The present invention relates to a variable load hydraulic control device comprising an inner tube able to be coupled to an upper tubular head to form an internal chamber and an external chamber, in addition to an inner casing, a floating piston, able to slide between the inner tube and the inner casing, a retaining ring, an upper spring, located between the floating piston and an extension of a washer located inside the upper tubular head, a lower spring, located between the floating piston and an extension of the inner casing, a control surface, a leak opening to communicate the external chamber and the internal chamber, wherein the static load of the hydraulic control device determines the position of the floating piston and the section of passage through the leak opening.

The present invention relates to a variable load hydraulic control device comprising an inner tube able to be coupled to an upper tubular head to form an internal chamber and an external chamber, in addition to an inner casing, a floating piston, able to slide between the inner tube and the inner casing, a retaining ring, an upper spring, located between the floating piston and an extension of a washer located inside the upper tubular head, a lower spring, located between the floating piston and an extension of the inner casing, a control surface, a leak opening to communicate the external chamber and the internal chamber, wherein the static load of the hydraulic control device determines the position of the floating piston and the section of passage through the leak opening.

An assembly for damping switching movements has a housing, which physically surrounds at least one piston, and which at least partly physically surrounds at least one rod. The rod is movable relative to the housing. The piston delimits a first fluid volume, which is fluidically connected to a second fluid volume by way of a throughflow opening. The rod is formed at one end as a hollow tube and physically surrounds the first fluid volume. The piston is guided in the hollow-tubular end of the at least one rod. A method for damping switching movements in a high-voltage circuit breaker includes decreasing a damping rate of the assembly for damping in a period in the time profile of the switching movement, in particular after a previous increase in the damping rate during the switching movement.

An assembly for damping switching movements has a housing, which physically surrounds at least one piston, and which at least partly physically surrounds at least one rod. The rod is movable relative to the housing. The piston delimits a first fluid volume, which is fluidically connected to a second fluid volume by way of a throughflow opening. The rod is formed at one end as a hollow tube and physically surrounds the first fluid volume. The piston is guided in the hollow-tubular end of the at least one rod. A method for damping switching movements in a high-voltage circuit breaker includes decreasing a damping rate of the assembly for damping in a period in the time profile of the switching movement, in particular after a previous increase in the damping rate during the switching movement.

A solar tracker system includes a support tube, a solar panel assembly connected to the support tube, and an active lock connected to the support tube. The active lock includes a housing defining a chamber and a seal. The seal prevents a flow of fluid through the chamber when the active lock is in a sealed state and allows the flow of fluid through the chamber when the active lock is in an unsealed state. The active lock further includes a locking system motor connected to the seal to transition the active lock between the sealed state and the unsealed state, a battery providing power to the locking system motor, and an antenna for receiving instructions controlling the locking system motor.

A vibration damper for a vehicle, includes at least one cylinder tube forming a fluid chamber, in which a piston assembly is axially and slidingly arranged and divides the cylinder tube into two working chambers, an upper and a lower working chamber, and wherein the piston assembly has an axially moveable main piston which is axially fixed to a piston rod that can move axially relative to the cylinder tube, and which has a piston valve influencing the fluid flow between the upper and lower working chambers, and wherein a further stroke-dependent piston is arranged on an axial extension of the piston rod in the direction of the cylinder base, which operates once a determined damper stroke is achieved. The stroke-dependent piston has a smaller diameter than the main piston and only operates when plunging into a smaller diameter of an inner casing surface. The stroke-dependent piston therefore has a stroke-dependent valve, and the stroke-dependent piston also has a frequency-dependent valve in addition to the stroke-dependent valve.

Disclosed is a shock absorber. The shock absorber includes a cylinder filled with a fluid, and a piston valve coupled to an end of a piston rod to partition the inside of the cylinder into a rebound chamber and a compression chamber and to which a lower washer is fastened at a lower end thereof, and further includes a guide member disposed to be spaced apart from the lower side of the piston valve so as to be movable forward and backward within the cylinder and having a connection flow path communicating a pressing chamber formed at a lower side and the compression chamber, a bumper member provided to be compressible in the pressing chamber to elastically support the guide member, and a support member coupled to an end of the cylinder to support a lower end of the bumper member and having a communication hole communicating with the pressing chamber, wherein the bumper member partitions the pressing chamber into a first pressing chamber and a second pressing chamber and has a plurality of side holes communicating the first pressing chamber and the second pressing chamber.

A suspension apparatus includes a spring piston and a spring tube body. The spring piston is slidably disposed within the spring tube body to move within the spring tube body over a travel along an axis of reciprocation. The spring piston bounds a primary positive gas spring chamber at least a first portion of a primary negative gas spring chamber. The suspension apparatus also includes a secondary negative gas spring chamber and a separator. The separator permits fluid pressure communication between the primary negative gas spring chamber and the secondary negative gas spring chamber over a first portion of the travel of the spring piston, and the separator prevents fluid pressure communication between the primary negative gas spring chamber and the secondary negative gas spring chamber over a second portion of the travel of the spring piston.

A suspension apparatus includes a spring piston and a spring tube body. The spring piston is slidably disposed within the spring tube body to move within the spring tube body over a travel along an axis of reciprocation. The spring piston bounds a primary positive gas spring chamber at least a first portion of a primary negative gas spring chamber. The suspension apparatus also includes a secondary negative gas spring chamber and a separator. The separator permits fluid pressure communication between the primary negative gas spring chamber and the secondary negative gas spring chamber over a first portion of the travel of the spring piston, and the separator prevents fluid pressure communication between the primary negative gas spring chamber and the secondary negative gas spring chamber over a second portion of the travel of the spring piston.

A shock absorber including a damper and a valve assembly for throttling fluid flow between a compression damper chamber and a pneumatic spring, with a valve assembly extending from an inner end portion of the damper into the compression damper chamber along a longitudinal central axis of the damper. A piston assembly is provided that includes an inner space which is open to the compression damper chamber and configured to receive and sealingly engage a distal portion of the valve assembly at an inner operational range of stroke and to disengage the valve assembly upon movement outside the inner operational range of stroke. The sealing engagement between the distal portion of the valve assembly and the inner space divides the compression damper chamber into an inner volume within the inner space and an outer volume in front of the piston assembly.