A clamp assembly includes a body part having a recess of different sizes for holding an elongated structure with different sizes and shapes. A horizontal spaced T-slot is located on a first side surface of the body part at its top and a T-shaped protruding arm is located on a second side surface of the body part at its top. The clamp assembly includes a male locking section with an extended snap arm located on the first side surface of the body part at its bottom and a female locking section with a stopper located on the second side surface of the body part at its bottom. The T-shaped protruding arm is locked into the T-slot and simultaneously the male locking section is locked into the female locking section, such that the clamp assembly is detachably assembled with another clamp assembly.

A clamp assembly includes a body part having a recess of different sizes for holding an elongated structure with different sizes and shapes. A horizontal spaced T-slot is located on a first side surface of the body part at its top and a T-shaped protruding arm is located on a second side surface of the body part at its top. The clamp assembly includes a male locking section with an extended snap arm located on the first side surface of the body part at its bottom and a female locking section with a stopper located on the second side surface of the body part at its bottom. The T-shaped protruding arm is locked into the T-slot and simultaneously the male locking section is locked into the female locking section, such that the clamp assembly is detachably assembled with another clamp assembly.

An apparatus for reducing discharge pressure includes a compensator reservoir and a compensator line. The compensator line connects the compensator reservoir and a liquid line. The liquid line connects an outdoor heat exchanger and an indoor heat exchanger of a reversible HVAC system. The compensator line includes a connection to the compensator reservoir and a connection to the liquid line. A first expansion device is disposed in the liquid line and configured to only act on refrigerant flowing towards the outdoor heat exchanger. A second expansion device disposed in the liquid line and configured to only act on refrigerant flowing towards the indoor heat exchanger. The compensator is operable to receive refrigerant, driven by pressure, from the HVAC system, and further operable to allow refrigerant to flow back into the HVAC system.

An apparatus for reducing discharge pressure includes a compensator reservoir and a compensator line. The compensator line connects the compensator reservoir and a liquid line. The liquid line connects an outdoor heat exchanger and an indoor heat exchanger of a reversible HVAC system. The compensator line includes a connection to the compensator reservoir and a connection to the liquid line. A first expansion device is disposed in the liquid line and configured to only act on refrigerant flowing towards the outdoor heat exchanger. A second expansion device disposed in the liquid line and configured to only act on refrigerant flowing towards the indoor heat exchanger. The compensator is operable to receive refrigerant, driven by pressure, from the HVAC system, and further operable to allow refrigerant to flow back into the HVAC system.

A vibration damper for a fuel conduit of a gas turbine combustor includes a mounting portion and a damping portion. The mounting portion is secured to the fuel conduit, and the damping portion includes a stack of damping washers, a bushing on top of the stack of damping washers, a spring clip secured around the stack of damping washers and the bushing, and a shoulder bolt disposed through the bushing and the stack of damping washers and engaged to the mounting portion.

A vibration damper for a fuel conduit of a gas turbine combustor includes a mounting portion and a damping portion. The mounting portion is secured to the fuel conduit, and the damping portion includes a stack of damping washers, a bushing on top of the stack of damping washers, a spring clip secured around the stack of damping washers and the bushing, and a shoulder bolt disposed through the bushing and the stack of damping washers and engaged to the mounting portion.

A fixation member configured to fix a filler pipe to the vehicle body includes a flexural deformation portion. In a non-surrounded state, this flexural deformation portion is not flexurally deformed but is located on the inner side of the outer circumference of a filler neck body. In a surrounded state, the flexural deformation portion is flexurally deformed to induce a pressing force and provides the pressing force to the filler pipe. This configuration suppresses rattling of the filler pipe over a long time period.

A fixation member configured to fix a filler pipe to the vehicle body includes a flexural deformation portion. In a non-surrounded state, this flexural deformation portion is not flexurally deformed but is located on the inner side of the outer circumference of a filler neck body. In a surrounded state, the flexural deformation portion is flexurally deformed to induce a pressing force and provides the pressing force to the filler pipe. This configuration suppresses rattling of the filler pipe over a long time period.

In a vibration damper of a turbomolecular vacuum pump, a vacuum tightness function and a vibration damping function are both performed by one ore more toroidal rings made of an elastic material. The elastic rings assume a resting configuration while the vacuum pump is not operating and the damper is at atmospheric pressure, and they assume a compressed configuration while the vacuum pump is operating and the damper is under vacuum conditions. In the compressed configuration, the elastic rings are deformed due to a compression force. This deformation of the elastic rings prevents metal-to-metal contact between the vacuum pump and a vacuum chamber to which the pump is connected through the damper.

In a vibration damper of a turbomolecular vacuum pump, a vacuum tightness function and a vibration damping function are both performed by one ore more toroidal rings made of an elastic material. The elastic rings assume a resting configuration while the vacuum pump is not operating and the damper is at atmospheric pressure, and they assume a compressed configuration while the vacuum pump is operating and the damper is under vacuum conditions. In the compressed configuration, the elastic rings are deformed due to a compression force. This deformation of the elastic rings prevents metal-to-metal contact between the vacuum pump and a vacuum chamber to which the pump is connected through the damper.