enginehistory.org

[rwahlgren]

When did Wright start using steel crankcases?

[kmccutcheon]

With the G100 Cyclone, about 1937.

1938 G100 Sales Brochure

The construction is covered in a patent by Rudolph Daub, who made application in 1937.
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Kimble D. McCutcheon

[rwahlgren]

What about Germany? Were the Americans first or ?

Edit to correct a miss spelled word.

[kmccutcheon]

I don't know. Looks like you'll have to do some research...
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Kimble D. McCutcheon

[rwahlgren]

And makes me wonder why PW didn't use it. All most all PW important people came from Wright?

[kmccutcheon]

[dpennings]

I took a look into my book (Kyrill von Gersdorf, Kurt Grassmann, Helmut Schubert: Flugmotoren und Strahltriebwerke) and found no direct information, but a section view of the BMW 801. The walls of the crankcase look quite thin, so it might be made out of steel/cast iron. Also on photographs, the crank case are painted, which is more likley done on steel parts than on aluminium.

[kmccutcheon]

While the BMW 801 had a steel crankcase, the R-1820 G100 was in PRODUCTION in January 1937. rwahlgren wanted the first use.
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Kimble D. McCutcheon

[rwahlgren]

[dpennings]

actually, the cylinder head of the BMW 801 are made of an aluminum alloy wich is very corrosion and heat resistant and was used on motorcycles (the Boxer engines). I've been searching this alloy (I read about it a couple of years ago).

On car engines, aluminum parts are usually not protected and the salt on the streets (maybe unkown for people from California....) takes its toll...

Seams like, crank cases of radial engines are more stressed than those of inline engines, otherwise they wouldn't be made of steel...

Its remarkable that these late radials contain much more iron than aluminum, the cylinders are made of steel as well. The cylinder heads are the only mayor highly stressed parts out of aluminum.

[rwahlgren]

[dpennings]

the crankcases of radials are full of thread holes, therefore steel makes much sence. You can use bolts with higher strenght in steel thread holes which can save quite a lot of weight. You also get rid of the thermal expansion problems.

[kmccutcheon]

[dpennings]

I have to say, that idea is brilliant, I will keep it in my mind and might reuse it somewhere else in future... He deserved every penny for it!

[rwahlgren]

I would like to know how they maintained a decent finish in those radiused holes? Especially in those days that would be a pretty slow machining operation. Easy to have the cutter leave chatter marks, because of the large area for the size cutter used, also one side is pulling down and other pushing up on the cutter, surface speed is much slower towards the shank and or center of the cutter. But then its just speculation until you actually do the cut.
It would be horrible doing that on a manual milling machine of any sort back then using an indexing head. Rather than the cutter they show in the Patent, a multiple drilling machine using reverse counter sink cutters with the spherical ground on them would be much faster, back in the non CNC days.

After finding this looks like they would not use a manual machine.
https://www.youtube.com/watch?v=sBfFpcdyd5Q