Implementations of the present invention relate to devices, systems, and methods for isolating electronic components from input vibrations. The vibration isolation device may passively isolate the housed electronics from substantially all input vibrations. The vibration isolation device may include elastic members to suspend the electronic components within a support frame such that input vibrations are unable to directly influence the electronic components.

The present disclosure provides a connector. The connector is applied in a vehicle-mounted display device and connected between a first component and a second component of the vehicle-mounted display device. The connector includes: a main body with a first end and an opposite second end; a limiting connection portion disposed at the first end of the main body and used to mount the main body to the second component; a deformable supporting portion that is deformable under force and disposed on the main body between the first end and the second end; and a fastening portion disposed at the second end of the main body and used to fix the first component.

The present invention provides a test device for a quasi zero stiffness isolator, and belongs to the technical field of vibration response tests of isolators. The device comprises a negative stiffness adjusting mechanism, a positive stiffness adjusting mechanism, and a beam-damping block mechanism. The negative stiffness adjusting mechanism and the positive stiffness adjusting mechanism are connected successively and installed on a beam-mass block system. The test device for the quasi zero stiffness isolator can realize smooth longitudinal vibration of a tested system, and can also flexibly adjust the positive stiffness value and the negative stiffness value of an overall mechanism. The present invention is suitable for a vibration model test of the quasi zero stiffness isolator, and solves the problems of complicated use method, impossibility of flexible adjustment of mechanism stiffness and complicated replacement process of stiffness elements in the device for the existing quasi zero stiffness isolator.

An energy damping and displacement control device is disclosed. The energy damping and displacement control device can include a contact protrusion and an energy damping pad constructed of a resilient material. The energy damping pad can have a first face oriented along a first plane. The energy damping pad can also have a second face oriented along a second plane transverse to the first plane, and toward the contact protrusion. In a static condition, the first and second faces of the energy damping pad can be separated from the contact protrusion. In a dynamic condition, displacement motion of the contact protrusion relative to the energy damping pad can be limited by contact with at least one of the first or second faces of the energy damping pad, which provides energy damping and motion displacement control of the contact protrusion in multiple axes.

A system for a projection exposure apparatus which comprises a first component, a second component, and a decoupling device configured to decouple the second component in more than one degree of freedom from mechanical excitations of the first component. The decoupling device comprises first decoupling elements which have a positive stiffness. The decoupling device also comprises second decoupling elements, which have a negative stiffness. The decoupling device further comprises a third component, which is arranged between the first and second components.

The invention provides a vibration isolation system (IS), comprising a piston (402) to carry a payload, a connecting member (410), a spring (404) and a flexible member (408). The spring is arranged to support the piston along a direction with a positive stiffness. The flexible member is arranged to apply a force to the piston along the direction via the connecting member with a negative stiffness.

Provided is a connector including: a first buffer member including a spiral-shaped wire; a second buffer member that has a substantially annular and flat plate-like shape; a collar member that includes a cylindrical portion surrounded by the first buffer member and the second buffer member, a first flange facing a radially inner side of the first buffer member, and a second flange facing a radially inner side of the second buffer member; and a coupling member that includes a first holder section holding radially outer sides of the first buffer member and the second buffer member, a second holder section holding the shielding body, and a coupling member base portion, in which a gap is formed between the second buffer member and the cylindrical portion, and the radially inner sides of the first buffer member and the second buffer member are sandwiched by the first flange and the second flange.

An embodiment of the present application discloses an anti-fall device including a trigger mechanism, a deformable structure and a shell. The deformable structure is connected with the trigger mechanism and is set to be compressed and elastically deformed when located in the shell. The trigger mechanism is set in the shell and is configured to drive the deformable structure to move in a direction away from the trigger mechanism, so that the deformable structure pops out of the shell and recovers to a natural state from a compressed state.

An apparatus may include an enclosure that includes a plurality of mounting features that are configured to receive information handling systems, a plurality of casters coupled to the enclosure, and first and second dampers. The first damper may have a first resonance frequency and be disposed such that, when the information handling systems are received in the enclosure, the first damper is coupled between the information handling systems and the plurality of casters. The second damper may have a second, different resonance frequency and be disposed such that, when the information handling systems are received in the enclosure, the second damper is coupled between the information handling systems and the plurality of casters.

A vibration-proof mount which is interposed between a vibration device including a vibration source and an elastic member disposed on a foundation surface includes an upper base plate including a first mounting portion where the vibration device is mounted, a lower base pate arranged below the upper base plate and supporting the upper base plate, and a plurality of connecting members connecting the upper base plate and the lower base plate, the plurality of connecting members including at least two or more first connecting members disposed between the first mounting portion and the lower base plate at intervals from one another. The first mounting portion is configured to have higher rigidity than the lower base plate.