Nickel and sulfur speciation of residual oil fly ashes from two electric utility steam-generating units

Abstract

Representative duplicate fly ash samples were obtained from the stacks of 400- and 385-MW utility boilers (Unit A and Unit B, respectively) using a modified U.S. Environmental Protection Agency (EPA) Method 17 sampling train assembly as they burned 0.9 and 0.3 wt % S residual (No. 6 fuel) oils, respectively, during routine power plant operations. Residual oil fly ash (ROFA) samples were analyzed for Ni concentrations and speciation using inductively coupled plasma-atomic emission spectroscopy, X-ray absorption fine structure (XAFS) spectroscopy, and X-ray diffraction (XRD). ROFA deionized H2O extraction residues were also analyzed for Ni speciation using XAFS and XRD. Total Ni concentrations in the ROFAs were similar, ranging from 1.3–1.5 wt %; however, stack gas Ni concentrations in the Unit A were 0.990 μg/Nm3 compared with 0.620 μg/Nm3 for Unit B because of the greater residual oil feed rates employed at Unit A to attain higher 400-MW load conditions with a lower heating value oil. Ni speciation analysis results indicated that ROFAs from Unit A contain ∼3 wt % NiSO4 ∼ xH2O (where x is assumed to be 6 for calculation purposes) and ∼4.5 wt % of a Ni-containing spinel compound, similar in composition to (Mg, Ni)(Al, Fe)2O4. ROFAs from Unit B contain on average 2 wt % NiSO4 ∼ 6 H2O and 1.1 wt % NiO. XAFS and XRD analyses did not detect any nickel sulfide compounds, including carcinogenic nickel subsulfide (Ni3S2) (XAFS detection limit is 5% of the total Ni concentration). In addition, XAFS measurements indicated that inorganic sulfate and organic thiophene species accounted for >97% of the total S in the ROFAs. Unit A ROFAs contained much lower thiophene proportions because cyclone-separated ROFA reinjection is employed on this unit to collect and reburn the larger carbonaceous particles. © 2005 Air & Waste Management Association.