Determination of state-of-discharge of zinc-silver oxide button cells. II. Impedance measurements

The prediction of the state-of-discharge of numerous types of Zn-Ag₂O button cells from six international manufacturers has been investigated using the impedance technique over an extended frequency range. The frequency responses at various states-of-discharge are presented and it is shown that the changes in impedance which result from discharging provide several potential parameters for the state-ofdischarge prediction. The complex impedance plot of the undischarged cells usually shows a fairly welldefined semicircle at high frequencies and a straight line with a slope between 40 and 50° at low frequencies. As discharge proceeds, the diameter of the semicircle increases and the overlap between the semicircle and the low-frequency straight line increases. The most attractive method would be to determine a parameter such as a characteristic relaxation frequency in the complex impedance plot. Unfortunately, no unambiguous characteristic parameter can be extracted due to the non-ideal shape of the impedance response at high frequencies. The determination of the diameter of the high-frequency semicircle has been faced with the same difficulties. The most reliable test was found to be the determination of either the phase of the impedance, or a corrected phase^– taken from the high-frequency intercept. The proposed prediction is a go/no go indication on the basis of one- or two-frequency measurements for or,^– respectively. The selection is made at 20–40% state-of-discharge. The charge withdrawn is negligibly small and the time of the test is between 1 and 100 s depending on the type of cell. A calibration is necessary for each cell dimension and each manufacturer. Some 10–16% of the types of cells investigated could not be selected successfully, mainly because of too large a dispersion of the electrical characteristics of the cells, especially for small newly developed types, and of the similarity of the ( and values in the low and high state-of-discharge in the appropriate frequency range. The latter difficulty arises from the difference of the frequency response between the undischarged and the partly discharged cells occurring at high frequencies.This is the second of a series of papers dedicated to Professor Ernest Yeager on the ocasion of his 60th birthday.