So I've been doing some reading about velocity stack designs.
I spotted these threads & thought it was an interesting read.
Btw, what I've read is the Intake Length is from the back of the valve face to the opening of the plenum.Found this on the 'Busa site:
The length of the stack- Positive and negative pressure waves travel up and down the intake track caused by the inertia of the air being accelerated and decelerated. The objective of adjusting the length of the intake track is to have a positive pressure wave arrive at the intake valve just as it opens or just before it closes so to push more air into the cylinder. The length of the intake track is important because the pressure wave moves at the speed of sound and the timing of the wave’s arrival at the intake valve is controlled by the length of the intake which is easily adjusted by changing the length of the velocity stack.
There are three major causes of these pressure waves. The first is the lowering of the piston on the intake stroke causes a negative pressure wave. The second is the scavenging of the exhaust which is seen in the intake track because of the valve overlap period. This creates a negative pressure wave in the intake track. The third is the closing of the intake valve. This causes a positive pressure wave due to the sudden deceleration of the air mass behind the closed intake valve.
The pressure wave(s) travels up the intake track and is inverted (positive to negative or negative to positive) at the opening of the velocity stack and is reflected back down to the valve. If the valve is closed when it arrives, it will bounce off the intake valve travel back to the velocity stack opening where it is inverted again and reflected back down to the valve. If the pressure wave(s) is tuned to arrive at the intake valve at the correct time, the engine can see a momentary supercharging effect of up to 7 psi. This explains why a normal aspirated engine can have over 100% volumetric efficiency.
There are a number of ball park equations for determining the ideal intake track length, but they are very rough estimates. Understanding the above concepts you can see that intake tuning (or velocity stack length) is affected by the type of exhaust system (4:1 or 4:2:1) and the primary and secondary lengths, exhaust balance tubes, cam timing and cam overlap. In addition, muffler design, compression ratio and airbox resonance can play a part in intake tuning.
Sales comment- With the large variety of modified Hayabusas out there, no one length stack is ideal for all bikes. 3 different stack lengths are offered so that the correct stack can be purchased for your bike. General guidelines are provided to assist with selection. A tuner’s kit is offered to assist with the serious racer in optimizing his set up.
Metric Induction Wave Tuning Calculator
Welcome to the Velocity-of-Sound.com metric (cm) induction wave tuning calculator. This calculator will determine the most efficient overall length of the intake runners to optimise the intake system. This updated calculator allows the user to decide how many induction waves they want to calculate for. The optimum is the first wave, however, it should be recognised that both the first and second waves are usually too long for most practical applications - NASCAR engines use the third wave. We recommend you start at the third wave and go from there. Just enter the number of waves in the second box. Do as many calculations as needed to get a workable compromise between performance and the practical space constraints on your vehicle. Once you have found the most practical dimensions, all you do is measure the current intake runner length and subtract this from the length advised in the calculator - the bit left over is the length of the velocity stack. This will tell you how long the velocity stacks should be, but remember to allow about a half inch so the stack can slide over or inside the end of the runner (usually the carbie or throttle body).
Please Note: Thanks to a very helpful customer, it now works with major browsers.
Also Note: The Number of Induction Waves in the calculator refers to the number of waves to which the intake runner is tuned. NASCAR engineers use the third wave, you can now to use any number you like for optimum tuning.
http://www.velocity-of-sound.com/veloci ... lator2.htm
The Std VTR cam duration is 245°.
Last one.There are actually 3. Here's an interesting article on the subject.How The Hell Would You Measure Number Of Induction Waves ?
"The intake system (induction system) can be tuned to provide maximum power. Just like the exhaust, you can time the pressure waves in the induction to actually force a lager air/fuel charge into the cylinder.
This theory is derived from the helmholtz theory. You can find many articles on helmholtz theory on the internet. First you need to understand how a wave acts. Take a pail of water where the water is still. Now drop a small pebble into the center of the bucket and you can see that it makes a ripple (a wave) in the water. If you watch the ripple you will see that it travels to the side of the bucket, but it doesn’t stop there. It travels back to the center after bouncing off the sides of the bucket. Then it travels back to the wall of the bucket. It keeps traveling back and forth, but the ripple gets smaller and looses momentum the more it travels."
The idea is to get your "pail" (intake length and diameter) the correct size for a specific, optimum RPM so that the wave arrives at the intake valve just as it opens, forcing more air into the cylinder.
Ever since NASCAR competitors started looking for every single available spec of horsepower, especially for the mandated restrictor plate races on the super speedway tracks, the intake tuning separated the men from the boys. The difference is that they run the engine at or close to the optimum RPM a majority of the time so the results are much more evident.
The HD Destroyer equal length stacks are "tuned" to perform at or near the 8,000-10,000 RPM range as that is where they operate for all of 10 seconds or so.... They start at 7000 at the line and go up from there. Tuning the velocity stacks for a street-ridable bike now leads me to believe that the offset pair (one short and one long) would take advantage of a wider range of RPMs.
Looking at other performance bike sites ('Busa, GSXR, etc.) an interesting fact has surfaced. The velocity stack length is one of the parameters in a long equation of cam duration, valve size, head porting, throttle body size, bore, stroke and exhaust tuning.
It's not a case of one size fits all.
HH
The above quotes were pulled from this forum http://www.1130cc.com/forums/showthread.php?t=118537The following is a condensed version of some good info I found in a Superflow 1020 Flowbench Manual:
"When the intake valve closes , a pressure pulse bounces back out the intake tract, and then in again toward the valve. By making the intake tract the proper length, the returning pulse can be timed to arrive just after bottom dead center of the next intake cycle, shoving extra air in and keeping exhaust gasses out of the intake port. To use this pulse the intake port must be the correct length. The pulse will help only through a narrow range of rpm. Above or below a certain range the pulse will actually decrease power so proper synchronization is essential. There are actually several pulses which can be used corresponding to the 2nd, 3rd and 4th time the pulse arrives at the valve. The 2nd pulse is the best the others are weaker and shorter.
2nd Harmonic 132,000 / RPM = Length in inches
Tuning Range is: 89% -108% of target RPM. The pulse strength is + or - 10%
3rd Harmonic 97,000 / RPM = Length in inches
Tuning Range is : 91% - 104% of target RPM. The pulse strength is + or - 7%
4th Harmonic 74,000 / RPM = Length in inches
Tuning Range is : 93% -104% of target RPM. The pulse strength is + or - 4%
Pulse strength varies with intake valve opening and flow
The chart shows the pulses which can be used to obtain the inlet system length, divide the number shown by the RPM for peak power.
For example, at 8,000 RPM for the second harmonic the formula would be: length = 132,000/8,000 = 16.5"
This is the desired length from the intake valve to the air inlet entrance For engines with a plenum chamber type intake, the length is from the valve to the plenum chamber. The pulse in the example will benefit from 89% up to 108% of 8,000 RPM, or from 7,120 RPM to 8,640 RPM. The greatest benefit will occur at about 3% below 8,000 RPM. Below 7,120 RPM or above 8,640 RPM the pulse will actually work to decrease engine power".
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I've only just finished reading this & only came across it whilst looking to see what the pro's & con's are when running different length velocity stacks. So have done no working out at all yet
