I think the problem with the gauges they were testing is that getting accurate. . . .
I don't remember if they checked the Carter ETG l mentioned below. Probably not.
I have broken this down into a simple physics problem, where the characteristics of a vibrating steel string are extremely well understood. Take a piece of steel of a certain mass, suspend it between two points with a tension of x, and we can compute the FF (fundamental frequency) produced with extreme accuracy. Far greater accuracy than required for tensioning a bandsaw, in fact.
Back in high school physics we tensioned wires of different compositions and were unable to detect differences. If there was a difference, we didn't have the gear to find it at the time.
Compositions maybe, but not different thicknesses. Stringed instruments have different diameter strings or wires don't they? Something is missing. Or is it a comfort thing? Ernie, can you help out here?
That is why audio transducers of different compositions sound largely alike. Aluminum, plastic, paper, and even Kevlar cones with rubber and foam and cloth and even paper surrounds produce the same fundamental frequencies. The differences come in the harmonics (distortions). All I care about is the FF.
Not the same thing at all. Transducers don't vibrate on their own, they are physically moved by a component that responds to a magnetic field or piezio electric effect vibrating at selected frequencies.
Hopefully (due to the reasons above), that won't become necessary. But I will tell you that an area that concerns me is blades with carbide teeth. I need to do some testing there.
Anything that changes within the measured oscillating distance (between guides)- extra teeth, fewer teeth, added weight/heavier teeth, etc. will change the freq vs tension. Another thing you will need to do is to ensure the distance and anchor point are constant and very accurate. If a blade is tensioned to X psi but the tuning distance is changed, the pitch will change- e.g. a slide guitar. You can compute what effect changing the distance will have on your results. You won' be able to rely on the upper and lower wheel tangent points either.That distance will be different between saws and among blades whose length is not precise.
Tire thickness, etc. will have an effect, also. You will need to use special clamping bracket to be sure you tension you have a fixed length. If you use a clamping device you will need to clamp, test, unclamp, adjust tension, clamp, test, etc.
Yes, if one has the $$$ and the 14" saw, the Carter system looks like a great way to go.
Frankly, I believe the price is high because the demand is low. That unit has a commonly available transducer and likely a single chip driving a readout that costs pennies. The last I looked, it has come down from the $200-$300 range to around $150 which is still too high, but given some competition or volume it could and should go MUCH lower. Look what happened to the price of the Oneida dust deputy :wsmile:.
The primary reason for following-through with this is that it will hopefully provide a gold standard in determining tension (short of the Carter solution, which only works w/ 14" saws). 99% of users have no problem, as you say, with that built-in scale. But when there is a problem or a question, hopefully this will provide a precise method of testing one's current built-in gauge.
I believe when Carter says it will fit most 14" bandsaws they are not excluding 12", 20" or other bandsaws etc. And, despite what Carter says, his unit can be mounted to any bandsaw that has a tensioning device where you can slip the sensor between two parts, including, contrary to their site, bandsaws with quick tension levers- they just haven't designed a mount for it, yet.
Like I said, I think you may be on to something, mainly for repeatable setup, but am doubtful you'll come up with a "gold standard."
In addition to things we have discussed, one of the main reasons I say that is- there is no such thing as a "gold standard." I frankly don't see where any of the bandsaw or blade manufacturers can come up with objective tensioning data- there is no "magic" number- 20 Kpsi might work fine but 27,250 psi might work just as well. I think it is all subjective- they make a blade or saw, and have their R&D folks test it cutting wood. If a particular blade
seems to cut ok at 20 Kpsi for some unspecified types of woods, then, wa la, it is a 20 Kpsi blade. What is the tolerance. It certainly won't cut like a dog at 19,500 psi, work like a champ at 20 Kpsi, then like a dog at 20,500!
For me, once I hear 20,000 on a saw, I can get there every time in the future just from memory. Which is a good thing, 'cause my saw doesn't have a scale.
Another thought/question- how will you calibrate your unit initially? How will you know what the tension on the saw blade is when you are showing X Hz on the Chromatic tuner? Without absolutely knowing every single factor, you really don't want to rely on an equation. You will need a gold standard to start with- possibly something like a Carter ETG- a chicken-egg situation? I raised these questions with Mark D. off line, but he didn't answer. In reality, no math is needed to verify your idea- Buy a Carter ETG- check the pitch of various size and construction blades at various tensions, and see if it works and with the resolution and repeatability that is useable.
Crank her up to a high 'C' and let her rip.
Keep us updated.
