Implementations of energy harvester systems may include: an accumulator having an air bladder separated from water by a membrane; one or more hydro turbines coupled with the accumulator; two or more check valves each coupled with one of the one or more hydro turbines; a system battery coupled to the power conditioner; and an electronic load coupled to the system batter through the power conditioner; wherein the two or more check valves are configured to be in contact with water.

A stepwise operating parallel-type hydro power generation system having a fixed flow path includes a parallel pipe, a first power generation facility, a second power facility generation facility, first and second flow regulators, and a controller. The parallel pipe includes an inlet pipe, an outlet pipe, and a first straight pipe and a second straight pipe. The first and second straight pipes connected between the inlet pipe and the outlet pipe. Each of the first and second power generation facilities includes a water turbine rotating with the water introduced thereinto and a power generator operating according to the rotation of the water turbine. The controller is configured to open and close either or both of the first and second flow rate regulators at the same time.

Systems and methods for operating a fluid supply system. The methods comprise: using a micro-turbine and an Energy Harvesting Circuit (EHC) to harvest energy from a fluid flowing through a pipeline; operating a switch to disconnect the EHC from the micro-turbine when an amount of energy harvested reaches a threshold value; detecting by a sensor device an amount of natural fluid flow through the pipeline while the EHC is disconnected from the micro-turbine; and operating the switch to reconnect the EHC to the micro-turbine after the amount of natural fluid flow has been detected.

A generator moving through a medium has a contacting surface structure relative to a frame with a spring coupled between the two. The contacting surface structure also has an electrogenerative portion coupled to the contacting surface structure and the frame, such as a piezoelectric or electromagnetic structure, although other types of structures are known within the art. The movement of the frame through the medium exerts forces upon the contacting surface structure which causes contacting surface structure movement relative to the base structure through the electrogenerative portion. The spring provides a force upon the contacting surface structure in response to the force from the fluid flow.

A stepwise operating parallel-type hydro power generation system having a fixed flow path includes a parallel pipe, a first power generation facility, a second power facility generation facility, first and second flow regulators, and a controller. The parallel pipe includes an inlet pipe, an outlet pipe, and a first straight pipe and a second straight pipe. The first and second straight pipes connected between the inlet pipe and the outlet pipe. Each of the first and second power generation facilities includes a water turbine rotating with the water introduced thereinto and a power generator operating according to the rotation of the water turbine. The controller is configured to open and close either or both of the first and second flow rate regulators at the same time.

A fluid flow actuated tool including a housing, a tool and an actuating mechanism. The housing includes a housing interior. The housing interior receives a flow of fluid. The actuating mechanism includes a fluid wheel structure. The fluid wheel structure is connected to the tool. At least a portion of the fluid wheel structure is arranged in the flow of fluid for rotating the fluid wheel structure. The tool is actuated based on rotation of the fluid wheel structure.

Through dividing all blades into four or more blade groups including a certain number, which is three or more, of the blades, the blade located in the rearmost portion of each blade group in a direction of rotation is selected as a main blade, and remaining blades are selected as auxiliary blades, the length of each of the auxiliary blades is set to be shorter than the length of the main blade, and corresponding inner edge portions are positioned to the front, in the direction of rotation, of a normal line that passes through an outer edge portion of the blade, and an extension line of a chord line that connects the outer edge portion and the inner edge portion of the blade to one another are made to intersect with the main blade that is adjacent to the front in the direction of rotation.

A system for use with a fluid-containing body having a body wall with an opening and defining a body interior, and for use with a device to be inserted and extracted by said system via said opening into the fluid-containing body, said system having a central axis and comprising: a proximal portion configured for being attached to the body wall when mounting the system in said opening, and having a first chamber configured for receiving said device therein; a sealable interface having a first side facing said first chamber and a second side in a direction opposite said first chamber and defining a distal area configured for receiving said device from said first chamber; said sealable interface, when unsealed, being configured to allow passage therethrough of the device along said central axis between the first chamber and the distal area; a pressure regulating mechanism configured for regulating pressure within said first chamber between pressure at an upper exterior of the proximal portion and pressure at the distal area; and a second chamber encompassing at least a part of the distal area and configured for receiving the device therein; said sealable interface, when unsealed, being configured to allow passage therethrough of the device along said central axis between the first and the second chambers.

The present invention is turbine generator capable of integration into a bio-physiological or microfluidic system. The generator can convert biomechanical energy into electrical energy by using electromagnetic subsystems to transform the kinetic energy to electricity. These systems have the potential to convert hydraulic energy (such as flow of body fluid, blood flow, contraction of blood vessel, dynamic fluid in nature) into electric energy that may be sufficient for self-powering nano/micro devices and systems, such as artificial organs, valves, sensors, micro motors, and micro robots. The system incorporates a new turbine model having, notched blades; a rotor in levitation; and a special casing capable of integration into a bio-physiological or microfluidic system.

A hydroelectric facility for generating electrical energy from the flow of water circulating in a water network, includes at least one cross-flow pico-turbine mounted on a shaft extending perpendicular to a direction of the water flow, the pico-turbine including a substantially annular blade installed in the water flow in order to generate a mechanical energy of rotation, at least one generating unit, installed outside of the water flow and coupled to the shaft of the pico-turbine in order to transform the mechanical energy of rotation into electrical energy, at least one measurement and control unit, installed outside of the water flow, connected to the generating unit, controlling the distribution of the collected electrical energy as well as the rotation of the pico-turbine depending on the characteristics of the water flow.