Provided is a stereoscopic surface display device including a stereoscopic display unit having a cell area, wherein the stereoscopic display unit includes a first flexible layer, a first optical waveguide and a first optical output unit in the first flexible layer, wherein the first optical output unit are disposed in the cell area, a first light source disposed on a side of the stereoscopic display unit, wherein the first optical waveguide connects the first light source and the first optical output unit, a first photothermal response layer on the first flexible layer, wherein the first photothermal response layer is configured to receive output light emitted from the first optical output unit and emit thermal energy, and a shape deformation layer on the first photothermal response layer, wherein the shape deformation layer is configured to generate bending deformation by receiving the thermal energy from the first photothermal response layer.

A gradient energy system includes a membrane module including a first section, a second section, and a membrane separating the first section and the second section. A first gas may be provided within the first section. A second gas may be provided within the second section. The membrane module may be configured such that a differential associated with the first gas and the second gas generates a fluid pressure force or an electrical current. A method of recovering energy from gradients of gas mixtures may include providing a first gas to a first section of a membrane module, providing a second gas to a second section of the membrane module, which may be separated from the first section by a membrane, and/or recovering energy generated via a differential between the first gas and the second gas.

Systems and methods for generating and a controller for controlling generation of geothermal power in an organic Rankine cycle (ORC) operation in the vicinity of a wellhead during hydrocarbon production to thereby supply electrical power to one or more of in-field operational equipment, a grid power structure, and an energy storage device. In an embodiment, during hydrocarbon production, a temperature of a flow of wellhead fluid from the wellhead or working fluid may be determined. If the temperature is above a vaporous phase change threshold of the working fluid, heat exchanger valves may be opened to divert flow of wellhead fluid to heat exchangers to facilitate heat transfer from the flow of wellhead fluid to working fluid through the heat exchangers, thereby to cause the working fluid to change from a liquid to vapor, the vapor to cause a generator to generate electrical power via rotation of an expander.

A light turbine, turbine, and turbine housing are described, in which the turbine housing can include a main housing and a chimney. The main housing and chimney define a circular path within which vanes located on the ends of spokes can move. Movement of the vanes can cause rotation of a shaft attached to the spokes. The chimney can be removably attached to the main housing to allow access to the vanes, which can be removably attached to the spokes. The turbine housing and turbine can be configured such that various compositions and/or configurations of vanes can be evaluated in conjunction with one or more forms of energy sources, such as an electromagnetic radiation source. The turbine housing can enable selective evaluation within ambient air, a partial vacuum, and/or the like.

Methods and systems are provided for a power-generating fluid flow arrangement. In one example, the fluid flow arrangement may include a primary conduit flowing a pressurized fluid and a bypass conduit coupled to the primary conduit. The bypass conduit may divert a portion of the pressurized fluid flow from the primary conduit to drive rotation of a turbine. A dual valve may be arranged in the bypass conduit to control both flow and pressure in the fluid flow arrangement.

The invention relates to a body (2), at least one actuator (3) produced from an electro-active polymer material that changes form due to electrical energy, thereby actuating the body (2), at least two strengtheners (4) allowing the actuator (3) to change its form, each holding the actuator (3) from a different side, and are positioned oppositely on the body (2), at least one retainer tip (5) holding the actuator (3) from at least one side thereof.

An anode current collector of an electrochemical compressor includes a plurality of first portions and a plurality of second portions that are alternately arranged from the first end portion toward an inner side in a plane direction of the anode current collector. In the first portion, a first porous body, a second porous body, and a third porous body are sequentially stacked. In the second portion, the first portion, the third porous body, and the second porous body are sequentially stacked. The porosity of the second porous body is larger than the porosity of the first porous body and the porosity of the third porous body is larger than the porosity of the second porous body.

A light turbine, turbine, and turbine housing are described, in which the turbine housing can include a main housing and a chimney. The main housing and chimney define a circular path within which vanes located on the ends of spokes can move. Movement of the vanes can cause rotation of a shaft attached to the spokes. The chimney can be removably attached to the main housing to allow access to the vanes, which can be removably attached to the spokes. The turbine housing and turbine can be configured such that various compositions and/or configurations of vanes can be evaluated in conjunction with one or more forms of energy sources, such as an electromagnetic radiation source. The turbine housing can enable selective evaluation within ambient air, a partial vacuum, and/or the like.

An electricity generation process is disclosed. The process comprises injecting an aqueous feed stream into a salt formation to dissolve the salt contained therein, and then extracting a saline stream containing said dissolved salt from the salt formation. The process also comprises converting latent osmotic energy present in said saline stream into electricity by passage through an osmotic power unit comprising a semi-permeable membrane which permits the passage of water but not the passage of salts in which said saline stream is passed over one side of the semi-permeable membrane, a low salinity stream being passed over the other side of said membrane. The process also comprises using an output stream derived from the low salinity stream as the aqueous feed stream.

A process for generating power from a warm saline steam (1) obtained from geothermal sources. The process involves extracting a warm saline stream (1) from an underground geothermal formation (2), reducing the temperature of the saline stream (1) by passing the stream through a thermal power unit (5) in which thermal energy present in the stream is extracted. The process also involves converting latent osmotic energy present in the stream into electricity by passing the stream through an osmotic power unit (7) comprising a semi-permeable membrane (8). The output stream (13) derived from passage through the osmotic power unit is injected into a second, different underground formation.