The present application relates to a modular tower-type solar thermal power generation system, which comprises: a solar thermal collector device configured for collecting solar thermal energy, a heat exchanger connected to the solar thermal collector device and configured for producing superheated saturated steam, and a thermal power conversion device connected to the heat exchanger and configured for converting the superheated saturated steam into electrical energy; the solar thermal collector device comprises a plurality of tower-type solar thermal modules. By adopting a solar power generation system with a modular solar energy collector device, the present application can simplify the construction process, reduce the construction period, and can further reduce design cost and investment cost of a power station, as well as improve the efficiency of the heliostat field; moreover, when one of the single towers malfunctions, the working situations of other tower-type solar thermal modules won't be affected, and thus the continuity and stability of power supply using the whole power generation system are ensure.

The disclosed embodiments relate to the design of a system that converts sunlight into electricity. During operation, the system concentrates the sunlight onto a front surface of a selective absorber, wherein the selective absorber comprises a semiconductor material having a band gap capable of absorbing most spectral components of the sunlight (such as intrinsic silicon), and wherein the concentrated sunlight causes heat to build up in the selective absorber. Next, the system uses heat obtained from the selective absorber to drive a heat engine, which converts the heat into mechanical energy. Finally, the system converts the mechanical energy into electricity.

The invention provides a process for removal of gaseous decomposition products from high temperature heat transfer fluid HTF of an operational solar thermal power plant having an HTF circuit, in which a volume increase of the HTF in the HTF circuit which is caused by incident solar radiation in an HTF-traversed solar field and consequent heating by day takes place regularly in a day-night cycle and the additional volume formed by the volume increase is collected from the HTF circuit in an expansion vessel, a portion of the additional volume of the HTF is transferred into a drainage vessel operated at relatively low pressure in which gaseous decomposition products and low-boiling constituents escape from the HTF, wherein the low-boiling constituents are condensed, and during the volume contraction of the HTF occurring during the night-time cooling a portion of the additional volume of the HTF is recycled from the drainage vessel into the expansion vessel and from the expansion vessel into the HTF circuit, wherein the volumes in the expansion vessel and the drainage vessel becoming vacant as a result of the transferrals of the HTF are filled with inert gas.

A thermal energy storage system comprising a working fluid to store and transfer thermal energy between a heat source and a thermal load and a vessel to store the working fluid. The vessel has an interior region and a floating separator piston in the interior region to separate a hot portion from a cold portion of the working fluid. There is a first manifold thermally coupled to an output of the heat source and to an input of the thermal load and fluidly coupled to the interior region of the vessel and a second manifold thermally coupled to an input of the heat source and an output of the thermal load and fluidly coupled to the interior region of the vessel. There is a controller configured to maintain the working fluid in a liquid state.

The invention belongs to the technical field of solar thermal power generation equipment, and discloses a combined solar thermal power generation system. The system comprises a parabolic trough collector subsystem, a heat exchanger subsystem, a Rankine cycle power generation subsystem and a dish power generation subsystem; the parabolic trough collector subsystem comprises a trough-type mirror field, a pump and a valve; the heat exchanger subsystem comprises a superheater, an evaporator and a preheater; the Rankine cycle power generation subsystem comprises a temperature-decreased pressure reducer, a steam turbine, an electric generator, a condenser, a condensate pump, a deaerator and a feedwater pump; and the dish power generation subsystem comprises a dish-type mirror field and a Stirling engine set. The system utilizes the heat released by the cold chamber of the Stirling engine by condensed fluid of the Rankine cycle. It provides an extra heat source for the Rankine cycle, which increases the power of the steam turbine and improves the solar to electric efficiency of the thermal power generation system.

A solar thermal power generation system includes a solar heat collection system that generates superheated steam by solar heat, a main power generation system that performs power generation by part of the superheated steam generated by the solar heat collection system, a solar heat storage/release system that stores heat in a heat storage medium or releases the heat stored in the heat storage medium, and a secondary power generation system that performs power generation by saturated steam generated by the heat storage or the heat release in the solar heat storage/release system. The solar heat storage/release system includes a heat storage heater for exchanging heat between the rest of the superheated steam generated by the solar heat collection system and the heat storage medium to store heat in the heat storage medium and to generate saturated steam, a low-temperature tank for containing the heat storage medium to be supplied to the heat storage heater, and a high-temperature tank for containing the heat storage medium after the heat storage in the heat storage heater. The secondary power generation system includes a saturated steam turbine into which the saturated steam generated by the heat storage heater can be introduced.

Disclosed is a solar energy power generation system capable of effectively collecting solar energy resulting in high electricity generation efficiency. The solar energy power generation system includes a solar energy collector configured to collect solar heat and to convert an energy absorption medium into a gaseous state, a steam turbine configured to generate kinetic energy using the energy absorption medium in the gaseous state generated in the solar energy collector, a generator configured to convert the kinetic energy generated in the steam turbine into electric energy, a condenser configured to cool the energy absorption medium in the gaseous state discharged from the steam turbine into a liquid state, and a circulation pump configured to pump the energy absorption medium in the liquid state cooled by the condenser toward the solar energy collector. The solar energy collector includes a solar energy collection pipe having an absorption medium flow path for allowing the energy absorption medium to flow therethrough, and at least one lens configured to concentrate solar energy on the solar energy collection pipe.

A solar power system having a heat exchanger, a heat-focusing mirror used to receive sunlight, a turbine generator, and a battery coupled to the turbine generator is provided. The heat exchanger has a first guiding channel for a first heat-exchange fluid and a second guiding channel for a second heat-exchange fluid. Sunlight is focused to the first heat-exchange fluid flow in the first guiding channel by the heat-focusing mirror. One end of the turbine generator is communicated with the outlet of the second guiding channel. The second heat-exchange fluid is suitable for driving the turbine generator to produce an electric power, and the electric power can be stored into the battery.

Various examples of systems and methods are provided for Lyapunov control for uncertain systems. In one example, a system includes a process plant and a robust Lyapunov controller configured to control an input of the process plant. The robust Lyapunov controller includes an inner closed loop Lyapunov controller and an outer closed loop error stabilizer. In another example, a method includes monitoring a system output of a process plant; generating an estimated system control input based upon a defined output reference; generating a system control input using the estimated system control input and a compensation term; and adjusting the process plant based upon the system control input to force the system output to track the defined output reference. An inner closed loop Lyapunov controller can generate the estimated system control input and an outer closed loop error stabilizer can generate the system control input.

Implementations of a system for collecting radiant energy with a non-imaging solar concentrator are provided. In some implementations, the system may be configured to focus radiant energy striking a plurality of concentric, conical ring-like reflective elements of the non-imaging concentrator onto a receiver positioned thereunder and to rotate and/or pivot the receiver so that at least a portion thereof is always kept within the focal point (or area) of the non-imaging concentrator. Wherein the center of the focal point (or area) is fixed with respect to the ground. In some implementations, the system for collecting radiant energy with a non-imaging solar concentrator may comprise a tracking apparatus configured to support the non-imaging concentrator and position it so that the sun is normal thereto, and a piping system that is configured to transfer concentrated solar energy from the receiver to an absorbing system where the energy is finally utilized.