A strut assembly includes a piston rod of a shock absorber, an upper support of the shock absorber, a bearing, a spring and a buffer block, which are coaxially arranged. The upper support of the shock absorber has a first through hole, the bearing has a second through hole, and a portion of the upper support of the shock absorber is arranged in the second through hole, the buffer block has a third through hole, and one end of the piston rod of the shock absorber is located in the first through hole, the other end of the piston rod of the shock absorber passes through the third through hole, the buffer block is connected with the upper support of the shock absorber, the spring is sleeved around the piston rod of the shock absorber, and the spring is connected with the bearing. The present disclosure further provides a vehicle.

End mount assemblies include a mounting bracket dimensioned for securement to an end member of a gas spring and damper assembly. The end mount assembly can include an inner mounting element dimensioned for securement to an elongated damping rod of the gas spring and damper assembly. A first plurality of bushing elements can be operatively disposed between the inner mounting element and the mounting bracket. A second plurality of bushing elements can be operatively disposed between the inner mounting element and the end member. Gas spring and a damper assemblies including such an end mount assembly as well as suspension systems and methods of assembly are also included.

End mount assemblies include a mounting bracket dimensioned for securement to an end member of a gas spring and damper assembly. The end mount assembly can include an inner mounting element dimensioned for securement to an elongated damping rod of the gas spring and damper assembly. A first plurality of bushing elements can be operatively disposed between the inner mounting element and the mounting bracket. A second plurality of bushing elements can be operatively disposed between the inner mounting element and the end member. Gas spring and a damper assemblies including such an end mount assembly as well as suspension systems and methods of assembly are also included.

End mount assemblies include a mounting bracket dimensioned for securement to an end member of a gas spring and damper assembly. The end mount assembly can include an inner mounting element dimensioned for securement to an elongated damping rod of the gas spring and damper assembly. A first plurality of bushing elements can be operatively disposed between the inner mounting element and the mounting bracket. A second plurality of bushing elements can be operatively disposed between the inner mounting element and the end member. Gas spring and a damper assemblies including such an end mount assembly as well as suspension systems and methods of assembly are also included.

Disclosed is a magneto-rheological strut comprising a housing tube, a damper body tube, and a bearing assembly disposed between the housing tube and the damper body tube. The bearing assembly comprises a bearing sleeve, with two integral annular bearings within the bearing sleeve and bearing against the damper body tube, and two internal annular seals abutting the radially external surface of the damper body tube and defining a fluid-tight internal lubricant chamber between the internal annular seals. The bearing assembly further comprises two external annular seals abutting the internal surface of the housing tube and defining an external lubricant chamber between the external annular seals and the housing tube. The bearing sleeve further comprises a number of radial channels passing through its wall and joining the internal lubricant chamber with the external lubricant chamber.

In one embodiment, the present disclosure provides a vibration damping device configured to decouple vibration of an electric motor for a ventilator, comprising: a base plate (140); a bearing unit (150) for supporting the electric motor, a plurality of decoupling elements (120), which are releasably coupled via retaining elements (151) to the bearing unit (150) and positionable between the bearing unit (150) and the base plate (140): wherein: the base plate (140) comprises mounting structures (141) for the decoupling elements (120) and fixing means (110) with a head (111): and each decoupling element (120) comprises adjacent to a recess at least one clamping section (121) for the corresponding fixing means (110) on the base plate (140); further wherein each of the fixing means (110) is configured to establish a force-fit and/or form-fit connection with the corresponding mounting structure (141) and the at least one clamping section (121) of the decoupling element (120) is pressed between a portion of the head (112) and the mounting structure (141) for a backlash free mounting of the decoupling element (120) to the base plate (140) in its mounted state. Due to the backlash-free mounting, the damping element cannot be loosened in the mounted state.

Providing an overturn preventing device which can easily be mounted between a top surface of an article and a ceiling and a method of mounting the overturn preventing device. The overturn preventing device includes a damper. The damper is mounted between a top surface of a piece of furniture (an article) and a ceiling. The damper includes a cylinder and a piston. A hydraulic fluid (operating liquid) and a compressed gas are enclosed in the cylinder. The piston is slidably housed in the cylinder. When the damper is to be mounted between the top surface of the furniture and the ceiling, the piston is housed in the compressed gas enclosed above the hydraulic fluid. The piston can be moved into the hydraulic fluid when the furniture is tilted and the damper is contracted by a predetermined length.

Disclosed is a magneto-rheological strut comprising a housing tube, a damper body tube, and a bearing assembly disposed between the housing tube and the damper body tube. The bearing assembly comprises a bearing sleeve, with two integral annular bearings within the bearing sleeve and bearing against the damper body tube, and two internal annular seals abutting the radially external surface of the damper body tube and defining a fluid-tight internal lubricant chamber between the internal annular seals. The bearing assembly further comprises two external annular seals abutting the internal surface of the housing tube and defining an external lubricant chamber between the external annular seals and the housing tube. The bearing sleeve further comprises a number of radial channels passing through its wall and joining the internal lubricant chamber with the external lubricant chamber.

End mount assemblies include a mounting bracket dimensioned for securement to an end member of a gas spring and damper assembly. The end mount assembly can include an inner mounting element dimensioned for securement to an elongated damping rod of the gas spring and damper assembly. A first plurality of bushing elements can be operatively disposed between the inner mounting element and the mounting bracket. A second plurality of bushing elements can be operatively disposed between the inner mounting element and the end member. Gas spring and a damper assemblies including such an end mount assembly as well as suspension systems and methods of assembly are also included.