An air powered engine assembly for improving efficiency includes a housing, which has an axle rotationally engaged thereto and extending through a front and a rear thereof. A turbine and a cam are engaged to the axle and positioned within the housing proximate to the front and the rear, respectively. The cam is bilobal. A plate engaged to the housing defines a chamber therein. The plate has a plurality of apertures positioned therein. Each of a set of reciprocating compressors is engaged to the housing and is fluidically engaged to the chamber. The reciprocating compressor comprises a piston rotationally engaged to an arm, which is rotationally engaged the housing. The reciprocating compressor forces air through the apertures to turn the turbine to rotate the axle. The cam is rotated to selectively engage alternatingly positioned arms as the axle rotates to actuate associated reciprocating compressors.

Aspects of the disclosure provide a power conversion system and a method for conversing power. The power conversion system includes a first fluid holding tank, a second fluid holding tank, a fluid inlet hose, a fluid outlet hose, a fluid container, and one or more tension springs connected to the upper surface of the container and to a lower surface of the first fluid holding tank. The power conversion system further includes a rotational component connected to a lower side of the container via a connecting rod. The power conversion system further includes a generator connected to the rotational component via a horizontal shaft. The power conversion system further includes a feedback hose connected between the second fluid holding tank and the first fluid holding tank. The power conversion system further includes a hydraulic pump connected to the second fluid holding tank.

A torque conversion device has: a second rotor having a second rotating shaft parallel to a first rotating shaft of a first rotor; link portions having first mounting portions attached to the first rotor, and second mounting portions attached to the second rotor, the link portions interposed between first rotor and second rotor; and weights mounted to the link portions and located on either side of the first mounting portions. The distance between first mounting portions and second mounting portions is equal to the distance between first rotating shaft and second rotating shaft, and the distance between first rotating shaft and first mounting portions is equal to the distance between the second rotating shaft and the second mounting portions.

An energy storage and delivery system includes an elevator, where the elevator is operable to move one or more blocks from a lower elevation to a higher elevation to store energy (e.g., via the potential energy of the block in the higher elevation) and operable to move one or more blocks from a higher elevation to a lower elevation (e.g., by gravity) to generate electricity (e.g., via the kinetic energy of the block when moved to the lower elevation). The energy storage system can, for example, store electricity generated from solar power as potential energy in the stacked blocks during daytime hours when solar power is available, and can convert the potential energy in the stacked blocks into electricity during nighttime hours when solar energy is not available, and deliver the converted electricity to the electrical grid.

A generator (100) and/or machine (110) generating mechanical energy and functioning on the principle of exploitation of an energy allowing the existence of centrifugal forces (Fc) on masses (120) being displaced in rotation, into an effective elliptic trajectory (150), about a respective shaft (128) freely rotatably mounted on a plate (122) itself freely rotatably mounted on a main shaft (202) freely rotatably mounted on a fixed chassis (140). The centrifugal forces generated by the masses (120) transmit a rotational oscillating movement of the plate (122) transferred by a mechanical energy transmission mechanism into a continuous rotation movement to an output torque mechanism freely mounted on the main shaft (202).

A generator (100) and/or machine (110) generating mechanical energy and functioning on the principle of exploitation of an energy allowing the existence of centrifugal forces (Fc) on masses (120) being displaced in rotation, into an effective elliptic trajectory (150), about a respective shaft (128) freely rotatably mounted on a plate (122) itself freely rotatably mounted on a main shaft (202) freely rotatably mounted on a fixed chassis (140). The centrifugal forces generated by the masses (120) transmit a rotational oscillating movement of the plate (122) transferred by a mechanical energy transmission mechanism into a continuous rotation movement to an output torque mechanism freely mounted on the main shaft (202).

A system and method in at least one embodiment for separating fluids including liquids and gases into subcomponents by passing the fluid through a vortex chamber into an expansion chamber and then through at least a portion of a waveform pattern present between at least two rotors and/or disks. In further embodiments, a system and method is offered for harnessing fields created by a system having rotating rotors and/or disks having waveform patterns on at least one side to produce current within a plurality of coils. In at least one embodiment, the waveform patterns include a plurality of hyperbolic waveforms axially aligned around a horizontal center of the system.

A system and method in at least one embodiment for separating fluids including liquids and gases into subcomponents by passing the fluid through a vortex chamber into an expansion chamber and then through at least a portion of a waveform pattern present between at least two rotors and/or disks. In further embodiments, a system and method is offered for harnessing fields created by a system having rotating rotors and/or disks having waveform patterns on at least one side to produce current within a plurality of coils. In at least one embodiment, the waveform patterns include a plurality of hyperbolic waveforms axially aligned around a horizontal center of the system.

An energy conversion method transfers energy from celestial bodies, including the Earth, to a vehicle apparatus by way of a gravity assist, a descent towards the surface of the celestial body, or both. The energy transferred to the vehicle apparatus may be utilized by: a kinetic energy converter apparatus converting the kinetic energy to any form of kinetic energy, potential energy, or both; doing work on any end use process or power plant apparatus immediately, later, or both; storing the kinetic energy, the potential energy, or both on an accumulator apparatus to be utilized on site, at another location, or both.

A gravity and buoyancy engine producing energy via a cyclical process of harnessed gravity and buoyancy has a gravity chamber, at least one air lock chamber, at least one electricity producing system, at least one buoyant object, and at least one vertical motion transfer assembly. The gravity chamber provides a zone for the buoyant object to engage the vertical motion transfer assembly as the buoyant object descends toward the air lock chamber. The vertical motion transfer assembly further transfers kinetic energy from the vertical motion of the buoyant object to the electricity generating system in order to provide useable electrical energy. The airlock chamber subsequently reintroduces the buoyant object into the buoyancy chamber to return said buoyant object to an elevated position and recycle through the gravity chamber.