The first prototypes of the hydrogen-powered vehicles are now being tested on European roads.

The first prototypes of the hydrogen-powered vehicles are now being tested on European roads.

Photo: BMW

The BMW Group is beginning to test near-standard vehicles with a hydrogen fuel cell drive train in everyday conditions on European roads. Prototypes of the BMW i Hydrogen NEXT will examine how effectively the CO2-free drive train, model-specific chassis technology, and vehicle electronics systems work together under real-life conditions. The BMW i Hydrogen NEXT is a pure electric vehicle that uses hydrogen as fuel by converting it into electricity in a fuel cell. The recently launched testing program will pave the way for the BMW Group to present a small-series model with this sustainable drive technology, developed on the basis of the BMW X5, in late 2022. Extensive field testing of these vehicles will provide practical experience in the use of this sustainable drive technology.

Hydrogen fuel cell technology has the long-term potential to supplement internal combustion engines, plug-in hybrid systems, and battery-electric vehicles within the BMW Group’s flexible drive train strategy. It could become an attractive alternative to battery-electric drive trains – especially for customers who do not have their own access to electric charging infrastructure or who frequently drive long distances.

Like the fuel tank of a conventional combustion-engine model, the hydrogen tank of the BMW i Hydrogen NEXT can also be filled within three to four minutes.

Field testing focused on efficiency, safety, convenience, reliability – and driving pleasure

A central element of the BMW i Hydrogen NEXT road tests now underway is fine-tuning the software that controls all driving and operating functions. The fuel cell system, hydrogen tanks, performance buffer battery, and central vehicle control unit have all previously been tested individually and together in hundreds of test runs conducted on test benches. This functional testing is now being followed with field testing on the roads. The intensive program, which is conducted under everyday conditions and real traffic situations, helps development engineers validate the efficiency, safety, convenience, and reliability of all components. At the same time, the test series is designed to ensure the characteristic driving pleasure of BMW models – even with locally emission-free mobility using pioneering hydrogen fuel cell technology.

The BMW i Hydrogen NEXT uses fuel cells from the product development cooperation with the Toyota Motor Corporation. The individual cells come from Toyota, while the fuel cell stack and complete drive system are original BMW Group developments. The cooperation established in 2013 seeks to optimise the everyday practicality and scalability of hydrogen fuel cell technology for use in each company’s respective production vehicles through the intensive exchange of experience.

Typical BMW driving dynamics delivered by electric drive train with system output of 275 kW/374 hp

The complete drive system in the BMW i Hydrogen NEXT combines hydrogen fuel cell technology with fifth-generation BMW eDrive technology – which can already be experienced in the BMW iX3 and soon the BMW iX and BMW i4, as well. Energy is generated in the fuel cell as the result of a chemical reaction between the hydrogen carried by the vehicle and oxygen from the air. This delivers an electrical output of 125 kW/170 hp. An electric converter located below the fuel cell adjusts its voltage to that of the electric motor, which powers the BMW i Hydrogen NEXT.

Energy stored in a performance buffer battery is also used for dynamic acceleration manoeuvres and short bursts of speed for overtaking. As a result, the system delivers an output of 275 kW/374 hp that corresponds exactly to that of the most powerful six-cylinder in-line petrol engine currently used in BMW models.

The energy stored in the performance buffer battery is generated in an efficient way during driving by recovering energy from coasting overrun and braking phases. The hydrogen needed to supply the fuel cell is stored in two 700-bar tanks made of carbon-fibre reinforced plastic (CFRP), which together hold six kilograms of hydrogen. Its precisely controlled reaction with oxygen in the fuel cell generates electricity, while water vapor is the only emission produced by the drive train.

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