Abstract: Method for vibration damping of and vibration damper assembly for semi-submerged or submerged structure, based on separating hydrodynamic added mass from the semi-submerged or submerged structure by means of a vibration damper assembly exhibiting spring and/or damper properties and use the hydrodynamic added mass as a reaction mass in the vibration damper assembly.
Type:
Grant
Filed:
March 6, 2018
Date of Patent:
November 8, 2022
Assignee:
Momentum Technologies AS
Inventors:
Even Lund, Håvard Bjørkøy Johnsen, Tomas Lundqvist, Lina Ödlund
Abstract: Method for vibration damping of and vibration damper assembly for semi-submerged or submerged structure, based on separating hydrodynamic added mass from the semi-submerged or submerged structure by means of a vibration damper assembly exhibiting spring and/or damper properties and use the hydrodynamic added mass as a reaction mass in the vibration damper assembly.
Type:
Application
Filed:
March 6, 2018
Publication date:
November 7, 2019
Applicant:
Momentum Technologies AS
Inventors:
Even LUND, Håvard Bjørkøy JOHNSEN, Tomas LUNDQVIST, Lina ÖDLUND
Abstract: A drive system, in particular for applications in conveying technology and the food industry, having a fixed shaft, an electric motor including a rotor rotatable about the shaft and a stator, a transmission, and a drum configured to be driven by the transmission at a reduced rotational speed and concentrically rotatable about the shaft. The rotor and the transmission are arranged within the drum, and the stator of the electric motor is arranged outside the drum.
Abstract: A turbine has a hollow conical rotor sealed by a base end cap. The outer race of a bearing is centered and mounted on the end cap. An intake shaft mounted within the bearing's inner race passes through the race. High-pressure fluid introduced into a passage within the intake shaft passes through a nozzle arm and nozzle mounted on the intake shaft within the interior of the rotor and is directed by the nozzle against the inner surface of the rotor. Friction and adhesion between the fluid and the inner surface transfers kinetic energy to the rotor, causing it to rotate. Fluid is exhausted from the interior of the cone through a passage in an output shaft attached to the apex of the rotor. Mechanical power may be extracted from the rotating output shaft directly, or through pulleys, gears, or other means. The turbine may be enhanced by addition of a cylinder between the base of the cone and the end cap, providing more surface area for energy exchange.