After four years of development work, the BMW iX5 Hydrogen vehicle and development project has entered its critical next phase. The BMW Group is providing international media representatives with the first vehicles in a pilot fleet that will go into service this year, paving the way for potential series production.
The German carmaker began production of its first ever Sports Activity Vehicle (SAV) featuring hydrogen fuel cell technology in December 2022. The fleet of under 100 vehicles will then be employed internationally for demonstration and trial purposes for various target groups. This active driving experience will therefore be the first chance for people not involved in the development process to gain a direct impression of what the BMW iX5 Hydrogen has to offer.
“Hydrogen is a versatile energy source that has a key role to play in the energy transition process and therefore in climate protection. After all, it is one of the most efficient ways of storing and transporting renewable energies,” said Oliver Zipse, Chairman of the Board of Management of BMW. “We should use this potential to also accelerate the transformation of the mobility sector. Hydrogen is the missing piece in the jigsaw when it comes to emission-free mobility. One technology on its own will not be enough to enable climate-neutral mobility worldwide.”
iX5 Hydrogen
The BMW iX5 Hydrogen, developed on the basis of the current BMW X5, was first unveiled as a concept at the IAA Show in 2019. Initial prototypes were then made available at the IAA Mobility 2021 for visitors to experience in action as shuttle vehicles.
Its hydrogen fuel cell system is further proof of the BMW Group’s leading development expertise in the field of electric drive technologies. The BMW Group produces the highly efficient fuel cell systems for the pilot fleet at its in-house competence centre for hydrogen in Munich. This technology is one of the core elements in the iX5 Hydrogen and generates a high continuous output of 125 kW/170 hp.
A chemical reaction takes place in the fuel cell between gaseous hydrogen from the tanks and oxygen from the air. Maintaining a steady supply of both elements to the fuel cell’s membrane is of crucial importance for the drive system’s efficiency. In addition to the technological equivalents of features found on combustion engines, such as charge air coolers, air filters, control units and sensors, the BMW Group also developed special hydrogen components for its new fuel cell system. These include the high-speed compressor with turbine and high-voltage coolant pump, for instance.
The BMW Group sources the individual fuel cells from the Toyota Motor Corporation. The two companies have enjoyed a partnership characterised by trust for many years and have been collaborating on fuel cell drive systems since 2013.
Fuel cell systems are manufactured in two main steps, based on the individual fuel cells. The cells are first assembled into a fuel cell stack. The next step involves fitting all the other components to produce a complete fuel cell system.
Stacking of the fuel cells is largely a fully automated process. Once the individual components have been inspected for any damage, the stack is compressed by machine with a force of five tonnes and placed in a housing. The stack housing is manufactured in the light metal foundry at BMW Group Plant Landshut using a sandcasting technique.
For this, molten aluminium is poured into a mould made from compacted sand mixed with resin in a process specially designed for this small-series vehicle.
The pressure plate, which delivers hydrogen and oxygen to the fuel cell stack, is made from cast plastic parts and light-alloy castings, also from the Landshut plant. The pressure plate forms a gas-tight and water-tight seal around the stack housing.
Final assembly of the fuel cell stacks includes a voltage test along with extensive testing of the chemical reaction within the cells. Finally, all the different components are fitted together in the assembly area to produce the complete system.
During this system assembly stage, further components are fitted, such as the compressor, the anode and cathode of the fuel-cell system, the high-voltage coolant pump and the wiring harness.
In combination with a highly integrated drive unit using fifth-generation BMW eDrive technology (the electric motor, transmission and power electronics are grouped together in a compact housing) at the rear axle and a power battery with lithium-ion technology developed specially for this vehicle, the powertrain channels maximum output of 295kW / 401 hp onto the road. In coasting overrun and braking phases, the motor also serves as a generator, feeding energy back into a power battery.
Production at Munich pilot plant
The BMW iX5 Hydrogen is being built in the BMW Group’s pilot plant at its Research and Innovation Centre (FIZ) in Munich. This is the interface between development and production where every new model from the company’s brands is made for the first time. Around 900 people work there in the body shop, assembly, model engineering, concept vehicle construction and additive manufacturing.
They are tasked with ensuring that both the product and the manufacturing process are ready for series production. In the case of the BMW iX5 Hydrogen, specialists in hydrogen technology, vehicle development and initial assembly of new models have been working closely together to integrate the cutting-edge drive and energy storage technology.
Hydrogen allows rapid re-fuelling
The hydrogen needed to supply the fuel cell is stored in two 700-bar tanks made of carbon-fibre reinforced plastic (CFRP). Together these hold almost six kilograms of hydrogen, enough to give the BMW iX5 Hydrogen a range of 504 km (313 miles) in the WLTP cycle. Filling up the hydrogen tanks only takes three to four minutes – so the BMW iX5 Hydrogen can also provide the driving pleasure for which BMW is renowned over long distances, with just a few, short stops along the way.
BMW iX5 Hydrogen Fast Facts
Maximum output of overall drive system: 295 kW/401 hp
Electric continuous output of the fuel-cell system: 125 kW/170 hp
Maximum output of the battery (lithium-ion technology): 170 kW/231 hp
Maximum output of the highly integrated electric drive unit: 295 kW/401 hp
Capacity of the hydrogen tanks: 6 kg hydrogen (gaseous)
Acceleration 0-100kph (62mph) < 6 sec
Top speed: Over 180kph (112mph)
Hydrogen consumption in the WLTP cycle: 1.19 kg/100 km
Range in the WLTP cycle: 504 km (313 miles)