The purpose of this study is to investigate the transient response analysis of high pressure steam pipeline system. The mathematical model contain three governing equations, included continuity equation, momentum equation and energy equation. With these three governing equations, we can get flow rate, pressure and temperature. There are two types of mathematical analysis method, one is explicit method and the other is implicit method. For explicit method can use smaller time step but time step is limited by stability and computation time will spend more time. For implicit method can be applied to the long-term transients due to it is stable when using large time step and will reduce computation time. Therefore, we use fully implicit method in this study. And the algorithm to solve the governing equations is based on Newton-Raphson method. Combine fully implicit method and Newton-Raphson method in our calculation loop. In the single pipe system, we simulate two types of fluid, one is compressible fluid and the other is incompressible fluid. Each system is compared with Aspen Plus simulation at steady state. We also discuss different time step and number of sections in order to make a good choice in calculation loop. In the looped steam network, the calculation loop we add modified Hardy Cross method in calculation loop to calculate flow rate distribution. In the case study, start from one special case of looped network: branch network, then we design two-looped network, multi-supply and multi-demand network and larger looped network. In these case studies, transient condition is flow rate change. With different operation, we provide the calculation results of units’ temperature and pressure change. And we hope that we can give them a way to make decision when the transient conditions happen.