I think the total volume is given by V=a(1-2a)^2/(1-4a^3), where the value of 'a' to give maximum volume is 0.174 and the corresponding value of V is 0.076.

See attached.

Alan

Thanks, Alan!

What can you say about this solution:

Interesting recursive relation for 'a'. Can't see where this particular one comes from! No real need for intermediate results here of course; just set 'a' to be the same on both sides and solve for a to get the infinite recursion value immediately.

Alan

AlanStevens wrote: Interesting recursive relation for 'a'. Can't see where this particular one comes from!

I can't see too

One reader of first my book on Mathcad (see the Preface >>>) has sent me this solution without any description (may de he was legendary Tom Gutman )

And other same problem! How many cones with max sum volumes we can do from one circle workpiece?

Here's a "starter for ten". Numerical only. I've assumed each segment angle bears same relationship to what remains as first segment angle bears to whole cirlce. I haven't proved that this leads to the maximum volume (it might not!).

Alan

AlanStevens wrote: Here's a "starter for ten".

Ten!?

Sorry, Alan!

I think we can have only two cones with max sum volume.

The sum volume is less with 3-d cone!

Yes, the infinite cone assumption is easily outmatched here.

Alan

PS The phrase, "starter for ten", comes from a quiz show in which contestants have to answer a "starter" question that gives them 10 points if they answer correctly.

AlanStevens wrote: PS The phrase, "starter for ten", comes from a quiz show ...

OK!

We say in Russia in same case "dance from the oven"!

I've figured out where the recursion relation for the boxes comes from:

Alan

Thanks, Tom Gutman

And what about cones from the round workpiece?!