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US20130263585A1 - Multiple cavern compressed air energy storage system and method - Google Patents

Multiple cavern compressed air energy storage system and method Download PDF

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Publication number
US20130263585A1
US20130263585A1 US13/833,000 US201313833000A US2013263585A1 US 20130263585 A1 US20130263585 A1 US 20130263585A1 US 201313833000 A US201313833000 A US 201313833000A US 2013263585 A1 US2013263585 A1 US 2013263585A1
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United States
Prior art keywords
cavern
compressor
piping system
air
generator
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
US13/833,000
Inventor
Alissa OPPENHEIMER
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Chamisa Energy Co LLC
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Chamisa Energy Co LLC
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Chamisa Energy Co LLC filed Critical Chamisa Energy Co LLC
Priority to US13/833,000 priority Critical patent/US20130263585A1/en
Priority to PCT/US2013/035446 priority patent/WO2013152285A1/en
Priority to US14/005,074 priority patent/US20140338318A1/en
Assigned to CHAMISA ENERGY COMPANY, LLC reassignment CHAMISA ENERGY COMPANY, LLC ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: OPPENHEIMER, Alissa
Publication of US20130263585A1 publication Critical patent/US20130263585A1/en
Abandoned legal-status Critical Current

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01DNON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
    • F01D15/00Adaptations of machines or engines for special use; Combinations of engines with devices driven thereby
    • F01D15/10Adaptations for driving, or combinations with, electric generators
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02CGAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
    • F02C6/00Plural gas-turbine plants; Combinations of gas-turbine plants with other apparatus; Adaptations of gas-turbine plants for special use
    • F02C6/14Gas-turbine plants having means for storing energy, e.g. for meeting peak loads
    • F02C6/16Gas-turbine plants having means for storing energy, e.g. for meeting peak loads for storing compressed air
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J15/00Systems for storing electric energy
    • H02J15/006Systems for storing electric energy in the form of pneumatic energy, e.g. compressed air energy storage [CAES]
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05DINDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
    • F05D2260/00Function
    • F05D2260/42Storage of energy
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/16Mechanical energy storage, e.g. flywheels or pressurised fluids

Definitions

  • CAES Compressed Air Energy Storage
  • CAES systems typically utilize off-peak (low-cost) electrical power to compress air, the compressed air is stored in a storage vessel and the stored, compressed air is used at a later time to generate electricity during peak (high-price) electric usage times.
  • CAES systems have been utilized to power various mechanism.
  • the CAES system may store the compressed air in a relatively large volume vessel, potentially an underground cavern, for later use of the compressed air to generate electricity.
  • These CAES systems generally utilize a single cavern to store the compressed air and later draw the compressed air from the single cavern to generate electricity.
  • These single cavern systems suffer from a limited volume of compressed air storage space, the inability to introduce compressed air into the cavern and withdraw compressed air from the cavern at the same time, shutdown of the system for malfunctions with the cavern or maintenance on the cavern and its related hardware or similar limitations resulting from the single cavern design.
  • a further consequence of the single-cavern design is that the conversion process (energy to compressed air, or compressed air to energy) is unidirectional. The two functions cannot be performed at the same time, thus limiting the utility of the system for storage, generation and grid-balancing.
  • CAES systems that may include multiple air storage mechanisms or vessels often have a high pressure vessel and a low pressure vessel that are connected in series to each other. This arrangement also results in the inability to pressurize one of the vessels at the same time as air from a second vessel is utilized to generate electricity.
  • These multiple cavern conventional CAES systems limit the ability to operate a compressor utilizing alternatively generated electricity from, for example, solar panels on a hot sunny day in the summer, to compress air and store the air in a vessel, while at the same time using previously pressurized and stored air from a second vessel to drive a generator and produce power. Peak performance for certain alternatively energy generators may coincide with peak power requirements of an electrical system and a CAES system that does not permit storing energy at the same time as previously stored energy is utilized to address peak power needs is disadvantageous.
  • the preferred multiple cavern or vessel CAES system addresses the limitations of the previous CAES systems by employing an efficient overall system for producing power utilizing stored air pressure from underground caverns.
  • an energy system for storing compressed air and utilizing the compressed air to generate electricity includes a first storage cavern and a second storage cavern.
  • the second storage cavern is separate from the first storage cavern.
  • An air compressor is in fluid communication with the first and second storage caverns. The air compressor is driven by electricity from an alternative energy generator or off-peak electrical energy to provide pressurized air to the first and second caverns.
  • An electric generating mechanism is in fluid communication with the first and second storage caverns. The electric generating mechanism generates electricity utilizing the compressed air from the first and/or second cavern(s), typically during peak electric usage periods.
  • a preferred energy system is utilized for storing pressurized air and using the pressurized air to generate electricity.
  • the energy system includes a first storage cavern and a second storage cavern separate from the first storage cavern.
  • An air compressor is in fluid communication with the first and second storage caverns through a compressor piping system.
  • the air compressor is configured to provide pressurized air to the first and second caverns through the compressor piping system.
  • An electric generating mechanism is in fluid communication with the first and second storage caverns through a generator piping system.
  • the compressor piping system is separate from the generator piping system.
  • a combustion chamber is in fluid communication with the generator piping system and is located upstream of airflow relative to the electric generating mechanism.
  • the combustion chamber is configured to preheat the pressurized air flowing to the electric generating mechanism.
  • a controller is in communication with the air compressor, the electric generating mechanism, the compressor piping system and the generator piping system. The controller is configured to operate the energy system such that the compressor directs compressed air into the first storage cavern through the compressor piping system at the same time the electric generating mechanism generates electricity utilizing at least compressed air from the second cavern.
  • a recuperator is in fluid communication with the electric generating mechanism through an exhaust piping system.
  • the exhaust piping system includes an exhaust and is separate from the generator piping system and the compressor piping system.
  • the recuperator is configured to transfer heat energy from exhaust air of the electric generating mechanism to the generator piping system.
  • FIG. 1 is a perspective, partial cross-sectional view of a multiple cavern compressed air energy storage system in accordance with a preferred embodiment of the present application.
  • FIG. 2 is a block diagram of the multiple cavern compressed air energy storage system of FIG. 1 .
  • the present application is directed to an energy system, generally designated 10 , for storing pressurized air to generate electricity.
  • the energy system includes a first storage cavern 12 for storing the compressed air and a second storage cavern 14 separate from the first storage cavern 12 .
  • the second storage cavern 14 is also used for storing compressed air.
  • An air compressor 16 is in fluid communication with the first and second storage caverns 12 , 14 .
  • the air compressor 16 is preferably driven by electricity from an alternative energy generator 18 or off-peak electrical energy, preferably from a conventional power grid 20 , to provide pressurized air to the first and second caverns 12 , 14 .
  • An electric generating mechanism 22 is also in fluid communication with the first and second storage caverns 12 , 14 .
  • the electric generating mechanism 22 is preferably in fluid communication with the first and second storage caverns 12 , 14 through a generator piping system 24 .
  • the generator piping system 24 preferably includes several control valves 13 b, 15 b, which will be described in greater detail below, to selectively open and/or close flow of pressurized air from the first and second storage caverns 12 , 14 to the electric generating mechanism 22 .
  • the air compressor 16 is preferably in fluid communication with the first and second storage caverns 12 , 14 through a compressor piping system 25 .
  • the compressor piping system 25 also preferably includes control valves 13 a, 15 a, which will be described in greater detail below, to selectively open and/or close the flow of pressurized air from the air compressor 16 to the first and second storage caverns 12 , 14 .
  • the compressor piping system 25 is preferably separate from the generator piping system 24 such that the flow of pressurized air from the air compressor 16 and to the electric generating mechanism 22 can proceed independently of each other.
  • a controller 26 is preferably utilized to control the preferred system 10 , including the various valves 13 a, 13 b, 15 a, 15 b, to operate the various components, including controlling flow of pressurized air to the electric generating mechanism 22 and from the air compressor 16 to and from the first and second storage caverns 12 , 14 , respectively.
  • the electric generating mechanism 22 generates electricity utilizing at least the compressed air from the first cavern 12 and/or the second cavern 14 .
  • the controller 26 preferably controls the generation of pressurized air and electricity such that air is pressurized during off-peak times and electricity is generated during peak usage hours from the compressed or pressurized air that was pressurized during off-peak electric usage times or by the alternate energy generators 18 .
  • Profits and efficiency can me maximized by storing energy while operating expenses are low and producing energy while demand is high. Profits and efficiency can also be maximized by producing energy with the alternative energy generator 18 when the alternative energy if available for production, regardless of whether demand on the electric grid 20 is high or low.
  • the controller 26 is in communication with the air compressor 16 , the electric generating mechanism 22 , the compressor piping system 25 , and the generator piping system 24 .
  • the controller 26 is configured to operate the energy system 10 such that the compressor directs compressed air into the first storage cavern 12 through the compressor piping system 25 at the same time the electric generator mechanism 22 generates electricity utilizing at least compressed air from the second cavern 14 .
  • the preferred controller 26 is able to constantly generate compressed air using the compressor 16 , which is preferably driven by off-peak electricity from the electric grid 20 or alternatively generated electricity from an alternative energy generator 18 , and at the same time produce electricity utilizing the electric generating mechanism 22 , which is driven at least partially by compressed air from the storage caverns 12 , 14 .
  • the controller 26 may also individually operate the compressor 16 to produce pressurized air for introduction into the caverns 12 , 14 , such as during off-peak electric utilization on the electric grid 20 or when the alternative electric generator 18 is operating, while at the same time the electrical generating mechanism 22 is shut down and not producing electricity.
  • the controller 22 is able to produce power from the compressed air stored in the caverns 12 , 14 when the air compressor 16 is not operating.
  • the system 10 also includes a third storage cavern 28 .
  • the first, second and third storage caverns 12 , 14 , 28 are preferably comprised of underground caverns that are generally air tight for a reasonable amount of time and relatively large such that a significant volume of compressed air may be stored in the caverns 12 , 14 , 28 without excessive loss of air pressure due to leakage from the caverns 12 , 14 , 28 .
  • the third storage cavern 28 is preferably in fluid communication with the air compressor 16 through the compressor piping system 25 and the electric generating mechanism 22 through the generator piping system 24 .
  • the system 10 is not limited to the inclusion of the first, second and third caverns 12 , 14 , 28 or to these caverns being underground caverns 12 , 14 , 28 .
  • the system 10 may alternatively include above-ground pressurized air storage, such as a fourth storage cavern or vessel 46 , which is described in greater detail below, or alternative underground pressure vessels (not shown) for storing the pressurized air, including many more storage caverns than those shown in the appended figures.
  • the system 10 is not limited to inclusion of the first, second and third storage caverns 12 , 14 , 28 and may include only the first storage cavern 12 and/or second storage cavern 14 for storage of the pressurized air and operation of the preferred system 10 .
  • the preferred energy system 10 also includes a compressor valve 16 a, a first cavern inlet valve 13 a, a second cavern inlet valve 15 a, a third cavern inlet valve 29 a, a fourth cavern or vessel inlet valve 47 a, a generator valve 22 b, a first cavern outlet valve 13 b, a second cavern outlet valve 15 b, a third cavern outlet valve 29 b and a fourth cavern or vessel outlet valve 47 b.
  • the controller 26 is preferably able to control the opening and closing of the valves 16 a, 13 a, 15 a, 29 a, 47 a, 22 b, 13 b , 15 b, 29 b, 47 b to efficiently operate the system 10 .
  • the first, second, third and fourth cavern inlet valves 13 a, 15 a, 29 a, 47 a and the compressor valve 16 a are associated with the compressor piping system 25 and the first, second, third and fourth cavern outlet valves 23 b, 15 b, 29 b, 47 b and the generator valve 22 b are associated with the generator piping system 24 .
  • the energy system 10 is not limited to inclusion of each of the preferred valves 16 a, 13 a, 15 a, 29 a, 47 a, 22 b, 13 b, 15 b, 29 b , 47 b and may include more or less valves associated with the compressor, generator and/or exhaust piping systems 25 , 24 , 48 .
  • the compressor valve 16 a and the first, second, third and fourth cavern inlet valves 13 a, 15 a, 29 a, 47 a are preferably opened by the controller 26 to allow pressurized air to selectively flow into the first, second, third and fourth caverns or vessels 12 , 14 , 28 , 46 , respectively.
  • the generator valve 22 b and/or the first, second, third and fourth cavern outlet valves 13 b , 15 b, 29 b, 47 b are preferably opened by the controller 26 to selectively allow pressurized air to flow from the first, second, third and/or fourth caverns or vessel 12 , 14 , 28 , 46 into the electrical generator mechanism 22 to generate electricity.
  • the creation, modification, improvement and/or use of the multiple subsurface storage caverns 12 , 14 , 28 and the vessel 46 is preferred, as this design allows for a degree of operational flexibility that is preferred over existing power generation resources.
  • the multiple subsurface storage caverns 12 , 14 , 28 and the vessel 46 enable the simultaneous depletion and filling of the various storage caverns 12 , 14 , 28 and the vessel 46 with pressurized air in a single facility or system 10 . This, in turn, enables the preferred system 10 to respond to the electric energy market in both real-time and day ahead scenarios and operational conditions.
  • the utilization of the underground storage caverns 12 , 14 , 28 and the vessel 46 utilizes the storage capacity of the caverns 12 , 14 , 28 and the vessel 46 to promote relatively safe storage of a large volume of pressurized air.
  • the storage caverns 12 , 14 , 28 and the vessel 46 are preferably located on the same site or parcel of property as the air compressor 16 , the electric generating mechanism 22 , a combustion chamber 32 and a recuperator 30 , which are each components of the preferred energy system 10 .
  • Maintaining the underground storage caverns 12 , 14 , 28 and/or the vessel 46 on the same site promotes efficient utilization of the system 10 by limiting pressure losses in the piping systems 24 , 25 and facilitating quick production of electrical energy with the electric generating mechanism 22 .
  • Close proximity or positioning of the underground storage caverns 12 , 14 , 28 and/or the vessel 46 beneath or immediately adjacent relative to the electric generating mechanism 22 promotes quick response in providing pressurized air to the electric generating mechanism 22 .
  • Quickly providing pressurized air to the electric generating mechanism 22 permits the preferred system 10 to promptly address fluctuations in draw on the electric grid 20 , by quickly providing supplemental power to the electric grid 20 during peak demand or spikes in demand.
  • at least portions of the preferred underground storage caverns 12 , 14 , 28 are positioned directly beneath or below the site or facility that houses the electric generating mechanism 22 and the air compressor 16 .
  • the flexibility and responsiveness of the preferred system 10 that utilizes the multiple storage caverns 12 , 14 , 28 and the vessel 46 also makes it possible for a facility to simultaneously act as both a controllable load and a generation resource. Accordingly, the preferred system 10 can provide an array of power products, including ancillary services, as well as peaking, intermediate and base load energy.
  • the preferred system 10 is also flexible in that air pressure may be loaded into the caverns 12 , 14 , 28 and the vessel 46 independently or at the same time as the pressurized air in others of the caverns 12 , 14 , 28 and the vessel 46 is utilized to generate electricity with the generator 22 .
  • the preferred energy system 10 also includes the recuperator 30 positioned between the storage caverns 12 , 14 , 28 and the vessel 46 and the electric generating mechanism 22 in the generator piping system 24 .
  • the recuperator 30 is also in fluid communication with the electric generating mechanism 22 through an exhaust piping system 48 on the exhaust side of the electric generating mechanism 22 .
  • the exhaust piping system 48 is separate from the generator piping system 24 and the compressor piping system 25 .
  • the recuperator 30 preferably transfers heat energy from exhaust air of the electric generating mechanism 22 that is flowing through the exhaust piping system 48 to intake air from the storage caverns 12 , 14 , 28 in the generator piping system 24 that is entering the electric generating mechanism 22 .
  • the recuperator 30 improves the efficiency of the system by recycling the heat in the exhaust air flowing through the exhaust piping system 48 back into the air flowing through the generator piping system 24 by pre-heating the intake air flowing into the electric generating mechanism 22 . Once the heat from the exhaust air is transferred to the intake air, the cooled air is exhausted from an exhaust pipe 30 a of the recuperator 30 .
  • the preferred system 10 also includes the combustion chamber 32 in communication with the generator piping system 24 and upstream of airflow relative to the electric generating mechanism 22 .
  • the combustion chamber 32 is configured to preheat the pressurized air flowing to the electric generating mechanism 22 .
  • the combustion chamber 32 is preferably positioned between the recuperator 30 and the electric generating mechanism 22 such that the pressurized air flowing into the combustion chamber 32 is preheated by the recuperator 30 prior to entering the combustion chamber 32 .
  • the combustion chamber 32 is a natural gas fueled combustion chamber 32 that heats the intake gas flowing out of the recuperator 30 before the pressurized and heated gas flows into and through the electric generating mechanism 22 .
  • the combustion chamber 32 is not limited to being natural gas fueled and may be comprised of nearly any variety of combustion chamber 32 that is fueled by nearly any variety of fuel for combustion, as would be apparent to one having ordinary skill in the art based upon the present disclosure.
  • the air compressor 16 of the preferred embodiment includes a compressor 34 and a motor 36 .
  • the motor 36 is preferably powered by off-peak electricity from the conventional power grid 20 or the alternate energy generator 18 , such as a solar farm, wind farm, hydroelectric power, biofuel facilities, and like alternative energy generators 18 .
  • a water cooling tower 38 is preferably associated with the compressor 34 to cool the compressor 34 during operation, but is not limiting and the compressor 34 may operate without the water cooling tower 38 without significantly impacting the operation of the preferred multiple cavern energy system 10 .
  • the electric generating mechanism 22 of the preferred embodiment includes a generator 40 , a low-pressure turbine 42 , a high-pressure turbine 44 and the natural gas-fueled combustion chamber 32 .
  • the heated, pressurized intake air from the recuperator 30 preferably flows into the combustion chamber 32 for further heating, through the high-pressure turbine 44 to generate electricity and through the low-pressure turbine 42 to generate additional energy by driving the generator 40 .
  • the energy from the generator 40 preferably flows into the conventional power grid 20 for use by consumers.
  • the electric generating mechanism 22 is not limited to the inclusion of both the high-pressure and low-pressure turbines 44 , 42 and may include a single turbine (not shown) or an alternative mechanism to drive the generator 40 .
  • the combustion chamber 32 is also not limited to the preferred natural gas-fueled combustion chamber 32 and may comprise nearly any component that is able to heat the pressurized air to drive the electric generating mechanism 22 and generate electricity with the generator 40 .
  • the preferred multiple cavern energy system 10 also includes the fourth storage cavern or vessel 46 .
  • the fourth storage cavern or vessel 46 is preferably in fluid communication with the air compressor 34 through the compressor piping system 25 and with the electric generating mechanism 22 through the generator piping system 24 , respectively.
  • the fourth storage cavern or vessel 46 may be mounted at or above ground and preferably operates as a fail-safe vessel if the caverns 12 , 14 , 28 are being improved or maintained to provide a limited amount of pressurized air to temporarily run the system 10 .
  • the fourth storage cavern or vessel 46 is also preferably located on the same site or at the same facility as the air compressor 16 and the electric generating mechanism 22 to provide quick response to electric grid 20 demands and to limit air pressure losses in the compressor piping system 25 and the generator piping system 24 .
  • the system 10 is not limited to having a specific number of storage caverns 12 , 14 , 28 and/or vessels 46 and may operate with a single source of pressurized air, be it stored in one of the caverns 12 , 14 , 28 , the vessel 46 or in another storage mechanism.
  • the storage caverns 12 , 14 , 28 and/or vessels 46 may be located at a site or facility distances from the air compressor 16 and the electric generating mechanism 22 .
  • the alternative energy generator 18 of the preferred embodiment may include a solar power farm, a wind power farm, a hydroelectric dam, a hydroelectric generator, a biofuel facility or other like alternative energy sources.
  • the alternative energy generator 18 is preferably utilized to power the compressor 16 to pressurize air for storage and later use or for use when electric grid 20 draw is at its peak.
  • the controller 26 is utilized to control the air compressor 34 , the electric generating mechanism 22 and the systems for controlling the generator and compressor piping systems 24 , 25 .
  • the controller 26 directs the air compressor 34 to compress air using off-peak electricity or alternatively generated electricity from the power grid 20 and preferably directs the electric generating mechanism 22 to generate electricity utilizing the compressed air during peak electricity usage time periods.
  • the system 10 of the preferred embodiment is capable of operating such that the air compressor 34 provides compressed air to the first cavern 12 and the electric generating mechanism 22 generates electricity using compressed air from the second cavern 14 at the same time.
  • the controller 26 may actuate the compressor 16 to operate utilizing power from the off-peak electric grid 20 and/or the alternative energy generator 18 , the compressor valve 16 a, the first cavern inlet valve 13 a, the second cavern outlet valve 15 b and the generator valve 22 b are actuated to the open position and the first cavern outlet valve 13 b and the second cavern inlet valve 15 a are actuated to the closed position to generate electricity using the electric generating mechanism 22 using pressurized air from the second storage cavern 14 and to load pressurized air into the first storage cavern 12 at the same time.
  • the third and fourth cavern inlet valves 29 a, 47 a and the third and fourth cavern outlet valves 29 b, 47 b are actuated to the closed position by the controller 26 , but are not so limited.
  • the third and fourth cavern inlet valves 29 a, 47 a may each or individually be actuated to the open position such that the pressure in each of the first, third and fourth storage caverns 12 , 28 46 are maintained at the same pressure while the pressurized air from the second storage cavern 14 is utilized to generate electricity.
  • This arrangement is not meant to be limiting and the preferred system 10 may be otherwise operated and controlled by the controller 26 to store pressurized air and generate electricity, as would be understood by one having ordinary skill in the art based on a review of the present disclosure.
  • the electric generating mechanism 22 of the preferred embodiment is capable of producing at least two hundred Megawatts (200 MW) of power and, in a more preferably is capable of producing at least eight hundred Megawatts (800 MW) of power.
  • the preferred energy system 10 also preferably includes first, second, third and fourth cavern pressure sensors 50 a, 50 b, 50 c, 50 d positioned within the first, second, third and fourth storage caverns or vessels 12 , 14 , 28 , 46 that are in communication with the controller 26 .
  • the cavern pressure sensors 50 a, 50 b, 50 c, 50 d provide air pressure readings to the controller 26 such that the controller 26 is able to efficiently control the preferred system 10 for producing electric power.
  • the controller 26 may direct pressurized air from the air compressor 16 to the first cavern 12 if a pressure reading from the first cavern pressure sensor 50 a indicated the air pressure in the first cavern 12 is lower than the air pressure in any of the other caverns 14 , 28 , 46 .
  • the controller 26 may actuate each of the second cavern inlet valve 15 a , the third cavern inlet valve 29 a and the fourth cavern or vessel inlet valve 47 a to the open position such that each of the second, third and fourth caverns or vessels 14 , 28 , 46 receive pressurized air from the air compressor 16 to equalize the pressure in the second, third and fourth caverns or vessels 14 , 28 , 46 for storage and later use.
  • the second, third and fourth cavern pressure sensors 50 b, 50 c , 50 d should concurrently provide readings to the controller 26 indicating the second, third and fourth caverns or vessels 14 , 28 , 46 have the same or a similar air pressure therein.
  • the controller 26 may also be in communication with additional pressure sensors, such as pressure sensors in the compressor piping system 25 , the generator piping system 24 , the exhaust piping system 48 or other locations in the system 10 to provide checks and control parameters for the controller 26 .
  • the controller 26 may be in communication with additional sensors (not shown), such as temperature sensors in the air compressor 61 , the caverns 12 , 14 , 28 , 26 , the electric generating mechanism 22 , the recuperator 30 , generally at the site to monitor ambient conditions and otherwise to provide further control parameters to the controller 26 .
  • the controller 26 is also preferably in communication with the electric grid 20 to monitor electric demand, draw and other related parameters that permit the controller 26 to react to conditions of the electric grid 20 when operating and controlling the preferred system 10 .
  • the system 10 may further include an exit valve 52 and an exhaust valve 54 associated with the exhaust piping system 48 .
  • the exit valve 52 is preferably positioned downstream of the recuperator 30 and upstream of the exhaust or exit pipe 30 a to control flow of the exhaust from the preferred system 10 .
  • the exit valve 52 may also operate as a flow restriction to efficiently operate the recuperator 30 by controlling the flow of exhaust air through the recuperator 30 to maximize the heat transfer between the exhaust air in the exhaust piping system 48 in the recuperator 30 and the intake air in the generator piping system 24 in the recuperator 30 .
  • the exhaust valve 54 is preferably similarly utilized to control the flow of exhaust air flow into the recuperator 30 .
  • the exit valve 52 and the exhaust valve 54 are preferably in communication with and under the control of the controller 26 for actuation to and between open and closed positions.
  • the controller 26 may further be in communication with flow sensors in the compressor, generator and exhaust piping systems 25 , 24 , 48 to monitor and control the flow of pressurized air and exhaust through the system 10 .
  • the controller 26 is not limited to being in communication with the pressure sensors 50 a, 50 b, 50 c, 50 d, the temperature sensors and/or the flow sensors, but these sensors are preferred to provide control parameters to the controller 26 , such that the controller 26 is able to operate the preferred system 10 in an efficient manner.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Filling Or Discharging Of Gas Storage Vessels (AREA)

Abstract

An energy system for storing pressurized air and utilizing the pressurized air to generate electricity includes a first storage cavern, a second storage cavern, an air compressor in fluid communication with the first and second storage caverns, an electric generating mechanism, a combustion chamber, a controller and a recuperator. The air compressor is in fluid communication with a compressor piping system, the electric generating mechanism and the combustion chamber are in fluid communication with a generator piping system and the recuperator is in fluid communication with an exhaust piping system and the generator piping system. The controller is configured to operate the energy system such that the compressor directs compressed air into the first storage cavern through the compressor piping system at the same time the electric generating mechanism generates electricity utilizing at least compressed air from the second cavern.

Description

    CROSS-REFERENCE TO RELATED APPLICATIONS
  • The present application claims the benefit of U.S. Provisional Patent Application No. 61/621,232, filed on Apr. 6, 2012 and titled “Multiple Cavern Compressed Air Energy Storage System and Method” the entire contents of which are incorporated herein by reference in its entirety.
  • BACKGROUND OF THE INVENTION
  • Compressed Air Energy Storage (CAES) involves the storage of compressed air, typically in a large volume, for use at another time. CAES systems typically utilize off-peak (low-cost) electrical power to compress air, the compressed air is stored in a storage vessel and the stored, compressed air is used at a later time to generate electricity during peak (high-price) electric usage times. CAES systems have been utilized to power various mechanism.
  • The CAES system may store the compressed air in a relatively large volume vessel, potentially an underground cavern, for later use of the compressed air to generate electricity. These CAES systems generally utilize a single cavern to store the compressed air and later draw the compressed air from the single cavern to generate electricity. These single cavern systems suffer from a limited volume of compressed air storage space, the inability to introduce compressed air into the cavern and withdraw compressed air from the cavern at the same time, shutdown of the system for malfunctions with the cavern or maintenance on the cavern and its related hardware or similar limitations resulting from the single cavern design. A further consequence of the single-cavern design is that the conversion process (energy to compressed air, or compressed air to energy) is unidirectional. The two functions cannot be performed at the same time, thus limiting the utility of the system for storage, generation and grid-balancing.
  • In addition, CAES systems that may include multiple air storage mechanisms or vessels often have a high pressure vessel and a low pressure vessel that are connected in series to each other. This arrangement also results in the inability to pressurize one of the vessels at the same time as air from a second vessel is utilized to generate electricity. These multiple cavern conventional CAES systems limit the ability to operate a compressor utilizing alternatively generated electricity from, for example, solar panels on a hot sunny day in the summer, to compress air and store the air in a vessel, while at the same time using previously pressurized and stored air from a second vessel to drive a generator and produce power. Peak performance for certain alternatively energy generators may coincide with peak power requirements of an electrical system and a CAES system that does not permit storing energy at the same time as previously stored energy is utilized to address peak power needs is disadvantageous.
  • The preferred multiple cavern or vessel CAES system addresses the limitations of the previous CAES systems by employing an efficient overall system for producing power utilizing stored air pressure from underground caverns.
  • BRIEF SUMMARY OF THE INVENTION
  • Briefly stated, in a preferred embodiment, an energy system for storing compressed air and utilizing the compressed air to generate electricity includes a first storage cavern and a second storage cavern. The second storage cavern is separate from the first storage cavern. An air compressor is in fluid communication with the first and second storage caverns. The air compressor is driven by electricity from an alternative energy generator or off-peak electrical energy to provide pressurized air to the first and second caverns. An electric generating mechanism is in fluid communication with the first and second storage caverns. The electric generating mechanism generates electricity utilizing the compressed air from the first and/or second cavern(s), typically during peak electric usage periods.
  • In another aspect, a preferred energy system is utilized for storing pressurized air and using the pressurized air to generate electricity. The energy system includes a first storage cavern and a second storage cavern separate from the first storage cavern. An air compressor is in fluid communication with the first and second storage caverns through a compressor piping system. The air compressor is configured to provide pressurized air to the first and second caverns through the compressor piping system. An electric generating mechanism is in fluid communication with the first and second storage caverns through a generator piping system. The compressor piping system is separate from the generator piping system. A combustion chamber is in fluid communication with the generator piping system and is located upstream of airflow relative to the electric generating mechanism. The combustion chamber is configured to preheat the pressurized air flowing to the electric generating mechanism. A controller is in communication with the air compressor, the electric generating mechanism, the compressor piping system and the generator piping system. The controller is configured to operate the energy system such that the compressor directs compressed air into the first storage cavern through the compressor piping system at the same time the electric generating mechanism generates electricity utilizing at least compressed air from the second cavern. A recuperator is in fluid communication with the electric generating mechanism through an exhaust piping system. The exhaust piping system includes an exhaust and is separate from the generator piping system and the compressor piping system. The recuperator is configured to transfer heat energy from exhaust air of the electric generating mechanism to the generator piping system.
  • BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
  • The foregoing summary, as well as the following detailed description of the invention, will be better understood when read in conjunction with the appended drawing. For the purpose of illustrating the invention, there is shown in the drawing an embodiment which is presently preferred. It should be understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown. In the drawings:
  • FIG. 1 is a perspective, partial cross-sectional view of a multiple cavern compressed air energy storage system in accordance with a preferred embodiment of the present application; and
  • FIG. 2 is a block diagram of the multiple cavern compressed air energy storage system of FIG. 1.
  • DETAILED DESCRIPTION OF THE INVENTION
  • Certain terminology is used in the following description for convenience only and is not limiting. Unless specifically set forth herein, the terms “a”, “an” and “the” are not limited to one element but instead should be read as meaning “at least one”. The words “right,” “left,” “lower,” and “upper” designate directions in the drawing to which reference may be made. The words “inwardly” or “distally” and “outwardly” or “proximally” may refer to directions toward and away from, respectively, the geometric center or orientation of the device and related parts thereof. The terminology includes the above-listed words, derivatives thereof and words of similar import.
  • Referring to FIGS. 1 and 2, the present application is directed to an energy system, generally designated 10, for storing pressurized air to generate electricity. The energy system includes a first storage cavern 12 for storing the compressed air and a second storage cavern 14 separate from the first storage cavern 12. The second storage cavern 14 is also used for storing compressed air. An air compressor 16 is in fluid communication with the first and second storage caverns 12, 14. The air compressor 16 is preferably driven by electricity from an alternative energy generator 18 or off-peak electrical energy, preferably from a conventional power grid 20, to provide pressurized air to the first and second caverns 12, 14.
  • An electric generating mechanism 22 is also in fluid communication with the first and second storage caverns 12, 14. The electric generating mechanism 22 is preferably in fluid communication with the first and second storage caverns 12, 14 through a generator piping system 24. The generator piping system 24 preferably includes several control valves 13 b, 15 b, which will be described in greater detail below, to selectively open and/or close flow of pressurized air from the first and second storage caverns 12, 14 to the electric generating mechanism 22. In addition, the air compressor 16 is preferably in fluid communication with the first and second storage caverns 12, 14 through a compressor piping system 25. The compressor piping system 25 also preferably includes control valves 13 a, 15 a, which will be described in greater detail below, to selectively open and/or close the flow of pressurized air from the air compressor 16 to the first and second storage caverns 12, 14. The compressor piping system 25 is preferably separate from the generator piping system 24 such that the flow of pressurized air from the air compressor 16 and to the electric generating mechanism 22 can proceed independently of each other.
  • A controller 26 is preferably utilized to control the preferred system 10, including the various valves 13 a, 13 b, 15 a, 15 b, to operate the various components, including controlling flow of pressurized air to the electric generating mechanism 22 and from the air compressor 16 to and from the first and second storage caverns 12, 14, respectively. The electric generating mechanism 22 generates electricity utilizing at least the compressed air from the first cavern 12 and/or the second cavern 14. The controller 26 preferably controls the generation of pressurized air and electricity such that air is pressurized during off-peak times and electricity is generated during peak usage hours from the compressed or pressurized air that was pressurized during off-peak electric usage times or by the alternate energy generators 18. Through this type of control, profits and efficiency can me maximized by storing energy while operating expenses are low and producing energy while demand is high. Profits and efficiency can also be maximized by producing energy with the alternative energy generator 18 when the alternative energy if available for production, regardless of whether demand on the electric grid 20 is high or low.
  • The controller 26 is in communication with the air compressor 16, the electric generating mechanism 22, the compressor piping system 25, and the generator piping system 24. The controller 26 is configured to operate the energy system 10 such that the compressor directs compressed air into the first storage cavern 12 through the compressor piping system 25 at the same time the electric generator mechanism 22 generates electricity utilizing at least compressed air from the second cavern 14. The preferred controller 26 is able to constantly generate compressed air using the compressor 16, which is preferably driven by off-peak electricity from the electric grid 20 or alternatively generated electricity from an alternative energy generator 18, and at the same time produce electricity utilizing the electric generating mechanism 22, which is driven at least partially by compressed air from the storage caverns 12, 14. The controller 26 may also individually operate the compressor 16 to produce pressurized air for introduction into the caverns 12, 14, such as during off-peak electric utilization on the electric grid 20 or when the alternative electric generator 18 is operating, while at the same time the electrical generating mechanism 22 is shut down and not producing electricity. In addition, during high electric grid 20 utilization or peak hours and when the alternative electric generator 18 is not producing power, the controller 22 is able to produce power from the compressed air stored in the caverns 12, 14 when the air compressor 16 is not operating.
  • In the preferred embodiment, the system 10 also includes a third storage cavern 28. The first, second and third storage caverns 12, 14, 28 are preferably comprised of underground caverns that are generally air tight for a reasonable amount of time and relatively large such that a significant volume of compressed air may be stored in the caverns 12, 14, 28 without excessive loss of air pressure due to leakage from the caverns 12, 14, 28. The third storage cavern 28 is preferably in fluid communication with the air compressor 16 through the compressor piping system 25 and the electric generating mechanism 22 through the generator piping system 24. The system 10 is not limited to the inclusion of the first, second and third caverns 12, 14, 28 or to these caverns being underground caverns 12, 14, 28. The system 10 may alternatively include above-ground pressurized air storage, such as a fourth storage cavern or vessel 46, which is described in greater detail below, or alternative underground pressure vessels (not shown) for storing the pressurized air, including many more storage caverns than those shown in the appended figures. In addition, the system 10 is not limited to inclusion of the first, second and third storage caverns 12, 14, 28 and may include only the first storage cavern 12 and/or second storage cavern 14 for storage of the pressurized air and operation of the preferred system 10.
  • The preferred energy system 10 also includes a compressor valve 16 a, a first cavern inlet valve 13 a, a second cavern inlet valve 15 a, a third cavern inlet valve 29 a, a fourth cavern or vessel inlet valve 47 a, a generator valve 22 b, a first cavern outlet valve 13 b, a second cavern outlet valve 15 b, a third cavern outlet valve 29 b and a fourth cavern or vessel outlet valve 47 b. The controller 26 is preferably able to control the opening and closing of the valves 16 a, 13 a, 15 a, 29 a, 47 a, 22 b, 13 b, 15 b, 29 b, 47 b to efficiently operate the system 10. The first, second, third and fourth cavern inlet valves 13 a, 15 a, 29 a, 47 a and the compressor valve 16 a are associated with the compressor piping system 25 and the first, second, third and fourth cavern outlet valves 23 b, 15 b, 29 b, 47 b and the generator valve 22 b are associated with the generator piping system 24. The energy system 10 is not limited to inclusion of each of the preferred valves 16 a, 13 a, 15 a, 29 a, 47 a, 22 b, 13 b, 15 b, 29 b, 47 b and may include more or less valves associated with the compressor, generator and/or exhaust piping systems 25, 24, 48. The compressor valve 16 a and the first, second, third and fourth cavern inlet valves 13 a, 15 a, 29 a, 47 a are preferably opened by the controller 26 to allow pressurized air to selectively flow into the first, second, third and fourth caverns or vessels 12, 14, 28, 46, respectively. Likewise, the generator valve 22 b and/or the first, second, third and fourth cavern outlet valves 13 b, 15 b, 29 b, 47 b are preferably opened by the controller 26 to selectively allow pressurized air to flow from the first, second, third and/or fourth caverns or vessel 12, 14, 28, 46 into the electrical generator mechanism 22 to generate electricity.
  • The creation, modification, improvement and/or use of the multiple subsurface storage caverns 12, 14, 28 and the vessel 46 is preferred, as this design allows for a degree of operational flexibility that is preferred over existing power generation resources. The multiple subsurface storage caverns 12, 14, 28 and the vessel 46 enable the simultaneous depletion and filling of the various storage caverns 12, 14, 28 and the vessel 46 with pressurized air in a single facility or system 10. This, in turn, enables the preferred system 10 to respond to the electric energy market in both real-time and day ahead scenarios and operational conditions. In addition, the utilization of the underground storage caverns 12, 14, 28 and the vessel 46 utilizes the storage capacity of the caverns 12, 14, 28 and the vessel 46 to promote relatively safe storage of a large volume of pressurized air. The storage caverns 12, 14, 28 and the vessel 46 are preferably located on the same site or parcel of property as the air compressor 16, the electric generating mechanism 22, a combustion chamber 32 and a recuperator 30, which are each components of the preferred energy system 10. Maintaining the underground storage caverns 12, 14, 28 and/or the vessel 46 on the same site promotes efficient utilization of the system 10 by limiting pressure losses in the piping systems 24, 25 and facilitating quick production of electrical energy with the electric generating mechanism 22. Close proximity or positioning of the underground storage caverns 12, 14, 28 and/or the vessel 46 beneath or immediately adjacent relative to the electric generating mechanism 22 promotes quick response in providing pressurized air to the electric generating mechanism 22. Quickly providing pressurized air to the electric generating mechanism 22 permits the preferred system 10 to promptly address fluctuations in draw on the electric grid 20, by quickly providing supplemental power to the electric grid 20 during peak demand or spikes in demand. In the preferred system, at least portions of the preferred underground storage caverns 12, 14, 28 are positioned directly beneath or below the site or facility that houses the electric generating mechanism 22 and the air compressor 16.
  • The flexibility and responsiveness of the preferred system 10 that utilizes the multiple storage caverns 12, 14, 28 and the vessel 46 also makes it possible for a facility to simultaneously act as both a controllable load and a generation resource. Accordingly, the preferred system 10 can provide an array of power products, including ancillary services, as well as peaking, intermediate and base load energy. The preferred system 10 is also flexible in that air pressure may be loaded into the caverns 12, 14, 28 and the vessel 46 independently or at the same time as the pressurized air in others of the caverns 12, 14, 28 and the vessel 46 is utilized to generate electricity with the generator 22.
  • The preferred energy system 10 also includes the recuperator 30 positioned between the storage caverns 12, 14, 28 and the vessel 46 and the electric generating mechanism 22 in the generator piping system 24. The recuperator 30 is also in fluid communication with the electric generating mechanism 22 through an exhaust piping system 48 on the exhaust side of the electric generating mechanism 22. The exhaust piping system 48 is separate from the generator piping system 24 and the compressor piping system 25. The recuperator 30 preferably transfers heat energy from exhaust air of the electric generating mechanism 22 that is flowing through the exhaust piping system 48 to intake air from the storage caverns 12, 14, 28 in the generator piping system 24 that is entering the electric generating mechanism 22. The recuperator 30 improves the efficiency of the system by recycling the heat in the exhaust air flowing through the exhaust piping system 48 back into the air flowing through the generator piping system 24 by pre-heating the intake air flowing into the electric generating mechanism 22. Once the heat from the exhaust air is transferred to the intake air, the cooled air is exhausted from an exhaust pipe 30 a of the recuperator 30.
  • The preferred system 10 also includes the combustion chamber 32 in communication with the generator piping system 24 and upstream of airflow relative to the electric generating mechanism 22. The combustion chamber 32 is configured to preheat the pressurized air flowing to the electric generating mechanism 22. The combustion chamber 32 is preferably positioned between the recuperator 30 and the electric generating mechanism 22 such that the pressurized air flowing into the combustion chamber 32 is preheated by the recuperator 30 prior to entering the combustion chamber 32. In the preferred embodiment, the combustion chamber 32 is a natural gas fueled combustion chamber 32 that heats the intake gas flowing out of the recuperator 30 before the pressurized and heated gas flows into and through the electric generating mechanism 22. The combustion chamber 32 is not limited to being natural gas fueled and may be comprised of nearly any variety of combustion chamber 32 that is fueled by nearly any variety of fuel for combustion, as would be apparent to one having ordinary skill in the art based upon the present disclosure.
  • The air compressor 16 of the preferred embodiment includes a compressor 34 and a motor 36. The motor 36 is preferably powered by off-peak electricity from the conventional power grid 20 or the alternate energy generator 18, such as a solar farm, wind farm, hydroelectric power, biofuel facilities, and like alternative energy generators 18. A water cooling tower 38 is preferably associated with the compressor 34 to cool the compressor 34 during operation, but is not limiting and the compressor 34 may operate without the water cooling tower 38 without significantly impacting the operation of the preferred multiple cavern energy system 10.
  • The electric generating mechanism 22 of the preferred embodiment includes a generator 40, a low-pressure turbine 42, a high-pressure turbine 44 and the natural gas-fueled combustion chamber 32. The heated, pressurized intake air from the recuperator 30 preferably flows into the combustion chamber 32 for further heating, through the high-pressure turbine 44 to generate electricity and through the low-pressure turbine 42 to generate additional energy by driving the generator 40. The energy from the generator 40 preferably flows into the conventional power grid 20 for use by consumers. The electric generating mechanism 22 is not limited to the inclusion of both the high-pressure and low- pressure turbines 44, 42 and may include a single turbine (not shown) or an alternative mechanism to drive the generator 40. The combustion chamber 32 is also not limited to the preferred natural gas-fueled combustion chamber 32 and may comprise nearly any component that is able to heat the pressurized air to drive the electric generating mechanism 22 and generate electricity with the generator 40.
  • The preferred multiple cavern energy system 10 also includes the fourth storage cavern or vessel 46. The fourth storage cavern or vessel 46 is preferably in fluid communication with the air compressor 34 through the compressor piping system 25 and with the electric generating mechanism 22 through the generator piping system 24, respectively. The fourth storage cavern or vessel 46 may be mounted at or above ground and preferably operates as a fail-safe vessel if the caverns 12, 14, 28 are being improved or maintained to provide a limited amount of pressurized air to temporarily run the system 10. The fourth storage cavern or vessel 46 is also preferably located on the same site or at the same facility as the air compressor 16 and the electric generating mechanism 22 to provide quick response to electric grid 20 demands and to limit air pressure losses in the compressor piping system 25 and the generator piping system 24. However, the system 10 is not limited to having a specific number of storage caverns 12, 14, 28 and/or vessels 46 and may operate with a single source of pressurized air, be it stored in one of the caverns 12, 14, 28, the vessel 46 or in another storage mechanism. In addition, the storage caverns 12, 14, 28 and/or vessels 46 may be located at a site or facility distances from the air compressor 16 and the electric generating mechanism 22.
  • The alternative energy generator 18 of the preferred embodiment may include a solar power farm, a wind power farm, a hydroelectric dam, a hydroelectric generator, a biofuel facility or other like alternative energy sources. The alternative energy generator 18 is preferably utilized to power the compressor 16 to pressurize air for storage and later use or for use when electric grid 20 draw is at its peak.
  • In the preferred embodiment, the controller 26 is utilized to control the air compressor 34, the electric generating mechanism 22 and the systems for controlling the generator and compressor piping systems 24, 25. The controller 26 directs the air compressor 34 to compress air using off-peak electricity or alternatively generated electricity from the power grid 20 and preferably directs the electric generating mechanism 22 to generate electricity utilizing the compressed air during peak electricity usage time periods. The system 10 of the preferred embodiment is capable of operating such that the air compressor 34 provides compressed air to the first cavern 12 and the electric generating mechanism 22 generates electricity using compressed air from the second cavern 14 at the same time. For example, the controller 26 may actuate the compressor 16 to operate utilizing power from the off-peak electric grid 20 and/or the alternative energy generator 18, the compressor valve 16 a, the first cavern inlet valve 13 a, the second cavern outlet valve 15 b and the generator valve 22 b are actuated to the open position and the first cavern outlet valve 13 b and the second cavern inlet valve 15 a are actuated to the closed position to generate electricity using the electric generating mechanism 22 using pressurized air from the second storage cavern 14 and to load pressurized air into the first storage cavern 12 at the same time. In this preferred example, the third and fourth cavern inlet valves 29 a, 47 a and the third and fourth cavern outlet valves 29 b, 47 b are actuated to the closed position by the controller 26, but are not so limited. For example, the third and fourth cavern inlet valves 29 a, 47 a may each or individually be actuated to the open position such that the pressure in each of the first, third and fourth storage caverns 12, 28 46 are maintained at the same pressure while the pressurized air from the second storage cavern 14 is utilized to generate electricity. This arrangement is not meant to be limiting and the preferred system 10 may be otherwise operated and controlled by the controller 26 to store pressurized air and generate electricity, as would be understood by one having ordinary skill in the art based on a review of the present disclosure.
  • The electric generating mechanism 22 of the preferred embodiment is capable of producing at least two hundred Megawatts (200 MW) of power and, in a more preferably is capable of producing at least eight hundred Megawatts (800 MW) of power.
  • The preferred energy system 10 also preferably includes first, second, third and fourth cavern pressure sensors 50 a, 50 b, 50 c, 50 d positioned within the first, second, third and fourth storage caverns or vessels 12, 14, 28, 46 that are in communication with the controller 26. The cavern pressure sensors 50 a, 50 b, 50 c, 50 d provide air pressure readings to the controller 26 such that the controller 26 is able to efficiently control the preferred system 10 for producing electric power. For example, the controller 26 may direct pressurized air from the air compressor 16 to the first cavern 12 if a pressure reading from the first cavern pressure sensor 50 a indicated the air pressure in the first cavern 12 is lower than the air pressure in any of the other caverns 14, 28, 46. Alternatively, if the a first cavern outlet valve 13 b is actuated to the open position such that pressurized air from the first underground cavern 12 is flowing to the electric generating mechanism 22 to generate electricity, the controller 26 may actuate each of the second cavern inlet valve 15 a, the third cavern inlet valve 29 a and the fourth cavern or vessel inlet valve 47 a to the open position such that each of the second, third and fourth caverns or vessels 14, 28, 46 receive pressurized air from the air compressor 16 to equalize the pressure in the second, third and fourth caverns or vessels 14, 28, 46 for storage and later use. The second, third and fourth cavern pressure sensors 50 b, 50 c, 50 d should concurrently provide readings to the controller 26 indicating the second, third and fourth caverns or vessels 14, 28, 46 have the same or a similar air pressure therein.
  • The controller 26 may also be in communication with additional pressure sensors, such as pressure sensors in the compressor piping system 25, the generator piping system 24, the exhaust piping system 48 or other locations in the system 10 to provide checks and control parameters for the controller 26. In addition, the controller 26 may be in communication with additional sensors (not shown), such as temperature sensors in the air compressor 61, the caverns 12, 14, 28, 26, the electric generating mechanism 22, the recuperator 30, generally at the site to monitor ambient conditions and otherwise to provide further control parameters to the controller 26. The controller 26 is also preferably in communication with the electric grid 20 to monitor electric demand, draw and other related parameters that permit the controller 26 to react to conditions of the electric grid 20 when operating and controlling the preferred system 10.
  • The system 10 may further include an exit valve 52 and an exhaust valve 54 associated with the exhaust piping system 48. The exit valve 52 is preferably positioned downstream of the recuperator 30 and upstream of the exhaust or exit pipe 30 a to control flow of the exhaust from the preferred system 10. The exit valve 52 may also operate as a flow restriction to efficiently operate the recuperator 30 by controlling the flow of exhaust air through the recuperator 30 to maximize the heat transfer between the exhaust air in the exhaust piping system 48 in the recuperator 30 and the intake air in the generator piping system 24 in the recuperator 30. the exhaust valve 54 is preferably similarly utilized to control the flow of exhaust air flow into the recuperator 30. The exit valve 52 and the exhaust valve 54 are preferably in communication with and under the control of the controller 26 for actuation to and between open and closed positions.
  • The controller 26 may further be in communication with flow sensors in the compressor, generator and exhaust piping systems 25, 24, 48 to monitor and control the flow of pressurized air and exhaust through the system 10. The controller 26 is not limited to being in communication with the pressure sensors 50 a, 50 b, 50 c, 50 d, the temperature sensors and/or the flow sensors, but these sensors are preferred to provide control parameters to the controller 26, such that the controller 26 is able to operate the preferred system 10 in an efficient manner.
  • It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. It is understood, therefore, that this invention is not limited to the particular embodiments disclosed, but it is intended to cover modifications within the spirit and scope of the present invention as defined by the present disclosure.

Claims (5)

1. An energy system for storing pressurized air and utilizing the pressurized air to generate electricity, the energy system comprising:
a first storage cavern;
a second storage cavern separate from the first storage cavern;
an air compressor in fluid communication with the first and second storage caverns through a compressor piping system, the air compressor configured to provide pressurized air to the first and second caverns through the compressor piping system;
an electric generating mechanism in fluid communication with the first and second storage caverns through a generator piping system, the compressor piping system being separate from the generator piping system;
a combustion chamber in fluid communication with the generator piping system and upstream of airflow relative to the electric generating mechanism, the combustion chamber configured to preheat the pressurized air flowing to the electric generating mechanism;
a controller in communication with the air compressor, the electric generating mechanism, the compressor piping system and the generator piping system, the controller configured to operate the energy system such that the air compressor directs compressed air into the first storage cavern through the compressor piping system at the same time the electric generating mechanism generates electricity utilizing at least compressed air from the second cavern; and
a recuperator in fluid communication with the electric generating mechanism through an exhaust piping system, the exhaust piping system including an exhaust and being separate from the generator piping system and the compressor piping system, the recuperator configured to transfer heat energy from exhaust air of the electric generating mechanism to the generator piping system.
2. The energy system of claim 1 wherein the air compressor is powered by one of an alternative energy generator and off-peak electrical energy from a power grid.
3. The energy system of claim 1, further comprising:
a third storage cavern being in fluid communication with the air compressor through the compressor piping system and the electric generating mechanism through the generator piping system.
4. The energy system of claim 1, wherein the compressor piping system includes a compressor valve, a first cavern inlet valve and a second cavern inlet valve, the generator piping system including a generator valve, a first cavern outlet valve and a second cavern outlet valve, the controller configured to actuate the air compressor, the first cavern inlet, the second cavern outlet and the generator valves to an open position and the first cavern outlet and the second cavern inlet valves to a closed position when the air compressor directs compressed air into the first storage cavern at the same time the electric generating mechanism generates electricity utilizing at least the compressed air from the second cavern.
5. The energy system of claim 1, further comprising:
a storage vessel in fluid communication with the compressor piping system, the storage vessel mounted at a ground level.
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20160130986A1 (en) * 2014-11-03 2016-05-12 Board Of Regents, The University Of Texas System Power conditioning and energy storage device using hydraulic-pneumatic sequentially fired pulse forming networks
EP3115603A1 (en) * 2015-07-10 2017-01-11 Eichner, Dominik Device and method for the production of electrical current
US10208666B2 (en) 2015-02-04 2019-02-19 Paul H. F. Merswolke Compressed air energy system
US11644210B1 (en) * 2021-12-31 2023-05-09 Kepler Energy Systems, Inc. Power shift system to store and distribute energy with direct compressor drive

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP6456236B2 (en) 2015-05-11 2019-01-23 株式会社神戸製鋼所 Compressed air storage generator
IL269163B (en) 2019-09-08 2020-05-31 Augwind Ltd System for energy storage and electrical power generation
US11532949B2 (en) 2019-09-08 2022-12-20 Augwind Ltd. System for energy storage and electrical power generation

Family Cites Families (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2433896A (en) * 1943-04-16 1948-01-06 Frazer W Gay Means for storing fluids for power generation
US4353214A (en) * 1978-11-24 1982-10-12 Gardner James H Energy storage system for electric utility plant
US4237692A (en) * 1979-02-28 1980-12-09 The United States Of America As Represented By The United States Department Of Energy Air ejector augmented compressed air energy storage system
US5845479A (en) * 1998-01-20 1998-12-08 Electric Power Research Institute, Inc. Method for providing emergency reserve power using storage techniques for electrical systems applications
DE102006035273B4 (en) * 2006-07-31 2010-03-04 Siegfried Dr. Westmeier Process for effective and low-emission operation of power plants, as well as for energy storage and energy conversion
US7877999B2 (en) * 2007-04-13 2011-02-01 Cool Energy, Inc. Power generation and space conditioning using a thermodynamic engine driven through environmental heating and cooling

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20160130986A1 (en) * 2014-11-03 2016-05-12 Board Of Regents, The University Of Texas System Power conditioning and energy storage device using hydraulic-pneumatic sequentially fired pulse forming networks
US10208666B2 (en) 2015-02-04 2019-02-19 Paul H. F. Merswolke Compressed air energy system
US10557411B2 (en) 2015-02-04 2020-02-11 Paul H. F. Merswolke Compressed air energy system
EP3115603A1 (en) * 2015-07-10 2017-01-11 Eichner, Dominik Device and method for the production of electrical current
US11644210B1 (en) * 2021-12-31 2023-05-09 Kepler Energy Systems, Inc. Power shift system to store and distribute energy with direct compressor drive

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