Process for evaluating corrosion resistance of coating

What is claimed is: 1. A process for evaluating corrosion resistance of an anode coating applied over a surface of an anode and corrosion resistance of a cathode coating applied over a surface of a cathode comprising: (i) sealably positioning said anode in an anode holder located on a chamber of a corrosion resistance evaluator, said chamber containing an electrolyte therein such that a portion of said anode coating is exposed to said electrolyte, said portion of said anode coating having an anode defect thereon; (ii) sealably positioning said cathode in a cathode holder located on said chamber such that a portion of said cathode coating is exposed to said electrolyte, said portion of said cathode coating having a cathode defect thereon; (iii) directing a computer of said evaluator through computer readable program code means residing on a usable storage medium located in said computer and configured to cause said computer to perform following steps comprising: a) subjecting said portions of said anode coating and said cathode coating to a start-up period; b) directing an impedance measurement device in communication with said computer and is connected to said cathode and said anode to measure an impedance A across the cathode and anode during said start-up period at preset intervals to produce n1 set of said impedances A measured at preset frequencies ranging from 100000 to 10 −6 Hz of AC power with an amplitude ranging from 10 to 50 mV supplied by an alternating current variable power generator in communication with said computer, said alternating current variable power generator having AC output leads that connect to said cathode and anode; c) generating A impedance Nyquist plot for each said impedance A in said n1 set; d) determining start-up solution resistances ( Sta R sol.n1 ) by: 1. measuring a distance between zero point on X-axis of said A impedance Nyquist plot and a point on said X-axis of said A impedance Nyquist plot where an impedance curve or an extrapolated impedance curve directed to high start-up solution frequencies in said A impedance Nyquist plot intersects said X-axis to obtain real part of said impedance A at said high start-up solution frequencies; and 2. repeating said step (d) (1) for each said impedance A in said n1 set; e) determining start-up resistances ( Sta R Sta.n1 ) by: 1. measuring a distance between zero point on X-axis of said A impedance Nyquist plot and a point on said X-axis of said A impedance Nyquist plot where an impedance curve or an extrapolated impedance curve directed to low start-up resistance frequencies in said A impedance Nyquist plot intersects said X-axis to obtain real part of said impedance A at said low start-up resistance frequencies; and 2. repeating said step (e) (1) for each said impedance A in said n1 set; f) directing a direct current variable power generator to apply V1 preset DC voltages in a stepwise manner for T1 preset durations, wherein said direct current measurement device in communication with said computer and connected to said cathode and said anode is used to measure said preset DC voltages and wherein said V1 preset DC voltage ranges from 0.1 millivolts to 10 volts and said T1 preset duration ranges from half an hour to 100 hours; g) directing said impedance measurement device to measure an impedance B at the end of each of said preset duration at said preset frequencies of AC power supplied by said alternating current variable power generator to produce n2 set of said impedances B; h) generating B impedance Nyquist plot for each said impedance B in said n2 set; i) determining stepped-up solution resistances ( Stp R sol.n2 ) by: 1. measuring a distance between zero point on X-axis of said B impedance Nyquist plot and a point on said X-axis of said B impedance Nyquist plot where an impedance curve or an extrapolated impedance curve directed to high stepped-up solution frequencies in said B impedance Nyquist plot intersects said X-axis to obtain real part of said impedance B at said high stepped-up solution frequencies; 2. repeating said step (i) (1) for each said impedance B in said n2 set; j) determining stepped-up resistances ( Stp R Stp.n2 ) by: 1. measuring a distance between zero point on X-axis of said B impedance Nyquist plot and a point on said X-axis of said B impedance Nyquist plot where an impedance curve or an extrapolated impedance curve directed to low stepped-up resistance frequencies in said B impedance Nyquist plot intersects said X-axis to obtain real part of said impedance B at said low stepped-up resistance frequencies; and 2. repeating said step (j) (1) for each said impedance B in said n2 set; k) subjecting said portions of said anode coating and said cathode coating to T2 preset recovery periods in between each of said T1 preset durations; l) directing said impedance measurement device to measure an impedance C at the end of each of said T2 preset recovery periods at said preset frequencies of AC power supplied by said alternating current variable power generator to produce n3 set of said impedances C; m) generating C impedance Nyquist plot for each said impedance C in said n3 set; n) determining recovery solution resistances ( Rec R sol.n3 ) by: 1. measuring a distance between zero point on X-axis of said C impedance Nyquist plot and a point on said X-axis of said C impedance Nyquist plot where an impedance curve or an extrapolated impedance curve directed to high recovery solution frequencies in said C impedance Nyquist plot intersects said X-axis to obtain real part of said impedance C at said high recovery solution frequencies; 2. repeating said step (n) (1) for each said impedance C in said n3 set; o) determining recovery resistances ( Rec R Rec.n3 ) by 1. measuring a distance between zero point on X-axis of said C impedance Nyquist plot and a point on said X-axis of said C impedance Nyquist plot where an impedance curve or an extrapolated impedance curve directed to low recovery resistance frequencies in said C impedance Nyquist plot intersects said X-axis to obtain real part of said impedance C at said low recovery resistance frequencies; and 2. repeating said step (o) (1) for each said impedance C in said n3 set; p) calculating corrosion performance resistance (R perf ) of said anode and said cathode pair by using the following equation: R perf =[Σ Sta f n1 )( Sta R Sta.n1 − Sta R Sol.n1 )]/ n 1+[Σ Stp f n2 ( Stp R Stp.n2 − Stp R Sol.n2 )]/ n 2+[Σ Rec f n3 ( Rec R Rec.n3 − Rec R Sol.n3 )]/ n 3, wherein n1, n2, and n3 are constant values that range from 1 to 100; and Sta f n1 , Stp f n2 , and Rec f n3 are constant values that range from 0.0000001 to 1, and wherein the constant value for n1, n2, and n3 is the number of values that are summed for each summation; and q) causing computer to direct a computer monitor to: (q1) display the corrosion performance resistance (R perf ), (q2) direct a printer to print the corrosion performance resistance (R perf ), (q3) transfer the corrosion performance resistance (R perf ) to a remote computer or a remote database, or (q4) a combination thereof. 2. The process of claim 1 wherein said cathode and said anode are made of steel. 3. The process of claim 1 wherein said anode coating and said cathode coating results from a multilayer coating composition comprising an automotive OEM paint, an automotive refinish paint, a marine paint, an aircraft paint, an architectural paint, an industrial paint, a rubberized coating, a polytetrafluoroethylene coating, or a zinc-rich primer. 4. The process of claim 1 wherein said chamber is surrounded by a thermal jacket to maintain temperature of said electrolyte at a desired temperature ranging from 0.5° C. to 99.5° C. 5. The process of cl