Differential gravity power generator FIG. 1 consisting of a box height H, filled with fluid, subject to gravity. The box is divided into T.sub.1 (1, 2, 3, 4, 5, 8) and T.sub.2 (2, 3, 5, 6, 7, 8) by plane (2, 3, 5, 8) with openings A above and B below. The difference of effective head of T.sub.2 over T.sub.1 is ⅓H, resulting in a fluid flow from T.sub.2 to T.sub.1 through B. From the continuity equation an equal quantity of fluid flows from T.sub.1 to T.sub.2 through A, establishing a fluid conserving motion, demonstrated with working models. Applications: electricity generation with water or other fluid like liquid CO.sub.2 and motive purposes like propulsion of ships.

A method for driving a transmission mechanism output power in response to an anticipated fluid-pressure gradient field is provided. The method includes sensing the change of direction of pressure gradient field at a desired location from the different area of the transmission mechanism within fluid. The method further includes constructing fluid-pressure gradient field based upon isolation-fluid apparatus or low-density fluid space installed on a transmission mechanism within fluid.

A method for driving a transmission mechanism output power in response to an anticipated fluid-pressure gradient field is provided. The method includes sensing the change of direction of pressure gradient field at a desired location from the different area of the transmission mechanism within fluid. The method further includes constructing fluid-pressure gradient field based upon isolation-fluid apparatus or low-density fluid space installed on a transmission mechanism within fluid.

A method for obtaining fluid gravitational potential energy and buoyant potential energy by utilizing an internal space of a rotor on turbine engine is provided. The method includes allowing fluid to act on the outer space of the rotor to form a reciprocating power with the interior of the rotor through utilizing a spatial structure of the rotor. The method further includes the rotor on the turbine obtaining a rotational torque of the turbine engine in response to fluid transient action at the desired location.

A machine for driving an electric generator moves a power module through a DOWN and UP duty cycle along a closed-loop, vertically oriented pathway. In the DOWN portion of the duty cycle, the module falls through air under the influence of gravity and generates kinetic energy for work to drive the electric generator. Upon disengagement of the power module from the electric generator, the kinetic energy of the power module then dives the power module into a bi-level water tank for a subsequent UP portion of the duty cycle. A valve mechanism and a displacement device are submerged in the bi-level tank to cooperate, in combination with each other, to create an unobstructed underwater pathway for the power module through the bi-level tank. The power module then rises under the influence of buoyancy to generate sufficient momentum for exit from the bi-level tank, and a consecutive duty cycle.

A machine for driving an electric generator moves a power module through a DOWN and UP duty cycle along a closed-loop, vertically oriented pathway. In the DOWN portion of the duty cycle, the module falls through air under the influence of gravity and generates kinetic energy for work to drive the electric generator. Upon disengagement of the power module from the electric generator, the kinetic energy of the power module then dives the power module into a bi-level water tank for a subsequent UP portion of the duty cycle. A valve mechanism and a displacement device are submerged in the bi-level tank to cooperate, in combination with each other, to create an unobstructed underwater pathway for the power module through the bi-level tank. The power module then rises under the influence of buoyancy to generate sufficient momentum for exit from the bi-level tank, and a consecutive duty cycle.

The invention relates to a hydraulic device that uses gravity and buoyancy forces, in which during a rotation of the assembly, movable masses (M1, . . . , Mn) are displaced by means of a force acting on the masses that counteracts the weight force in such a way that said masses contribute to the rotational movement.

The invention relates to a hydraulic device that uses gravity and buoyancy forces, in which during a rotation of the assembly, movable masses (M1, . . . , Mn) are displaced by means of a force acting on the masses that counteracts the weight force in such a way that said masses contribute to the rotational movement.

Energy is harvesting from fluids with different densities, such as water (34) and air (38) with a rotor (12) that is selectively above and below a water surface (30). The rotor (12) has cavities (31,32) inside tubes (18) with apertures (24) in walls (22) of the tubes (18). In a submerged mode, with the rotor (12) in the water (34), air is trapped in tubes (18) on one side of the rotor (12), which has apertures (24) facing down and air is released from the tubes (18) on the opposite side of the rotor (12), which has apertures (24) facing up. The opposite happens in an elevated mode.

A bi-level tank includes a transfer tank and a return tank containing a volume of water, including transfer and return components in the transfer and return tanks, respectively, and a transition component. A bellows couples an upper surface of a piston in the transfer tank to the return component that exerts pressure on the upper surface, while a lower surface of the piston is under pressure from a pressured fluid supplied by a source thereof, producing a pressure differential on the piston. Actuation of a force-applying mechanism on the piston sufficient to overcome the pressure differential displaces the piston for exchanging respective volumes of the return component and the fluid from the source. An extensible and retractable constant-volume boot holds the transition component around the bellows and has valves configured to open and close for equalizing pressure between the boot and the transfer tank.