I'm surely not the only one trying to follow another recent thread with some interesting contradictions about tiller shape as it relates to front profile, so I thought I would try to clarify for my own sake as well as others'. Also, this thread gives those interested a place to collect their thoughts and share opinions on the subject without hijacking a bow post. I use the word opinions due to the somewhat disparate examples and experiences being offered, and encourage all to come with an open mind and keep things as lighthearted as one can be while having a disagreement. Hopefully this will give us newbies some food for thought on all sides.
I believe that a major source of the argument was a discrepancy between people talking about profile-matched bend versus what portions of a limb should in general bend more for optimal performance. These are two separate concepts and were being discussed as one. Let's separate them!
Part 1! Here's what I "know" so far, in as concise a few bullet points as I can muster about how front profile and tiller shape relate. Please weigh in and correct me where I've misunderstood, as I'm still pretty new to all of this.
1. Thicker wood stresses the functional surfaces more quickly when bent. Thus, a thicker piece of wood reaches the same amount of surface strain as a thinner piece while bent less. Simply put, you can only bend a certain thickness of wood so far before it will break. The thicker, the quicker. Here's a link for you engineer types.
http://paleoplanet69529.yuku.com/topic/28701/minumum-bend-radius?page=1#.UPDz82czTrJ
2. By making a portion of the limb wider than the rest, you can keep up weight while reducing thickness to safely and effectively concentrate more bend into that part of the working limb (a mollegabet is an extreme example) while still having equal strain throughout. So the widest parts of a limb "can/should" bend more when drawn, which pulls your tiller away from an even circle shape.
Conclusion on front profile: When people talk about tiller matching front profile, they mean that wider portions of a limb have the ability to carry more curve and narrower portions will be less curved when drawn while still having equal strain along the limb. This same principle is in effect when people discuss how wide overall to make a bow to achieve a certain poundage at draw length based on the overall length of bow, but can be applied to smaller portions of the limb as well if you'd like to move more of the bend to one portion of the limb or another. For example, in the difference between a molly and a parallel limb, to achieve equal strain, the molly bends more at the widest and less at the narrowest, while a parallel limb will bend closer to the same throughout. This all makes wonderful sense.
Part 2!The second topic of discussion, which is what it seems like Ryoon was trying to call to the fore with his provocative comments about gizmos and a parallel limb still not demanding circular tiller, is of overall bend placement as a general rule for performance. Correct me if I'm wrong, but here's where I think the actual discussion lies. Once you have your personal ideal for overall bend placement, then you can adjust that per your front profile.
If we take a hypothetical bow that is 1 inch wide straight from tip to tip with no tapers, and want those tips to slam home to the "greatest effect" regardless of draw weight or wood used, what will the bend look like? Would it be a perfect circle? Would it be whip-ended? How about a double helix! What trade-offs are there for hand shock, accuracy, durability, etc. versus increased speed? This is a question both of personal experience (art) and of engineering (science) with validity in both sides.
Let the opinions fly like so many arrows from a well-tillered stick!
