The ECU 90 adjusts an electric power value supplied to the electric motor 93 based on the auxiliary steering command value. The ECU 90 acquires information on an induced voltage from the electric motor 93 or information output from a resolver or the like provided in the electric motor 93. When the ECU 90 controls the electric motor 93, the force required for operating the steering wheel 81 is reduced.

  Note that the steering device 80 does not necessarily need to include the electric motor 93. That is, the steering device 80 need not be an electric power steering device.

  FIG. 2 is a cross-sectional view of the steering gear box of the present embodiment. 3 and 4 are enlarged sectional views of one end of the steering gear box according to the present embodiment. In FIG. 2, the electric motor 93 and members associated with the electric motor 93 are omitted.

  As shown in FIGS. 2 and 3, the steering device 80 includes a housing 10 that forms a steering gear box, the ball joint 3, and the boot 5.

  The housing 10 is a cylindrical member, more specifically, a cylindrical member. The housing 10 rotatably supports the pinion 88a. The housing 10 supports the rack 88b so as to be movable in the axial direction. The rack 88b extends through the housing 10 in the axial direction. Each end of the rack 88b is immersed or protrudes into each end of the housing 10 when the rack 88b moves in the axial direction due to the rotation operation of the steering wheel 81.

  The ball joint 3 connects the rack 88b and the tie rod 89. The ball joint 3 includes a socket 31 and a ball 32. The socket 31 is fixedly connected to each end of the rack 88b. The ball 32 is fixedly connected to one end of the tie rod 89. The other end of the tie rod 89 is connected to the above-described link mechanism (not shown). The ball 32 is held by the socket 31. The ball 32 is supported so as to roll with respect to the socket 31. Therefore, the tie rod 89 is provided so as to be able to swing through the ball joint 3 so as to be inclined in all radial directions with respect to the axial direction of the rack 88b by the rolling of the ball 32 with respect to the socket 31.

  As shown in FIG. 3, the boot 5 is a tubular member that covers the ball joint 3. The material of the boot 5 is, for example, ethylene propylene rubber or an olefin elastomer. The elongation percentage of the boot 5 is, for example, 200%. The elongation percentage is calculated by {(L−L0) / L0} × 100, where L0 is the initial distance between gauge points of the test piece and L is the distance between gauge points at break in the tensile test of the material. Value.

  As shown in FIG. 3, the boot 5 includes a first fixing part 51, a second fixing part 52, and a bellows part 53.

  The first fixing portion 51 is formed in a cylindrical shape, forms a base end of the boot 5, and overlaps the end of the housing 10 in the radial direction. The first fixing portion 51 is provided with a fastening member 11 on a radially outer side. The fastening member 11 is an annular member formed of, for example, metal, and is wound around the first fixing portion 51. Therefore, the first fixing portion 51 is attached to the housing 10 by the fastening member 11, and the boot 5 is connected to the housing 10.

  The second fixing portion 52 is formed in a cylindrical shape and forms the tip of the boot 5, and overlaps a middle portion of the tie rod 89 in the radial direction. The second fixing portion 52 is provided with the fastening member 12 on a radially outer side. The fastening member 12 is an annular member formed of, for example, metal, and is wound around the second fixing portion 52. Therefore, the second fixing portion 52 is attached to the tie rod 89 by the fastening member 12, and the boot 5 is connected to the tie rod 89.

  The bellows portion 53 has a first bellows portion 53A, a second bellows portion 53B, and a small diameter portion 53C.

  The first bellows portion 53A has a plurality of convex portions 53Aa whose diameter gradually increases outward in the radial direction and concave portions 53Ab whose diameter gradually decreases radially inward. A meandering wall having a cross-sectional shape is formed in a cylindrical shape continuously in the circumferential direction. Therefore, the first bellows portion 53A is formed so as to be deformable in the axial direction and the radial direction by the bellows shape of the convex portion 53Aa and the concave portion 53Ab. The first bellows portion 53A is integrally connected to the first fixing portion 51 attached to the housing 10 at a neutral position of the rack 88b, and is arranged from the housing 10 in the axial direction to the end of the ball joint 3.

  In the present embodiment, the outer diameter DaA of the first bellows portion 53A, which is the radial dimension between the protrusions 53Aa, is formed to be constant in the axial direction. In the first bellows portion 53A, an inner diameter DbA, which is a radial dimension between the concave portions 53Ab, is formed to be constant in the axial direction. In the first bellows portion 53A, the amplitude SA between the convex portion 53Aa and the concave portion 53Ab is formed constant in the axial direction.

  Here, the neutral position of the rack 88b will be described. The rack 88b is provided to extend in the axial direction through the housing 10 as described above. When the rack 88b moves in the axial direction due to the rotation operation of the steering wheel 81, each end is immersed in each end of the housing 10. Or protrude. The rack 88b is configured to extend continuously in the axial direction. In the rotation operation of the steering wheel 81, one end protrudes from the end of the housing 10 while the other end is immersed in the end of the housing 10. . The rack 88 b has one end most protruding from the end of the housing 10, and the other end most immersed in the end of the housing 10. A configuration in which one end of the rack 88 b projects most from the end of the housing 10 and the other end is most immersed in the end of the housing 10 corresponds to the maximum rotation position in the rotation operation of the steering wheel 81. On the other hand, at a neutral rotation position in the rotation operation of the steering wheel 81, each end of the rack 88b also projects from each end of the housing 10. The position where each end of the rack 88b protrudes similarly from each end of the housing 10 is the neutral position of the rack 88b. The neutral position of the rack 88b is a neutral rotational position in the rotation operation of the steering wheel 81, and the wheels are straightened so that the vehicle goes straight. In the present embodiment, the rack 88b is shown in a neutral position in each of the drawings. When the end of the rack 88b is immersed in the end of the housing 10, the stopper 14 fixed on the outer periphery of the rack 88b comes into contact with the receiving portion 13 fixed in the cylinder of the housing 10. The immersion of the other end is restricted, so that the protrusion of the one end is also restricted.

  The end of the ball joint 3 is a tip 31a of the ball joint 3 facing the tie rod 89 of the socket 31.

  Therefore, the first bellows portion 53A is arranged in the neutral position of the rack 88b in a range of the axial dimension LA from the first fixing portion 51 attached to the housing 10 to the tip 31a of the socket 31 in the ball joint 3. Have been.

  The second bellows portion 53B has a plurality of convex portions 53Ba whose diameter gradually increases outward in the radial direction and concave portions 53Bb whose diameter gradually decreases radially inward. A meandering wall having a sectional shape is formed in a cylindrical shape continuously in the circumferential direction. Therefore, the second bellows portion 53B is formed so as to be deformable in the axial direction and the radial direction by the bellows shape of the convex portion 53Ba and the concave portion 53Bb. The second bellows portion 53B is integrally connected to the second fixing portion 52 attached to the tie rod 89 at the neutral position of the rack 88b, and is arranged from the tie rod 89 toward the ball joint 3 side. The second bellows 53B does not extend from the tie rod 89 to the tip 31a of the socket 31, which is the end of the ball joint 3. Therefore, the second bellows portion 53B is arranged in the range of the axial dimension LB between the second fixing portion 52 attached to the tie rod 89 and the middle of the tie rod 89 on the ball joint 3 side at the neutral position of the rack 88b. Have been.

  Further, in the present embodiment, the second bellows portion 53B is formed such that an outer diameter DaB, which is a radial dimension between the convex portions 53Ba, is gradually reduced in the axial direction toward the tie rod 89 side. The second bellows portion 53B is formed such that an inner diameter DbB, which is a radial dimension between the concave portions 53Bb, is gradually reduced in the axial direction toward the tie rod 89 side. In the second bellows portion 53B, the amplitude SB between the convex portion 53Ba and the concave portion 53Bb is formed constant in the axial direction.

  The small-diameter portion 53C meanders radially in and out by alternately connecting a plurality of convex portions 53Ca whose diameter gradually increases radially outward and concave portions 53Cb whose diameter gradually decreases radially inward in the axial direction. A wall having a sectional shape is formed in a cylindrical shape continuously in the circumferential direction. Therefore, the small diameter portion 53C is formed so as to be deformable in the axial direction and the radial direction by the bellows shape of the convex portion 53Ca and the concave portion 53Cb. The small diameter portion 53C is integrally connected to the first bellows portion 53A and the second bellows portion 53B so as to connect the first bellows portion 53A and the second bellows portion 53B, and at a neutral position of the rack 88b, the ball joint 3 The socket 31 is disposed from the end 31a of the socket 31 toward the tie rod 89 side. Therefore, the small diameter portion 53C is integrally connected to the first bellows portion 53A, from the tip 31a of the socket 31, which is the end of the ball joint 3, toward the tie rod 89 side, and is integrally connected to the second bellows portion 53B, and in the middle of the tie rod 89. It is arranged in the range of the axial dimension LC between the two.

  The small diameter portion 53C is formed such that an inner diameter DbC, which is a radial dimension between the concave portions 53Cb, is smaller than an inner diameter DbA of the first bellows portion 53A and an inner diameter DbB of the second bellows portion 53B, which are other portions. In the small diameter portion 53C, the outer diameter DaC, which is the radial dimension between the convex portions 53Ca, is smaller than the outer diameter DaA of the first bellows portion 53A and the outer diameter DaB of the second bellows portion 53B, which are the other portions. Have been. Note that the small diameter portion 53C is formed such that the inner diameter DbC and the outer diameter DaC are smaller than the inner diameter DbB and the outer diameter DaB of the second bellows portion 53B at the connection portion with the second bellows portion 53B. The inner diameter DbC and the outer diameter DaC may be formed to be larger than the inner diameter DbB and the outer diameter DaB of the second bellows 53B on the tie rod 89 side of the gradually reduced second bellows 53B.

  The small-diameter portion 53C is formed so that the inner diameter DbC and the outer diameter DaC gradually decrease as the distance from the connection portion with the first bellows portion 53A and the second bellows portion 53B increases, and is constant at the central portion in the axial direction. Becomes In the small-diameter portion 53C, the amplitude SC between the convex portion 53Ca and the concave portion 53Cb is formed constant at the center in the axial direction.

  As described above, the boot 5 includes the first bellows portion 53A, the second bellows portion 53B, and the small diameter portion 53C between the first fixing portion 51 attached to the housing 10 and the second fixing portion 52 attached to the tie rod 89. The first bellows portion 53A, the small-diameter portion 53C, and the second bellows portion 53B are arranged in this order within the range of the axial dimension L to form the bellows portion 53.

  Also, the boot 5 has a pitch PA, which is an interval between the convex portion 53Aa and the concave portion 53Ab adjacent in the axial direction in the first bellows portion 53A, and an interval between the convex portion 53Ba and the concave portion 53Bb adjacent in the axial direction in the second bellows portion 53B. And the pitch PC, which is the interval between the convex portion 53Ca and the concave portion 53Cb adjacent in the axial direction in the small-diameter portion 53C, are formed equally and uniformly. The first bellows portion 53A, the second bellows portion 53B, and the small diameter portion 53C have the same thickness and are formed uniformly.

  As described above, in the steering device 80 of the present embodiment, the bellows portion 53 of the boot 5 is located at the neutral position of the rack 88b more axially on the tie rod 89 side than the ball joint 3 than other portions. It has a small diameter portion 53C with a small inner diameter DbC. With this configuration, the small diameter portion 53C of the entire boot 5 is easily deformed flexibly, and the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment) are hardly deformed.

  Thereby, as shown in FIG. 4, when the tie rod 89 swings in the neutral position of the rack 88b so as to tilt in the radial direction with respect to the axial direction of the rack 88b, the small diameter portion 53C is The portion (the first bellows portion 53A and the second bellows portion 53B in the present embodiment) is more greatly deformed and bends closer to the tie rod 89 than the ball joint 3. As a result, the steering device 80 can reduce a situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3, and can suppress wear of the boot 5.

  When the tie rod 89 does not swing or is extremely small, the other portions of the small-diameter portion 53C (the first bellows portion 53A and the second bellows portion 53B in this embodiment) are unlikely to be deformed, so that the vibration during running of the vehicle is reduced. This suppresses a significant change in the position of the entire boot 5. As a result, the steering device 80 can reduce a situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3, and can suppress wear of the boot 5.

  When the rack 88b extends toward the tie rod 89 from the neutral position, the other portions of the small diameter portion 53C (the first bellows portion 53A and the second bellows portion 53B in the present embodiment) are unlikely to be deformed, and the small diameter portion 53C is large. Due to the deformation, the ball joint 3 does not exceed the small diameter portion 53C. For this reason, even if the tie rod 89 swings in this state, the small diameter portion 53C of the boot 5 is more greatly deformed than the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment). It bends on the tie rod 89 side from the ball joint 3. As a result, the steering device 80 can reduce a situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3, and can suppress wear of the boot 5.

  When the rack 88b is reduced toward the housing 10 from the neutral position, the ball joint 3 moves within the range of another portion (the first bellows portion 53A in the present embodiment) of the small diameter portion 53C on the housing 10 side. For this reason, even if the tie rod 89 swings in this state, the small diameter portion 53C of the boot 5 is more greatly deformed than the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment). It bends on the tie rod 89 side from the ball joint 3. As a result, the situation where the boot 5 slides on the outer peripheral surface of the ball joint 3 can be reduced, and wear of the boot 5 can be suppressed. Further, since the other portion (the first bellows portion 53A in the present embodiment) of the small-diameter portion 53C on the housing 10 side is unlikely to be deformed, when the rack 88b is reduced from the neutral position to the housing 10 side, the boots 5 The pinching between the joint 3 and the housing 10 is suppressed. As a result, the steering device 80 can suppress wear of the boot 5.

  In the steering device 80 of the present embodiment, the small-diameter portion 53C is formed to have an inner diameter DbC and an outer diameter DaC smaller than other portions (in the present embodiment, the first bellows portion 53A and the second bellows portion 53B). Is preferred.

  Thereby, as a whole, the small diameter portion 53C of the boot 5 is more easily deformed more flexibly than the other portions (the first bellows portion 53A and the second bellows portion 53B in the present embodiment), and the other portions (the booklets) are formed. In the embodiment, the first bellows portion 53A and the second bellows portion 53B) are more difficult to deform. As a result, in the steering device 80, the situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3 can be further reduced, and the wear of the boot 5 can be further suppressed.

  In the steering device 80 of the present embodiment, it is preferable that the small-diameter portion 53C has the smallest inner diameter in the axial direction of the bellows portion 53.

  As a result, in the boot 5, the small-diameter portion 53C as a whole is most easily deformed in the axial direction of the bellows portion 53. As a result, in the steering device 80, the situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3 can be further reduced, and the wear of the boot 5 can be further suppressed.

  In the steering device 80 of the present embodiment, the small diameter portion 53C is formed such that the inside diameter DbC is smaller than the outside diameter D of the ball joint 3.

  Here, the outer diameter D of the ball joint 3 is a portion having the largest radial dimension in the socket 31 of the ball joint 3.

  Accordingly, the boot 5 is more easily bent on the tie rod 89 side than the ball joint 3, and the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment) are less likely to be deformed. As a result, in the steering device 80, the situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3 can be further reduced, and the wear of the boot 5 can be further suppressed.

(Modification)
5 and 6 are enlarged cross-sectional views of one end of a steering gear box according to a modification. Note that the same components as those described in the above-described embodiment are denoted by the same reference numerals, and redundant description will be omitted.

  As shown in FIG. 5, in the steering device 80 of the modified example, the bellows 53 of the boot 5 is located at the neutral position of the rack 88 b at a position closer to the tie rod 89 than the ball joint 3 in the axial direction. It has a small diameter portion 53C with a small inner diameter DbC. With this configuration, the small diameter portion 53C of the entire boot 5 is easily deformed flexibly, and the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment) are hardly deformed.

  Specifically, the small-diameter portion 53C has an inner diameter DbC smaller than other portions (in the modified example, the inner diameter DbA of the first bellows portion 53A and the inner diameter DbB of the second bellows portion 53B), and the outer diameter DaC is other portion (deformed). In the example, the outer diameter DaA of the first bellows portion 53A and the maximum outer diameter DaB of the second bellows portion 53B) are the same. Therefore, the small diameter portion 53C has a larger amplitude SC between the convex portion 53Ca and the concave portion 53Cb than the other portions (the first bellows portion 53A and the second bellows portion 53B in the modified example). With this configuration, the small diameter portion 53C of the entire boot 5 is more easily deformed, and the other portions (the first bellows portion 53A and the second bellows portion 53B in the present embodiment) are more difficult to deform.

  Thereby, as shown in FIG. 6, when the tie rod 89 swings in the neutral position of the rack 88b so as to be inclined in the radial direction with respect to the axial direction of the rack 88b, the small-diameter portion 53C The portion (the first bellows portion 53A and the second bellows portion 53B in the present embodiment) is more greatly deformed and bends closer to the tie rod 89 than the ball joint 3. As a result, the steering device 80 can reduce a situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3, and can suppress wear of the boot 5.

  When the tie rod 89 does not swing or is extremely small, the other portions of the small-diameter portion 53C (the first bellows portion 53A and the second bellows portion 53B in this embodiment) are unlikely to be deformed, so that the vibration during running of the vehicle is reduced. This suppresses a significant change in the position of the entire boot 5. As a result, the steering device 80 can reduce a situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3, and can suppress wear of the boot 5.

  When the rack 88b extends toward the tie rod 89 from the neutral position, the other portions of the small diameter portion 53C (the first bellows portion 53A and the second bellows portion 53B in the present embodiment) are unlikely to be deformed, and the small diameter portion 53C is large. Due to the deformation, the ball joint 3 does not exceed the small diameter portion 53C. For this reason, even if the tie rod 89 swings in this state, the small diameter portion 53C of the boot 5 is more greatly deformed than the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment). It bends on the tie rod 89 side from the ball joint 3. As a result, the steering device 80 can reduce a situation in which the boot 5 slides on the outer peripheral surface of the ball joint 3, and can suppress wear of the boot 5.

  When the rack 88b is reduced toward the housing 10 from the neutral position, the ball joint 3 moves within the range of the first bellows 53A. For this reason, even if the tie rod 89 swings in this state, the small diameter portion 53C of the boot 5 is more greatly deformed than the other portions (the first bellows portion 53A and the second bellows portion 53B in this embodiment). It bends on the tie rod 89 side from the ball joint 3. As a result, the situation where the boot 5 slides on the outer peripheral surface of the ball joint 3 can be reduced, and wear of the boot 5 can be suppressed. Further, since other portions of the small diameter portion 53C (the first bellows portion 53A and the second bellows portion 53B in the present embodiment) are not easily deformed, when the rack 88b is reduced to the housing 10 side from the neutral position, the boot 5 is moved. Is suppressed from being pinched by the ball joint 3 and the housing 10. As a result, the steering device 80 can suppress wear of the boot 5.

3 Ball joint 5 Boot 10 Housing 11 Tightening member 12 Tightening member 13 Receiving part 14 Stopper 31 Socket 31a Tip 32 Ball 51 First fixing part 52 Second fixing part 53 Bellows part 53A First bellows part 53Aa Convex part 53Ab Recess 53B Second bellows 53Ba convex 53Bb concave 53C small diameter portion 53Ca convex 53Cb concave 80 steering device 81 steering wheel 82 steering shaft 84 universal joint 85 intermediate shaft 86 universal joint 87 pinion shaft 88a pinion 88b rack 89 tie rod 93 electric motor 94 torque sensor 95 Vehicle speed sensor 98 Ignition switch 99 Power supply DaA Outer diameter DaB of first bellows Outer diameter DaC of second bellows Outer diameter DbA of smaller diameter DbA Inner diameter DbB of first bellows Inner diameter DbC of two bellows Inner diameter L of small diameter part Axial dimension LA of bellows part Axial dimension LB of first bellows part Axial dimension LC of second bellows part Axial dimension PA of small diameter part PA First bellows Part pitch PB second bellows part pitch PC small diameter part pitch SA first bellows part amplitude SB second bellows part amplitude SC small diameter part amplitude

Claims (4)

A cylindrical housing;
An axially movable rack extending through the housing;
A ball joint disposed at an end of the rack;
A tie rod provided swingably with respect to the rack via the ball joint;
Boots covering the ball joint,
With
The boot is formed with a bellows portion in which convex portions and concave portions are alternately connected while being fixed to the housing side and the tie rod side, and the bellows portion is, at a neutral position of the rack, the tie rod than the ball joint. A steering device having a small-diameter portion having an inner diameter smaller than other portions in the axial direction on the side. The steering device according to claim 1, wherein the small diameter portion has an inner diameter and an outer diameter smaller than other portions. The steering device according to claim 1, wherein the small-diameter portion has the smallest inner diameter in the axial direction of the bellows portion. The steering device according to any one of claims 1 to 3, wherein the small diameter portion has an inner diameter smaller than an outer diameter of the ball joint.

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