Simulation of Load Cycles in Pressurized SOFC Systems and Economic Evaluation

As known from literature [1], the pressurization of SOFC systems may lead to increased efficiencies and higher power output. These benefits will have to be utilized in future power generation in order to meet the requirements of higher electrical power demand as well as the goals of lower emissions. Operating a hybrid power plant at full load only is not always an option. Small power plants have to be able to run in load-following mode in order to keep the load of the grid low. By alternating the power of the gas turbine, a hybrid power plant would only be capable of following load in a band of 100 to 80%. Therefore, load alternation of the SOFC system is crucial for the operation of a hybrid power plant. The model of an SOFC system in a hybrid power plant has been presented before [2]. In this presentation we focus on the load-following capability of the modelled SOFC system. A series of step responses in load demand was applied to the system model, giving a close insight into the systems dynamic capabilities. These step responses will be discussed in detail and rules for dynamic system operation will be developed from these simulations. These rules have to be applied in order to keep the system within safe operation boundaries. Further complete load cycle simulations will be presented based on typical household load demands showing the dynamic capability of the pressurized fuel cell system. The prospects of pressurized SOFC systems in stationary power generation will be discussed on the basis of economical considerations. The operation of the SOFC at full load operation as well as at dynamic load conditions will be considered. 1. Virkar, The effect of pressure on solid oxide fuel cell performance. 1997, Westinghouse Electric Corporation, University of Utah, Department of Material's Science and Engineering. 2. F. Leucht and K. A. Friedrich, "SOFC System Modelling in the Hybrid Power Plant Project," in Proceedings of the 6th Symposium on Fuel Cell Modelling and Experimental Validation, Bad Herrenalb (Germany) (2009)

Distinct Redox Regulation in Sub-Cellular Compartments in Response to Various Stress Conditions in Saccharomyces cerevisiae

Responses to many growth and stress conditions are assumed to act via changes to the cellular redox status. However, direct measurement of pH-adjusted redox state during growth and stress has never been carried out. Organellar redox state (E (GSH)) was measured using the fluorescent probes roGFP2 and pHluorin in Saccharomyces cerevisiae. In particular, we investigated changes in organellar redox state in response to various growth and stress conditions to better understand the relationship between redox-, oxidative- and environmental stress response systems. E (GSH) values of the cytosol, mitochondrial matrix and peroxisome were determined in exponential and stationary phase in various media. These values (−340 to −350 mV) were more reducing than previously reported. Interestingly, sub-cellular redox state remained unchanged when cells were challenged with stresses previously reported to affect redox homeostasis. Only hydrogen peroxide and heat stress significantly altered organellar redox state. Hydrogen peroxide stress altered the redox state of the glutathione disulfide/glutathione couple (GSSG, 2H(+)/2GSH) and pH. Recovery from moderate hydrogen peroxide stress was most rapid in the cytosol, followed by the mitochondrial matrix, with the peroxisome the least able to recover. Conversely, the bulk of the redox shift observed during heat stress resulted from alterations in pH and not the GSSG, 2H(+)/2GSH couple. This study presents the first direct measurement of pH-adjusted redox state in sub-cellular compartments during growth and stress conditions. Redox state is distinctly regulated in organelles and data presented challenge the notion that perturbation of redox state is central in the response to many stress conditions