论文信息 - Development of a 25kW-Class PEM Fuel Cell System for the Propulsion of a Leisure Boat

Development of a 25kW-Class PEM Fuel Cell System for the Propulsion of a Leisure Boat

A 25kW-class polymer electrolyte membrane (PEM) fuel cell system has been developed for the propulsion of a leisure boat. The fuel cell system was designed to satisfy various performance requirements, such as resistance to shock, stability under rolling and pitching oscillations, and durability under salinity condition, for its marine applications. Then, the major components including a 30kW-class PEM fuel cell stack, a DC-DC converter, a seawater cooling system, secondary battery packs, and balance of plants were developed for the fuel cell system. The PEM fuel cell stack employs a unique design structure called an anodic cascade-type stack design in which the anodic cells are divided into several blocks to maximize the fuel utilization without hydrogen recirculation devices. The performance evaluation results showed that the stack generated a maximum power of 31.0kW while maintaining a higher fuel utilization of 99.5% and an electrical efficiency of 56.1%. Combining the 30-kW stack with other components, the 25kW-class fuel cell system boat was fabricated for a leisure. As a result of testing, the fuel cell system reached an electrical efficiency of 48.0% at the maximum power of 25.6kW with stable operability. In the near future, two PEM fuel cell systems will be installed in a 20-m long leisure boat to supply electrical power up to 50kW for propelling the boat and for powering the auxiliary equipments.

[1] In-Su Han,et al. Optimal Sizing of the Manifolds in a PEM Fuel Cell Stack using Three-Dimensional CFD Simulations , 2013 .

[2] Vicki P. McConnell,et al. Now, voyager? The increasing marine use of fuel cells , 2010 .

[3] R. N. Richardson,et al. Hydrogen fuel in a marine environment , 2007 .

[4] Kevin Kendall,et al. Electronic integration of fuel cell and battery system in novel hybrid vehicle , 2012 .

[5] Zhiping Luo,et al. Evaluation of self-water-removal in a dead-ended proton exchange membrane fuel cell , 2013 .

[6] A. Veziroğlu,et al. Fuel cell vehicles: State of the art with economic and environmental concerns , 2011 .

[7] Steve Barrett,et al. Marine applications of fuel cell technology , 2003 .

[8] Mario Paolone,et al. Experimental analysis of a PEM fuel cell performance at variable load with anodic exhaust management optimization , 2013 .

[9] Jongkoo Lim,et al. Effect of serpentine flow-field designs on performance of PEMFC stacks for micro-CHP systems , 2011 .

[10] Jiujun Zhang,et al. A review of water flooding issues in the proton exchange membrane fuel cell , 2008 .

[11] Shiauh-Ping Jung,et al. Flow distribution in the manifold of PEM fuel cell stack , 2007 .

[12] In-Su Han,et al. PEM fuel-cell stack design for improved fuel utilization , 2013 .

[13] Sivakumar Pasupathi,et al. Fuel cell-battery hybrid powered light electric vehicle (golf cart): Influence of fuel cell on the driving performance , 2013 .