Polygeneration microgrids: A viable solution in remote areas for supplying power, potable water and hydrogen as transportation fuel

This paper presents the concept and the design of a hybrid renewable energy polygeneration microgrid along with its technical and economical evaluation. The energy of the sun and the wind is harvested by photovoltaics and a wind turbine. Besides that, the components of the microgrid include a battery bank, a Proton Exchange Membrane (PEM) fuel cell, a PEM electrolyzer, a metal hydride tank, a reverse osmosis desalination unit using energy recovery and a control system. The microgrid covers the electricity, transport and water needs and thus its products are power, hydrogen as transportation fuel and potable water through desalination. Hydrogen and the desalinated water also act as medium to long term seasonal storage. A design tool based on TRNSYS 16, GenOpt 2.0 and TRNOPT was developed using Particle Swarm Optimization method. The economic evaluation of the concept was based on the discounting cash flow approach. The Monte Carlo Simulation method was used in order to take uncertainty into account. A technically feasible polygeneration microgrid adapted to a small island is financially profitable with a probability of 90% for the present and 100% at the medium term.

► Polygeneration of power, hydrogen and potable water through desalination in remote areas. ► Particle Swarm Optimization for the design of Polygeneration microgrid design with TRNSYS, GenOpt and TRNOPT. ► Economic evaluation with Monte Carlo simulation for the calculation of NPV distribution. ► Polygeneration microgrids are technically feasible and most likely financially profitable.