A fluidic solar actuation system comprising a plurality of fluidic solar actuators that each include a first fluidic inflatable actuator, and a second fluidic inflatable actuator. The system also includes a fluidic routing system configured to covey a fluid originating from a fluid source to: the respective first fluidic inflatable actuators of the plurality of fluidic solar actuators, the first fluidic inflatable actuators ganged so as to be fluidically connected such that the first fluidic inflatable actuators are configured to be inflated together and separate from the second fluidic inflatable actuators, and the respective second fluidic inflatable actuators of the plurality of fluidic solar actuators, the second fluidic inflatable actuators ganged so as to be fluidically connected such that the second fluidic inflatable actuators are configured to be inflated together and separate from the first fluidic inflatable actuators.

A fluidic solar actuation system comprising a plurality of fluidic solar actuators that each include a first fluidic inflatable actuator, and a second fluidic inflatable actuator. The system also includes a fluidic routing system configured to covey a fluid originating from a fluid source to: the respective first fluidic inflatable actuators of the plurality of fluidic solar actuators, the first fluidic inflatable actuators ganged so as to be fluidically connected such that the first fluidic inflatable actuators are configured to be inflated together and separate from the second fluidic inflatable actuators, and the respective second fluidic inflatable actuators of the plurality of fluidic solar actuators, the second fluidic inflatable actuators ganged so as to be fluidically connected such that the second fluidic inflatable actuators are configured to be inflated together and separate from the first fluidic inflatable actuators.

According to one or more embodiments, an intelligent solar racking system is provided. The intelligent solar racking system includes a racking frame that receives and mechanically supports solar modules. The intelligent solar racking system includes sensors distributed throughout the racking frame. Each of the sensors detects and reports parameter data by generating output signals. The sensors include module sensors positioned to associate with each of the solar modules and detect a module presence as the parameter data for the solar modules. The intelligent solar racking system includes a computing device that receives, stores, and analyzes the output signals to determine and monitor operations of the intelligent solar racking system.

A device is provided. The device includes mechanically stacked layers. The mechanically stacked layers include a bottom layer and upper layers. Each upper layer includes a transmissive solar cell that converts light energy into electricity. Each upper layer transmits unconverted portions of the light energy towards the bottom layer. The bottom layer includes a solar cell that converts the unconverted portions of the light energy into electricity.

A solar module racking system including a frame. The frame includes pre-wired receptacles for rapid assembly of solar modules. The frame receives and mechanically supports each solar module. The frame arranges the solar modules in a first planar direction, in a second planar direction, and in a vertical direction that is normal to the first and second planar directions. Each pre-wired receptacles individually and electrically connect each of the solar modules after insertion of that module into the frame. The solar module racking system provides a 2 by 1 by 1 configuration or a 1 by 2 by 1 configuration for the plurality of solar modules corresponding to the first planar direction, the second planar direction, and the vertical direction. A first module and a second module are arranged in the first planar direction or the second planar direction, respectively.

A solar actuator system comprising at least one actuator assembly. The actuator assembly includes: a top coupler; an angled bottom coupler having a top-end and respective first and second faces on opposing first and second sides of the top-end, the angled bottom coupler coupled to the top coupler via a one-degree-of-freedom joint between the top coupler and the angled bottom coupler; and at least a first and second actuator, with the first actuator disposed on the first side of the angled bottom coupler and the second actuator disposed on the second side of the angled bottom coupler.

A solar actuator system comprising at least one actuator assembly. The actuator assembly includes: a top coupler; an angled bottom coupler having a top-end and respective first and second faces on opposing first and second sides of the top-end, the angled bottom coupler coupled to the top coupler via a one-degree-of-freedom joint between the top coupler and the angled bottom coupler; and at least a first and second actuator, with the first actuator disposed on the first side of the angled bottom coupler and the second actuator disposed on the second side of the angled bottom coupler.

A method for controlling the orientation of a single-axis solar tracker (1) orientable about an axis of rotation (A), said method implementing the following steps: a) observing the evolution over time of the cloud coverage above the solar tracker (1); b) determining the evolution over time of an optimum inclination angle of the solar tracker (1) substantially corresponding to a maximum of solar radiation on the solar tracker (1), depending on the observed cloud coverage; (c) predicting the future evolution of the cloud coverage based on the observed prior evolution of the cloud coverage; d) calculating the future evolution of the optimum inclination angle according to the prediction of the future evolution of the cloud coverage; e) servo-controlling the orientation of the solar tracker (1) according to the prior evolution of the optimum inclination angle and depending on the future evolution of the optimum inclination angle. The present invention finds application in the field of solar trackers.

A method for controlling the orientation of a single-axis solar tracker (1) orientable about an axis of rotation (A), said method implementing the following steps: a) observing the evolution over time of the cloud coverage above the solar tracker (1); b) determining the evolution over time of an optimum inclination angle of the solar tracker (1) substantially corresponding to a maximum of solar radiation on the solar tracker (1), depending on the observed cloud coverage; (c) predicting the future evolution of the cloud coverage based on the observed prior evolution of the cloud coverage; d) calculating the future evolution of the optimum inclination angle according to the prediction of the future evolution of the cloud coverage; e) servo-controlling the orientation of the solar tracker (1) according to the prior evolution of the optimum inclination angle and depending on the future evolution of the optimum inclination angle. The present invention finds application in the field of solar trackers.

A control method for optimizing a solar-to-power efficiency of a solar-aided coal-fired power system under off-design working conditions is provided. Through reading the relevant information of the solar collecting system, the coal-fired power generation system, the environmental conditions, and the working conditions of the solar-aided coal-fired power system, the water flow rate range able to be heated by the solar collecting unit and the solar-coal feedwater flow distribution ratio range are determined; through establishing the relationship between the solar-to-power efficiency and the solar-coal feedwater flow distribution ratio, the solar-coal feedwater flow distribution ratio is regulated, so that a flow rate of water entering the solar collecting system to be heated is controlled, thereby maximizing the solar-to-power efficiency and improving the economy of the solar-aided coal-fired power system. The present invention provides clear guidance to improve the utilization rate of solar energy and facilitate the consumption of the renewable energy.