A shaking unit for the generation of one-dimensional oscillating movements of a machine part mass is provided having a coupling part for mechanical coupling to the machine part mass, a counter-mass which is coupled resiliently to the coupler part and, via the latter, to the machine part mass, and a drive system which acts in a sprung manner between the coupler part and the counter-mass. The coupling part may surround the counter-mass as a frame. At least one of two pneumatic springs of the drive system, which are arranged on both sides of the counter-mass, is loaded with a minimum and/or with a maximum load pressure of the pneumatic springs depending on an oscillation state.

A mechanical actuator for Magnetic Resonance Elastography (MRE) and a method for inducing shear waves for MRE as well as respective system and method for MRE using the principle of centrifugal force for wave induction is disclosed. The mechanical actuator comprises a passive driver including a rotational turbine vibrator having an eccentric weight, the turbine vibrator being powered by a fluid (e.g. compresses air or water), and an active driver configured to control the pressure of the fluid powering the turbine vibrator.

A hydraulic vibration generation device or hydraulic motor is provided. The device includes a manifold having an inner volume with a pressure chamber extending into the inner volume, a fluid inlet orifice and a fluid outlet orifice. The device further includes a vibration generating member having a grooved drive and an off-center weight and retaining plates. The inner volume receives the vibration generating member within the inner volume. The vibration generating member rotates and generates vibration in response to hydraulic fluid flowing into the manifold through the inlet orifice and directed through the pressure chamber, relieves pressure upon exiting the pressure chamber and out of the manifold through the outlet orifice. Also provided a hydraulic motor with a same manifold and pressure chamber, but with a power generating member having the same groove drive without and off-center weight. Rotation of the power generating member generates power.

A vibration system for a compactor drum including a central support structure fixedly mounted within the compactor drum. The vibration system also includes a first vibratory exciter coupled to the central support structure. The vibration system further includes a second vibratory exciter coupled to the central support structure. The second vibratory exciter is longitudinally spaced apart from the first vibratory exciter. The vibration system includes a stabilizer element coupled to, and extending between, the first and second vibratory exciters. The stabilizer element is parallel to the central support structure.

A method for adjusting the position of an eccentric mass from the axis of rotation of a mechanism comprises rotating an eccentric mass about an axis of rotation, and moving the eccentric mass closer or further away from the axis of rotation solely by the changing the speed of rotation of the eccentric mass about the axis of rotation.

A vibrator-system for sinking an object into the ground by means of vibration, comprises a suspension yoke, a carter or carters mounted to the suspension yoke and equipped with a rotatable eccentric weight or weights for the generation of the vibration, and clamping means connected at a side of the carter or carters that is opposite to the suspension yoke for clamping the object, wherein the vibrator system is convertible between a first configuration and a second configuration, wherein in the first configuration a single carter is mounted to the suspension yoke and the clamping means are mounted to the single carter, and that in the second configuration two carters, each equipped with a rotatable eccentric weight or weights, are mounted between the suspension yoke and the clamping means.

A hydraulic vibration generation device or hydraulic motor is provided. The device includes a manifold having an inner volume with a pressure chamber extending into the inner volume, a fluid inlet orifice and a fluid outlet orifice. The device further includes a vibration generating member having a grooved drive and an off-center weight and retaining plates. The inner volume receives the vibration generating member within the inner volume. The vibration generating member rotates and generates vibration in response to hydraulic fluid flowing into the manifold through the inlet orifice and directed through the pressure chamber, relieves pressure upon exiting the pressure chamber and out of the manifold through the outlet orifice. Also provided a hydraulic motor with a same manifold and pressure chamber, but with a power generating member having the same groove drive without and off-center weight. Rotation of the power generating member generates power.

A pneumatic vibration device with a rotatable piston shaft comprises a piston body and a gas diverter. The piston body comprises a piston shaft, an input shaft and a piston cylinder body. The piston shaft comprises a hollow spindle with two ends connected to a first piston and a second piston through connection bearings respectively. The first piston and the second piston are connected through an inner sleeve. The spindle is connected to a rotary connection member. The input shaft stretches into the inner sleeve and is matched and connected with the rotary connection member. The gas diverter comprises a first gas diversion port and a second diversion port. The pneumatic vibration device is compact in structure and high in adaptability, and can realize rotation and vibration of drilling tools.

Slipform paver may include rheometers for measuring rheological parameters. The rheometers may include vane rheometers in a grout box of the slipform mold. The slipform paver may dynamically determining the rheological parameters of concrete and controlling a target vibrational frequency of vibrators based on the rheological parameters. The slipform paver may also use depth sensors, cameras, and/or electric vibrators for controlling the target vibration frequency.

A hydraulic vibration generation device or hydraulic motor is provided. The device includes a manifold having an inner volume with a pressure chamber formed in the inner volume, a fluid inlet orifice and a fluid outlet orifice. The device further includes a vibration generating member having a grooved drive and an off-center weight and retaining plates. The inner volume receives the vibration generating member within it. The vibration generating member rotates and generates vibration in response to hydraulic fluid flowing into the manifold through the inlet orifice and directed through the pressure chamber, relieves pressure upon exiting the pressure chamber into a pressure relief channel and out of the manifold through the outlet orifice. Also provided a hydraulic motor with a same manifold and pressure chamber, but with a power generating member having the same groove drive without an off-center weight. Rotation of the power generating member generates power.