A solar oven designed for year-round use is readily-accessible and easy to use by simply removing a protective oven cover. The solar oven replicates the mainstream cook's current pattern with standard stoves, requiring little set-up or storage. Access to the solar oven is from the front and solar heat is stored in an upper oven chamber. By changing the solar oven chamber above the door, heat remains in the trapezoidal-pyramid cover during transfers and condensation is reduced to a minimum. By raising and lowering the floor, the solar oven allows the gasketed oven chamber to perform food cooking while being protected to prevent loss of heat. The solar oven remains available in all weather, does not fade in color and is attractive to most mainstream cooks.

To position a solar oven radiation collection device, a structural extension assembly extends in a radial direction with respect to a structure. A moveable transport provides linear movement of the solar oven radiation collection device along an axis of the structural extension assembly. A linear deploy electric motor is used to control linear movement of the solar oven radiation collection device along the axis of the structural extension assembly. A solar altitude electric motor is used to adjust orientation of the solar oven radiation collection device to take into account changes in solar altitude with respect to time. A solar azimuth electric motor is used to adjust orientation of the solar oven radiation collection device to take into account changes in azimuth with respect to time.

To position a solar oven radiation collection device, a structural extension assembly extends in a radial direction with respect to a structure. A moveable transport provides linear movement of the solar oven radiation collection device along an axis of the structural extension assembly. A linear deploy electric motor is used to control linear movement of the solar oven radiation collection device along the axis of the structural extension assembly. A solar altitude electric motor is used to adjust orientation of the solar oven radiation collection device to take into account changes in solar altitude with respect to time. A solar azimuth electric motor is used to adjust orientation of the solar oven radiation collection device to take into account changes in azimuth with respect to time.

Examples are provided herein that relate to solar heating with a solar refraction device. One example provides a solar heating system, comprising a container configured to enclose contents within the container in a closed configuration, and a solar refraction device comprising a lens array assembly having a plurality of lens array sub-assemblies, the lens array assembly configured to refract solar energy impinging on the lens array assembly to focus refracted solar energy at a plurality of focal points positioned to heat the contents enclosed within the container, each focal point corresponding to a corresponding lens array sub-assembly of the plurality of lens array sub-assemblies.

A positioning system attached to an outside of a building structure positions a radiation collection device such as a solar oven. The positioning system allows the collection device to be positioned in a plurality of locations where at least one of the plurality of locations is away from the building structure to allow the radiation collection device to collect solar radiation.

Positioning a radiation collection device such as a solar oven using a positioning system attached to an outside of a building structure. The positioning system allowing the collection device to be positioned in a plurality of locations where at least one of the plurality of locations is away from the building structure to allow the radiation collection device to collect solar radiation.

Examples are provided herein that relate to solar heating with a solar refraction device. One example provides a solar heating system, comprising a container configured to enclose contents within the container in a closed configuration, and a solar refraction device comprising a lens array assembly having a plurality of lens array sub-assemblies, the lens array assembly configured to refract solar energy impinging on the lens array assembly to focus refracted solar energy at a plurality of focal points positioned to heat the contents enclosed within the container, each focal point corresponding to a corresponding lens array sub-assembly of the plurality of lens array sub-assemblies.

Positioning a radiation collection device such as a solar oven using a positioning system attached to an outside of a building structure. The positioning system allowing the collection device to be positioned in a plurality of locations where at least one of the plurality of locations is away from the building structure to allow the radiation collection device to collect solar radiation.

A solar cooking appliance comprises a solar heat collector for collecting and storing solar heat. A first solid heat storage and conducting material for storing and conducting solar heat, the solid heat storage and conducting material is placed within the solar heat collector, the solar heat collector heats the solid heat storage and conducting material to a temperature higher than the water boiling temperature. A heat insulated solar cooking utensil is positioned outside of the solar heat collector, having a cooking utensil and a heat insulation. A second heat-transferring and conducting material connected thermally to the first solid heat storage and conducting material to the heat insulated solar cooking utensil for transferring solar heat.

The present invention discloses a portable solar cooker, belonging to the field of solar heat utilization. The solar cooker comprises an upper functional assembly, a lower control assembly and a rotary apparatus which are sequentially connected, wherein the upper functional assembly is configured to reflect sunlight, collect heat in a focusing manner and further heat water or foods, the upper functional assembly is closed to form a box body when being in a non-operative state, and the upper functional assembly is opened when being in an operative state; the lower control assembly is connected with the upper functional assembly, and makes the upper functional assembly be subjected to pitch adjustment; the lower control assembly is connected with the rotary apparatus, and the lower control assembly and the upper functional assembly are driven by the rotary apparatus to rotate so that tracking the sun is realized. The portable solar cooker disclosed by the present invention not only has functions of boiling water and cooking foods, but also has the advantages of facilitating carrying and tracking the sun, and can achieve full utilization of solar energy anytime and anywhere, thereby making the application of the solar energy be fully developed.