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Originally Posted by NoDOHC
Good call on the math error! I should have just given the original equation. Apparently the algebra is a bit rusty (I didn't think it looked right, but I couldn't find the formula solved for L in the book).
The natural frequency formula is correct though, I just checked it.
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It happens to the best of us. I can't remember the times I've taken a test and screwed up some simple algebra and ended up with a horrible, horrible, horrible wrong answer.
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Anyway, I like where you are going with this. Something to remember on the Plenum is that the two rotors are 180 degrees out of phase and have a 270 degree intake duration. This means that both rotors take in air at the same time.
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That's actually really helpful, but I think we need to adjust the angle of intake and have it based off of port size, and what not as you're going to get a larger intake with a bridge port compared to a street port
Well my class is finished, time to get back to what I was doing.
I like it a lot and I figure this will be an easy tool for other rotary (and heck, even them piston) guys to effectively make and design a proper manifold without the downfall of one too short or too long. If anyone is able I'd like to see someone make this into a web app that RCC can host on their page (I'll make a thread about it in lounge for those interested).
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There are more advanced formulas for varying cross-sectional-area runners, but I don't have the ambition to enter them into paintbrush and you can probably find them online anyway without any errors.
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I don't even know where to begin with that. Could you point me in the right direction?
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If you want to do the math yourself, it is very simple to draw it up as a dynamic system and then find characteristic equations for it. I say this because you are most likely taking a course in dynamic systems right now or in the near future.
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Actually I don't think I have any dynamic systems setup for my classes now or in the near future. This is why I'm doing a lot of it on my own. I can probably do something similar to what you're telling me in the schools CFD program (if I can ever get it running)
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The Plenum has compliance as it acts as an accumulator. The runner has a resistance (dissipative) and Reluctance (inertial) element to it. The port closing is the disturbance function. The system is a lot harder with changing area.
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You're going to have to go into more detail if you're going to make me want to understand what you're saying.
I think I understand, but I'm not too sure.
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Anyway, you will find that the wave intensity is a logarithmic decaying function and that the time constant is related to the runner smoothness (resistance) and the air velocity (inertia). I can't find the equation right now, maybe it is in a book at work.
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If you ever come across it in the near future post it up (don't forget references).
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I will try to find it and let you do the Algebra.
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DEAL!