I hope others also take an interest in your design since you've taken the time and effort to present it in full .. we definitely need more clean energy technologies (non-hydrocarbon CO2 emitting).mryy wrote:Fletcher,
I will combine your last two posts in this reply.
I have laid out what I *believe* is a plausible and true-to-Bessler concept. I hope others may be inspired and even improved on it. This planet definitely needs more in the way of clean energy.
Karl the Landgrave of Hesse said the wheel was very simple. It could be built by a carpenter's boy. He was amazed that it hadn't been invented before. Bessler himself said no one would buy his contraption for the asking price if they saw its inside.
I judge all designs by the above statements. Some may argue that simplicity is a subjective matter. They say what is simple to one person may not be simple to another. Dunno. In light of those statements by Bessler and Karl I would say that a wheel is simple if the average young person, say the age of 16, can look at it and understand its workings (and build it if the person is an apprentice carpenter especially of the 18th century German kind). Yes, I'm being blunt here. Can an apprentice understand and build the ??theOne?? and ??theTwo$$ -- of course! :)
I also judge all designs based on B's. and Karl's statements. It's kinda the ruler I apply. Subjective is itself subjective lol. Can an apprentice firstly understand your design ? I think so if they read thru carefully and studied the schematics. Of course, if they saw a real-world one in action they would instantly understand - no brainer. Could an apprentice build one ? Definitely if the saw one in action, they'd just copy the parts you made and used. From the schematics maybe not so easy to build as there'd be a lot of tweaking and testing to fine tune it and discover things about it along the way to it being a runner. For instance, as you mentioned to Tarsier, you might start with the simplest form first, with curved return ramps, then upgrade for improvements that potentially would improve performance.
I'd just like to remind everybody about the clue you refer to.mryy wrote:Furthermore none of the other designs that I've seen even adequately address the "hung together" principle (prefer it over the term "connectedness") or the clue about 1 lb dropping and 4 lb rising (4:1 clue), if they even address it at all. It goes without saying that the more a design fits the documented information the more likely the *possibility* of it being a Bessler wheel. Between a concept that appears to conform to 80% of the information and the other 50%, the former is the better candidate. Is this the dark side of Ockham's razor? :)
Here's the translation from John Collins AP book; followed by Stewart and Tinhead's translation for comparison.
"a great craftsman would be that man who can 'lightly' cause a heavy weight to fly upwards! Who can make a pound-weight rise as 4 ounces fall, or 4 pounds rise as 16 ounces fall. If he can sort that out, the motion will perpetuate itself. But if he can't, then his hard work shall be all in vain" – AP pg 295
He will be called a great craftsman, who can easily/lightly (without much effort) throw a heavy thing high, and if one pound falls a quarter, it shoots four pounds four quarters high. &c. members Stewart & Tinhead
However, I also just want to indulge for a moment and include the chapter in JC's AP from where it comes, for greater context.
XLIII. Are there any more doubting lions roaring around? Then let them come and sit down by me, and my wheel shall openly revolve for them. I've nothing to hide, for all the inmost parts, and the perpetual-motion structures, retain the power of free movement, as I've been saying since 1712. I'd like, at this point, to give a brief description of it. So then, a work of this kind of craftsmanship has, as its basis of motion, many separate pieces of lead. These come in pairs, such that, as one of them takes up an outer position, the other takes up a position nearer the axle. Later, they swap places, and so they go on and on changing places all the time. (This principle is in fact the one that Wagner said he owed to me - but I was quite wrongly implicated, as I'd never informed anyone about the matter.) At present, as far as I'm concerned, anyone who wants can go on about the wonderful doings of these weights, alternately gravitating to the centre and climbing back up again, for I can't put the matter more clearly. //
// But I would just like to add this friendly little note of caution:- A great craftsman would be that man who can "lightly" cause a heavy weight to fly upwards! Who can make a pound-weight rise as 4 ounces fall, or 4 pounds rise as 16 ounces fall. If he can sort that out, the motion will perpetuate itself. But if he can't, then his hard work shall be all in vain. He can rack his brains and work his fingers to the bones with all sorts of ingenious ideas about adding extra weights here and there. The only result will be that his wheel will get heavier and heavier - it would run longer if it were empty! Have you ever seen a crowd of starlings squabbling angrily over the crumbs on a stationary mill-wheel? That's what it would be like for such a fellow and his invention, as I know only too well from my own recent experience! //
// I also think it's a good thing to be completely clear about one further point. Many would-be Mobile-makers think that if they can arrange for some of the weights to be a little more distant from the centre than the others, then the thing will surely revolve. A few years ago I learned all about this the hard way. And then the truth of the old proverb came home to me that one has to learn through bitter experience. There's a lot more to matters of mechanics than I've revealed to date, but since there's no urgent need involved, I'll refrain from giving more information at the moment.
Here, imo, is what I think this chapter is about ..
First part .. basis of motion is made up of lead weights, that routinely swap places from closer to the axle to further from it. [me .. sounds remarkably like a mundane conservative OB wheel format]
Second part .. friendly note of caution (about what he just said in first part) .. somewhat tongue-in-cheek he says if you can lift more for less then you will have a winner and be a great craftsman and have a PMM. If you can't sort it out, then as he knows very well from his own experience, it will fail.
Third part .. he wants to clarify one more point. [he seems to be referring back again to designs in the first part]. He learned the hard way about failure. Then he says there is more to learn about mechanics that he hasn't yet revealed.
My analysis and conclusion of this chapter .. B. sings the praises of weight-shifting wheels, where weights swap positions in and out from the axle. Then he maligns the builder who thinks he can cheat mechanics and Archimedes Law of Levers. [so that is not what he was doing inside his wheels], because it will fail. Then he clarifies one further point about weight swapping position wheels .. he again says he learned thru bitter experience and, discovered another way (that actually works) for these to work, which he hasn't shared. IMO !
Can you provide a reference or quote regarding "Bessler did mention that his wheel employed "hoisted" and "hoisting" weight types the latter being heavier" ? I can't place that information. Thanks.mryy wrote:The Warraneck Wheel from your recollected description doesn't appear so simple in its use of a compressed air piston. The piston seems like it could be complicated/high precision unit to construct if I'm not wrong. Bessler did mention that his wheel employed "hoisted" and "hoisting" weight types the latter being heavier. I do not see it here. It isn't a Bessler wheel not that it ever claimed to be. The good side is that ??theOne$$ has a found a long lost kin (of the projectile class). :)
