Renew process implementation for reactor bottom head
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G21C-017/00
G21C-013/02
G21C-013/00
출원번호
US-0606359
(2006-11-30)
등록번호
US-8705684
(2014-04-22)
발명자
/ 주소
Ortega, Frank
Pao, Hsueh-Wen Na
Offer, Henry Peter
Chan, Ahdee Quan
출원인 / 주소
General Electric Company
대리인 / 주소
Nixon & Vanderhye P.C.
인용정보
피인용 횟수 :
1인용 특허 :
8
초록▼
A surface conditioning scheduling process is used to mitigate susceptibility to crack initiation or crack growth in a boiling water nuclear reactor using a plurality of working crews. A plurality of working zones are defined in an annulus region of a reactor vessel flange, and a plurality working zo
A surface conditioning scheduling process is used to mitigate susceptibility to crack initiation or crack growth in a boiling water nuclear reactor using a plurality of working crews. A plurality of working zones are defined in an annulus region of a reactor vessel flange, and a plurality working zones are defined in a core region of the reactor vessel. One of the working crews is positioned in each of the annulus region working zones, and one of the working crews is positioned in each of the core region working zones. The working crews perform surface conditioning in areas of the reactor vessel accessible from their respective working zones such that the surface conditioning process can be completed in no more than thirty days.
대표청구항▼
1. A surface conditioning scheduling process to mitigate susceptibility to crack initiation or crack growth in a boiling water nuclear reactor or pressurized water nuclear reactor using a plurality of working crews, the process comprising: (a) defining a plurality of working zones in an annulus regi
1. A surface conditioning scheduling process to mitigate susceptibility to crack initiation or crack growth in a boiling water nuclear reactor or pressurized water nuclear reactor using a plurality of working crews, the process comprising: (a) defining a plurality of working zones in an annulus region of a reactor vessel flange;(b) assembling a circular platform on the reactor vessel flange such that the circular platform is supported on the reactor vessel flange and extends radially inward from the reactor vessel flange toward a central axis of the reactor vessel, the annulus region working zones residing on the circular platform at a level above the reactor vessel flange;(c) positioning one of the working crews in each of the annulus region working zones;(d) defining a plurality working zones in a core region of the reactor vessel;(e) positioning one of the working crews in each of the core region working zones; and(f) the working crews performing surface conditioning in areas of the reactor vessel accessible from their respective working zones such that the surface conditioning process can be completed in no more than thirty days. 2. A process according to claim 1, using at least eight working crews, wherein step (a) is practiced by defining at least four annulus region working zones, and wherein step (d) is practiced by defining at least four core region working zones. 3. A process according to claim 1, wherein the boiling water nuclear reactor includes a main bridge providing access to at least a first part of core region, the process further comprising, prior to step (e) assembling an auxiliary bridge adjacent a second part of the core region, each of the core region working zones residing on at least one of the main bridge and the auxiliary bridge. 4. A process according to claim 1, further comprising defining annulus region reactor zones including first area zones, second area zones, first leg zones, second leg zones, vert zones, and combination zones. 5. A process according to claim 4, further comprising defining core region reactor zones including stub tube zones, CRDH zones, ICMH zones, and dP/SLC zones. 6. A process according to claim 5, wherein each of the working crews in the annulus region working zones performs surface conditioning on one of the stub tube zones, the CRDH zones, the first area zones, and the second area zones. 7. A process according to claim 6, wherein at least one of the annulus region working crews additionally performs surface conditioning on a dP/SLC zone and an ICMH zone. 8. A process according to claim 7, wherein each of the working crews in the core region working zones performs surface conditioning on one of the stub tube zones, the CRDH zones, and the ICMH zones. 9. A process according to claim 8, wherein at least one of the core region working crews additionally performs surface conditioning in at least one of the first area zones, the second area zones, the first leg zones, the second leg zones, and the vert zones. 10. A surface conditioning scheduling process to mitigate susceptibility to crack initiation or crack growth due to tensile surface stresses in a boiling water nuclear reactor or pressurized water nuclear reactor using a plurality of working crews, the process comprising: assembling a circular platform on a reactor vessel flange such that the circular platform is supported on the reactor vessel flange and extends radially inward from the reactor vessel flange toward a central axis of the reactor vessel;assembling an auxiliary bridge;positioning a first plurality of working crews on the circular platform adjacent a corresponding first plurality of working zones in an annulus region of the reactor vessel flange at a level above the reactor vessel flange;positioning a second plurality of working crews on a reactor main bridge adjacent a second plurality of working zones in a core region of the reactor vessel;positioning a third plurality of working crews on the auxiliary bridge adjacent a third plurality of working zones in the core region of the reactor vessel; andthe working crews performing surface conditioning in areas of the reactor vessel accessible from at least one of the circular platform, the main bridge, and the auxiliary bridge. 11. A process according to claim 10, using eight working crews, wherein the first plurality of working crews comprises four working crews, wherein the second plurality of working crews comprises two working crews, and wherein the third plurality of working crews comprises two working crews. 12. A component surface treatment scheduling process for delivering treatment processes to component surfaces in a boiling water nuclear reactor or pressurized water nuclear reactor using a plurality of working crews, the process comprising: assembling a circular platform on a reactor vessel flange such that the circular platform is supported on the reactor vessel flange and extends radially inward from the reactor vessel flange toward a central axis of the reactor vessel;assembling an auxiliary bridge;positioning a first plurality of working crews on the circular platform adjacent a corresponding first plurality of working zones in an annulus region of the reactor vessel flange at a level above the reactor vessel flange;positioning a second plurality of working crews on a reactor main bridge adjacent a second plurality of working zones in a core region of the reactor vessel;positioning a third plurality of working crews on the auxiliary bridge adjacent a third plurality of working zones in the core region of the reactor vessel; andthe working crews performing treatment processes on component surfaces in areas of the reactor vessel accessible from at least one of the circular platform, the main bridge, and the auxiliary bridge. 13. A process according to claim 12, wherein the treatment processes include welding, coating, inspection, thermal treatment, and excavation.
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