To provide a solar power generation site construction method enabling a great improvement in power generation efficiency through effectively utilizing a space of a power generation site with an irregular planar shape. A solar module 7 is configured by arranging a plurality of solar cell groups, each including a plurality of solar cells. A plurality of types of unit modules are prepared including a one-unit module 7.sub.-1 including one solar module, a reference unit module 7.sub.-s including a plurality (N) of solar modules serving as a construction standard, and n-unit modules 7.sub.-n including an arbitrary number (n), which falls between 2 and N−1, of solar modules. The solar modules 7 are densely laid in an area with a two-dimensional shape in top view of a field 35 of a power generation site, by combining the plurality of types of unit modules 7.sub.-1, 7.sub.-S, 7.sub.-n.

The present disclosure provides systems and methods for flexible renewable energy power generation. The present disclosure also provides systems and methods for firming power generation from multiple renewable energy sources.

This invention presents an electronically configurable architecture where the plurality of photovoltaic panels can be connected to deliver the maximum power output. This architecture provides maximum power point to the maximum number of photovoltaic panels by connecting them in parallel. Under-rated panels are dynamically coupled with over-rated or maximum-rated panels in a series-connected architecture to utilize the under rated power in the final delivery. Notable efficiency improvements may be observed in contrast to the prevailing optimization with minimum power drop out architecture. The architectural modifications are proposed with bi-stable electromagnetic changeover contacts to minimize the power dissipation in control side. Moreover the rearrangement in connection architecture is proposed to be communicated on instance and regular basis through SMS and SPI protocol for easy fault diagnosis by the service personnel from the proposed data mining firmware.

Systems and methods are provided for solar energy management that can charge a battery from a solar panel as well as operate without a battery, using the same equipment. This multi-modal functionality provides the ability to incrementally increase capacity and extend the availability of electricity from daytime-only to a continuous supply irrespective of solar conditions.

A photovoltaic power generation system includes a protection switch and a plurality of DC-DC converters. Each DC-DC converter includes a direct current bus, a DC-DC circuit, and at least one input interface. The input interface is configured to connect to a photovoltaic unit. The photovoltaic unit includes at least one photovoltaic module. The input interface is connected to the direct current bus by using the protection switch, the direct current bus is connected to an input end of the DC-DC circuit, and an output end of the DC-DC circuit is an output end of the DC-DC converter. The protection switch includes a release device and a switching device that are connected in series. The release device is configured to: when a short-circuit fault occurs on a line in which the release device is located, control the switching device to be disconnected.

A method may include determining a position and movement of a shadow on a plurality of solar modules of a solar power plant using an analysis of irradiance data from sensors disposed proximate the plurality of solar modules. The method may include predicting future power output for the plurality of solar panels based on the movement of the shadow over the plurality of solar modules and modifying a power output of the solar power plant based on the predicted future power output.

A control method for a direct current electrical device and a direct current electrical device. The method includes: acquiring input parameters of a power supply of the direct current electrical device, identifying a type of the power supply according to the input parameters, and determining an operation mode of the direct current electrical device corresponding to the type of the power supply, and controlling an operation of the direct current electrical device according to the operation mode.

A DC/DC converter system includes a current sensor sensing a current flowing from a photovoltaic panel to a power converter device, and a DC/DC converter provided between a battery facility and the power converter device and configured to convert first DC power output from the battery facility into second DC power. The DC/DC converter includes a first operation mode in which the second DC power is generated to allow an output current and an output voltage to simulate the photovoltaic-cell current-voltage characteristics according to a current value sensed with the current sensor. The DC/DC converter may also include a second operation mode executing a boost operation of increasing a potential at a connection node, and a third operation mode in which a voltage at the connection node is converted to charge the battery facility. The DC/DC converter can selectively switch among the first, second, and third operation modes.

An electrical energy storage system is provided in this dislosure, which includes: M battery packs; M first DC/DC converters, where first terminals of the M first DC/DC converters are respectively connected to the M battery packs, the M first DC/DC converters are classified into N first DC/DC converter sets; and N second DC/DC converters, where the N second DC/DC converters one-to-one correspond to the N first DC/DC converter sets, a first terminal of each second DC/DC converter is connected to second terminals of all first DC/DC converters in a first DC/DC converter set corresponding to the second DC/DC converter, a second terminal of each second DC/DC converter is connected to a first interface of the electrical energy storage system, the first interface is to receive a direct current from a power generation system or output a direct current to the power generation system.

A distributed power system including multiple (DC) batteries each DC battery with positive and negative poles. Multiple power converters are coupled respectively to the DC batteries. Each power converter includes a first terminal, a second terminal, a third terminal and a fourth terminal. The first terminal is adapted for coupling to the positive pole. The second terminal is adapted for coupling to the negative pole. The power converter includes: (i) a control loop adapted for setting the voltage between or current through the first and second terminals, and (ii) a power conversion portion adapted to selectively either: convert power from said first and second terminals to said third and fourth terminals to discharge the battery connected thereto, or to convert power from the third and fourth terminals to the first and second terminals to charge the battery connected thereto. Each of the power converters is adapted for serial connection to at least one other power converter by connecting respectively the third and fourth terminals, thereby forming a serial string. A power controller is adapted for coupling to the serial string. The power controller includes a control part adapted to maintain current through or voltage across the serial string at a predetermined value.