An engine has two pressure vessels arranged as a diametrically opposed pair. Each pressure vessel has an operating pressure sufficient to hold gas at a pre-defined pressure. At least one gas compressor is in communication with each pressure vessel, and the gas compressor is capable of compressing a gas in each pressure vessel to the pre-defined pressure. A pressure relief mechanism is in communication with each pressure vessel. The pressure relief mechanism is capable of returning the gas in each vessel to atmospheric pressure.

An apparatus and process for capturing mechanical work from the kinetic energy of a downward moving weighted vessel. The apparatus comprises an elevated downward-moving weighted vessel, a point of impact, a force transfer means to harness the impact, and a post-impact diversion means of the weighted vessel for unobstructed continuation of the process. In use, as the point of impact and force transfer means optimally aligns at the top of their upstroke, the sensor-initiated synchronized release and acceleration of the elevated weighted vessel results in downward movement, generating an exponentially multiplied weight force upon impact due to the accelerated kinetic force it acquires while descending. At the impact point, the kinetic energy force is transmitted from the moving vessel to the energy transfer means. The post-impact weighted moving vessel is then diverted out of the impact area to make way for the unobstructed continuation of the energy transfer cycle.

An apparatus and process for capturing mechanical work from the kinetic energy of a downward moving weighted vessel. The apparatus comprises an elevated downward-moving weighted vessel, a point of impact, a force transfer means to harness the impact, and a post-impact diversion means of the weighted vessel for unobstructed continuation of the process. In use, as the point of impact and force transfer means optimally aligns at the top of their upstroke, the sensor-initiated synchronized release and acceleration of the elevated weighted vessel results in downward movement, generating an exponentially multiplied weight force upon impact due to the accelerated kinetic force it acquires while descending. At the impact point, the kinetic energy force is transmitted from the moving vessel to the energy transfer means. The post-impact weighted moving vessel is then diverted out of the impact area to make way for the unobstructed continuation of the energy transfer cycle.

A power generation system including a partially enclosed container assembly housing a plurality of spherical balls at a container height disposed above a ground surface, each of the plurality of spherical balls having a ball weight. The power generation system also includes a conveyor assembly with a conveyor-drive system having a plurality of ball-catch members. The conveyor assembly includes a proximal end coupled to the container assembly, a distal end, and a conveyer length separating the proximal and distal ends. The conveyor assembly spans downwardly from the container assembly at a location below the container height and is operably configured, via the ball-catch members of the conveyor-drive system, to transport the spherical balls. A generator is operably coupled to the conveyor-drive system and is operably configured to produce electricity. The power generation system also includes a lift assembly having a lift-drive system spanning from a ball-receiving position to a ball-dispersing position with a height disposed above the ground surface that is greater than the container height. The lift-drive system includes a ball-platform sized to hold the plurality of spherical balls and a platform operably coupled to the lift-drive system that is sized to hold a plurality of users. The platform includes a raised position and a lowered position along a lift translation path. The raised position includes a height disposed above the ground surface that is greater than the container height. Movement of the platform of the lift-drive system along the lift translation path is operably configured to move the ball-platform of the lift-drive system along ball-platform translation path to transport the spherical balls to the ball-dispersing position.

A power generation system including a partially enclosed container assembly housing a plurality of spherical balls at a container height disposed above a ground surface, each of the plurality of spherical balls having a ball weight. The power generation system also includes a conveyor assembly with a conveyor-drive system having a plurality of ball-catch members. The conveyor assembly includes a proximal end coupled to the container assembly, a distal end, and a conveyer length separating the proximal and distal ends. The conveyor assembly spans downwardly from the container assembly at a location below the container height and is operably configured, via the ball-catch members of the conveyor-drive system, to transport the spherical balls. A generator is operably coupled to the conveyor-drive system and is operably configured to produce electricity. The power generation system also includes a lift assembly having a lift-drive system spanning from a ball-receiving position to a ball-dispersing position with a height disposed above the ground surface that is greater than the container height. The lift-drive system includes a ball-platform sized to hold the plurality of spherical balls and a platform operably coupled to the lift-drive system that is sized to hold a plurality of users. The platform includes a raised position and a lowered position along a lift translation path. The raised position includes a height disposed above the ground surface that is greater than the container height. Movement of the platform of the lift-drive system along the lift translation path is operably configured to move the ball-platform of the lift-drive system along ball-platform translation path to transport the spherical balls to the ball-dispersing position.

An energy storage system and method that enables gravity-based energy storage to have a significantly larger capacity in a single shaft for given capital cost and thus an improved cost per unit energy for large scale energy storage as well as enabling continuity of power input and output at an external connection point across the extent of the system's energy capacity comprises a multi-weight storage system having at least two weights, two transporters each with a transporter linkage that can be coupled to and decoupled from the respective weight and for transporting the weight along a pre-defined path defining a vertical displacement and defining a respective path volume, a second linkage path volume defined by the area of the second linkage decoupled from a weight and developed or swept along a respective pre-defined vertically displaced path, wherein the second linkage path volume does not overlap with the first path volume.

An energy storage system and method that enables gravity-based energy storage to have a significantly larger capacity in a single shaft for given capital cost and thus an improved cost per unit energy for large scale energy storage as well as enabling continuity of power input and output at an external connection point across the extent of the system's energy capacity comprises a multi-weight storage system having at least two weights, two transporters each with a transporter linkage that can be coupled to and decoupled from the respective weight and for transporting the weight along a pre-defined path defining a vertical displacement and defining a respective path volume, a second linkage path volume defined by the area of the second linkage decoupled from a weight and developed or swept along a respective pre-defined vertically displaced path, wherein the second linkage path volume does not overlap with the first path volume.

An energy storage and delivery system includes a crane operable to move 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 blocks from the higher elevation to the 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 blocks remain vertically spaced from each other, and a vertical distance between the lower elevation and the higher elevation of each of the blocks is the same.

An energy storage and delivery system includes a crane operable to move 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 blocks from the higher elevation to the 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 blocks remain vertically spaced from each other, and a vertical distance between the lower elevation and the higher elevation of each of the blocks is the same.

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.