The 1937 Hindenburg disaster is often mentioned as proof that hydrogen is too flammable and dangerous for commercial use. Well hydrogen is flammable, and while the Hindenburg was full of hydrogen when it started burning, but a look at a color photograph of the fire ( below), or at the B+W Newsreel film of the fire, suggests that it is not the hydrogen burning, but the skin of the zeppelin and the fuel. Note the red color of the majority flame, and note the black smoke. Hydrogen fires are typically invisible or very light blue, and hydrogen fires produce no smoke.
Closeup of the Hindenburg burning. It is the skin and gasoline that burns, not the gaseous hydrogen.
The Hindenburg was not a simple hydrogen balloon either. It was a 15 story tall airship with state-rooms, a dining room and an observation deck. It carried 95 or so passengers and crew. There was plenty of stuff to burn besides hydrogen. Nor could you say that a simple spark had set things off. The Hindenburg crossed the ocean often: every 2 1/2 days. Lightning strikes were common, as were “Saint Elmo’s fire,” and static electricity discharges. And passengers smoked onboard. Holes and leaks in the skin were also common, both on the Hindenburg and on earlier airships. The hydrogen-filled, Graf Zeppelin logged over 1 million flight miles and over 500 trips with no fires. And it’s not like helium-filled zeppelins and blimps are much safer. The photo below shows the fire and crash of a helium-filled Goodyear blimp, “Spirit of Safety”, June, 2011. Hydrogen has such a very high thermal conductivity that it is nearly as hard to light as helium. I recently made this video where I insert a lit cigar into a balloon filled with hydrogen. There is no fire, but the cigar goes out. In technical terms, hydrogen is said to have a low upper combustion limit.
Helium-filled goodyear blimp “spirit of safety” catches fire and burns before crashing. It’s not the helium burning.
The particular problem with the Hindenburg seems to have been its paint, skin and fuel, the same problems as caused the fire aboard the “Spirit of Safety.” The skin of the Hindenburg was cotton, coated with a resin-dope paint that contained particles of aluminum and iron-oxide to help conduct static electricity. This combination is very flammable, essentially rocket fuel, and the German paint company went on to make rocket fuel of a similar composition for the V2 rockets. And the fuel was flammable too: gasoline. The pictures of the Hindenburg disaster suggest (to me) that it is the paint and the underlying cotton skin that burned, or perhaps the fuel. A similar cause seems to have beset the “Spirit of Safety.” For the Hindenburg’s replacement, The Graf II, the paint composition was changed to replace the aluminum powder with graphite – bronze, a far less flammable mixture, and more electrically conductive. Sorry to say, there was no reasonably alternative to gasoline. To this day, much of sport ballooning is done with hydrogen; statistically it appears no more dangerous than hot air ballooning.
It is possible that the start of the fire was a splash of gasoline when the Hindenburg made a bumpy contact with the ground. Another possibility is sabotage, the cause in a popular movie (see here), or perhaps an electric spark. According to Aviation Week, gasoline spoiled on a hot surface was the cause of the “Spirit of Safety fire,” and the Hindenburg disaster looks suspiciously similar. If that’s the case, of course, the lesson of the Hindenburg disaster is reversed. For safety, use hydrogen, and avoid gasoline.
Dr. Robert E. Buxbaum, January 8, 2016. My company, REB Research, makes hydrogen generators, and other hydrogen equipment. If you need hydrogen for weather balloons, or sport ballooning, or for fuel cells, give us a call.
No gasoline. The big, V-16 Daimler engines burned Diesel. It did not contact the ground either – not until it caught fire anyway. It was pulling up to a mooring mast when it exploded. Most likely one of the many steel wires inside snapped and tore open a gas cell and created a massive leak, too large for the venting system to compensate for. The Hydrogen mixed with air and static electricity provided a spark as mooring lines dropped to the ground and “earthed”. There is a lot to this story. The Nazis did not like the Zeppelin company because Eckener, its head man, was very anti-Nazi. The regular captain had been replaced with someone more politically acceptable but less experienced. He most likely made a turn that was too sharp while dodging thunder storms that day and that is what caused the wire to snap. You can’t make sharp turns in Zeppelins. Experienced Zeppelin men knew this from years of experience flying WWI “Zeps”. Meanwhile the Graf Zeppelin safely flew over a million miles filled with Hydrogen and using gasoline and “blau gas” as fuel. Goering had it dismantled.
You got to be kidding, the hydrogen is burning you just can’t see it because it’s nearly invisible but if you watch the film (moving picture) the speed at which the Hindenburg burns you know the hydrogen is burning. The Germans did a lot of research and investigation afterwards and static discharge is believed to be the cause. There are plenty of articles out there about this.
Hydrogen does not burn. It explodes! It produces water when it combusts. Anti fire.
Hydrogen has both an upper and a lower combustion limit. When there is too much hydrogen, it doesn’t burn, just like when there is too little. I have a video where I stick a lit cigar into a mylar balloon of hydrogen, no pop, no burn, no bang. The cigar goes out.