Vane carrier thermal management arrangement and method for clearance control
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01D-025/26
F02C-009/16
출원번호
US-0795542
(2013-03-12)
등록번호
US-8920109
(2014-12-30)
발명자
/ 주소
Tham, Kok-Mun
Lee, Ching-Pang
Terpos, Brian H.
Simko, Dustan M.
출원인 / 주소
Siemens Aktiengesellschaft
인용정보
피인용 횟수 :
1인용 특허 :
14
초록▼
A thermal management arrangement (110) in a gas turbine engine (60), including: a conduit-arrangement (62) providing fluid communication between a compressor section (156) and: a relatively thermally responsive portion (52) of a turbine vane carrier (10); and a relatively thermally unresponsive port
A thermal management arrangement (110) in a gas turbine engine (60), including: a conduit-arrangement (62) providing fluid communication between a compressor section (156) and: a relatively thermally responsive portion (52) of a turbine vane carrier (10); and a relatively thermally unresponsive portion (48) of a first turbine vane carrier. The conduit-arrangement includes: a general cooling flow outlet (122) disposed proximate the relatively thermally responsive portion of the turbine vane carrier and configured to discharge a general cooling flow (124); and an impingement flow outlet (118) disposed proximate the relatively thermally unresponsive portion and configured to discharge an impingement flow (120). The thermal management arrangement is configured such that a flow rate of the impingement flow is effective to accelerate a thermal response of the relatively thermally unresponsive portion toward a thermal response of the relatively thermally responsive portion.
대표청구항▼
1. A thermal management arrangement in a gas turbine engine, comprising: a conduit-arrangement providing fluid communication between a compressor section and: a relatively thermally responsive portion of a turbine vane carrier; and a relatively thermally unresponsive portion of the turbine vane carr
1. A thermal management arrangement in a gas turbine engine, comprising: a conduit-arrangement providing fluid communication between a compressor section and: a relatively thermally responsive portion of a turbine vane carrier; and a relatively thermally unresponsive portion of the turbine vane carrier, the conduit-arrangement comprising: a general cooling flow outlet disposed proximate the relatively thermally responsive portion of the turbine vane carrier and configured to discharge a general cooling flow; andan impingement flow outlet disposed proximate the relatively thermally unresponsive portion and configured to discharge an impingement flow onto the relatively thermally unresponsive portion;wherein the thermal management arrangement is configured such that a flow rate of the impingement flow is effective to accelerate a thermal response of the relatively thermally unresponsive portion toward a thermal response of the relatively thermally responsive portion and wherein the turbine vane carrier comprises a discrete ring disposed within an outer casing of the gas turbine engine and comprising the relatively thermally responsive portion and the relatively thermally unresponsive portion. 2. The thermal management arrangement of claim 1, wherein the impingement flow is free of active supplemental heating and cooling. 3. The thermal management arrangement of claim 1, further comprising a turbine vane carrier flow regulation arrangement configured to actively control an impingement flow rate and a general cooling flow rate. 4. A thermal management arrangement in a gas turbine engine, comprising: a first conduit-arrangement providing fluid communication between a first compressor section and a first turbine vane carrier flange, the first conduit-arrangement comprising a first impingement flow outlet disposed proximate the first turbine vane carrier flange, anda first turbine vane carrier comprising a discrete first ring disposed within an outer casing of the gas turbine engine, the first ring comprising the first turbine vane carrier flange,wherein a first pressure in the first compressor section drives a first impingement flow of compressed air through the first conduit-arrangement and wherein the first impingement flow impinges the first turbine vane carrier flange directly after the first impingement flow exits the first impingement flow outlet. 5. The thermal management arrangement of claim 4, wherein after impinging the first turbine vane carrier flange the first impingement flow flows into a flow of hot gases flowing through a turbine comprising the first turbine vane carrier flange. 6. The thermal management arrangement of claim 4, further comprising a first turbine vane carrier flow regulation arrangement configured to control a rate of flow of the first impingement flow. 7. The thermal management arrangement of claim 4, the first conduit-arrangement further comprising a first general cooling outlet configured to deliver a first general cooling flow of compressed air to the first ring, wherein the first general cooling flow is delivered to a second portion of the first ring having a different average mass per unit arc length than a first portion of the first ring comprising the first turbine vane carrier flange, wherein the thermal management arrangement is configured such that relative flow rates of the first impingement flow and the first general cooling flow are correlated to the respective thermal responses of the first portion and the second portion. 8. The thermal management arrangement of claim 7, further comprising a first turbine vane carrier flow regulation arrangement configured to actively control the relative flow rates of the first impingement flow and the first general cooling flow. 9. The thermal management arrangement of claim 4, wherein the first impingement flow is free of active supplemental heating and cooling. 10. The thermal management arrangement of claim 4, further comprising: a second conduit-arrangement providing fluid communication between a second compressor section and a second turbine vane carrier flange, the second conduit-arrangement comprising a second impingement flow outlet disposed proximate the second turbine vane carrier flange, wherein a second pressure in the second compressor section drives a second impingement flow of compressed air through the second conduit-arrangement, wherein the second pressure is less than the first pressure, wherein the second impingement flow impinges the second turbine vane carrier flange, and wherein the second turbine vane carrier comprises a discrete second ring within the outer casing, the second ring comprising the second turbine vane carrier flange. 11. The thermal management arrangement of claim 10, the second conduit-arrangement further comprising a second general cooling outlet configured to deliver a second general cooling flow of compressed air to the second ring, wherein the second general cooling flow is delivered to a second portion of the second ring having a different average mass per unit arc length than a first portion of the second ring comprising the second turbine vane carrier flange, wherein the thermal management arrangement is configured such that relative flow rates of the second impingement flow and the second general cooling flow are correlated to the respective thermal responses of the first portion and the second portion. 12. The thermal management arrangement of claim 11, further comprising a second turbine vane carrier flow regulation arrangement configured to actively control the relative flow rates of the second impingement flow and the second general cooling flow. 13. A method of thermally managing a gas turbine engine, comprising: establishing fluid communication between a first location in a compressor and a first turbine vane carrier via a first conduit-arrangement;utilizing a greater pressure at the first location to drive a first impingement flow of compressed air from the first location to the first turbine vane carrier;impinging a first circumferential portion of the first turbine vane carrier with the first impingement flow directly after the first impingement flow exits an impingement flow outlet of the first conduit-arrangement, andcontrolling an ovalization of the first turbine vane carrier by matching a thermal response of the first circumferential portion of the first turbine vane carrier with a second thermal response of a second circumferential portion of the first turbine vane carrier, wherein the first circumferential portion and the second circumferential portion comprise a different average mass per unit arc length,wherein the first turbine vane carrier comprises a discrete ring disposed within an outer casing of the gas turbine engine, the discrete ring comprising the first circumferential portion and the second circumferential portion. 14. The method of claim 13, further comprising utilizing the greater pressure at the first location to drive a first general cooling flow of compressed air to the second circumferential portion of the first turbine vane carrier. 15. The method of claim 14, further comprising regulating independently a rate of flow of the first impingement flow and a rate of flow of the first general cooling flow, effective to control the ovalization of the first turbine vane carrier. 16. The method of claim 15, wherein the rate of flow of the first impingement flow and the rate of flow of the first general cooling flow are actively regulated. 17. The method of claim 13, further comprising guiding the first impingement flow into a flow of hot gases in a turbine comprising the first turbine vane carrier after the first impingement flow impinges the first circumferential portion of the first turbine vane carrier. 18. The method of claim 13, wherein the fluid communication occurs without active, supplemental heating or cooling of the first impingement flow. 19. The method of claim 13, further comprising heating the first circumferential portion of the first turbine vane carrier during startup of the gas turbine engine using the first impingement flow. 20. The method of claim 13, further comprising cooling the first circumferential portion of the first turbine vane carrier during shutdown of the gas turbine engine using the first impingement flow.
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