Combined solar thermal power generation system

Abstract

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.

Claims

1. A combined solar thermal power generation system, comprising: a parabolic trough collector subsystem, a heat exchanger subsystem, a Rankine cycle power generation subsystem, and a dish power generation subsystem; wherein said parabolic trough collector subsystem comprises a parabolic trough mirror field, a pump, and a valve, one end of said parabolic trough mirror field is connected to said pump and the other end of said parabolic trough mirror field is connected to said valve; wherein said heat exchanger subsystem comprises a superheater, an evaporator, and a preheater, said superheater is successively connected to said evaporator and said preheater, and said superheater also is connected to said pump, and said preheater is connected to said valve; wherein said 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, one end of said temperature-decreased pressure reducer is connected to said superheater, the other end of said temperature-decreased pressure reducer is connected to said steam turbine, said condenser, and said condensate pump, said steam turbine is connected to said electric generator and said deaerator, said deaerator is connected to said feedwater pump, and said feedwater pump is connected to said preheater; and wherein said dish power generation subsystem comprises a dish mirror field and a Stirling engine set, said dish mirror field is used for collecting solar energy and providing heat for said Stirling engine set, and an inlet of a cold chamber of said Stirling engine set is connected to said condensate pump, an outlet of said cold chamber is connected to said deaerator.

2. The combined solar thermal power generation system according to claim 1, wherein said parabolic trough collector subsystem includes a parabolic trough collector.

3. The combined solar thermal power generation system according to claim 1, wherein said parabolic trough collector subsystem employs heat-conducting oil or molten salts as a heat-conducting working medium.

4. The combined solar thermal power generation system according to claim 1, wherein said dish mirror field includes a heat collector disposed at a focal point of a dish collector for gathering sunlight to heat air to obtain a hot air, the hot air flows to a hot chamber of said Stirling engine set.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates the structure of a combined solar thermal power generation system.

DETAILED DESCRIPTION

(2) For clear understanding of the objectives, technical schemes and advantages of the disclosure, and detailed description of the disclosure will be given below in conjunction with accompanying drawings and specific embodiments. It should be noted that the embodiments are only meant to explain the invention, and not to limit the scope of the invention. Additionally, technical features referred by embodiments described below may be mutually combined as long as they do not conflict.

(3) As illustrated in FIG. 1, a combined solar thermal power generation system comprises a parabolic trough collector subsystem 10, a heat exchanger subsystem 20, a Rankine cycle power generation subsystem 30 and a dish power generation subsystem 40;

(4) the parabolic trough collector subsystem 10 comprises a trough-type mirror field 11, a pump 12 and a valve 13, one end of the trough-type mirror field 11 is connected to the pump 12 and the other end of the trough-type mirror field 11 is connected to the valve 13;

(5) the heat exchanger subsystem 20 comprises a superheater 21, an evaporator 22 and a preheater 23, the superheater 21 is successively connected to the evaporator 22 and the preheater 23, and also is connected to the pump 12, and the preheater 23 is connected to the valve 13;

(6) the Rankine cycle power generation subsystem 30 comprises a temperature-decreased pressure reducer 31, a steam turbine 32, an electric generator 33, a condenser 34, a condensate pump 35, a deaerator 36 and a feedwater pump 37, one end of the temperature-decreased pressure reducer 31 is connected to the superheater 21, the other end of the temperature-decreased pressure reducer 31 is connected to the steam turbine 32, the condenser 34 and the condensate pump 35, the steam turbine 32 is connected to the electric generator 33 and the deaerator 36, the deaerator 36 is connected to the feedwater pump 37, and the feedwater pump 37 is connected to the preheater 23; and

(7) the dish power generation subsystem 40 comprises a dish-type mirror field 41 and a Stirling engine set 42, the dish-type mirror field 41 is used for collecting solar energy and providing heat for the Stirling engine set 42, and cold chambers of the Stirling engine set 42 are connected to the condensate pump 35 and the deaerator 36.

(8) The parabolic trough collector subsystem 10 is formed by assembling a modularized trough-type integral heat collection device, and the dish power generation subsystem 40 is formed by assembling a modularized dish-type integral heat collection device.

(9) A trough mirror field employs two loops, utilizes a heat-conducting medium for absorbing solar radiation energy and then for heating a working medium in a heat exchanger. The heat-conducting medium may employ heat-conducting oil or a molten salt.

(10) A Rankine cycle subsystem may employs a water working medium or an organic working medium, the working medium of the Rankine cycle subsystem forms a condensed fluid after passing through the condenser 34, the condensed fluid facilitates heat exchange after flowing through the surface of the cold chamber of a Stirling engine, and the working medium of Rankine cycle becomes a superheated steam after passing through a heat exchanger connected to the trough collector field.

(11) A dish subsystem employs a single-dish or double-dish system which facilitates reflection-dish single-axis or double-axis automatic tracking and possesses a fixed receiver, the dish-type mirror field 41 employs a parabolic dish collector capable of automatically tracking sun through a single axis or double axes, the cold chambers of the Stirling engine set 42 are cooled by a fluid condensed by the condenser 34, and the dish collector gathers sunlight to the hot chamber of the Stirling engine so as to provide thermal energy for the Stirling engine.

(12) The four subsystems of the invention operates jointly so as to facilitate conversion between solar energy and electric energy and output electric energy, the parabolic trough collector subsystem 10 and the dish power generation subsystem 40 are relatively independent, the heat-conducting medium in the parabolic trough collector subsystem 10 transfers collected thermal energy to a working medium of the Rankine cycle power generation subsystem in the heat exchanger subsystem 20, the dish-type mirror field 41 of the dish power generation subsystem 40 collects solar energy and provides thermal energy for the Stirling engine set 42, and the Stirling engine set 42 applies work outwardly and generates power.

(13) The working medium of the Rankine cycle power generation subsystem 30 firstly flows through the cold chamber of the Stirling engine set 42 to obtain a part of thermal energy, then enters the heat exchanger subsystem 20 and is heated into a superheated steam, and then the superheated steam enters the steam turbine 32 for working and driving the electric generator 33 to generate electricity.

(14) For more detailed description of the implementation process of the above embodiment, a trough system employs Dow Thermal A heat-conducting oil as a heat transfer medium, a dish system employs air with the pressure of 0.5 MPa as a heat transfer medium, and Rankine cycle employs water as a working medium, and the combined solar thermal power generation system comprehensively utilizing Rankine cycle and Stirling cycle possesses the following related design parameters shown in table 1.

(15) TABLE-US-00001 TABLE 1 Related design parameters of the combined power generation system Item Unit Value Solar radiation intensity kW/m.sup.2 0.7 Power of the electric generator 33 kW 200 Collector field efficiency of the parabolic trough % 71.8 collector subsystem 10 Main steam temperature of the steam turbine 32 C. 340 Main steam pressure of the steam turbine 32 MPa 2.35 Exhaust pressure of the steam turbine 32 MPa 0.015 Relative internal efficiency of the steam turbine 32 % 71.1 Efficiency of the electric generator 33 % 97.5 Collector field efficiency of the dish power generation % 80 subsystem 40 Hot chamber temperature of the Stirling engine set 42 C. 722 Compression ratio of the Stirling engine set 42 3.375

(16) In order to further suggest the efficiency improvement of the system by combined usage of Rankine cycle and Stirling cycle, comparison under different numbers of Stirling engines is performed between schemes of the system of the invention and schemes of employing stand alone power generation through Rankine cycle and Stirling cycle. The comparison conditions are as follows: the solar radiation intensity is same, the heat-transfer working medium, the heat collection area and the collector field efficiency of the trough systems are same, the heat collection area and the optical efficiency of the dish systems are same, the hot chamber temperature of the Stirling engine sets 42 is same, the main steam parameters and the exhaust parameter of the steam turbine 32 are same, the power generation efficiency of the group of the steam turbine 32 and the power generator 33 are same. In the stand alone power generation scheme, the cold chambers of the Stirling engine set 42 employ a mature water-cooling technology. The simulation comparison results and the scheme of the combined system of the invention are compared in table 2.

(17) TABLE-US-00002 TABLE 2 Comparison between simulation calculation results and those of the scheme of the combined system of the invention Generation power Total solar to electric Efficiency of the Stirling of the electric generator conversion engine set 42 (kW) 33 (kW) efficiency of the system Number Scheme of Scheme of Scheme of of Scheme stand alone Scheme stand alone Scheme standalone Stirling of the power of the power of the power engine invention generation invention generation invention generation 1 5.390 5.587 200 198.33 0.1674 0.1661 2 1.072 1.118 200 196.67 0.1706 0.1681 3 1.599 1.677 200 195.02 0.1737 0.1701 4 2.120 2.236 200 193.36 0.1768 0.1721 5 2.635 2.795 200 191.72 0.1798 0.1740 6 3.145 3.354 200 190.08 0.1827 0.1759 7 3.649 3.913 200 188.44 0.1855 0.1778 8 4.147 4.472 200 186.81 0.1883 0.1797 9 4.640 5.031 200 185.18 0.1910 0.1815

(18) As shown in table 2, in the provided scheme of the combined system of the invention, the efficiency of the group of the steam turbine and the electric generator 33 is higher than those of schemes of stand alone power generation through Rankine cycle and Stirling cycle, the total solar to electric conversion efficiency of the system is relatively high, and along with increase of the number of the Stirling engine, the efficiency improvement is increased. Therefore, the invention is capable of improving the solar to electric conversion efficiency of a solar thermal power generation system by utilizing a conventional solar heat collection technology.

(19) While preferred embodiments of the invention have been described above, it will be obvious to those skilled in the art that the invention is not limited to disclosure in the embodiments and the accompanying drawings. Any modification, equivalent alterations and improvements without departing from the spirit and the principle of the invention fall within the scope of the invention.