Disclosed is a structure for preventing vibrations of equipment, which is capable of preventing vibrations generated by equipment disposed in an industrial facility, a bogie, a facility disposed in a clean room, or the like from being transmitted to the outside of the equipment. The vibrations generated by the equipment may be blocked from being transmitted to a steel grating, which is a lower structure, through a wheel by mounting an anti-vibration unit for blocking the vibrations generated by the equipment on the wheel mounted on a lower end of the equipment. In addition, vibrations, which are transmitted through a fixing bolt, of the equipment may be blocked by forming the anti-vibration unit to surround the fixing bolt for fixing the wheel to the equipment.

Disclosed is a structure for preventing vibrations of equipment, which is capable of preventing vibrations generated by equipment disposed in an industrial facility, a bogie, a facility disposed in a clean room, or the like from being transmitted to the outside of the equipment. The vibrations generated by the equipment may be blocked from being transmitted to a steel grating, which is a lower structure, through a wheel by mounting an anti-vibration unit for blocking the vibrations generated by the equipment on the wheel mounted on a lower end of the equipment. In addition, vibrations, which are transmitted through a fixing bolt, of the equipment may be blocked by forming the anti-vibration unit to surround the fixing bolt for fixing the wheel to the equipment.

A laminated elastomeric journal bearing has an outer sleeve having an inner surface, at least a portion of each end of the inner surface being a concave surface of revolution, and an inner sleeve having an outer surface, at least a portion of each end of the outer surface being a convex surface of revolution. Alternating layers of elastomer and metal are located between the sleeves, with adjacent surfaces of the layers and the sleeves being adhered to each other.

The present invention relates to a solar panel to which a high-damping stacked reinforcement part is applied and, more specifically, to a solar panel to which a high-damping stacked reinforcement part is applied, comprising: a power generation unit for generating electrical energy; a coupling part to which the power generation unit is coupled, and which has a circuit formed therein; and a reinforcement part for reinforcing the rigidity of the coupling part and damping vibration to be transmitted, and thus the present invention can prevent the power generation unit from being damaged by vibration, or the solar panel from inducing wobbling of a satellite by failing to damp the vibration.

A reinforcing vibration-damping material that includes a reinforcing material and a vibration-damping material disposed on the reinforcing material in a thickness direction of the reinforcing material. The vibration-damping material has a first portion that overlaps the reinforcing material in the thickness direction and a second portion that does not overlap the reinforcing material in the thickness direction. When the reinforcing vibration-damping material is attached to the object, the reinforcing material is adhered to the object and the second portion of the vibration-damping material is also adhered to the object so that the vibration-damping material suppresses the downward displacement of the reinforcing material.

An elastomeric body for vibration damping and/or suspension, has a base body and a flame-retarding coating which covers at least one section of the base body, wherein the flame-retarding coating has at least two intumescent fire protection systems and the first fire protection system contains expandable graphite which comprises at least a first fraction with an average grain size of more than 180 μm and at least a second fraction with an average grain size of less than 180 μm, and the second fire protection system forms a support structure in the expanded state, which structure at least partially fixes the expanded graphite in the expanded state.

The invention relates to a vibration absorber arrangement (2) for attaching at least one vibration absorber (4) to a rail (1), comprising: a clamping means (3) which has a clamp fastening portion (12) and a fastening portion (11) for at least one vibration absorber (4) on the outside thereof, wherein the clamp fastening portion (12) can be clamped between one end (16) of a clamp (5) and a foot (8) of the rail (1) and the fastening portion (11) presses with its inside against a web (9) of the rail (1), the clamp (5) being formed as an integral spring clip.

The invention relates to a vibration absorber arrangement (2) for attaching at least one vibration absorber (4) to a rail (1), comprising: a clamping means (3) which has a clamp fastening portion (12) and a fastening portion (11) for at least one vibration absorber (4) on the outside thereof, wherein the clamp fastening portion (12) can be clamped between one end (16) of a clamp (5) and a foot (8) of the rail (1) and the fastening portion (11) presses with its inside against a web (9) of the rail (1), the clamp (5) being formed as an integral spring clip.

A vibration damping device for a structure 1 includes a circular tubular member 3 having a circular tubular inner peripheral surface 2; a columnar elongated member 6 which is disposed in the circular tubular member 3 relatively movably in a direction X with respect to the circular tubular member 3 and having a circular tubular outer peripheral surface 5; and a circular tubular elastic member 10 which has a circular tubular member outer peripheral surface 8 fixed to the inner peripheral surface 2 of the circular tubular member 3 and a circular tubular member inner peripheral surface 9 fixed to the circular tubular outer peripheral surface 5 of the elongated member 6, and which is disposed between the inner peripheral surface 2 of the circular tubular member 3 and the outer peripheral surface 5 of the elongated member 6.

A vibration damping device for a structure 1 includes a circular tubular member 3 having a circular tubular inner peripheral surface 2; a columnar elongated member 6 which is disposed in the circular tubular member 3 relatively movably in a direction X with respect to the circular tubular member 3 and having a circular tubular outer peripheral surface 5; and a circular tubular elastic member 10 which has a circular tubular member outer peripheral surface 8 fixed to the inner peripheral surface 2 of the circular tubular member 3 and a circular tubular member inner peripheral surface 9 fixed to the circular tubular outer peripheral surface 5 of the elongated member 6, and which is disposed between the inner peripheral surface 2 of the circular tubular member 3 and the outer peripheral surface 5 of the elongated member 6.