A mass flow controller includes an inlet, a flow path in which fluid passes, a mass flow sensor configured to provide a signal corresponding to mass flow of the fluid through the flow path; a control valve configured to regulate a flow of the fluid out of an outlet of the mass flow controller; and a passive damping system coupled to the control valve and configured to dissipate fluid flow induced vibrations introduced by the control valve assembly. The passive damping system includes a damping pad between a receiver section of a valve base and a diaphragm backer. The passive damping system can also include a damping washer. The passive damping system can include one or more plunger balls between the damping pad and the valve base or one or more wave springs.

A damper includes a pressure tube and a piston defining a rebound chamber and a compression chamber within the pressure tube. The damper further includes an adapter attached to the pressure tube. The damper includes a retainer slidably disposed within the pressure tube. The retainer and the adapter define an end chamber therebetween within the pressure tube. The damper also includes a cup movably disposed within the pressure tube between the retainer and the adapter. The damper further includes a tubular member disposed adjacent to the cup and attached to the adapter. The tubular member includes at least one through aperture. The damper includes a base valve attached to the adapter. The damper also includes a first spring disposed between the retainer and the cup and a second spring disposed between cup and the adapter.

A spring-damper assembly includes a damper, a coil spring disposed axially about the damper and directly or indirectly engaging an upper spring seat and a lower spring seat. A spherical support is disposed about and coupled to the damper or strut and is in contact with the upper spring seat or the lower spring seat, respectively. The spherical support allows relative movement between the spherical support and the associated upper or lower spring seat to provide a self-aligning feature for minimizing side forces exerted by the coil spring on the damper or strut. In one exemplary embodiment, a layer of material is disposed between the spherical support and the associated upper or lower spring seat to facilitate relative movement between the spherical support and the associated upper or lower spring seat.

A laundry treating apparatus includes a main body, a washing tub, and a suspension assembly. The suspension assembly includes a support rod, an elastic member, and a damper. The damper includes a cap, a housing, and a friction member. The friction member is disposed in both the cap and the housing, and is configured to press the support rod through the coupling of the female coupling portion and the male coupling portion.

An energy absorbing strut having, a first end coupled with an inner cylinder, and a second end connected with a hollow rod extending within the inner cylinder. A piston is carried by the rod having an outer surface sealing against an inside diameter of the inner cylinder and forming a compression chamber and a rebound chamber bounded by the piston, the rod having an internal passageway communicating between the compression chamber and the rebound chamber. An inertial mass carried by the rod movable axially on the rod between a closed position against and annular rod passageway and an open position opening the rod passageway and allowing the flow of a hydraulic fluid between the compression chamber and the rebound chamber. A spring acts on the inertial mass biasing the inertial mass toward the closed position. The energy absorbing strut may be used in a blast mitigation system for a military vehicle or other applications for providing shock isolation between two structures.

A suspension array includes a support rod, an elastic member wound around the support rod, a housing supported by the elastic member and including a compartment surrounding the support rod, the support rod being coupled to the housing while penetrating the housing in the longitudinal direction, a friction member installed inside the housing to cause friction with the support rod when the friction member in the compartment is displaced, and a cap penetrated in the longitudinal direction by the support rod and coupled with the housing to cover the compartment, wherein the support rod penetrates the cap along the longitudinal direction and wherein the housing includes one or more first holes configured to discharge, to the outside, condensate generated in an inner space defined by the coupling between the cap and the housing.

Disclosed is a shock absorber for a vehicle including a cylinder filled with a fluid, a piston rod disposed inside the cylinder, a piston valve disposed at a lower portion of the piston rod, a stopper installed above the piston valve on the piston rod, a free piston configured to divide the cylinder into a first chamber and a second chamber below the first chamber and installed on the piston rod to be movable upward from the stopper, a spring configured to elastically support the free piston, and a bypass portion provided on an inner circumferential surface of the cylinder.

A hydraulic mount assembly includes a mount body defining a cavity. A powertrain includes a dynamic mass, and a structure that supports the dynamic mass. The assembly is attached to the structure and supports the dynamic mass. A first plate is fixed relative to the mount body inside the cavity to separate the cavity into a first chamber and a second chamber. The first plate defines a plurality of first passages that fluidly connects the first and second chambers. A decoupler is disposed between the first and second chambers. An actuator is coupled to the first plate. The decoupler is movable in response to actuation of the actuator. The decoupler abuts the first plate when in a locked position to prevent fluid communication through the first passages. The decoupler is movable relative to the first plate when in an unlocked position to allow fluid communication through the first passages.

A vibration isolator includes a series of hard bushings that press against each other and slide, under the constraint of friction from the engagement of the bushings. A fastener, such as a bolt, passes through the engaged bushings, and one or more springs provide a spring force that maintains the engagement of the bushings. The bushings may include top and bottom bushings having chamfered surfaces, which engage corresponding upper and lower sloped surface on a middle friction bushing which can slide relative to the top and bottom bushings. The isolator may be part of a vibration isolation system that includes multiple isolators to provide isolation for an isolated object. The bushings may be made of metal or another suitable hard material. The isolator may be suitable in particular for vibration isolation in situations where vibrations are of severe, but short duration.

A vibration isolator includes a series of hard bushings that press against each other and slide, under the constraint of friction from the engagement of the bushings. A fastener, such as a bolt, passes through the engaged bushings, and one or more springs provide a spring force that maintains the engagement of the bushings. The bushings may include top and bottom bushings having chamfered surfaces, which engage corresponding upper and lower sloped surface on a middle friction bushing which can slide relative to the top and bottom bushings. The isolator may be part of a vibration isolation system that includes multiple isolators to provide isolation for an isolated object. The bushings may be made of metal or another suitable hard material. The isolator may be suitable in particular for vibration isolation in situations where vibrations are of severe, but short duration.