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Date: Sat, 24 Dec 2005 02:30:36 -0500
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From: REHBINC@aol.com
Subject: Re: [LML] Re: Where has all the power gone?
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Skip/Walter,


**Can you explain why spark advance is a good idea in auto engines and 
a bad one in airplanes?**

It's not necessarily.   It all depends on the power and fuel being used.

You can actually gain power in an aircraft engine at takeoff power by 
RETARDING the timing from the historically chosen timing.  That has 
several advantages.

OTOH, you can gain power in cruise in most situations (NA) by advancing 
the timing during that power demand.

If the thetaPP is 10 like it is at takeoff, retarding the timing will 
make more HP.  If it is 25, like it can be in cruise, advancing the 
timing will increase output.   IOW, if the thetaPP is 16 and you 
advance OR retard the timing, the power output goes down.

The objective is to have a thetaPP of 16dATDC in all conditions.  That 
results in the most mechanical advantage for the fuel charge being 
burned.  It improves the BSFC.

Water-cooled, iron-head engines have a wider detonation margin and 
withstand detonation a lot better than our aircraft engines, so we need 
to pay closer attention to these issues.
I supect Skip really wants to know why your car operates with a more or less 
continuously variable spark advance verses a static advance in an airplane. 
The principle reason is that rpm and cylinder filling are constantly changing in 
your car, while these values are almost constant in a typical aircraft engine.

Engine rpm is important because as the engine turns faster, the crank swings 
more degrees during the combustion process. This has two effects on the 
combustion process. First, for a given ignition point the peak pressure occurs 
occurs later in the power stroke (theta PP). Second, the shorter time at peak 
chamber pressure reduces the time for the fuel mixture to pyrolize (decompose into 
its combustible components). With less pyroysis, the detonation margin is 
increased. This is one reason why your old car may nock a bit at 45 mph steady 
state and not at 65 mph.

Cylinder filling is also important for two reasons and they work opposite one 
another. As you open the throttles, manifold pressure increases and the 
engine is fed denser air fuel mixture. This results in a higher cranking pressure. 
As the pressure increases, the flame speed decreases, requiring more spark 
advance to develop best power. (counter intuitive)

The other thing that happens with increasing cranking pressure, and the 
temperature that comes with it, is that we increase pyrolization and thus get 
closer to the detonation limit.

In an airplane with a constant prop, the engine barely changes speed the 
entire time the wheels are off the ground. With a fixed prop, the engine speed 
still changes much less than in a car. Thus the engine speed effects can be 
ignored without much loss.

In a typical airplane the most critical engine operation is at takeoff and 
the critical limitation is detonation. If the timing is adequately retarded to 
prevent detonation (or at least keep it under control) at full power take off, 
then it should also be safe when cylinder filling is reduced to 75% power. The 
reduced cranking pressure also slightly reduces the spark advance for best 
power/detonation limit because the flame speed is now faster (not a huge 
increase). Whether the increase in flame speed makes up for the increased detonation 
margin depends on the engine characteristics, particularly how it heats up.

Keep in mind also that the theta PP for best power is a function is of the 
combustion duration and of engine speed. As rpm and/or combustion duration 
approach zero the ideal theta PP approaches TDC. As theta PP drifts away from TDC 
the engine becomes less efficient. This is why open combustion chambers are so 
inefficient, the flame has to travel a greater distance and increases the 
combustion duration.

Ya'll have a merry Christmas,

Rob

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<DIV>
<DIV>Skip/Walter,</DIV>
<DIV>&nbsp;</DIV>
<DIV>&nbsp;</DIV>
<BLOCKQUOTE style=3D"PADDING-LEFT: 5px; MARGIN-LEFT: 5px; BORDER-LEFT: blue=20=
2px solid"><FONT face=3DArial>**Can you explain why spark advance is a good=20=
idea in auto engines and <BR>a bad one in airplanes?**<BR><BR>It's not neces=
sarily.&nbsp;&nbsp; It all depends on the power and fuel being used.<BR><BR>=
You can actually gain power in an aircraft engine at takeoff power by <BR>RE=
TARDING the timing from the historically chosen timing.&nbsp; That has <BR>s=
everal advantages.<BR><BR>OTOH, you can gain power in cruise in most situati=
ons (NA) by advancing <BR>the timing during that power demand.<BR><BR>If the=
 thetaPP is 10 like it is at takeoff, retarding the timing will <BR>make mor=
e HP.&nbsp; If it is 25, like it can be in cruise, advancing the <BR>timing=20=
will increase output.&nbsp;&nbsp; IOW, if the thetaPP is 16 and you <BR>adva=
nce OR retard the timing, the power output goes down.<BR><BR>The objective i=
s to have a thetaPP of 16dATDC in all conditions.&nbsp; That <BR>results in=20=
the most mechanical advantage for the fuel charge being <BR>burned.&nbsp; It=
 improves the BSFC.<BR><BR>Water-cooled, iron-head engines have a wider deto=
nation margin and <BR>withstand detonation a lot better than our aircraft en=
gines, so we need <BR>to pay closer attention to these issues.</FONT></BLOCK=
QUOTE></DIV>
<DIV>I supect Skip really wants to know why your car operates with a more or=
 less continuously variable spark advance verses a static advance in an airp=
lane. The principle reason is that rpm and cylinder filling are constantly c=
hanging in your car, while these values are almost constant in a typical air=
craft engine.</DIV>
<DIV>&nbsp;</DIV>
<DIV>Engine rpm is important because as the engine turns faster, the crank s=
wings more degrees during the combustion process. This has two effects on th=
e combustion process. First, for a given ignition point&nbsp;the peak pressu=
re occurs occurs later in the power stroke (theta PP). Second, the shorter t=
ime at peak chamber pressure reduces the time for the fuel mixture to pyroli=
ze (decompose into its combustible components). With less pyroysis, the deto=
nation margin is increased. This is one reason&nbsp;why your old car may noc=
k a bit at 45 mph steady state and not at 65 mph.</DIV>
<DIV>&nbsp;</DIV>
<DIV>Cylinder filling is also important for two reasons and they work opposi=
te one another. As you open the throttles, manifold pressure increases and t=
he engine is fed denser air fuel mixture. This results in a higher cranking=20=
pressure. As the pressure increases, the flame speed decreases, requiring mo=
re spark advance to develop best power. (counter intuitive)</DIV>
<DIV>&nbsp;</DIV>
<DIV>The other thing that happens with increasing cranking pressure, and the=
 temperature that comes with it,&nbsp;is that we increase pyrolization and t=
hus get closer to the detonation limit.</DIV>
<DIV>&nbsp;</DIV>
<DIV>In an airplane with a constant prop, the engine barely changes speed th=
e entire time the wheels are off the ground. With a fixed prop, the engine s=
peed still changes much less than in&nbsp;a car. Thus the engine speed effec=
ts can be ignored without much loss.</DIV>
<DIV>&nbsp;</DIV>
<DIV>In a typical airplane the most critical engine operation is at takeoff=20=
and the critical limitation is detonation. If the timing is adequately retar=
ded to prevent detonation (or at least keep it under control)&nbsp;at full p=
ower take off, then it should also be safe when cylinder filling is reduced=20=
to 75% power. The reduced cranking pressure also slightly reduces the spark=20=
advance for best power/detonation limit&nbsp;because the flame speed is now=20=
faster (not a huge increase). Whether the increase in flame speed makes up f=
or the increased detonation margin depends on the engine&nbsp;characteristic=
s, particularly how it heats up.</DIV>
<DIV>&nbsp;</DIV>
<DIV>Keep in mind also that the&nbsp;theta PP for best power is a function i=
s of the combustion duration and&nbsp;of engine speed. As rpm and/or combust=
ion duration approach zero the ideal theta PP approaches TDC. As theta PP dr=
ifts away from TDC the engine becomes less efficient. This is why open combu=
stion chambers are so inefficient, the flame has to travel a greater distanc=
e and increases the combustion duration.</DIV>
<DIV>&nbsp;</DIV>
<DIV>Ya'll have a merry Christmas,</DIV>
<DIV>&nbsp;</DIV>
<DIV>Rob</DIV>
<DIV>&nbsp;</DIV></BODY></HTML>

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