A cage energy supply system comprises wind power generation devices, a tail rope beam suspension device and a control device that are connected to the bottom of a cage box. The tail rope beam suspension device and the control device are located on the central axis of the bottom of the cage box, and the two sides of the tail rope beam suspension device are each connected to one wind power generation device. By means of the characteristics that the descending speed of the cage is high and the relative wind speed of an auxiliary shaft is high, the two wind power generation devices charge one storage battery at the same time, and the two storage batteries carry out charging and power supply alternately, so that a powered unit of the cage is supported by a stable and reliable power source all the time, the power supply requirement of the cage for the powered unit thereof is met, and meanwhile the power supply requirement for the control device is met. The devices are simple in structure and only need to be overhauled and maintained regularly. The present invention also relates to a control method for the cage energy supply system.

A cage energy supply system comprises wind power generation devices, a tail rope beam suspension device and a control device that are connected to the bottom of a cage box. The tail rope beam suspension device and the control device are located on the central axis of the bottom of the cage box, and the two sides of the tail rope beam suspension device are each connected to one wind power generation device. By means of the characteristics that the descending speed of the cage is high and the relative wind speed of an auxiliary shaft is high, the two wind power generation devices charge one storage battery at the same time, and the two storage batteries carry out charging and power supply alternately, so that a powered unit of the cage is supported by a stable and reliable power source all the time, the power supply requirement of the cage for the powered unit thereof is met, and meanwhile the power supply requirement for the control device is met. The devices are simple in structure and only need to be overhauled and maintained regularly. The present invention also relates to a control method for the cage energy supply system.

Various aspects of the technology provide for reducing noise and vibration in a pressure exchanger for high pressure fluid handling equipment such as a desalination system, by disposing grooves between a seal surface and a port. The groove reduces a hammer effect in moving high pressure fluid to a low pressure port and moving low pressure fluid to a high pressure port. Reduction in the hammer effect, in addition to reducing noise, reduces vibration that can cause deterioration of high pressure fluid handling equipment.

The present inventive concept provides for a method of harnessing artesian aquifer power. The method includes obtaining weather data and artesian aquifer data for a geolocation. Weather features and artesian aquifer features are extracted from the obtained weather data and artesian aquifer data, respectively. Compression and decompression events are predicted for water in an artesian well at the geolocation by mapping the weather features and the artesian aquifer features. A plurality of piezoelectric springs connected to the artesian well are modulated to maximize artesian aquifer energy harnessed based on the predicted compression and decompression events.

A hydroelectricity and compressed-air power converter system includes a first fill pool, a plurality of internal fill tanks, an external fill tank, a wave channel, a plurality of air-generator systems, a second fill pool, at least one air storage tank, and at least one generator system. The first fill pool is intermittently in fluid communication with the external fill tank through the plurality of internal fill tanks while the external fill tank is intermittently in fluid communication with the second fill pool through the wave channel. The second fill pool is selectively in fluid communication with the first fill pool through the at least one generator system so that a set amount of water can be circulated within the power converter system as it generates compressed-air from the plurality of air-generator systems and hydroelectricity from the at least one generator system.

Exemplary embodiments of the present invention disclose a method, computer program product, and system for energy production from fluid. In a step, the computer determines if the rate of the fluid level increase in the one of the one or more fluid reservoirs is above a predetermined threshold. In a step, the computer sends a signal to a bypass valve to open and release fluid through a bypass fluid connection from the one of the one or more fluid reservoirs if the rate of the fluid level increase in the one of the one or more fluid reservoirs is above a predetermined threshold. In a step, the computer sends a signal to a regulation valve to open for fluid connection to one or more turbines if the fluid level of the one of the one or more fluid reservoirs is above the predetermined threshold level.

The present invention is a system and method for recovering the kinetic energy created by movement of a vehicle frame relative to a vehicle suspension to generate electrical energy that may be utilized on-the-fly or stored in order to provide power to an electric vehicle, wherein an embodiment for a regenerative energy system uses a plurality of gear assemblies to convert linear up-and-down movement of the vehicle to rotary motion that is then amplified in rotational speed by a gear reduction system to cause rotational movement of a shaft of one or more generators in a single rotational direction to thereby generate electricity that may be utilized directly by electrical motors or stored in batteries or supercapacitors.

Energy harvesters (EH) which can effectively harvest wasted vibrational/kinematic energy and convert it into electrical energy for battery-free sensor operation are described herein. The energy harvesters can be integrated with a power management circuit and a wireless sensor for monitoring wind turbine blades. The target application of the energy harvesters includes powering the wireless sensors used for wind turbine blade structural monitoring.

The invention relates to a toroidal electric generator (100) comprising a stator (20), which includes a tubular body (21) supporting a plurality of windings (24), and a rotor (30) rotatable within the stator (20) and comprising a support element (31) and a plurality of hydraulic blades (32), each provided with a respective magnet (34) and mounted on the support element (31) integral to it. The toroidal electric generator (100) further comprises an external casing (40) and a plurality of separating elements (51, 52), each separating element being arranged between a respective pair of adjacent windings (24) of the plurality of windings (24) of the stator (20).

A method for harvesting energy through pressure retarded osmosis includes identifying and pumping a low salinity feed stream and a high salinity feed stream from upstream water sources to opposite ends of a semi-permeable membrane housing where the low salinity feed stream permeates through the semi-permeable membrane to the high salinity feed stream to pressurize and dilute it. The diluted stream rotates a turbine to generate electricity and produce a depressurized mid-salinity fluid. A system for harvesting energy through pressure retarded osmosis has a first and second upstream water source pumped through low and high salinity feed lines to opposite ends of a semi-permeable membrane housing including a container, a semi-permeable membrane, a low salinity side of the housing, and a high salinity housing. The system also has a low salinity exit line, a pressurized mid-salinity exit line, a turbine, a generator, and a depressurized mid-salinity exit line.