A steering apparatus of a vehicle includes: a dust pack housing coupled to a top portion of a dust cap, which is combined with a rack housing to surround a pinion shaft, the dust pack housing disposed between and supporting a dash panel of the vehicle and the dust cap; and a noise attenuation member disposed between the dust pack housing and the pinion shaft and having plate shape so that an inner side of the noise attenuation member is spaced apart from the pinion shaft and an outer side of the noise attenuation member is fitted to the dust pack housing to attenuate noise that is transmitted to the inside of the dust panel.

Magnetorheological-damper-based steering apparatus and methods for reducing steering wheel jerk resulting from off-road wheel impact are described. An example steering damper apparatus includes a magnetorheological (MR) rotary damper to be operatively coupled to a steering column shaft. The example steering damper apparatus further includes a sensor to detect an angular velocity associated with the steering column shaft. The example steering damper apparatus further includes a controller to energize the MR rotary damper in response to determining that the angular velocity exceeds an angular velocity threshold. The angular velocity threshold is associated with steering wheel jerk resulting from an off-road wheel impact.

Rotational inerters are described herein that can provide torque applications in response to a rotation component. The inerter can include a first shaft having a first longitudinal axis and a second shaft having a second longitudinal axis. A first gear can be connected with the first shaft and a second gear can be connected with the second shaft. The first and second gears can be in meshing engagement with one another. In some arrangements, the first gear can be a worm gear and the second gear can be a worm. A flywheel can be connected with the second shaft. Rotation of the first shaft can cause the second shaft to rotate. Arrangements described herein can cause a torque to be applied at the first shaft that is proportional to a rate of change of the angular velocity of the first shaft about the first longitudinal axis.

Vehicle steering can be synchronized by first, turning the steering rack from lock-to-lock to determine a steering rack midpoint, second, turning the steering wheel from lock-to-lock to determine a steering wheel midpoint, third, synchronizing the steering rack with the steering wheel based on the steering rack midpoint and the steering wheel midpoint, and fourth, piloting a vehicle based on the synchronized steering rack and steering wheel; wherein the steering rack is mechanically decoupled from a steering wheel of the vehicle before turning the steering rack from lock-to-lock and before turning the steering wheel from lock-to-lock.

Disclosed are vehicle steering column assemblies with viscous dampers, methods for making and for using such assemblies, and motor vehicles with steering column assemblies having viscous dampers. A steering column assembly is disclosed that includes a first shaft member that connects to a steering wheel/handle, and a second shaft member that connects to a vehicle body. These shaft members are telescopingly connected such that one shaft member selectively translates longitudinally with respect to the other shaft member. A viscous damper assembly is interposed between the two shaft members. The viscous damper assembly includes a damper housing with first and second reservoir volumes disposed inside the housing. Multiple constricted flow channels fluidly connect the reservoir volumes. Viscous fluid flows from the first reservoir volume, through the constricted flow channels, to the second reservoir volume in response to relative vibrational displacement between the shaft members to thereby viscously attenuate vibrational energy.

A bearing assembly for bearing a steering shaft includes a bearing housing, a bearing, and a damping disk. The housing has two housing sections. The bearing is integrated into the damping disk. The damping disk is positioned so that an inner wall of a first housing section radially supports a circumferential side of the damping disk, and such that a second housing section is axially supported by the damping disk.

Vehicle steering can be synchronized by first, turning the steering rack from lock-to-lock to determine a steering rack midpoint, second, turning the steering wheel from lock-to-lock to determine a steering wheel midpoint, third, synchronizing the steering rack with the steering wheel based on the steering rack midpoint and the steering wheel midpoint, and fourth, piloting a vehicle based on the synchronized steering rack and steering wheel; wherein the steering rack is mechanically decoupled from a steering wheel of the vehicle before turning the steering rack from lock-to-lock and before turning the steering wheel from lock-to-lock.

Rotational inerters are described herein that can provide torque applications in response to a rotation component. The inerter can include a first shaft having a first longitudinal axis and a second shaft having a second longitudinal axis. A first gear can be connected with the first shaft and a second gear can be connected with the second shaft. The first and second gears can be in meshing engagement with one another. In some arrangements, the first gear can be a worm gear and the second gear can be a worm. A flywheel can be connected with the second shaft. Rotation of the first shaft can cause the second shaft to rotate. Arrangements described herein can cause a torque to be applied at the first shaft that is proportional to a rate of change of the angular velocity of the first shaft about the first longitudinal axis.

An arrangement of the column (1) neutralising transient forces (C1, EA1) generated by a jolt to which the column (1) is subjected, by an automatic decoupling between two coaxial sections (1a, 1b) of the column (1). This decoupling is caused by angular movement of a coupling link (5) between the sections (1a, 1b), preventing transmission of the forces (C1, EA1) by a distal section (1a) to a proximal section (1b) of the column (1). Simultaneously with the decoupling, a compression is also caused of a prestressed elastic mounting region (6a) between the sections (1a, 1b), the jolt then no longer being absorbed by the driver but by the compression of the elastic region. The decoupling is followed by an automatic re-coupling between the two sections (1a, 1b) under the effect of the relaxing of the elastic region (6a).

Disclosed are vehicle steering column assemblies with viscous dampers, methods for making and for using such assemblies, and motor vehicles with steering column assemblies having viscous dampers. A steering column assembly is disclosed that includes a first shaft member that connects to a steering wheel/handle, and a second shaft member that connects to a vehicle body. These shaft members are telescopingly connected such that one shaft member selectively translates longitudinally with respect to the other shaft member. A viscous damper assembly is interposed between the two shaft members. The viscous damper assembly includes a damper housing with first and second reservoir volumes disposed inside the housing. Multiple constricted flow channels fluidly connect the reservoir volumes. Viscous fluid flows from the first reservoir volume, through the constricted flow channels, to the second reservoir volume in response to relative vibrational displacement between the shaft members to thereby viscously attenuate vibrational energy.