TURBINE WITH SOLAR COLLECTOR OR TURBOCHARGER, which is designed to originate innovative turbine kinetic energy through solar irradiation, irradiated by heliostats, parabolic or possibly to function with other types of fuel when not no solar radiation. With a heat exchanger through which passes the residual thermal energy is achieved in a higher efficiency than conventional turbines. In this set of turbine exchanged, collector and collector, its components are located so that the drop of the thermal fluid is the minimum possible. The team has been solar collector incorporated a radial type where the sunlight is irradiated, which in the collector, the heated fluid flowing through it which comes from the compressor, through the heat exchanger, and that the empty on the blades of the turbine motor generating a kinetic energy of a mechanical element that needs a turning force or power generators. This system can be developed to produce electric power from 1 kW to 15 kW in parable and even over twenty megawatts radiated tower heliostats. At low power is designed for can use the sensor and the sensor turbine or a turbocharger. No water uses er, no pollution and low installation costs, very significantly given the simplicity and innovation of its components.

The invention relates to an improved Brayton concentrated solar power generation method, which belongs to the technical field of solar power generation. The method performs the following steps under normal pressure or micro positive pressure: (1) the heat storage medium enters the heat collection device from the low-temperature tank; (2) the sunlight is collected to the heat collection device to transform the heat storage medium into the high-temperature heat storage medium; (3) the high-temperature heat storage medium enters the heat exchanger and exchanges heat with the power working medium; (4) the high-temperature power working medium after heat exchange enters the turbine generator set to provide power generation. Based on the method, the invention also provides a matched power generation system. Adopting the method and device of the invention for power generation has the advantages of low cost, easy construction and maintenance, high efficiency, less restriction, etc., can realize long-term and stable power generation, can be applied to any area, and is conducive to large-scale promotion.

The present invention is a renewable energy utilization engine power plant comprising; a solar radiant energy collecting system, wherein the solar radiant heat collecting system comprises; a focusing apparatus for collecting solar radiant energy, and a light guide for guiding the solar radiant energy collected by the focusing apparatus to a heating chamber; a biomass processing system, wherein the biomass processing system generates thermal energy from the conversion of biomass material; a combustible fluid processing system, wherein the combustible fluid processing system generates thermal energy from the combustion of the combustible fluid within the heating chamber; and a closed-cycle thermodynamic based engine driven by the collection of the solar radiant energy and thermal energy, wherein the mechanical power generated by the closed-cycle thermodynamic based engine is converted to electrical energy.

In one embodiment, the application provides a photon engine comprising one or more cylinders comprising: a primary prism and a secondary prism which may or may not comprise a linear switch, the primary prism comprising one or more light beam inlets and multiple internal faces comprising a primary back face, the secondary prism comprising multiple lateral faces and having a secondary back face positioned adjacent to and spaced apart from the primary back face, forming a non-transparent interface between the primary prism and the secondary prism; the primary prism comprising a light expander/contractor device communicating with the light beam inlet, the light expander/contractor device comprising facets adapted to produce a processed light beam by expanding the diameter of a light beam entering from a given direction; an optic switch comprising a piezoelectric actuator operatively coupled with the primary prism and/or the secondary prism and adapted to (a) compress the secondary back face relative to the primary back face to form a transparent interface therebetween, and (b) decompress the secondary back face relative to the primary back face to produce the non-transparent interface, thereby creating a containment chamber comprising a predetermined reflective light path comprising the secondary back face of the secondary prism and one or more movable reflective prisms arranged to communicate power output with an energy system; the one or more movable reflective prisms comprising a near total reflective surface (NTRS) comprising one or more NTRS prism(s); the photon engine being adapted to split the processed light beam multiple times to produce multiple processed light beams.

A solar concentrator (100) comprising: a base (190); a framework (170), the framework (170) being hingedly joined to the base (190) such that the framework (170) can be rotated relative to the base (190); and a plurality of mirrors (110) arranged relative to a first axis (200) of the framework (170), such that all of the mirrors (110) are located on one side of a plane which contains the first axis (200), each mirror being fixed to the framework (170) and each mirror being arranged to reflect light travelling parallel to the first axis (200) towards a common focus which lies on the first axis (200).

Disclosed is a solar refraction device (SRD) for heating industrial materials in a heating container, having a bottom, with diffuse solar energy that impinges on an outside surface of the SRD and is refracted through the SRD. The SRD may include a lens array assembly and a plurality of lens panes attached to the lens array assembly. The lens array assembly may include an outside surface corresponding to the outside surface of the SRD, an inside surface, and a plurality of lens array sub-assemblies.

Disclosed is a solar refraction device (SRD) for heating industrial materials in a heating container, having a bottom, with diffuse solar energy that impinges on an outside surface of the SRD and is refracted through the SRD. The SRD may include a lens array assembly and a plurality of lens panes attached to the lens array assembly. The lens array assembly may include an outside surface corresponding to the outside surface of the SRD, an inside surface, and a plurality of lens array sub-assemblies.

Thermal energy is derived from sunlight. The system has a heating surface arranged to support microparticles to be heated, and a group of optical-fibers arranged to transport sunlight to irradiate microparticles on the heating surface. The optical-fibers are moved relative to the heating surface to enable the microparticles to be heated by the transported light as the optical-fiber scans the microparticles. Apparatus for storing the heated particles and for using the thermal energy is also discussed.

The present invention is a renewable energy utilization engine power plant comprising; a solar radiant energy collecting system, wherein the solar radiant heat collecting system comprises; a focusing apparatus for collecting solar radiant energy, and a light guide for guiding the solar radiant energy collected by the focusing apparatus to a heating chamber; a biomass processing system, wherein the biomass processing system generates thermal energy from the conversion of biomass material; a combustible fluid processing system, wherein the combustible fluid processing system generates thermal energy from the combustion of the combustible fluid within the heating chamber; and a closed-cycle thermodynamic based engine driven by the collection of the solar radiant energy and thermal energy, wherein the mechanical power generated by the closed-cycle thermodynamic based engine is converted to electrical energy.

The present invention comprise an elastic piston system for the conversion of solar energy to electrical energy, the system comprising a solar energy concentrator 202, and at least two solar energy conversion cells 200 being configured to receive the sunlight 204 reflected from the solar energy concentrator 202. The solar energy conversion cell 200 comprises at least two elastic piston 302, 304 components. The elastic pistons 302, 304 being coupled via a conduit 314, 416 for the transmittal of a predetermined working fluid 418. The elastic pistons 302, 304 are configured to receive polarized sunlight and generate electrical energy in response to the reception of the polarized sunlight, The solar energy conversion cell further comprises a controller 306 component, The controller 306 being configured to regulate the compression cycles within the elastic piston 302, 304 components and extract electrical energy produced within the cell 200.