초록 ▼

Methods of arranging and operating a molten salt solar thermal energy system are disclosed. Molten salt flows from a set of cold storage tanks to solar receivers which heat the molten salt to a maximum temperature of about 850° F. The heated molten salt is sent to a set of hot storage tanks. The hea

Methods of arranging and operating a molten salt solar thermal energy system are disclosed. Molten salt flows from a set of cold storage tanks to solar receivers which heat the molten salt to a maximum temperature of about 850° F. The heated molten salt is sent to a set of hot storage tanks. The heated molten salt is then pumped to a steam generation system to produce steam for process and/or power generation. Lower salt temperatures are useful in processes that use lower steam temperatures, such as thermal desalination. Lower salt temperatures and low chloride molten salt reduce the corrosion potential, permitting the use of lower cost alloys for the solar receivers, hot storage tanks, salt pumps, piping and instrumentation and steam generation system. Multiple sets of modular, shop assembled storage tanks are also used to reduce the amount of salt piping, simplify draining, and reduce field assembly and plant cost.

대표청구항 ▼

1. A solar thermal energy generation and storage system, comprising: (A) a plurality of heliostat fields surrounding a central location, wherein each heliostat field comprises: (i) a solar receiver comprising a plurality of tube panels arranged on an exterior of a support structure, the tube panels

1. A solar thermal energy generation and storage system, comprising: (A) a plurality of heliostat fields surrounding a central location, wherein each heliostat field comprises: (i) a solar receiver comprising a plurality of tube panels arranged on an exterior of a support structure, the tube panels being fluidly connected to form at least one flow path; and(ii) a first plurality of heliostats arranged around the solar receiver;(B) a first set of cold storage tanks configured to supply heat transfer fluid to at least one solar receiver in the plurality of heliostat fields; and(C) a first set of hot storage tanks configured to receive heat transfer fluid from at least one solar receiver in the plurality of heliostat fields;wherein the first set of cold storage tanks comprises at least one cold fluid storage tank and at least one cold fluid pump tank, the at least one cold fluid pump tank having at least one pump to send the heat transfer fluid to the first solar receiver, and wherein the at least one cold fluid storage tank does not have a pump and is fluidly connected only to the at least one cold fluid pump tank. 2. The system of claim 1, further comprising a steam generation system that receives heat transfer fluid from the first set of hot storage tanks. 3. The system of claim 1, wherein the first set of cold storage tanks comprises a plurality of cold fluid storage tanks and only one cold fluid pump tank. 4. The system of claim 1, wherein the system further comprises hot salt piping; and wherein the first set of hot storage tanks and the hot salt piping are made from a chromium-molybdenum steel alloy, carbon steel, or a metal of lower grade than austenitic stainless steel. 5. The system of claim 1, wherein the first set of cold storage tanks and the first set of hot storage tanks each have a height of about 100 feet or less and a diameter of about 14 feet or less, such that the tanks can be shipped by truck. 6. The system of claim 1, wherein the central location contains a steam generation system, the first set of cold storage tanks, and the first set of hot storage tanks. 7. The system of claim 6, wherein the steam generation system comprises (i) only an evaporator; (ii) a preheater and an evaporator; (iii) a preheater, an evaporator, and a superheater; or (iv) a preheater, an evaporator, a superheater, and a reheater. 8. The system of claim 7, wherein the superheater or the reheater are made from a chromium-molybdenum steel alloy, carbon steel, or a metal of lower grade than austenitic stainless steel. 9. The system of claim 7, wherein the evaporator is made from carbon steel or a metal of lower grade than chromium-molybdenum steel alloy. 10. The system of claim 1, wherein the system comprises a plurality of sets of cold storage tanks and a plurality of sets of hot storage tanks, wherein the plurality of sets of cold storage tanks together supply heat transfer fluid to each solar receiver in the plurality of heliostat fields, and wherein the plurality of sets of hot storage tanks together receive heat transfer fluid from each solar receiver in the plurality of heliostat fields. 11. The system of claim 1, wherein (i) the tube panels of the at least one solar receiver, (ii) piping from the at least one solar receiver to the first set of hot storage tanks, and (iii) the first set of hot storage tanks are configured to handle heat transfer fluid having a maximum temperature of about 850° F. 12. The system of claim 1, further comprising a steam generation system comprising modular truck-shippable heat exchangers, a superheater, a reheater, an evaporator, and a preheater which receive the heat transfer fluid having a maximum temperature of about 850° F. and feedwater to generate steam from the feedwater; wherein the heat transfer fluid subsequently flows to the first set of cold storage tanks. 13. The system of claim 1, wherein the heliostat fields are arranged in a single perimeter around the central location or along any side of the central location so that the heliostat fields are next to the central location. 14. The system of claim 1, wherein the heliostat fields are arranged on all sides of the central location along a single perimeter. 15. A solar thermal energy generation and storage system, comprising: (A) a plurality of heliostat fields surrounding a central location, wherein each heliostat field comprises: (i) a solar receiver comprising a plurality of tube panels arranged on an exterior of a support structure, the tube panels being fluidly connected to form at least one flow path; and(ii) a first plurality of heliostats arranged around the solar receiver;(B) a first set of cold storage tanks configured to supply heat transfer fluid to each solar receiver in the plurality of heliostat fields; and(C) a first set of hot storage tanks configured to receive heat transfer fluid from each solar receiver in the plurality of heliostat fields;wherein the first set of cold storage tanks comprises at least one cold fluid storage tank and at least one cold fluid pump tank, the at least one cold fluid pump tank having at least one pump to send the heat transfer fluid to the first solar receiver, and wherein the at least one cold fluid storage tank does not have a pump and is fluidly connected only to the at least one cold fluid pump tank; andwherein the first set of hot storage tanks comprises at least one hot fluid storage tank and at least one hot fluid pump tank, the at least one hot fluid pump tank having at least one pump to send the heated heat transfer fluid to the steam generation system, and wherein the at least one hot fluid storage tank does not have a pump and is fluidly connected only to the at least one hot fluid pump tank. 16. A solar thermal enemy generation and storage system, comprising: (A) a plurality of heliostat fields surrounding a central location, wherein each heliostat field comprises: (i) a solar receiver comprising a plurality of tube panels arranged on an exterior of a support structure, the tube panels being fluidly connected to form at least one flow path; and(ii) a first plurality of heliostats arranged around the solar receiver;(B) a first set of cold storage tanks configured to supply heat transfer fluid to at least one solar receiver in the plurality of heliostat fields; and(C) a first set of hot storage tanks configured to receive heat transfer fluid from at least one solar receiver in the plurality of heliostat fieldswherein the first set of hot storage tanks comprises at least one hot fluid storage tank and at least one hot fluid pump tank, the at least one hot fluid pump tank having at least one pump to send the heated heat transfer fluid to the steam generation system, and wherein the at least one hot fluid storage tank does not have a pump and is fluidly connected only to the at least one hot fluid pump tank. 17. The system of claim 16, wherein the first set of hot storage tanks comprises a plurality of hot fluid storage tanks and only one hot fluid pump tank.