초록 ▼

Systems and methods for storing and releasing energy comprising directing inlet air into a vertical cold flue assembly, a portion of moisture being removed from the air within the cold flue assembly. The air is directed out of the cold flue assembly and compressed. The remaining moisture is substant

Systems and methods for storing and releasing energy comprising directing inlet air into a vertical cold flue assembly, a portion of moisture being removed from the air within the cold flue assembly. The air is directed out of the cold flue assembly and compressed. The remaining moisture is substantially removed and the carbon dioxide is removed from the air by adsorption. The air is cooled in a main heat exchanger such that it is substantially liquefied using refrigerant loop air, The substantially liquefied air is directed to a storage apparatus. The refrigerant loop air is cooled by a mechanical chiller and by a plurality of refrigerant loop air expanders. In energy release mode, working loop air warms the released liquid air such that the released liquid air is substantially vaporized, and the released liquid air cools the working loop air such that the working loop air is substantially liquefied. A portion of the released liquid air is directed to the at least one generator and used as bearing air for the at least one generator. The substantially vaporized air is directed to a combustion chamber and combusted with a fuel stream. Combustion gas may be directed from the combustion chamber to at least one expander, the expanded combustion gas split into two portions. The first portion may be directed to a first heat exchanger, and the second portion may be directed to a second heat exchanger such that the second portion heats and substantially vaporizes the released liquid air.

대표청구항 ▼

The invention claimed is: 1. An energy release system comprising: a storage apparatus; one or more heat exchangers, at least one of the heat exchangers being fluidly connected to the storage apparatus; at least one combustion chamber fluidly connected to at least one of the heat exchangers; one or

The invention claimed is: 1. An energy release system comprising: a storage apparatus; one or more heat exchangers, at least one of the heat exchangers being fluidly connected to the storage apparatus; at least one combustion chamber fluidly connected to at least one of the heat exchangers; one or more generator-loaded hot-gas expanders fluidly connected to the at least one combustion chamber and at least one of the heat exchangers; at least one generator fluidly connected to at least one of the hot-gas expanders, the generator producing electric power; and a stream of liquid air and a stream of working loop air, the stream of liquid air and the stream of working loop air being separate and distinct streams, the working loop air traveling in a closed loop such that liquid air released from the storage apparatus flows in a first general direction, and working loop air flows in a second general direction, the second general direction being substantially opposite to the first general direction; and the working loop air warms the released liquid air such that the released liquid air is substantially vaporized, and the released liquid air cools the working loop air such that the working loop air is substantially liquefied. 2. The system of claim 1 wherein the substantially vaporized air is directed to a combustion chamber and combusted with a fuel stream. 3. The system of claim 2 further comprising at least one valve, wherein combustion gas is directed from the combustion chamber to at least one generator-loaded hot gas expander and expanded in the generator-loaded hot-gas expander; the expanded combustion gas is split by the at least one valve into a first portion and a second portion, the first portion being relatively larger than the second portion; the first portion is directed to a first heat exchanger; and the second portion is directed to a second heat exchanger such that the second portion heats and substantially vaporizes the released liquid air; wherein the at least one generator comprises a plurality of generators and the at least one generator-loaded hot gas expander comprises a plurality of generator-loaded hot gas expanders. 4. The system of claim 3 wherein electric power is produced in two modes such that in the first mode the substantially liquefied working loop air is pumped to pressure and vaporized by hot combustion gas; and the vaporized high pressure working loop air is expanded in one of the generator-loaded hot-gas expander, wherein the generator produces electric power as a supplemental source of electric power; and in the second mode: the substantially vaporized air directed to a combustion chamber, combusted with a fuel stream and expanded in one of the generator-loaded hot-gas expanders produces electric power as a supplemental source of electric power. 5. The system of claim 4 wherein the supplemental source of electric power is stored during an off-peak demand period and released in response to a change in condition from an off-peak demand period to a peak demand period. 6. The system of claim 1 further comprising at least one cryogenic pump, wherein the substantially liquefied working loop air is pumped to pressure by the at least one cryogenic pump and vaporized by hot combustion gas in at least one of the heat exchangers; the vaporized high pressure working loop air is expanded in a generator-loaded hot-gas expander, wherein the generator produces electric power as a supplemental source of electric power for an electric grid; and the electric power stored as liquid air is stored during an off-peak demand period and released in response to a change in condition from an off-peak demand period to a peak demand period. 7. The system of claim 1 further comprising a liquid air production system, the liquid air production system comprising: one or more inlet air compressors; a molecular sieve assembly fluidly connected to a first inlet air compressor; a vertical cold flue assembly fluidly connected to the molecular sieve assembly and to a second inlet air compressor, the vertical cold flue assembly having an air inlet at or near its top into which inlet air is directed and an exit at or near its bottom; one or more inlet air heat exchangers including a main heat exchanger fluidly connected to at least one of the plurality of inlet air compressors; a storage apparatus fluidly connected to the main heat exchanger; an absorption chiller using a working fluid, the absorption chiller being fluidly connected to the cold flue assembly; and a mechanical chiller containing refrigerant fluid, the mechanical chiller being fluidly connected to the absorption chiller; and a refrigerant loop air assembly fluidly connected to the mechanical chiller. 8. The system of claim 7 wherein the refrigerant loop air assembly comprises: one or more refrigerant loop air compressors, at least one of the plurality of refrigerant loop air compressors being fluidly connected to the main heat exchanger; one or more refrigerant loop air cryogenic expanders; wherein the mechanical chiller is fluidly connected to at least one refrigerant loop air compressor, at least one refrigerant loop air cryogenic expander, the absorption chiller, and to the main heat exchanger; and wherein refrigerant loop air flows from the refrigerant loop assembly to the main heat exchanger to cool the inlet air to increase the efficiency of the energy load response system's power outflow function such that electric power may be released as a supplemental source of electric power. 9. The system of claim 8 wherein the refrigerant loop air is compressed by the one or more refrigerant loop air compressors and the heat of compression is recovered by at least the absorption chiller. 10. The system of claim 9 further comprising at least one valve, wherein the refrigerant loop air is split by the at least one valve such that a first portion is directed to the mechanical chiller and a second portion is directed to at least one refrigerant loop air cryogenic expander; the refrigerant loop air is cooled by the mechanical chiller and by the one or more refrigerant loop air cryogenic expanders and is directed to the main heat exchanger; and the refrigerant fluid within the mechanical chiller is condensed by cold working fluid sent to the mechanical chiller from the absorption chiller. 11. The system of claim 7 wherein recovered cold from a vapor portion of the substantially liquefied air further cools the inlet air in the main heat exchanger; the vapor portion of the substantially liquefied air is warmed by heat from the inlet air and recovered heat of compression; and the warmed vapor portion of the substantially liquefied air is directed to the molecular sieve assembly such that the vapor portion of the substantially liquefied air removes carbon dioxide and moisture from the molecular sieve assembly; wherein the substantially liquefied air is produced from inflow energy derived from one or more wind turbines and holds the energy in a storable form for later utilization as electric power. 12. A method of releasing stored power, comprising: releasing stored liquid air; pumping the released liquid air to pressure; creating a closed loop containing working loop air such that the released liquid air and the working loop air are separate and distinct streams; directing the released liquid air through at least one heat exchanger in a first general direction; directing working loop air through the at least one heat exchanger such that the working loop air flows in a second general direction, the second general direction being substantially opposite to the first general direction; warming the released liquid air with the working loop air such that the released liquid air is substantially vaporized; and cooling the working loop air with the released liquid air such that the working loop air is substantially liquefied. 13. The method of claim 12 further comprising the steps of: pumping the substantially liquefied working loop air to pressure; vaporizing the pressurized liquid working loop air by heat exchange with hot combustion gas; expanding the pressurized working loop air in a generator-loaded hot-gas expander such that the generator produces electric power as a supplemental source of electric power; and the electric power is stored during an off-peak demand period and released in response to a change in condition from an off-peak demand period to a peak demand period. 14. The method of claim 13 further comprising the steps of directing the formerly hot exhaust stream from the main heat exchanger to a moisture separator; recovering moisture from the hot exhaust stream in the moisture separator; pumping the recovered liquid moisture to pressure; warming the moisture by recovered heat in a warm heat exchanger; and directing the recovered moisture to the first generator-loaded hot-gas expander. 15. The method of claim 12 further comprising the steps of: directing the substantially vaporized and pressurized air to a combustion chamber; and combusting the substantially vaporized air with a fuel stream such that the substantially vaporized air produces electric power as a supplemental source of electric power; and the electric power is stored during an off-peak demand period and released in response to a change in condition from an off-peak demand period to a peak demand period. 16. The method of claim 15 further comprising the steps of: directing combustion gas from the combustion chamber to a first generator-loaded hot-gas expander; and expanding the combustion gas in the at least one generator-loaded hot-gas expander. 17. The method of claim 16 further comprising the steps of: splitting the expanded combustion gas into a first portion and a second portion, the first portion being relatively larger than the second portion; directing the first portion to a main heat exchanger to warm a cold pressurized air stream; directing the second portion to a second heat exchanger such that the second portion heats and substantially vaporizes the liquid air in the loop that is used to recover the cold from the main released air, where the loop air is heated and expanded in a second generator-loaded hot-gas expander; wherein the liquid air is produced from inflow energy derived from one or more wind turbines and holds energy in a storable form for later utilization as electric power. 18. A system for releasing off-peak power during peak demand periods, comprising: a storage apparatus; one or more heat exchangers, at least one of the heat exchangers being fluidly connected to the storage apparatus; at least one combustion chamber fluidly connected to at least one of the heat exchangers; one or more generator-loaded hot-gas expanders fluidly connected to the at least one combustion chamber and at least one of the heat exchangers; at least one generator fluidly connected to at least one of the hot-gas expanders, the generator producing electric power as a supplemental source of electric power; and a stream of liquid air and a stream of working loop air, the stream of liquid air and the stream of working loop air being separate and distinct streams the working loop air traveling in a closed loop such that liquid air released from the storage apparatus flows in a first general direction, and working loop air flows in a second general direction, the second general direction being substantially opposite to the first general direction; and the working loop air warms the released liquid air such that the released liquid air is substantially vaporized, and the released liquid air cools the working loop air such that the working loop air is substantially liquefied; wherein the substantially vaporized air is directed to the at least one combustion chamber, combusted with a fuel stream and expanded in one of the generator-loaded hot-gas expanders so that the substantially vaporized air produces electric power as a supplemental source of electric power. 19. The system of claim 18 wherein the electric power is stored during an off-peak demand period and released in response to a change in condition from an off-peak demand period to a peak demand period. 20. The system of claim 18 wherein the at least one generator comprises a plurality of generators and the one or more generator-loaded hot-gas expanders comprises a plurality of generator-loaded hot-gas expanders.