1-20 of 169 Search Results for

boiling water reactor

Follow your search
Access your saved searches in your account

Would you like to receive an alert when new items match your search?
Close Modal
Sort by
Series: ASM Handbook
Volume: 13C
Publisher: ASM International
Published: 01 January 2006
DOI: 10.31399/asm.hb.v13c.a0004145
EISBN: 978-1-62708-184-9
... Abstract This article focuses on the environmentally assisted cracking (EAC) of structural materials in boiling water reactors (BWRs), reactor pressure vessels, core internals, and ancillary piping. It discusses the effects of water chemistry on materials degradation, mitigation approaches...
Image
Published: 30 September 2015
Fig. 1 General Electric Type 1 boiling water reactor More
Image
Published: 30 September 2015
Fig. 3 Coated drywell head cover removed for inspection in boiling water reactor plant More
Image
Published: 30 September 2015
Fig. 4 Turbine generator unit in boiling water reactor plant More
Series: ASM Handbook
Volume: 5B
Publisher: ASM International
Published: 30 September 2015
DOI: 10.31399/asm.hb.v05b.a0006035
EISBN: 978-1-62708-172-6
.... These reactors are the boiling water reactor (BWR) and pressurized water reactor (PWR). The article provides information on the loss-of-coolant accident (LOCA) identified as the design basis accident (DBA), which can rapidly de-water the core of an operating nuclear reactor. To avoid LOCA, both the BWR...
Image
Published: 15 January 2021
Fig. 45 Schematic of boiling water nuclear reactor. Red arrows identify the jet pumps located between the reactor vessel and the reactor core. Source: Ref 28 More
Image
Published: 01 January 2006
Fig. 36 Relative corrosion rates for cladding with different precipitate sizes in boiling water reactor (BWR)- and pressurized water reactor (PWR)-type environments, when tested in and out of pile. Source: Ref 173 More
Image
Published: 01 January 2006
Fig. 1 Neutron fluence effects on irradiation-assisted stress-corrosion cracking susceptibility of type 304 stainless steel in boiling water reactor (BWR) environments. PWR, pressurized water reactor; IASCC, irradiation-assisted stress-corrosion cracking; dpa, displacements per atom. Source More
Image
Published: 01 January 1997
in a boiling-water-reactor core. More
Image
Published: 01 January 2006
Fig. 15 Crack-propagation rate for nonsensitized stainless steels in simulated boiling water reactor water at 288 °C (550 °F) as a function of yield stress. Source: Ref 56 More
Image
Published: 01 January 2006
Fig. 2 Pourbaix diagram for nickel and iron at 300 °C (570 °F) showing the principal pH-potential combinations for PWR primary and secondary water, boiling water reactor (BWR), normal water chemistry (NWC), and BWR hydrogen water chemistry (HWC), and the modes of stress-corrosion cracking (SCC More
Image
Published: 01 January 1997
Fig. 47 Predicted crack depth vs. time response for defected 28 in. diameter schedule 80 recirculation piping in a given boiling-water reactor to defined changes in water purity. Also shown is the crack-depth limit that can be resolved by nondestructive testing (NDT). More
Image
Published: 01 January 2003
Fig. 17 Variation in the average crack propagation rate in sensitized type 304 stainless steel in water at 288 °C (550 °F) with oxygen content. Data are from both constant extension rate (CERT) tests, constant load, and field observations on boiling water reactor piping. IGSCC, intergranular More
Image
Published: 01 January 2006
Fig. 5 Dependence of irradiation-assisted stress-corrosion cracking on fast neutron fluence for (a) creviced control blade sheath in high conductivity boiling water reactors (BWRs) ( Ref 30 ) and (b) as measured in slow strain rate tests at 3.7×10 7 s −1 on preirradiated type 304 stainless More
Image
Published: 01 January 2006
under unirradiated conditions for type 304 stainless steel in 288 °C (550 °F) water. With the exception of the boiling water reactor (BWR) measurements, all data were obtained in controlled radiation on/off experiments ( Ref 1 ). Curves in (b) show the trends in the proton-irradiated data, where More
Image
Published: 01 January 1997
Fig. 46 Theoretical and observed intergranular stress corrosion crackdepth vs. operational-time relationships for 28 in. diameter schedule 80 type 304 stainless steel piping for two boiling-water reactors operating at different mean coolant conductivities. Note the bracketing of the maximum More
Series: ASM Handbook
Volume: 13C
Publisher: ASM International
Published: 01 January 2006
DOI: 10.31399/asm.hb.v13c.a0004223
EISBN: 978-1-62708-184-9
..., that is, boiling water reactors (BWRs) and pressurized water reactors (PWRs), is necessary. Although corrosion was considered in all plant designs, corrosion was not considered as a serious problem. The major concern was general corrosion, and it was well known at the time of LWR design and construction...
Image
Published: 01 January 2006
Fig. 10 Data for fracture mechanics specimens of type 304 stainless steel exposed in the high flux region of the core and in the recirculation line of Nine Mile Point Unit 1 Boiling Water Reactor (BWR). All specimens were precracked and wedge loaded to an initial stress-intensity factor More
Image
Published: 01 January 2006
Fig. 11 (a) Crack length versus time for type 304 stainless steel irradiated to 4 dpa in a boiling water reactor showing the elevated crack growth rates at high corrosion potential, but significant decrease in growth rate as the corrosion potential is decreased. These data are plotted as large More
Series: ASM Handbook
Volume: 13C
Publisher: ASM International
Published: 01 January 2006
DOI: 10.31399/asm.hb.v13c.a0004148
EISBN: 978-1-62708-184-9
..., one should consider: the skeleton of the assemblies (the guide tubes—also called thimble tubes—and the spacer grids) and the channel box (in boiling water reactors, or BWRs) or pressure tubes (in CANDU and RBMK as described in Table 1 ). All these components are in contact with the primary...