A molded piston for an air spring for a vehicle suspension has an outer shell, a non-cylindrical central column braced in its relation to the outer shell by outer radial webs, and an upper surface having a recessed lower end closure seating surface. The non-cylindrical central column may have a chordal surface and a mounting stud sleeve and hole for attachment to a vehicle suspension member. The mounting stud sleeve and hole may be braced in its relation to the non-cylindrical central column by inner radial webs. The non-cylindrical central column may further have a locating sleeve and hole. The outer radial webs may be provided with Y-shaped webs connecting the outer radial webs to the outer shell and/or web arches.

Provided are an air spring upper support, a vehicle air spring assembly, and a vehicle. The air spring upper support is used for a vehicle air spring. The air spring upper support is configured to be of a split structure having an upper housing and a lower housing, the upper housing and the lower housing are connected to each other and form a receiving space, the air spring upper support further has a bushing, and the bushing is arranged in the receiving space.

A load sensor disposed between an air suspension assembly of a vehicle and a vehicle suspension, wherein the load sensor generates a load signal which varies based on an amount of force transferred from said vehicle frame to said vehicle suspension, wherein the load signal can be received by a load calculator to allow calculation of the load exerted from said vehicle frame to the vehicle suspension.

An inertia-actuated valve assembly includes a valve housing, a valve body and a biasing element. The valve housing includes a groove that has an open end fluidically accessible from along one side thereof. The valve housing includes a flow channel extending therethrough in fluid communication with the groove from along an opposing side of the valve housing. The valve body is positioned within the groove of the valve housing such that the valve body and the valve housing are axially co-extensive along at least a portion thereof. The biasing element operatively engages the valve body and generates a biasing force urging the valve body in a first axial direction. The biasing force is greater than a predetermined dynamic gas pressure threshold value multiplied by a pressure area and is less than or approximately equal to a valve body mass multiplied by 2.5 times the nominal acceleration due to gravity.

A dust cover is configured to cover an outer side of a damper extending in a predetermined direction. The dust cover includes bellows portions and a flange portion. The bellows portions are inclined alternately toward a radially outer side and a radially inner side in an axial direction. The flange portion extends radially outward from a cylindrical portion of the dust cover. The flange portion protrudes radially outward from the cylindrical portion of the dust cover by a dimension larger than a height dimension in a radial direction between a radially inner end and a radially outer end of each of the bellows portions. A thickness of the flange portion is larger than a thickness of the radially outer end of each of the bellows portions.

The invention relates to a preassembly device for preassembling an air spring on a body (e.g., a car body) that has an assembly interface. Embodiment of the preassembly device include a centering member for centering the preassembly device on the assembly interface, and a connector for connecting to an air spring. With embodiments, the preassembly device further includes a carrier (or support element) extending away from the preassembly device. A seal provided on the carrier for sealing a discharge opening of the body may be provided at the assembly interface, wherein the centering member may be configured for aligning the seal at the discharge opening. The invention provides a device that can provide a low-cost and simple sealing of the outlet openings in the area of the mounting interface.

A vehicle load-bearing member includes an electro-active material, a lead wire for delivering an electric current to the electro-active material, and a controller in communication with a power supply for supplying electric current to the electro-active material for changing dynamic characteristics of the electro-active material, wherein changing dynamic characteristics of the electro-active material changes at least one of dampening and stiffness of the vehicle load-bearing member by changing the shape of the electro-active material.

An air spring system for a commercial vehicle including an air spring device configured to be arranged in an interface region on a link, the air spring system configured such that, in the case of locking of the air spring device, an engagement element can be introduced into a receiving region, and, by way of an offset movement along an offset direction, the engagement element can be transferred from the receiving region into a positively locking region, in which the engagement element interacts in a positively locking manner with a positively locking element along a positively locking direction which differs from the offset direction.

Provided are an air spring upper support, a vehicle air spring assembly, and a vehicle. The air spring upper support is used for a vehicle air spring. The air spring upper support is configured to be of a split structure having an upper housing and a lower housing, the upper housing and the lower housing are connected to each other and form a receiving space, the air spring upper support further has a bushing, and the bushing is arranged in the receiving space.

A device for fastening an air spring to a body portion of a motor vehicle, at least comprising an air spring cover, wherein the air spring cover comprises at least one fastening means, by means of which the air spring can be connected to the body portion of the motor vehicle, wherein, for attachment of the air spring, the fastening means is plugged through an opening of the body portion and is fixed to said body portion in a force-fitting manner by a securing element, wherein a first and a second plastics part are provided for acoustic decoupling of the air spring, wherein the first plastics part, is clamped between the body portion and the securing element, and the second plastics part is provided so as to be positioned below the body portion.