Hydrogen internal combustion engine vehicle


A hydrogen internal combustion engine vehicle is a type of hydrogen vehicle using an internal combustion engine. Hydrogen internal combustion engine vehicles are different from hydrogen fuel cell vehicles. Instead, the hydrogen internal combustion engine is simply a modified version of the traditional gasoline-powered internal combustion engine.

History

designed in 1806 the De Rivaz engine, the first internal combustion engine, which ran on a hydrogen/oxygen mixture. Étienne Lenoir produced the Hippomobile in 1863. Paul Dieges patented in 1970 a modification to internal combustion engines which allowed a gasoline-powered engine to run on hydrogen.
Tokyo City University have been developing hydrogen internal combustion engine from 1970. They recently developed a hydrogen fueled Bus and Truck.
Mazda has developed Wankel engines that burn hydrogen. The advantage of using ICE such as wankel and piston engines is that the cost of retooling for production is much lower. Existing-technology ICE can still be used to solve those problems where fuel cells are not a viable solution as yet, for example in cold-weather applications.
Between 2005 - 2007, BMW tested a luxury car named the BMW Hydrogen 7, powered by a hydrogen ICE, which achieved 301 km/h in tests. At least two of these concepts have been manufactured.
HICE forklift trucks have been demonstrated based on converted diesel internal combustion engines with direct injection.
In the year 2000, a Shelby Cobra was converted to run on hydrogen in a project led by James W. Heffel. The hydrogen conversion was done with the aim of making a vehicle capable of beating the current land speed record for hydrogen powered vehicles. It achieved a respectable 108.16 mph, missing the world record for hydrogen powered vehicles by 0.1 mph.
Alset GmbH developed a hybrid hydrogen systems that allows vehicle to use petrol and hydrogen fuels individually or at the same time with an internal combustion engine. This technology was used with Aston Martin Rapide S during the 24 Hours Nürburgring race. The Rapide S was the first vehicle to finish the race with hydrogen technology.

Near zero emissions

The combustion of hydrogen with oxygen produces water as its only product:
In contrast, combustion of high temperature combustion fuels, such as kerosene, gasoline, or natural gas, with air can produce oxides of nitrogen, known as NOx.
Hydrogen has a wide flammability range in comparison with other fuels. As a result, it can be combusted in an internal combustion engine over a wide range of fuel-air mixtures. An advantage here is it can thus be on a lean fuel-air mixture.
Such a mixture is one in which the amount of fuel is less than the theoretical, stoichiometric or chemically ideal amount needed for combustion with a given amount of air.
Fuel economy is then greater and the combustion reaction is more complete. Also, the combustion temperature is usually lower, which reduces the amount of pollutants emitted through the exhaust.
The European emission standards measure emissions of carbon monoxide, hydrocarbon, non-methane hydrocarbons, nitrogen oxides, atmospheric particulate matter, and particle numbers.
According to a paper by L.M Das, hydrogen internal combustion generates no CO, CO2, SO2, HC or PM emissions. He describes it as "near zero emissions".
Tuning a hydrogen engine in 1976 to produce the greatest amount of emissions possible resulted in emissions comparable with consumer operated gasoline engines from 1976. More modern engines however often come equipped with exhaust gas recirculation, and this technology benefits hydrogen too in terms of NOx emissions.
Equation when ignoring EGR:

Adaptation of existing engines

The differences between a hydrogen ICE and a traditional gasoline engine include hardened valves and valve seats, stronger connecting rods, non-platinum tipped spark plugs, a higher voltage ignition coil, fuel injectors designed for a gas instead of a liquid, larger crankshaft damper, stronger head gasket material, modified intake manifold, positive pressure supercharger, and a high temperature engine oil. All modifications would amount to about one point five times the current cost of a gasoline engine. These hydrogen engines burn fuel in the same manner that gasoline engines do.
The theoretical maximum power output from a hydrogen engine depends on the air/fuel ratio and fuel injection method used. The stoichiometric air/fuel ratio for hydrogen is 34:1. At this air/fuel ratio, hydrogen will displace 29% of the combustion chamber leaving only 71% for the air. As a result, the energy content of this mixture will be less than it would be if the fuel were gasoline. Since both the carbureted and port injection methods mix the fuel and air prior to it entering the combustion chamber, these systems limit the maximum theoretical power obtainable to approximately 85% of that of gasoline engines. For direct injection systems, which mix the fuel with the air after the intake valve has closed, the maximum output of the engine can be approximately 15% higher than that for gasoline engines.
Therefore, depending on how the fuel is metered, the maximum output for a hydrogen engine can be either 15% higher or 15% less than that of gasoline if a stoichiometric air/fuel ratio is used. However, at a stoichiometric air/fuel ratio, the combustion temperature is very high and as a result it will form a large amount of nitrogen oxides, which is a criteria pollutant. Since one of the reasons for using hydrogen is low exhaust emissions, hydrogen engines are not normally designed to run at a stoichiometric air/fuel ratio.
Typically hydrogen engines are designed to use about twice
as much air as theoretically required for complete combustion.
At this air/fuel ratio, the formation of NOx is reduced
to near zero. Unfortunately, this also reduces the power output
to about half that of a similarly sized gasoline engine. To
make up for the power loss, hydrogen engines are usually
larger than gasoline engines, and/or are equipped with turbochargers
or superchargers.