Embodiments disclosed herein are directed to a rapidly deploying transportable power system for generating power. The rapidly deploying transportable power system embodiment disclosed herein can have a plurality of frame members containing a plurality of solar panels. Any embodiments of the rapidly deploying transportable power system can also have a transport enclosure configured to support the plurality of frame members and a rail system coupleable with the transport enclosure, the rail system being configured to support the plurality of frame members outside of the transport enclosure. In any embodiments, the plurality of frame members can be positionable within the transport enclosure with one frame member positionable above another frame member. Furthermore, the plurality of frame members can be movable along the rail system to positions outside of the transport enclosure along the track system.

A swivel and fanning drive for solar panels, including a base support, a swivel plate mounted pivotingly about a horizontal axis, and a plurality of solar panels that can be fanned in and out about a fan-out axis. The swivel plate can be pivoted by at least one crank and connecting rod. Pivotal movement of the swivel plate about a vertical axis can cause the solar panels to be fanned-in or fanned-out. A brake can resist movement of the solar panels about the fan-out axis.

A swivel and fanning drive for solar panels, including a base support, a swivel plate mounted pivotingly about a horizontal axis, and a plurality of solar panels that can be fanned in and out about a fan-out axis. The swivel plate can be pivoted by at least one crank and connecting rod. Pivotal movement of the swivel plate about a vertical axis can cause the solar panels to be fanned-in or fanned-out. A brake can resist movement of the solar panels about the fan-out axis.

This invention relates to a portable or fixed solar powered heating ventilation air conditioner (HVAC) system. The disclosed invention consists of the following major components. 1) Solar Hot Water Tank/Storage Tank, 2) Solar Generator, 3) Solar HVAC Heat Exchanger Unit, 4) Solar Grill, 5) Wireless Network Energy Monitoring System and 6) Supervisor Control and Data Acquisition (SCADA) system. Also included is a list of appliances that the HVAC system can be configured to function as: a) refrigerator, b) air purifier/fan, c) pressure cooker, d) drink dispenser, and e) pressurized hot water supply. The HVAC system and above listed appliances is designed to be used in homes, businesses, camping, military, hospitals, FEMA and in developing countries with very little electrical or plumbing infrastructure. The HVAC is capable of supplying all the above mention functions while being powered solely on solar power, solar hot water/fluid or geothermal and a chilled water source, therefore creating a NetZero Energy Machine that required no power from a utility grid when properly sized.

This invention relates to a portable or fixed solar powered heating ventilation air conditioner (HVAC) system. The disclosed invention consists of the following major components. 1) Solar Hot Water Tank/Storage Tank, 2) Solar Generator, 3) Solar HVAC Heat Exchanger Unit, 4) Solar Grill, 5) Wireless Network Energy Monitoring System and 6) Supervisor Control and Data Acquisition (SCADA) system. Also included is a list of appliances that the HVAC system can be configured to function as: a) refrigerator, b) air purifier/fan, c) pressure cooker, d) drink dispenser, and e) pressurized hot water supply. The HVAC system and above listed appliances is designed to be used in homes, businesses, camping, military, hospitals, FEMA and in developing countries with very little electrical or plumbing infrastructure. The HVAC is capable of supplying all the above mention functions while being powered solely on solar power, solar hot water/fluid or geothermal and a chilled water source, therefore creating a NetZero Energy Machine that required no power from a utility grid when properly sized.

The invention relates to a swivel and fanning drive for solar panels, comprising a base support, a rotary table, which is mounted on the base support pivotingly about a substantially vertical first axis, a swivel plate, which is mounted on the rotary table pivotingly about a substantially horizontal second axis, and a fanning shaft, which is mounted on the swivel plate pivotingly about a third axis and on which the solar panels can be mounted so as to be able to be fanned in and out about the aforesaid third axis, wherein the rotary table mounts one end of the swivel plate about the aforesaid second axis and, at a distance therefrom, mounts at least one crank, which is coupled by means of a connecting rod to the other end of the swivel plate to form a crank-rocker linkage.

The invention relates to a swivel and fanning drive for solar panels, comprising a base support, a rotary table, which is mounted on the base support pivotingly about a substantially vertical first axis, a swivel plate, which is mounted on the rotary table pivotingly about a substantially horizontal second axis, and a fanning shaft, which is mounted on the swivel plate pivotingly about a third axis and on which the solar panels can be mounted so as to be able to be fanned in and out about the aforesaid third axis, wherein the rotary table mounts one end of the swivel plate about the aforesaid second axis and, at a distance therefrom, mounts at least one crank, which is coupled by means of a connecting rod to the other end of the swivel plate to form a crank-rocker linkage.

A solar panel assembly is provided that comprises at least one solar panel (2) and a support structure (12) for supporting the at least one solar panel (2). The support structure (3) comprises a collapsible enclosure including a base (16) and plurality of walls (18, 20, 22) defining a sealed tillable chamber. The at least one solar panel (2) is mounted to one of the walls in use. At least part of the shell is formed of a flexible material arranged such that the enclosure is reconfigurable between a collapsed configuration and an expanded deployed configuration when the enclosure is filled. In the expanded deployed configuration the solar panel (2) is supported and arranged such that it is upwardly angled to receive solar energy.

A multifunction flat plate heat exchanger including a heat exchanging flat plate, a spectrum selectivity absorption layer, a light transmissive layer, at least one heat-conductive structure, and at least one airflow driving device is provided. The heat exchanging flat plate has a first plate surface, a second plate surface and a pipe tunnel located between the first plate surface and the second plate surface. The spectrum selectivity absorption layer covers the first plate surface. The light transmissive layer covers the spectrum selectivity absorption layer, and the light transmissive layer and the first plate surface are respectively located at two opposite sides of the spectrum selectivity absorption layer. The heat-conductive structure is disposed on the second plate surface. The airflow driving device is disposed at one side of the heat exchanging flat plate and the heat-conductive structure.

A localized heating structure includes a spectrally-selective solar absorber, that absorbs incident solar radiation and reflects at wavelengths longer than 2 m, with an underlying heat-spreading layer having a thermal conductivity equal to or greater than 50 W/(mK), a thermally insulating layer, adjacent to the spectrally-selective solar absorber, having a thermal conductivity of less than 0.1 W/(mK), one or more evaporation openings through the spectrally-selective solar absorber and the thermally insulating layer, and an evaporation wick, disposed in one or more of the evaporation openings in the thermally insulating layer, that contacts liquid and allows the liquid to be transported from a location beneath the thermally insulating layer through to the spectrally-selective solar absorber in order to generate vapor from the liquid. The thermally insulating layer is configured to have a density less than the liquid so that the localized heating structure is able to float on the liquid.