Supercharging a 944 - Why so hard?
#196
The reason I ask is that Corky Bell in his book Supercharged (Ch 5, page54-56) talks about the IC increasing charge density and thus HP (with a roots blower) over the same non-IC configuration. I can't get my head around this if you are getting 62CI of inlet air per rev regardless.
#197
the key is that cooling the air down so much lets you run more aggressive spark timing which makes the difference in power.
#198
Yes I understand that.
The reason I ask is that Corky Bell in his book Supercharged (Ch 5, page54-56) talks about the IC increasing charge density and thus HP (with a roots blower) over the same non-IC configuration. I can't get my head around this if you are getting 62CI of inlet air per rev regardless.
The reason I ask is that Corky Bell in his book Supercharged (Ch 5, page54-56) talks about the IC increasing charge density and thus HP (with a roots blower) over the same non-IC configuration. I can't get my head around this if you are getting 62CI of inlet air per rev regardless.
the 62 CI is a measurement of volume, eventual pressure factors in density that is affected by the temperature of the air.
#199
Yes I understand that.
The reason I ask is that Corky Bell in his book Supercharged (Ch 5, page54-56) talks about the IC increasing charge density and thus HP (with a roots blower) over the same non-IC configuration. I can't get my head around this if you are getting 62CI of inlet air per rev regardless.
The reason I ask is that Corky Bell in his book Supercharged (Ch 5, page54-56) talks about the IC increasing charge density and thus HP (with a roots blower) over the same non-IC configuration. I can't get my head around this if you are getting 62CI of inlet air per rev regardless.
the air is only compressed into boost once it's on the outlet side of the blower, being forced into a "room" (manifold) with all the air that has come thru the blower previously and not been ingested by the engine.
if the air has been intercooled before entering that room, mass X of air will take up less space (volume) than it would have if it weren't intercooled. mass per volume = density.
so if the room is a given size, and the intercooled air takes up less volume for a given mass, there's now more room for the blower to pack in even more air.
blower doesn't have to work as hard to blow this extra air into the room = less parasitic drive losses = more hp at the flywheel end instead of being used up at the crank pulley end.
the difference in parasitic loss isn't a whole lot though - as i said before the key is the ability to run more aggressive spark timing.
#200
Corky's calculations show with IC you can achieve the same power at a lower pressure ratio than an non-IC system. This is just based on the amount of air entering the cylinders. Does not take into consideration tuning advantages that can be exploited with cooler air charges. He also shows an IC system requires less SC CFM than an non-IC system. Again this is without tuning exploits.
I am not arguing with you, I am just pointing out Bell's inconsistencies with (everyone) here is saying....
I will see if I can post a snippet of his calculations if you don't have access to Bell's book. Has anyone here read this book and comment on these calcs in Ch 5?
I am not arguing with you, I am just pointing out Bell's inconsistencies with (everyone) here is saying....
I will see if I can post a snippet of his calculations if you don't have access to Bell's book. Has anyone here read this book and comment on these calcs in Ch 5?
#201
ive read that book a few times.
one thing that can be confusing is that in a piston engine with boost (either turbo or SC) CFM into the blower does not equal CFM out.
the engine will only ever ingest it's own displacement VOLUME, regardless of temperature, density or pressure.
when the intake valve opens (on a 2.5L 944) a given cylinder is going to pull in ~38 ci worth of air volume.
the CFM difference between what the blower will pull in per rev, versus what the engine will consume per rev, makes the pressure ratio.
a 500hp, 5.0L SC engine is pulling 750cfm at the blower inlet but only 450cfm is going thru the manifold, just much denser cfm's.
because the SC makes the charge air so hot, it is not very dense (low mass per unit volume).
38ci at 100*C is still 38ci, but has much less air mass in it than 38ci at 40*C.
more air mass + corresponding fuel mass = horsepower.
increasing the supercharger output pressure (drive ratio/pressure ratio) is one way of increasing the density of the air in the manifold - simply forcing even more air into the same size container, at an even higher temperature, will still pack more density (therefore mass) into a given volume.
however it is easier (less supercharger work) to get the air denser for more power by intercooling it, dropping the temperature which naturally makes the air molecules stick closer together (denser) to get more mass into the same 38ci cylinder.
one thing that can be confusing is that in a piston engine with boost (either turbo or SC) CFM into the blower does not equal CFM out.
the engine will only ever ingest it's own displacement VOLUME, regardless of temperature, density or pressure.
when the intake valve opens (on a 2.5L 944) a given cylinder is going to pull in ~38 ci worth of air volume.
the CFM difference between what the blower will pull in per rev, versus what the engine will consume per rev, makes the pressure ratio.
a 500hp, 5.0L SC engine is pulling 750cfm at the blower inlet but only 450cfm is going thru the manifold, just much denser cfm's.
because the SC makes the charge air so hot, it is not very dense (low mass per unit volume).
38ci at 100*C is still 38ci, but has much less air mass in it than 38ci at 40*C.
more air mass + corresponding fuel mass = horsepower.
increasing the supercharger output pressure (drive ratio/pressure ratio) is one way of increasing the density of the air in the manifold - simply forcing even more air into the same size container, at an even higher temperature, will still pack more density (therefore mass) into a given volume.
however it is easier (less supercharger work) to get the air denser for more power by intercooling it, dropping the temperature which naturally makes the air molecules stick closer together (denser) to get more mass into the same 38ci cylinder.
#202
Again the genesis of my original question... Is SC 62 CI per revolution based on the inlet conditions, outlet or something in between? If its the last 2 then I can understand how IC can affect mass flow rate.
When I get home from work I will post the sections I am questioning and see if you agree.
#203
are you looking at the equations like these?
http://www.lextreme.com/icvsnic.htm
i believe what happens is that not all of the air actually makes it out of the blower case because it's being pushed back by the compressed air already in the manifold.
so the rotors scoop up 62ci of air at the entrance but only push out into the manifold say 2/3 of that air.
the rest gets carried back around by the rotors which then displaces new air that would've come in.
higher pressures/temperatures exacerbate the "blow back" because the rotors don't have a very good seal between lobes (like a screw compressor does)
http://www.lextreme.com/icvsnic.htm
i believe what happens is that not all of the air actually makes it out of the blower case because it's being pushed back by the compressed air already in the manifold.
so the rotors scoop up 62ci of air at the entrance but only push out into the manifold say 2/3 of that air.
the rest gets carried back around by the rotors which then displaces new air that would've come in.
higher pressures/temperatures exacerbate the "blow back" because the rotors don't have a very good seal between lobes (like a screw compressor does)
#204
https://hydemotorworks.com/2015/10/1...gain-formulas/
Another write up of the power potential to gain.
Another write up of the power potential to gain.
#205
That site is blocked by my company's firewall.
Then its not positive displacement. That effect should be accounted for in the VE spec for the blower. I can see cetri's having this effect.
Then its not positive displacement. That effect should be accounted for in the VE spec for the blower. I can see cetri's having this effect.
#206
Not to throw everyone off...but you could just go with a standalone and do a proven air to air IC with https://www.ebay.com/itm/HX35-HX35W-...4383.l4275.c10
The main reason I went with a roots SC is...Hawaii's SCCA tracks are in a small area. I wanted the most immediate and low rpm boost possible for the tight course.
The main reason I went with a roots SC is...Hawaii's SCCA tracks are in a small area. I wanted the most immediate and low rpm boost possible for the tight course.
#207
I will try and make a post showing Corky's formula chain without violating copyright laws.
His chain is HP based not "boost" based. Mass flow rate is the objective. (in his calc chain). "Boost" is an outcome of increased mass flow rate and the engine cfm.
His chain is HP based not "boost" based. Mass flow rate is the objective. (in his calc chain). "Boost" is an outcome of increased mass flow rate and the engine cfm.
#208
that term's a little misleading but still generally correct.
remember that a Roots supercharger is an ancient device originally designed for blowing air into steel furnaces.
in the 1850's when it was invented it was not really a pressure-creating device, just a simple air mover "blower" that might've been barely above atmospheric output pressure.
the first major, widespread use of the roots blower in ICE design was the detroit diesel industrial (later automotive) engines from the 1930s.
2-stroke diesels can't aspirate from the crankcase like a gas engine so they used a roots blower on top to blow air into the chamber thru ports (no intake valves). even this was barely above atmospheric pressure - just enough to get roughly atmospheric pressure into the cylinder and account for flow losses caused by the complicated path the air had to take to get there.
in these simple air-moving applications they are truly "positive displacement" moving a fixed amount of air per revolution. there's no pressure on the outlet side of the rotors pushing back.
when the roots blower got borrowed for hotrodding purposes in the '40s and onwards was the first time this design was really making "boost".
the design has been heavily refined in the last 150+ years, adding more lobes to rotors and twisting them a little bit (GMC/DD), then a little more (1990s Eaton), then adding another lobe and twisting it further (Eaton TVS) to minimize the effect of "blowback".
remember that a Roots supercharger is an ancient device originally designed for blowing air into steel furnaces.
in the 1850's when it was invented it was not really a pressure-creating device, just a simple air mover "blower" that might've been barely above atmospheric output pressure.
the first major, widespread use of the roots blower in ICE design was the detroit diesel industrial (later automotive) engines from the 1930s.
2-stroke diesels can't aspirate from the crankcase like a gas engine so they used a roots blower on top to blow air into the chamber thru ports (no intake valves). even this was barely above atmospheric pressure - just enough to get roughly atmospheric pressure into the cylinder and account for flow losses caused by the complicated path the air had to take to get there.
in these simple air-moving applications they are truly "positive displacement" moving a fixed amount of air per revolution. there's no pressure on the outlet side of the rotors pushing back.
when the roots blower got borrowed for hotrodding purposes in the '40s and onwards was the first time this design was really making "boost".
the design has been heavily refined in the last 150+ years, adding more lobes to rotors and twisting them a little bit (GMC/DD), then a little more (1990s Eaton), then adding another lobe and twisting it further (Eaton TVS) to minimize the effect of "blowback".
#209
Here is a summary of Corky Bell's calculation chain.
Desired Power = stock power x pressure ratio x density ratio x VE ratio x drive power efficiency.
For his example he assumed: Stock engine: 302 CID, 220hp at 5500rpm, VE 80%, Objective: 320hp @5500 rpm
He assumes a VE ratio of 115% and a 90% drive efficiency for his sample calculation.
Solving the top equation for pressure ratio:
Intercooled 85% efficiency: density ratio = 0.97, pressure ratio = 1.45 or 6.6psi boost
Non-intercooled, temperature gain 180F: density ratio drops to 0.75, solving for pressure ratio = 1.87 or 12.8psi
For blower CFM required. Basic engine airflow rate = (cid x rpm x 0.5 x VE)/1728 = 384 cfm (assuming stock engine assumptions above)
Blower CFM required = stock engine CFM x Pressure ratio
Non-intercooled: 384 cfm x 1.87 = 718 cfm
Intercooled: 384 cfm x 1.45 = 557 cfm
So what is wrong with Corky's model?
Desired Power = stock power x pressure ratio x density ratio x VE ratio x drive power efficiency.
For his example he assumed: Stock engine: 302 CID, 220hp at 5500rpm, VE 80%, Objective: 320hp @5500 rpm
He assumes a VE ratio of 115% and a 90% drive efficiency for his sample calculation.
Solving the top equation for pressure ratio:
Intercooled 85% efficiency: density ratio = 0.97, pressure ratio = 1.45 or 6.6psi boost
Non-intercooled, temperature gain 180F: density ratio drops to 0.75, solving for pressure ratio = 1.87 or 12.8psi
For blower CFM required. Basic engine airflow rate = (cid x rpm x 0.5 x VE)/1728 = 384 cfm (assuming stock engine assumptions above)
Blower CFM required = stock engine CFM x Pressure ratio
Non-intercooled: 384 cfm x 1.87 = 718 cfm
Intercooled: 384 cfm x 1.45 = 557 cfm
So what is wrong with Corky's model?
Last edited by jderimig; 01-08-2018 at 07:47 PM.
#210
nothing's wrong with it, it's just not covering the reasoning behind why IC vs non-IC need different pressure levels to get the same air mass into the cylinders.
it does seem to be modeled around achieving an arbitrary temperature in the cylinder though.
you might find this interesting:
https://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=1126&context=icec
it does seem to be modeled around achieving an arbitrary temperature in the cylinder though.
you might find this interesting:
https://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=1126&context=icec