Abstract
Fuel cell gas turbine hybrid systems have achieved ultra-high efficiency and ultra-low emissions at small scales, but have yet to demonstrate effective dynamic responsiveness or base-load cost savings. Fuel cell systems and hybrid prototypes have not utilized controls to address thermal cycling during load following operation, and have thus been relegated to the less valuable base-load and peak shaving power market. Additionally, pressurized hybrid topping cycles have exhibited increased stall/surge characteristics particularly during off-design operation. This paper evaluates additional control actuators with simple control methods capable of mitigating spatial temperature variation and stall/surge risk during load following operation of hybrid fuel cell systems. The novel use of detailed, spatially resolved, physical fuel cell and turbine models in an integrated system simulation enables the development and evaluation of these additional control methods. It is shown that the hybrid system can achieve greater dynamic response over a larger operating envelope than either individual sub-system; the fuel cell or gas turbine. Results indicate that a combined feed-forward, P–I and cascade control strategy is capable of handling moderate perturbations and achieving a 2:1 (MCFC) or 4:1 (SOFC) turndown ratio while retaining >65% fuel-to-electricity efficiency, while maintaining an acceptable stack temperature profile and stall/surge margin.
Highlights
Distributed energy resources can be characterized as intermittent, base-load, or load following power generation
This paper will focus on the off-design performance, dynamic operation and control of hybrid fuel cell gas turbine technology
Analysis suggests that both molten carbonate [17] and solid oxide [18] fuel cell gas turbine (FC-GT) hybrids could be capable of dynamic load following at ultra-high efficiency with the appropriate controls to sustain stack integrity and lifespan [4,19e22]
Summary
Distributed energy resources can be characterized as intermittent, base-load, or load following power generation. Load following generators can meet building load dynamics, provide emergency or backup power, and support deployments of intermittent renewables; wind and solar. Micro-turbines operate at the distributed resource scale providing base-load power, peak reduction through manual dispatch, or backup power. In backup power or grid independent applications micro-turbines are capable of meeting rapid load dynamics, albeit with low efficiency and moderate to severe emissions penalties for part-load operating conditions [2]. To-date, stationary fuel cells have only been deployed as a distributed resource and have typically been operated as base load generators. This paper will demonstrate how fuel-cell gas turbine hybrids are capable load following over a broad operating envelope without the efficiency, emissions, or stack-life tradeoffs of either individual system
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