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http://dx.doi.org/10.7316/KHNES.2018.29.1.11

Research of High Efficiency Integrated Reforming System Using Separated Reforming System  

PARK, SANG-HYOUN (Grad. School of Mechanical Engineering, Dongguk University)
KIM, CHUL-MIN (Grad. School of Mechanical Engineering, Dongguk University)
SON, SUNG-HYO (Korea Gas Corporation)
JANG, SE-JIN (Korea Gas Corporation)
KIM, JAE-DONG (Korea Gas Corporation)
BANG, WAN-KEUN (CHP tech lnc.)
LEE, SANG-YONG (Grad. School of Mechanical Engineering, Dongguk University)
Publication Information
Transactions of the Korean hydrogen and new energy society / v.29, no.1, 2018 , pp. 11-18 More about this Journal
Abstract
A high efficiency integrated reforming system for improving the efficiency of the 5 kW PEMFC system used as the back up power of building was studied. The separated reforming system consisted of three parts - A steam reformer with two stage concentric circular shape, a heat exchanger type steam generator and a CO shift reactor. Temperature and steam carbon ratio (SCR) were control variables during operation. The operating conditions were optimized based on the thermal efficiency of the steam reformer as reformate gas composition changes at different temperature. In experiments, water was fully vaporized in the steam generator up to SCR 3.5 and the maximum thermal efficiency was achieved at the operating temperature around $700^{\circ}C$ in the steam reforming reactor. With the results of the separated reforming system research, we improved the shape of high efficiency integrated reformer. The performance evaluation of the integrated reformer was based on optimized operating conditions in SCR 3.5. As a result, the developed integrated reforming system maintained an efficiency of 76% and constant performance over 3,000 hours.
Keywords
Reformer; Fuel processor; PEMFC; Residential fuel cell; Fuel cell;
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