Solar power collection systems characterized by using a collimated or otherwise concentrated beam of solar radiation to directly heat a porcelain or other high-heat capacity ceramic heating element by contact with an absorption surface on the element, which element in turn heats a thermal storage medium by conduction, methods of using the systems for collecting solar energy, and applications of the systems are disclosed.

Solar power collection systems characterized by using a collimated or otherwise concentrated beam of solar radiation to directly heat a porcelain or other high-heat capacity ceramic heating element by contact with an absorption surface on the element, which element in turn heats a thermal storage medium by conduction, methods of using the systems for collecting solar energy, and applications of the systems are disclosed.

A solar energy device includes a first parabolic reflector and a second parabolic reflector. The first parabolic reflector reflects sunlight into the second parabolic reflector and the second parabolic reflector reflects substantially all of the sunlight through an opening in the first parabolic reflector. The sunlight is directed into a first heat exchanger behind the first parabolic reflector. Solar energy cooking devices and systems are also disclosed.

Solar power collection systems characterized by using a collimated or otherwise concentrated beam (201) of solar radiation to directly heat a porcelain or other high-heat capacity ceramic heating element (202) by contact with an absorption surface on the element, which element in turn heats a thermal storage medium (205) by conduction, methods of using the systems for collecting solar energy, and applications of the systems are disclosed.

Solar power collection systems characterized by using a collimated or otherwise concentrated beam (201) of solar radiation to directly heat a porcelain or other high-heat capacity ceramic heating element (202) by contact with an absorption surface on the element, which element in turn heats a thermal storage medium (205) by conduction, methods of using the systems for collecting solar energy, and applications of the systems are disclosed.

Particles for multifunctional thermal energy media of the present invention are a sand-based material and economical material with a high thermal storage capability, and iron oxides and aluminum oxide are added to the sand to retain high solar absorptivity at high temperatures.

Particles for multifunctional thermal energy media of the present invention are a sand-based material and economical material with a high thermal storage capability, and iron oxides and aluminum oxide are added to the sand to retain high solar absorptivity at high temperatures.

Omnivorous solar thermal thrusters and adjustable cooling structures are disclosed. In one aspect, a solar thermal rocket engine includes a solar thermal thruster configured to receive solar energy and one or more propellants, and heat the one or more propellants using the solar energy to generate thrust. The solar thermal thruster is further configured to use a plurality of different propellant types, either singly or in combination simultaneously. The solar thermal thruster is further configured to use the one or more propellants in both liquid and gaseous states. Related structures can include valves and variable-geometry cooling channels in thermal contact with a thruster wall.

Omnivorous solar thermal thrusters and adjustable cooling structures are disclosed. In one aspect, a solar thermal rocket engine includes a solar thermal thruster configured to receive solar energy and one or more propellants, and heat the one or more propellants using the solar energy to generate thrust. The solar thermal thruster is further configured to use a plurality of different propellant types, either singly or in combination simultaneously. The solar thermal thruster is further configured to use the one or more propellants in both liquid and gaseous states. Related structures can include valves and variable-geometry cooling channels in thermal contact with a thruster wall.

A method for improving the efficiency of a solar heating system based on absorbing heat from solar radiation into the outer surface of a concrete wall. The heat transfer device makes use of a fluid in a tube system to transfer heat from the outside of the wall to the inside of the wall. The inside wall is then used to heat air that is passed over it, and that air is then used to heat up a heat storage system.