2014
DOI: 10.2172/1167529
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Role of nuclear grade graphite in controlling oxidation in modular HTGRs

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Cited by 16 publications
(8 citation statements)
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“…Cu element makes the largest contribution to reduce the concentration of impurities in graphite. The HF is the best of reagent due to the lowest of total impurities which are obtained the graphite close to in low purity grades for nuclear graphite (1000 mg/kg) (Windes et al 2014). Several other elements like As, Ba, Ca, Ce, Eu Fe, Mg, Sm, and Th were also identified in the acid treatment sample but not identified in the non-treated acid sample.…”
Section: Resultsmentioning
confidence: 93%
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“…Cu element makes the largest contribution to reduce the concentration of impurities in graphite. The HF is the best of reagent due to the lowest of total impurities which are obtained the graphite close to in low purity grades for nuclear graphite (1000 mg/kg) (Windes et al 2014). Several other elements like As, Ba, Ca, Ce, Eu Fe, Mg, Sm, and Th were also identified in the acid treatment sample but not identified in the non-treated acid sample.…”
Section: Resultsmentioning
confidence: 93%
“…of impurities elements can cause an increase of the oxidation rate of carbon graphite, such as; Pb, Bi (very strong accelerators), Li, Na, K, V, Mn, Co, Cu, Ag (strong accelerators) and Mg, Al, Si, S, Ca, Ti, Cr, Fe, Ni, Zn, Sr, Zr, Mo, Ba (weak to moderate accelerators) (Maahs and Schryer 1967). High purity nuclear grade graphite requires a maximum total impurity of 300 mg/kg, and low purity grades are allowed a maximum total impurity level of 1000 mg/kg (Windes et al 2014). The other impurity elements which need to be avoided in the nuclear grade graphite are those elements having a large neutron absorption cross-section such as B, Cd, and some rare earth element (Sm, Eu, Gd, Dy, Er, Yb, Ce, Th) (Sadanandam and Sharma 2016).…”
mentioning
confidence: 99%
“…Self-sustaining combustion means that the heat of the reaction itself is sufficient to maintain the process. Although most assessments of the 1986 Chernobyl accident describe the burning of the graphite moderator as a "graphite fire," some HTGR researchers dispute this terminology and go as far as to assert that "selfsustained oxidation is physically impossible in nuclear grade graphite" (Windes et al 2014). However, other analysts are not willing to make such unequivocal conclusions, conceding that self-sustaining oxidation reactions during air ingress can occur "in extreme situations" (Morris et al 2004) or are merely "difficult to achieve" (Areva 2010).…”
Section: Other Htgr Hazardsmentioning
confidence: 99%
“…Graphite oxidation, an exothermic process, is an additional potential heat source within the core and must be considered in a D-LOFC accident. Significant air ingress is considered beyond design basis in a HTGR, and the contribution of graphite oxidation to fuel heat-up is thought to be limited by the maximum achievable flow of O 2 into the core through the postulated break [28][29][30][31][32]. For personal use only.…”
Section: Hypothetical Accident Progressionmentioning
confidence: 99%