[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5516/NET.03.2011.051

THE PREDICTION OF pH BY GIBBS FREE ENERGY MINIMIZATION IN THE SUMP SOLUTION UNDER LOCA CONDITION OF PWR

Yoon, Hyoungju (Department of Nuclear Engineering, University of Kyunghee)

Publication Information

Nuclear Engineering and Technology / v.45, no.1, 2013 , pp. 107-114 More about this Journal

Abstract

It is required that the pH of the sump solution should be above 7.0 to retain iodine in a liquid phase and be within the material compatibility constraints under LOCA condition of PWR. The pH of the sump solution can be determined by conventional chemical equilibrium constants or by the minimization of Gibbs free energy. The latter method developed as a computer code called SOLGASMIX-PV is more convenient than the former since various chemical components can be easily treated under LOCA conditions. In this study, SOLGASMIX-PV code was modified to accommodate the acidic and basic materials produced by radiolysis reactions and to calculate the pH of the sump solution. When the computed pH was compared with measured by the ORNL experiment to verify the reliability of the modified code, the error between two values was within 0.3 pH. Finally, two cases of calculation were performed for the SKN 3&4 and UCN 1&2. As results, pH of the sump solution for the SKN 3&4 was between 7.02 and 7.45, and for the UCN 1&2 plant between 8.07 and 9.41. Furthermore, it was found that the radiolysis reactions have insignificant effects on pH because the relative concentrations of HCl, $HNO_3$ , and Cs are very low.

Keywords

Sump; pH; Gibbs Free Energy; Chemical Equilibrium; Boric Acid; TSP; Radiolysis;

Citations & Related Records

Reference

1	U.S. Nuclear Regulatory Commission, Standard Review Plan 6.5.2. Rev.4 "Containment Spray as a Fission Product Cleanup System," NUREG-0800 (2007).
2	T. M. Besmann, "SOLGASMIX-PV, a Computer Program to Calculate Equilibrium Relationships in Complex Chemical Systems," ORNL/TM-5775, Oak Ridge National Laboratory (1986).
3	A. K. Convington, R. G. Bates, and R. A. Durst, "Definition of pH Scales, Standard Reference Values, Measurement of pH and Related Terminology," Pure & Appl. Chem., 57, 3, p. 534 (1985).
4	E. C. Beahm, R. A. Lorenz, and C. F. Weber, "Iodine Evolution and pH Control," NUREG/CR-5950 and ORNL/ TM-12242, Oak Ridge National Laboratory (1992).
5	E. C. Beahm, C. F. Weber, and T. S. Kress, "Iodine Chemical Forms in LWR Severe Accidents," NUREG/CR-5732 and ORNL/TM-11861, Oak Ridge National Laboratory (1991).
6	A. G. Croff, "ORIGEN2: A Versatile Computer Code for Calculating the Nuclide Compositions and Characteristics of Nuclear Materials," Nuclear Technology, 62, p. 335-352 (1983).
7	KHNP, "ShinKori Units 3 & 4 : Preliminary Safety Analysis Report," chapter 6, Korea Hydro & Nuclear Power Co., Ltd.
8	KEPCO, "Korea Nuclear Units 9 & 10 : Final Safety Analysis Report," chapter 6, Korea Electric Power Corporation.
9	E. E. Lewis, Nuclear Power Reactor Safety, 1st ed., p. 518 -521, John Wiley & Sons, Inc. (1977).
10	Malcolm W. Chase, Jr., "NIST-JANAF Thermochemical Tables, Fourth Edition, Part I. Al-Co," Journal of Physical and Chemical Reference Data, Monograph No. 9 (1998).
11	Malcolm W. Chase, Jr., "NIST-JANAF Thermochemical Tables, Fourth Edition, Part II. Cr-Zr," Journal of Physical and Chemical Reference Data, Monograph No. 9 (1998).