A trim lock and a centering assembly that provides a centering force between a first portion of a system and a second portion of the system. The centering assembly includes a centering stabilizer that provides a centering force along an axial direction thereof, a trim lock configured and arranged to change a location of one axial end of the centering stabilizer, with respect to the second portion of the system, between an original location and an adjusted location, and to lock the axial end of the centering stabilizer at the adjusted location, a connecting unit for operatively connecting the trim lock with the centering stabilizer, and a mounting member for movably mounting the centering stabilizer with respect to the second portion of the system, wherein the mounting member permits axial movement of the centering stabilizer with respect to said second portion of the system.

Adjustable suspension comprising a suspension body having a bottom, a piston disposed in the suspension body and comprising a piston head, the bottom and the piston head delimiting a main chamber inside said suspension body, the piston being movable in translation in the suspension body; and a fluid distribution device comprising a main fluid inlet configured to inject a fluid into the suspension and a fluid outlet, the piston being able to assume a first position in which the fluid distribution device is configured to bring the fluid injected through the main fluid inlet into the main chamber so as to deploy the piston and a second position in which the fluid distribution device is configured to guide the fluid injected through the main fluid inlet to the fluid outlet in order to evacuate the fluid out of the suspension.

A suspension system includes a first compression chamber and a second compression chamber with a damping chamber therebetween. The compression chambers may be independently filled with a compressible fluid, and the relative pressures may govern the rebound rate of the suspension. Seals that minimize friction, an adjustment system, and a stop are also included to enhance rider joy.

A user accessible shock travel spacer assembly is disclosed herein. The system is used on a shock assembly having a shaft with an initial predefined stroke length. A retaining cap having a retaining cap thickness and a retaining cap opening therethrough. The retaining cap opening having a diameter that is larger than an outer diameter (OD) of a shaft of a shock assembly. At least one fastener to fasten the retaining cap with a portion of the shock assembly about the shaft, such that the retaining cap reduces a stroke length of the shaft of the shock assembly by the retaining cap thickness.

In one embodiment, a gas spring having a travel control includes positive and negative chambers and a valve mechanism that controls the fluid communication between the chambers. The valve mechanism includes a valve bore that while only moving a small amount, allows for large changes in gas spring travel length.

Disclosed is a console bed mechanism to provide access to controls on console bed transported in a transport case. The console bed mechanism may include a base plate positioned in the transport case and comprising a bearing, an upper plate secured to the console bed and connected via the bearing to the base plate, a rotation arm having a lower end mounted to the base plate and an upper end mounted to the upper plate, the rotation arm configured to rotate the console bed between: a transport position in which the console bed is at least partially in the transport case, and an operation position in which the console bed is at least partially above the transport case and is positioned to be operated, and also including an elevation arm that raises the console bed and having a lower end mounted to the transport case and an upper end secured to the base plate.

A supporting device including an installation assembly; a first supporting arm assembly having a longitudinal direction, a first end, and a second end; a switching bracket; a bearing unit pivotally connected to the switching bracket; and at least one gas spring is provided. The first end is pivotally connected to the installation assembly. The switching bracket is pivotally connected to the second end of the first supporting arm assembly. The gas spring is disposed in the first supporting arm assembly and is respectively connected to the switching bracket and the installation assembly to provide a supporting force. Each gas spring has a hollow tube, a piston rod, and a compression spring. The piston rod is slidably disposed through the hollow tube and has a head. The head may be varied between maximum and minimum protruding positions relative to the hollow tube. The compression spring is sleeved on the piston rod.

A pressure-adjustable gas spring includes a first gas spring and a gas source for adjusting a pressure. One end of the gas source is connected with the first gas spring and another end is connected with an adjustment device for adjusting the volume of the gas source. The adjustment device includes a cavity for accommodating the gas source and a piston. One end of the piston opposite the gas source is connected with a driving subassembly. The driving subassembly includes a screw. One end of the screw is connected with the piston and another end extends out of the cavity. A nut is arranged on the end of the screw extending out of the cavity. A connection tube is arranged outside the nut in a sleeving manner. One end of the connection tube is connected with the cavity and a rotating block is mounted at an opening of another end.

An exemplary self-balancing air spring includes a first chamber, the first chamber defining a primary volume, the first chamber including a movable piston, a second chamber fluidicly coupled to the first chamber via a first orifice and a second orifice, the second chamber defining a secondary volume, and an actuator coupled to the movable piston. In some aspects, the first orifice is an electromechanical valve and the second orifice is a bleed valve that equalizes the pressure between the first and second chambers.

The invention relates to a device (10) for triggering a gas spring (1), comprising an actuating apparatus (2), an actuating element (4), which is operatively connected to the actuating apparatus (2) and acts on an end trigger (3) of the gas spring (1), and a housing (20), wherein the housing (20) has a gas-spring connection hole (70), by means of which the upper end region of the gas spring (1) can be connected with the trigger (3) fed through into the interior of the housing (20), the gas-spring connection hole (70) is designed a through-hole, and means for the clamping fixation of the upper end region of the gas spring (1) inserted into the hole are present, characterized in that the housing (20) has an open slot (60), which extends from the gas-spring connection hole (70) to the end outer face (66) of the housing (20) and over the length of the gas-spring connection hole (70) at least in some regions, a left and a right protruding side wall region (68.1, 68.2) are formed by means of the slot (60), and the means for clamping and fixing are present in the region of the left and the right side wall regions (68.1, 68.2), which means for clamping and fixing clamp the left and the right side wall regions (68.1, 68.2) to each other, whereby a clamping force is applied to the end region of the gas spring (1) inserted into the gas-spring connection hole (70).