Abstract
This paper presents a dynamic study of fuel cell gas turbine (SOFC/GT) hybrid systems, focusing on the response to a drastic transient in anode fuel composition for constant turbine speed operations. This work is motivated by the potential of fuel cells for fuel flexibility, which could extend the opportunities for sustainability and profitability in energy conversion systems. A combination of hardware and numerical models in a hybrid simulator is used to investigate the transient trajectories of fuel cell process variables as well as the consequent impacts of fuel cell thermal effluent on the integrated gas turbine engine. The conversion of thermal energy stored in the fuel cell stack to chemical energy during the reforming at the beginning of the cell resulted in a 17% increase in thermal effluent from the fuel cell to the turbine in the first few seconds of the transient. Fuel cell solid temperature gradients increased by 39% at 250s from the initiation of the transient. The distributed dynamic performance of the fuel cell in terms of the fuel composition gradient, thermal, and electrochemical performance across the fuel cell length was carefully characterized, considering their interactions and their impacts on the total system performance.
Highlights
IntroductionThis paper presents a dynamic study of fuel cell gas turbine (SOFC/GT) hybrid systems, focusing on the response to a drastic transient in anode fuel composition for constant turbine speed operations
study of fuel cell gas turbine (SOFC/GT) hybrids can be used in both the power plant and polygeneration plant contexts, this study focuses on the former kind of transition because it is the more extreme of the two
Due to the absence of methane (CH4) content in the coal-derived syngas used in this study, as shown in Figure 3, the composition gradient of each gas component was primarily driven by the water-gas shift (WGS)
Summary
This paper presents a dynamic study of fuel cell gas turbine (SOFC/GT) hybrid systems, focusing on the response to a drastic transient in anode fuel composition for constant turbine speed operations. A combination of hardware and numerical models in a hybrid simulator is used to investigate the transient trajectories of fuel cell process variables as well as the consequent impacts of fuel cell thermal effluent on the integrated gas turbine engine. The conversion of thermal energy stored in the fuel cell stack to chemical energy during the reforming at the beginning of the cell resulted in a 17% increase in thermal effluent from the fuel cell to the turbine in the first few seconds of the transient. The distributed dynamic performance of the fuel cell in terms of the fuel composition gradient, thermal and electrochemical performance across the fuel cell length was carefully characterized, considering their interactions and their impacts on the total system performance
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
