Compressed air energy storage system having a standby warm keeping system including an electric air heater
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02C-00100
F02G-00300
출원번호
US-0336809
(2003-01-06)
발명자
/ 주소
Kelller-Sornig, Peter
Mazza, Edoardo
Seketa, Bozidar
출원인 / 주소
Alstom Technology LTD
대리인 / 주소
Burns, Doane, Swecker &
인용정보
피인용 횟수 :
63인용 특허 :
17
초록▼
A compressed air energy storage system comprises a cavern (1) for stored compressed air and a system for providing the compressed air to a power train (3, 5), this system including a recuperator (7) and a first valve arrangement (8) that controls the flow of the compressed air from the recuperator a
A compressed air energy storage system comprises a cavern (1) for stored compressed air and a system for providing the compressed air to a power train (3, 5), this system including a recuperator (7) and a first valve arrangement (8) that controls the flow of the compressed air from the recuperator and to the power train (3, 5). A system for warm-keeping of the power train (3, 5) during stand-by operation of the compressed air energy storage system comprises the recuperator (2) and/or an auxiliary electrical air heater (11) and a second valve arrangement (10, 13) for controlling the airflow for warm-keeping. The system for warm-keeping of the power train allows improved temperature control and avoids disadvantages associated with a warm-keeping system having a combustor.
대표청구항▼
1. A compressed air energy storage system, comprising:a cavern for storing compressed air, a power train comprising a rotor and one or several expansion turbines, and a system providing the power train with the compressed air from the cavern that includes a recuperator for preheating the compressed
1. A compressed air energy storage system, comprising:a cavern for storing compressed air, a power train comprising a rotor and one or several expansion turbines, and a system providing the power train with the compressed air from the cavern that includes a recuperator for preheating the compressed air and a first valve arrangement, that controls the flow of preheated air from the recuperator to the power train, and the compressed air energy storage system further comprising a system for warm-keeping of the power train during stand-by operation of the compressed air energy storage system wherein the system for warm-keeping includes the recuperator and/or an auxiliary electrical air heater, an airflow being directed to the warm-keeping system for preheating and the thus preheated airflow being directed away from the system for warm-keeping and to the power train, and the system for warm-keeping furthermore includes an additional, second valve arrangement that controls either said airflow to the system for warm-keeping or said airflow away from said system for warm-keeping and to the power train, wherein the auxiliary electrical air heater and the second valve arrangement are positioned such that they bypass the first valve arrangement that controls the admission of compressed air to the power train. 2. A compressed air energy storage system, comprising:a cavern for storing compressed air, a power train comprising a rotor and one or several expansion turbines, and a system providing the power train with the compressed air from the cavern that includes a recuperator for preheating the compressed air and a first valve arrangement, that controls the flow of preheated air from the recuperator to the power train, and the compressed air energy storage system further comprising a system for warm-keeping of the power train during stand-by operation of the compressed air energy storage system wherein the system for warm-keeping includes the recuperator and/or an auxiliary electrical air heater, an airflow being directed to the warm-keeping system for preheating and the thus preheated airflow being directed away from the system for warm-keeping and to the power train, and the system for warm-keeping furthermore includes an additional, second valve arrangement that controls either said airflow to the system for warm-keeping or said airflow away from said system for warm-keeping and to the power train, wherein the auxiliary electrical air heater is arranged such that it bypasses both the recuperator and the first valve arrangement that controls the admission of compressed air to the power train, and the second valve arrangement is arranged prior to the auxiliary electrical air heater. 3. A compressed air energy storage system, comprising:a cavern for storing compressed air, a power train comprising a rotor and one or several expansion turbines, and a system providing the power train with the compressed air from the cavern that includes a recuperator for preheating the compressed air and a first valve arrangement, that controls the flow of preheated air from the recuperator to the power train, and the compressed air energy storage system further comprising a system for warm-keeping of the power train during stand-by operation of the compressed air energy storage system wherein the system for warm-keeping includes the recuperator and/or an auxiliary electrical air heater, an airflow being directed to the warm-keeping system for preheating and the thus preheated airflow being directed away from the system for warm-keeping and to the power train, and the system for warm-keeping furthermore includes an additional, second valve arrangement that controls either said airflow to the system for warm-keeping or said airflow away from said system for warm-keeping and to the power train, wherein an auxiliary fan is arranged prior to the auxiliary electrical air heater providing the auxiliary electrical air heater with an airflow to be preheated and the second valve arrangement is positioned to control the flow of preheated air away from the auxiliary electrical air heater and to the power train. 4. The compressed air energy storage system according to claim 1, wherein the airflow away from the system for warm-keeping is directed to gland seals on the rotor of the power train or to locations in the vicinity of the gland seals.5. The compressed air energy storage system according to claim 2, wherein the airflow away from the system for warm-keeping is directed to gland seals on the rotor of the power train or to locations in the vicinity of the gland seals.6. The compressed air energy storage system according to claim 3, wherein the airflow away from the system for warm-keeping is directed to gland seals on the rotor of the power train or to locations in the vicinity of the gland seals.
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