Title: Enhancing the Flexibility of Generation of Run-Of-the-River Hydro Power Plants

Run-of-the-River Hydro Power Plants (ROR HPPs) output can be characterized as fixed and predictable output with low cost of both installation and operation. ROR HPP generation is proportional to the water flow and cannot be adjusted to provide inertia to the grid, which is critical to power systems stability. Hence ROR HPP can only participate in low profit energy markets and not in the high profit ancillary service market. With the advances in energy storage, they can help build a synthetic energy reservoir. The combined operation of ROR HPPs and energy storage are capable of both ramping and variable power output, allowing participation in the ancillary service markets. However, energy storage technologies such as supercapacitors and flywheels, which are power dense can quickly charge/discharge within a short duration. Energy dense storage technologies such as batteries can provide long duration energy injection while the maximum ramping rate is much lower than power dense energy storage. In order to provide long duration fast ramping capability, Hybrid Energy Storage Systems (HESSs) including both power and energy dense energy storage are proposed to be integrated to enable the flexible operation of ROR HPP. Power dense energy storage with quick burst of energy can assist in regulation, whereas energy dense storage can provide energy balance over larger time. In this paper, the properties of different types of energy storage including the ramping rate, affordable energy storage capacity, thermal management, etc. are analyzed. The size of each type of energy storage is determined to ensure optimal combination of HESS and ROR HPP. A generic Front End Controller (FEC) is developed and customized for ROR HPP to provide real time control and cohesive operation of multiple units. FEC serves as the interface between utility management systems and ROR HPPs to ensure their integration with the centralized controls. Using the Automatic Generation Control (AGC) signal received from grid operator, FEC optimizes the ROR HPP turbine and HESS so that the aggregated generation can satisfy the market needs. Based on the study, system operator can acquire extra inertia support for system stability, and the ROR HPP operators can enhance their revenues by participating in wider market avenues.