Provided are a power storage control apparatus and a power storage control method with which a second power storage apparatus connected to a first storage apparatus via a power distribution network can be used based on an availability status of the first power storage apparatus under a configuration that a plurality of power storage apparatuses are deployed in the power distribution network. The power storage control apparatus includes a status determination part, a signal generation part and a communication part. The status control part determines the availability status of the first power storage apparatus deployed in the power distribution network. The signal generation part generates a control signal for using the second power storage apparatus connected to the first storage apparatus in the power distribution network instead of the first power storage apparatus based on a determination result from the status determination part. The communication part transmits the control signal generated by the signal generation part to the second power storage apparatus.

A hybrid solar thermal collector is provided. The hybrid solar collector comprises a photovoltaic element to convert sunlight into electricity; and a solar thermal collector device comprising an absorber element to convert sunlight into heat; wherein the absorber element is immersed in a heat transfer fluid in use.

A hybrid solar thermal collector is provided. The hybrid solar collector comprises a photovoltaic element to convert sunlight into electricity; and a solar thermal collector device comprising an absorber element to convert sunlight into heat; wherein the absorber element is immersed in a heat transfer fluid in use.

Improving wind-based piezoelectric power conversion is provided. For example, a piezoelectric element affixed to a vibratory member is provided. A rigid mounting system coupled with a rotatable base is provided for said vibratory member on one end of the vibratory member. A solar generator is coupled with the rigid mounting system and at least one obstacle is provided located on the flexing side of the vibratory member. The obstacle induces a vortex in the wind passing the obstacle and arriving at the vibratory member, which enhances wind-induced displacement in the vibratory member.

Improving wind-based piezoelectric power conversion is provided. For example, a piezoelectric element affixed to a vibratory member is provided. A rigid mounting system coupled with a rotatable base is provided for said vibratory member on one end of the vibratory member. A solar generator is coupled with the rigid mounting system and at least one obstacle is provided located on the flexing side of the vibratory member. The obstacle induces a vortex in the wind passing the obstacle and arriving at the vibratory member, which enhances wind-induced displacement in the vibratory member.

A power source apparatus that combines power generated by a photovoltaic system and power generated from another power source by using a power combiner and transmits the combined power to a load side, wherein an output voltage of the photovoltaic system can be changed by changing a cell connection state of a plurality of solar cells of the photovoltaic system, and the highest efficiency of the photovoltaic system can be obtained by adding the output voltage of the photovoltaic system to an output voltage of the another power source.

A power source apparatus that combines power generated by a photovoltaic system and power generated from another power source by using a power combiner and transmits the combined power to a load side, wherein an output voltage of the photovoltaic system can be changed by changing a cell connection state of a plurality of solar cells of the photovoltaic system, and the highest efficiency of the photovoltaic system can be obtained by adding the output voltage of the photovoltaic system to an output voltage of the another power source.

An integrated system for exploiting renewable energy sources based upon carbon dioxide captured from the atmosphere is provided, the system comprising: a solar energy collector; apparatus for capturing CO.sub.2 from the atmosphere; a wind power driven electrical generator; water power driven electrical generator; electric power distribution control means from the renewable energy sources; energy storage systems; water desalinating means and water electrolysis means powered by the renewably generated electricity; hydrocarbon fuel preparation means utilizing the hydrogen and the carbon dioxide generated by this system; and a body of saline water adjacent the land on which the integrated system is built.

Photovoltaic energy generation device, characterized in that it comprises at least one brick (120) comprising a lower terminal and an upper terminal, between which are arranged two cells (111), each comprising a photovoltaic cell (7), comprising one or more elementary photovoltaic cell(s), and a storage element (8) connected to the terminals of the photovoltaic cell, and at least three cell switchs (113), so as to be able to dispose the said two cells (111) in series or in parallel.

Photovoltaic energy generation device, characterized in that it comprises at least one brick (120) comprising a lower terminal and an upper terminal, between which are arranged two cells (111), each comprising a photovoltaic cell (7), comprising one or more elementary photovoltaic cell(s), and a storage element (8) connected to the terminals of the photovoltaic cell, and at least three cell switchs (113), so as to be able to dispose the said two cells (111) in series or in parallel.