Hybrid thermodynamic compressor (8) for compressing a working fluid, the compressor comprising a volumetric cylinder (1) and a thermal cylinder (2) connected to one another mechanically by a connecting rod system (5) and pneumatically by a connecting circuit (12) optionally with a valve (4), a reversible electric machine (6), the volumetric cylinder comprising a first piston (81) that separates a first chamber (Ch1) from a second chamber (Ch2), the thermal cylinder comprising a second piston (82) which separates a third chamber (Ch3) from a fourth chamber (Ch4), which can be brought into thermal contact with a heat source (21) to thereby generate a cycled movement in the thermal cylinder, and concerning the connecting rod system (5), the first and second pistons are connected to a rotor (52) by first and second respective connecting rods (91,92), with a predetermined angular offset (θd), the volumetric cylinder being equipped with non-return valves (61,62), the power produced in the thermal cylinder being transmitted to the volumetric cylinder essentially via the connecting circuit and not via the rod system.

A system that can eliminate engine combustion emissions in addition to raw and fugitive methane emissions associated with a gas compressor package. The system may comprise an air system for starting and instrumentation air supply; electrically operated engine pre/post-lube pump, compressor pre-lube pump, and cooler louver actuators; compressor distance piece and pressure packing recovery system; blow-down recovery system; engine crankcase vent recovery system; a methane leak detection system; and an overall remote monitoring system.

The present invention relates to a heart pump apparatus comprising a turbine pump for assisting the heart of a human patient. The invention is based on the realization that a turbine without a centre axis would improve the capacity of the heart help pump apparatus. The present invention also relates to a turbine pump system for assisting the heart of a human patient. The present invention also relates to operation methods and methods for surgically placing a rotating body of a turbine pump and a stator of a turbine pump in a patient.

The invention relates to a device and a method for compressing a working medium, comprising: compressing a drive medium in a compressor; moving a drive piston within a first cylinder by means of the compressed drive medium; moving a high-pressure piston, which compresses the working medium, within a second cylinder by means of the drive piston; and transferring heat from the compressed working medium to the compressed drive medium before the compressed drive medium enters the first cylinder of the drive piston.

A pumped-storage power plant may include a working cylinder partially submerged in a working fluid reservoir having an upper fluid compartment above a fluid level of the working fluid reservoir and a lower fluid compartment below the fluid level, a buoyant piston movably guided in the direction of gravity relative to the working cylinder and which seals off the upper fluid compartment such that a gravitationally induced exchange of fluid between the upper and the lower fluid compartment is prevented. The plant may operate in an energy charging mode where working fluid is introduced into the upper fluid compartment so that the buoyant piston is submerged in the lower fluid compartment, and an energy delivery mode where upper fluid is pressed out of the upper fluid compartment and/or a fluid column of the upper fluid built up during the energy charging mode is discharged from the upper fluid compartment.

A pumped-storage power plant may include a working cylinder partially submerged in a working fluid reservoir having an upper fluid compartment above a fluid level of the working fluid reservoir and a lower fluid compartment below the fluid level, a buoyant piston movably guided in the direction of gravity relative to the working cylinder and which seals off the upper fluid compartment such that a gravitationally induced exchange of fluid between the upper and the lower fluid compartment is prevented. The plant may operate in an energy charging mode where working fluid is introduced into the upper fluid compartment so that the buoyant piston is submerged in the lower fluid compartment, and an energy delivery mode where upper fluid is pressed out of the upper fluid compartment and/or a fluid column of the upper fluid built up during the energy charging mode is discharged from the upper fluid compartment.

A solar-powered aeration device for sludge turnover and planting includes a grow bed fixed on a floating body and floats on water. A bottom of the floating body is fixedly connected with an inner pipe; an outer pipe is sleeved outside the inner pipe. The outer pipe is nested in an air chamber; a bottom of the air chamber communicates and is fixedly connected with a water inlet pipe; the water inlet pipe laterally communicates with a suction tube. An aeration ring is fixedly arranged at a bottom of the outer pipe, and the aeration tube has an air outlet pipe in communication with the outside. A movable foot is rotationally provided at a tail end of the suction tube, and the movable foot adapts to surface fluctuations to swing in a range limited by an angle limiter.

An energy generator system is provided that is capable of capturing the transitory energy contained within the wind and converting it to a form of storable energy for later use in generating electricity. The energy generator system includes a compression system including an air compressor for compressing incoming air and a rotor for operating the compressor in response to the wind flowing over the rotor. An intake system is associated with the compression system and provides clean ambient air to the air compressor. The compression system and the intake system c contained in a wind tower having a head for supporting the rotor and an elongate pylon for positioning the rotor at a sufficient height to capture the energy of the wind. The natural energy system additionally includes a storage system for storing the compressed air produced by the air compressor.

An energy generator system is provided that is capable of capturing the transitory energy contained within the wind and converting it to a form of storable energy for later use in generating electricity. The energy generator system includes a compression system including an air compressor for compressing incoming air and a rotor for operating the compressor in response to the wind flowing over the rotor. An intake system is associated with the compression system and provides clean ambient air to the air compressor. The compression system and the intake system c contained in a wind tower having a head for supporting the rotor and an elongate pylon for positioning the rotor at a sufficient height to capture the energy of the wind. The natural energy system additionally includes a storage system for storing the compressed air produced by the air compressor.

An air compressor includes a driving device and a vehicle engine. The vehicle engine includes a casing with multiple cylinders and a crank located therein. Each of the cylinders has a piston movably received therein, and each piston has a piston rod which is pivotably connected to the crank. The driving device drives the crank. A cylinder head is mounted to the casing and includes an entrance and an exit. Each of the pistons is moved back-and-forth in the cylinder corresponding thereto by rotation of the crank. Air is sucked into the cylinders via the entrance and is compressed by the pistons. The compressed air is released via the exit.