This study is based on numerical method to simulate a laminar flow accessing a regular electric field while flowing between parallel plates at a regular velocity of flow, and analyze the instability of it, which in this case was affected by the electric field. The mathematical model in this study simply includes two electrode plates which produce electric field and fluid between parallel plates. As for the electric field, it is a field of electronics accessing perpendicularly with the flow of the fluid. We suppose the accessing fluid was the electrolyte aqueous solution which shall be affected by the electric field; therefore it will produce the conductivity gradient at a fixed velocity of the flow while accessed by the electric field. This theoretical analysis is very close to reality while considering the rate of diffusion caused by Brownian motion of flow particle and the displacement velocity of the flow charged particle caused by the electric field. Now we shall discuss the relation between the Re. number, electric field, and conductivity gradient by switching all different kind of conditions on operations. As a result, the stability of the value of Re. number remains unchanged in terms of the analysis of the longitudinal wave number, so all the analyses stay the same as that of the static flow; the instability of the flowing field occurs while Sc=10^4 as long as the conductivity gradient value changes or Re. number value changes on condition of Q(Q is used for showing the necessary electric field ) is less than a value of10^5. In terms of the analysis of the transverse wave number, the result shows that if we change the value of Re., Sc., and the conductivity gradient, in some cases, the instability phenomenon of transverse mode would occur first, and the instability phenomenon of longitudinal mode will occur later.