Transient Analysis of a Solid Oxide Fuel Cell/ Gas Turbine Hybrid System for Distributed Electric Propulsion

Chakravarthula, Venkata Adithya

January 2016

No description available.

Aerospace Engineering

Mechanical Engineering

SOFC

Hybrid Systems

SOFC-GT

Internal Steam reformer

Ersätta APU:n med SOFC-GT Hybridsystem inom luftfarten

Sarwari, Javid, Heidari, Abbas

January 2018

The current Auxiliary Power Unit (APU) contributes a lot to the greenhouse effect in terms of emissions, and in the form of noise and also is very heavy. The need for more electricity has increased in aircrafts and therefore major aircraft suppliers like Boeing and Airbus want to switch to more electric aircraft (MEA) which is lighter and has less environmental impacts. The purpose of this work is to investigate the possibilities of replacing today's traditional APU with fuel cells. In this work presents six different common fuel cell types which used commercially in various areas in the market. We have also analyzed and investigated the most suitable fuel cell types and have chosen to apply the SOFC-GT Hybrid Systems. We have investigated and compared both systems with pros and cons. We have used different methods in this work including the FOI3-method and Safran & Honeywell for calculations of emissions for all systems. Finally, we have analyzed and investigated the emissions, noise and weight for both systems. / Nuvarande Auxiliary Power Unit (APU) bidrar mycket negativt till växthuseffekten i form av emissionsutsläpp och även i form av buller och är dessutom mycket tunga. Behovet av mer elektricitet ökar i flygplan och därför vill stora flygplanstillverkare såsom Boeing och Airbus övergå till more electric aircraft (MEA) vilket är lättare och har mindre miljöpåverkan. Syftet med detta arbete är att undersöka möjligheterna av att ersätta dagens traditionella APU mot bränsleceller. I detta arbete presenteras sex olika bränslecellstyper som finns på marknaden och används kommersiellt inom olika områden. Vi har analyserat och undersökt de lämpligaste bränslecellstyper för applicering och därefter har vi valt att implementera SOFC- GT Hybridsystemen. Vi har undersökt och jämfört båda systemens för- och nackdelar. Metodmässigt används bland annat FOI3-Metoden och Safran & Honeywell för beräkningar av utsläpp av emissioner för samtliga system. Slutligen har vi analyserat och undersökt skillnader i utsläpp av emissioner, buller och vikt för båda systemen.

SOFC

SOFC-GT Hybridsystem

Auxiliary Power Unit (APU)

Fuel Cells

Aircraft

Aviation.

Bränsleceller

Emissioner

Växthuseffekten

Ersätta APU:n

Klimat

Civila luftfarten

Hybridsystem.

Aerospace Engineering

Rymd- och flygteknik

A hardware-based transient characterization of electrochemical start-up in an SOFC/gas turbine hybrid environment using a 1-D real time SOFC model

Hughes, Dimitri O.

08 July 2011

Solid oxide fuel cell/gas turbine (SOFC/GT) hybrid systems harness the capability to operate nearly 15 to 20 percentage points more efficiently than standard natural gas or pulverized coal power plants. Though the performance of these systems is quite promising, a number of system integration challenges, primarily with regards to thermal transport, still remain. It is for that reason that the Hybrid Performance Project (HyPer) facility, a Hardware-in-the-Loop SOFC/GT hybrid simulator, was built at the National Energy Technology Laboratory in Morgantown, WV. The HyPer facility couples an actual gas turbine with a combination of hardware and software that are used to simulate an actual SOFC. The facility is used to empirically address the system integration issues associated with fuel cell/gas turbine hybrids. Through this dissertation project, the software component of the SOFC simulator was upgraded from a 0-D lumped SOFC model to a 1-D, distributed, real-time operating SOFC model capable of spatio-temporal characterization of a fuel cell operating with a gas turbine in a hybrid arrangement. Once completed and verified, the upgraded HyPer facility was used to characterize the impact of cold air by-pass and initial fuel cell load on electrochemical start-up in an SOFC/GT hybrid environment. The impact of start-up on fuel cell inlet process parameters, SOFC performance and SOFC distributed behavior are presented and analyzed in comparative manner. This study represents the first time that an empirical parametric study, characterizing system operation during electrochemical start-up has been conducted.

Real-time model

Electrochemical start-up

Distributed model

Transient characterization

Start-up

Hybrid systems

Gas turbines

SOFC/GT hybrid

SOFC

Solid oxide fuel cells

Gas-turbines

Gas-turbine power-plants