A renewable energy cycle system and method thereof is disclosed, wherein the renewable energy cycle system comprises a water softening equipment, an electrolysis hydrogen equipment, at least a combustion boiler equipment, a generator and at least a steam efficacy conversion device. Herein softened water can be electrolyzed into hydrogen and oxygen by means of the electrolysis hydrogen equipment, and the decomposed hydrogen can be transported to the combustion boiler equipment for combustion such that the liquid in the combustion boiler equipment boils and generates saturated vapor pressure. Next, the generated saturated vapor pressure can be outputted into the steam efficacy conversion equipment such that the steam efficacy conversion equipment can convert the steam efficacy into mechanical energy thereby allowing the steam engine in the steam efficacy conversion equipment to rotate in high speed. Then, the generated high speed rotations can draw the generator to cut the internal magnetic lines to perform mechanical operations for power generation, and the electric energy created by the mechanical operations of power generation can be circularly provided to the electrolysis hydrogen equipment as the required electric power for operations thereof so as to achieve the objective of environment protective cycle power supply.

A power supply includes a housing receiving an electric motor, first and second fans, a generator, and a power device. The generator is concentrically mounted around the electric motor. When the electric motor is supplied with electricity from the power device and operates, a shaft of the electric motor drives the first fan to rotate, generating wind power close to the second fan. The second fan is rotated by the wind power in the housing and drives the second rotor and the second rotor seat to rotate. The first and second magnets create repulsive and attractive forces to provide inertia driving the second rotor seat, making the generator continuously supply electricity to the power device and the electric motor, thereby keeping the electric motor running to generate the wind power while the first fan continuously using the wind power to drive the second fan and the generator to generate electricity.

An apparatus and kit for capturing waste air flow wherein the apparatus comprises a shroud locatable over the waste airflow source, a first fan rotatably mounted within the should and a first electrical generator motor operably connected to and driven by rotation of the first fan, wherein the first fan is rotatable in a first direction by the waste air flow. The kit further comprises a second fan sized to correspond to and replace an existing axial fan.

A rotation device includes an output shaft, at least one rotatable rotary plate member arranged so that its rotation axis and the output shaft are coaxial, at least one weight member fixed to the rotary plate member, for biasing position of the center of gravity from the rotation axis of the rotary plate member, and at least one clutch mechanism arranged between the rotary plate member and the output shaft, for separating the rotary plate member and the output shaft with each other at a predetermined rotation angle. The clutch mechanism connects the rotary plate member with the output shaft when the center of gravity of the weight member descends, and separates the rotary plate member from the output shaft when the center of gravity of the weight member rises.

This invention relates to devices for converting a small input force to a larger output force and particularly relates to devices and methods for converting an input force to an output force comprising: an arm rotatable about an axis of rotation where the axis of rotation is moveable between first and second positions; an input force for rotating and moving the arm about the axis of rotation between the first and second positions; structure for controlling the rotation of the arm, movement and position of the axis of rotation to generate a non-circular orbital segment of the arm to transfer an output force between the first and second positions.

This invention relates to devices for converting a small input force to a larger output force and particularly relates to devices and methods for converting an input force to an output force comprising: an arm rotatable about an axis of rotation where the axis of rotation is moveable between first and second positions; an input force for rotating and moving the arm about the axis of rotation between the first and second positions; structure for controlling the rotation of the arm, movement and position of the axis of rotation to generate a non-circular orbital segment of the arm to transfer an output force between the first and second positions.

Provided is a power generation device using magnetic force, the power generation device comprising: a plurality of tunnel-type bodies having unilateral open passages and arranged and fixed at the same intervals on a revolutional orbit, wherein the respective tunnel-type bodies are provided with a plurality of permanent magnets between inner magnetic bodies and outer magnetic bodies, and permanent magnets and the outer magnetic bodies are attached to the outer surface of the inner magnetic bodies such that the permanent magnets facing the inner and outer magnetic bodies can have opposite polarities, thereby forming magnetic fields in inner body spaces; and magnetic border membranes having opposite magnetic poles on the inner and outer sides thereof and formed on entrance sides and exit sides of the tunnel-type bodies.

Provided is a power generation device using magnetic force, the power generation device comprising: a plurality of tunnel-type bodies having unilateral open passages and arranged and fixed at the same intervals on a revolutional orbit, wherein the respective tunnel-type bodies are provided with a plurality of permanent magnets between inner magnetic bodies and outer magnetic bodies, and permanent magnets and the outer magnetic bodies are attached to the outer surface of the inner magnetic bodies such that the permanent magnets facing the inner and outer magnetic bodies can have opposite polarities, thereby forming magnetic fields in inner body spaces; and magnetic border membranes having opposite magnetic poles on the inner and outer sides thereof and formed on entrance sides and exit sides of the tunnel-type bodies.

A transient liquid pressure power generation system can include a liquid source and a transient pressure drive device fluidly coupled to the liquid source. The transient pressure drive device can include a drive component, and a valve to cause a high pressure transient wave in the liquid traveling toward the liquid source to operate the drive component. The system can also include a liquid velocity continuation component downstream of the transient pressure drive device and a bypass conduit. Additionally, the system can include a heat source to receive liquid from the transient pressure drive device and heat liquid returning to the liquid source. The liquid velocity continuation component can operate to maintain continuous liquid flow from the liquid source to the heat source from the transient pressure drive device or the bypass conduit to cause immediate maximum liquid flow velocity from the transient pressure drive device upon opening the valve.

A transient liquid pressure power generation system can include a liquid source and a transient pressure drive device fluidly coupled to the liquid source. The transient pressure drive device can include a drive component, and a valve to cause a high pressure transient wave in the liquid traveling toward the liquid source to operate the drive component. The system can also include a liquid velocity continuation component downstream of the transient pressure drive device and a bypass conduit. Additionally, the system can include a heat source to receive liquid from the transient pressure drive device and heat liquid returning to the liquid source. The liquid velocity continuation component can operate to maintain continuous liquid flow from the liquid source to the heat source from the transient pressure drive device or the bypass conduit to cause immediate maximum liquid flow velocity from the transient pressure drive device upon opening the valve.