Ricardo’s Hydrogen Fuel Cell Module Successfully Reaches Full Power
The title of this post is the same as that of this press release from Ricardo.
This is the sub-heading.
Ricardo, a global strategic, environmental, and engineering consulting company, today announces a significant milestone in clean energy innovation with its new high-powered, multi-stack hydrogen fuel cell module technology successfully reaching 393kW of net electrical power, achieved within three months development from initial start-up.
These are the first two paragraphs.
This achievement was made possible due to Ricardo’s virtual engineering toolchain, which reduces physical prototyping costs and risks, accelerates development timelines, and provides a deeper understanding of system behaviours under diverse conditions.
Initially developed as part of the Sustainable Hydrogen Powered Shipping (sHYpS) Horizon Europe project for the maritime sector, Ricardo’s multi-stack hydrogen fuel cell module is designed to deliver high energy output with zero emissions. Its modular architecture integrates multiple fuel cell stacks to provide unmatched power density, and scalability while meeting the evolving energy demands of diverse applications, such as maritime, stationary power generation, rail and off-highway.
It certainly looks like Ricardo have developed a heavy end hydrogen fuel cell, that can be applied to a range of applications, in a very short time. Now that’s what I call world class engineering.
The last paragraph of the press release indicates what is possible.
To support the adoption of hydrogen technology, Ricardo has also developed a containerised solution, able to combine multiple fuel cell modules, enabling power output to be scaled up to 3MW per container, with the DC-DC power conversion on board, all without sacrificing efficiency or durability. When scaled up to incorporate multiple fuel cell modules housed within two bespoke containers, a total net electrical plant output of 6MW can be delivered. This is sufficient to power a 50,000 tonne 1,000 passenger cruise ship through important zero-emission mission cycles.
Although, this family of fuel cells, was originally developed for maritime applications, as an example of the flexibility of the system, it would surely be applicable for replacing any diesel engine from 2 MW upwards in a large number of rail, stationary and on and off-road applications.
This picture shows one of several hundred Class 66 locomotives on UK railways.
As they have an electric transmission, the 2 MW diesel engine could be fairly easily changed for a hydrogen fuel-cell of an appropriate size.
The Anonymous Widower 