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Date: Tue, 15 Dec 2009 08:26:24 -0600
Message-ID: <5cf132c0912150626y264c2f7ft61662511109b03bb@mail.gmail.com>
Subject: Re: [FlyRotary] Oil cooling
From: Mark Steitle <msteitle@gmail.com>
To: Rotary motors in aircraft <flyrotary@lancaironline.net>
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--0015175cab14bb99d6047ac52c9a
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On Tue, Dec 15, 2009 at 8:06 AM, Lynn Hanover <lehanover@gmail.com> wrote:

> Yes, my Fluidyne cooler should easily do the job of cooling my current
> engine.  But I am building a P-port 20B to replace this motor downstream, so
> I need to design for 375hp (375 x .8 = 300).  The Fluidyne cooler is 297 cu
> in (core size is 9 x 11 x 3).  Close enough for government work.
>
> Mark
>
> On Mon, Dec 14, 2009 at 5:48 PM, George Lendich <lendich@aanet.com.au>wrote:
>
>>  Sorry Mark,
>> It's hard to keep track of who's running what, on a 20B or say 300 +hp,
>>  two would still be too much, but you know that already, as you said your
>> running too cool. One of your coolers is more than a stock 13B cooler by
>> about 14 cu"
>> Do you or anyone know the size of the stock 20B oil cooler?
>>
>> Just playing with the figures, I guess I could use .8 or .85 cu" per Hp
>> for oil cooling, just as a linear calculation.  Using .8 , Mark's need for
>> 300hp is only 240cu", however each oil cooler is 189cu" ea. This area
>> required may need to increase incrementally with increased HP.
>> Anyone with any suggestions in regard to this?
>> George (down under)
>>
>> George,
>>
>> Keep in mind that I have a 50% greater cooling requirement than a 13B.
>> Mark
>> On Mon, Dec 14, 2009 at 3:51 PM, George Lendich <lendich@aanet.com.au>wrote:
>>
>>>   Mark/ Jeff,
>>> I hadn't bothered to check the size before as the Mazda oil cooler is
>>> known to be more than adequate. If your using over the Mazda size in
>>> cu" then your over sized. Both your cooler areas are well over sized. I seen
>>> one chap used two Mazda coolers when taking off on water using NOs, but he
>>> admitted it was over cooling.
>>> George ( down under)
>>>
>>> George,
>>>
>>> I'm not at the hangar today, but off the top of my head, they are about 4
>>> 1/2 x 18 x 2.  I had considered using two RX-7 coolers arranged in a wedge
>>> configuration.  But I ended up going with a large rectangular unit which I
>>> chose because the air would not have to change directions to get through the
>>> core.  Hopefully, that would provide lower cooling drag.
>>>
>>> Mark
>>>
>>> On Mon, Dec 14, 2009 at 1:50 PM, George Lendich <lendich@aanet.com.au>wrote:
>>>
>>>>  Mark /Jeff,
>>>> What is the Mazda cooler size., in comparison?
>>>> George ( down under)
>>>>
>>>> ----- Original Message -----
>>>> *From:* Mark Steitle <msteitle@gmail.com>
>>>> *To:* Rotary motors in aircraft <flyrotary@lancaironline.net>
>>>> *Sent:* Tuesday, December 15, 2009 3:34 AM
>>>> *Subject:* [FlyRotary] Re: Oil Cooling
>>>>
>>>> Jeff,
>>>>
>>>> I doubt an air lock is/was the problem as it was oriented with the
>>>> inlet/outlet on the side.  If there was an air lock, I would think that at
>>>> least part of the other end tank would get warm (which it doesn't).  Good
>>>> suggestion though.
>>>>
>>>> This single cooler is almost twice the size as one of your coolers.  So,
>>>> it should be up to the task at hand.  This is assuming that it is working as
>>>> designed.
>>>>
>>>> Mark
>>>>
>>>>
> Oil is a poor conductor of heat. It does not absorb heat readily and once
> heated does not give up heat readily. So, compared to a water radiator the
> oil cooler must be much larger than one would think.
>
> The rotor exposes a huge amount of iron to the fires of combustion. From
> that stand point the piston engine, with just the piston crown involved
> starts to look pretty clever.
>
> The rotor is cooled by the incoming fuel air mixture which expands
> violently when it "sees" the straight line infr-red 350 to 400 degrees of
> the rotor face. This expansion slows the incoming charge and in effect
> reduces the displacement of the engine. This is why the turbocharged engine
> works so well. The losses
> in charge volume are overcome by the turbo.
>
> So, the remaining cooling is by spraying hot oil into the rotor through
> those jets in the crank. The hot oil picks up some additional temperature
> and is whipped into a Mirical Whip like foam and it then drops into the pan
> through the center iron drain back cavity.
>
> Most oils do not give up those air bubbles (foam) very readily. And that
> air is an insulator, and that
> (in effect) makes your oil coolers smaller.
>
> This also affects oil pressure. As the oil is heated, non multi grades
> become thinner and develop higher leak rates, so the oil pump becomes just a
> bit less effective, and oil pressure drops a bit from the cold oil or cool
> oil numbers.
>
> The milti grade oils contain polymers (long strings of plastic) that link
> up when heated and this overcomes the thinning effect seen in straight
> weight oils. So you will see oil pressure increase with oil temperature. For
> a while. Over time the strings will be chopped up so many times the linking
> effect will become less appearant, and peak oil pressure will be lower. The
> polymer chains linking up makes foamed oil hold the air bubbles longer, and
> increases oil temperatures.
>
> If you have a margenal oil cooling system, you can control oil temps with
> the throttle. Less throttle = less temperature. More throttle = more
> temperature. The closer to the cooling limit you operate the more obvious
> the effect. Once heated it takes longer time wise to get back to a lower
> temperature.
>
> Plain bearings rely on an oil wedge that forms just in front of the loaded
> side of a bearing. Since combustion is only on one side of the engine, the
> oil wedge in the rotary and most engines is generally in one place on each
> main bearing. The oil temperature in the wedge is very much higher than the
> oil temperature gage will report to you. So the most important oil
> temperature is never reported.
>
> Oil pressure is used to move this superheated wedge oil off of the bearing,
> so as to keep the soft silver bearing stuff out of the oil filter and oil
> pan. This is why racers jack up the oil pressure. It has almost no affect on
> lubrication, just cooling the bearings.
>
> Oil weights are a measure of how fast they drain out of a little funnel.
> This has almost nothing to do with how good any particular oil will be at
> protecting bearings.
>
> Rotaries are difficult to start when cranking speeds are low. So a
> multigrade oil in very cold weather is helpful in this regard.
>
> The smaller number in a multi grade oil is the pour rate of the base stock
> oil. Like 5W-50. The big number is what the oil acts like (pours) when at
> operating temperature. The polymers in oil take up volume, so there is less
> oil in each can of a multi grade.
>
> Street oils have chemicals that neutralize acids generated from sulfer
> compounds in combustion. So sulfuric acid will not gobble up the bearings
> and aluminum stuff in you engine. Some oils have so much of this stuff that
> they claim you can go 7,000 miles between changes. So those cans have even
> less oil in them.
> Racing oils have few such chemicals but do have more anti scuff (zink
> compounds) and anti foamng compounds. Racing oil cans in straight weights
> have lots of oil in each can.  Nonsynthetic racing oils are cheap and can be
> changed often without breaking the bank.
>
> So, high oil temps endanger bearings. Produce even more foam, leading to
> more overheating. Oil temps above 160 degrees cost HP on the dyno.
>
> The very best oils for film strength and lubricity are the synthetics.
>
> There is no such thing as excessive  cooling capacity.
>
> Lynn E. Hanover
>
>
>
>
>
>
>
>
>
Lynn,

Thanks for the excellent lesson on oils and oil cooling.  I'm optimistic
that my oil temps will come down substantially with the new oil cooler.
Ground running has been encouraging.

What do you consider an optimum temperature for the water?

Mark S.

--0015175cab14bb99d6047ac52c9a
Content-Type: text/html; charset=ISO-8859-1
Content-Transfer-Encoding: quoted-printable

<br><br>
<div class=3D"gmail_quote">On Tue, Dec 15, 2009 at 8:06 AM, Lynn Hanover <s=
pan dir=3D"ltr">&lt;<a href=3D"mailto:lehanover@gmail.com">lehanover@gmail.=
com</a>&gt;</span> wrote:<br>
<blockquote class=3D"gmail_quote" style=3D"PADDING-LEFT: 1ex; MARGIN: 0px 0=
px 0px 0.8ex; BORDER-LEFT: #ccc 1px solid">
<div>Yes, my Fluidyne cooler should easily do the job of cooling my current=
 engine.=A0 But I am=A0building a P-port 20B to replace this motor downstre=
am, so I need to design for 375hp (375 x .8 =3D 300).=A0 The Fluidyne coole=
r is 297 cu in (core size is 9 x 11 x 3).=A0 Close enough for government wo=
rk.=A0 </div>

<div>=A0</div>
<div>Mark<br><br></div>
<div class=3D"gmail_quote">On Mon, Dec 14, 2009 at 5:48 PM, George Lendich =
<span dir=3D"ltr">&lt;<a title=3D"mailto:lendich@aanet.com.au" href=3D"mail=
to:lendich@aanet.com.au" target=3D"_blank">lendich@aanet.com.au</a>&gt;</sp=
an> wrote:<br>

<blockquote class=3D"gmail_quote" style=3D"PADDING-LEFT: 1ex; MARGIN: 0px 0=
px 0px 0.8ex; BORDER-LEFT: #ccc 1px solid">
<div bgcolor=3D"#ffffff">
<div><font face=3D"Arial" size=3D"2">Sorry Mark, </font></div>
<div><font face=3D"Arial" size=3D"2">It&#39;s hard to keep track of who&#39=
;s running what, on a 20B or say 300 +hp, =A0two would still be too much, b=
ut you know that already, as you said your running too cool. One of your co=
olers is more than a=A0stock 13B cooler by about 14 cu&quot;</font></div>

<div><font face=3D"Arial" size=3D"2">Do you or anyone know the size of the =
stock=A020B oil cooler?</font></div>
<div><font face=3D"Arial" size=3D"2"></font>=A0</div>
<div><font face=3D"Arial" size=3D"2">Just playing with the figures, I guess=
 I could use .8 or .85 cu&quot; per Hp for oil cooling, just as a linear ca=
lculation.=A0 Using .8 , Mark&#39;s need for 300hp is only 240cu&quot;, how=
ever each oil cooler is 189cu&quot; ea. This area required may need to incr=
ease incrementally=A0with increased HP.</font></div>

<div><font face=3D"Arial" size=3D"2">Anyone with any suggestions in regard =
to this?</font></div>
<div><font face=3D"Arial" size=3D"2">George</font>=A0<font face=3D"Arial" s=
ize=3D"2">(down under)</font><br></div>
<div>
<div></div>
<div>
<blockquote style=3D"PADDING-RIGHT: 0px; PADDING-LEFT: 5px; MARGIN-LEFT: 5p=
x; BORDER-LEFT: #000000 2px solid; MARGIN-RIGHT: 0px">
<div>George, </div>
<div>=A0</div>
<div>Keep in mind that I have a 50% greater cooling requirement than a 13B.=
<br></div>
<div>Mark<br></div>
<div class=3D"gmail_quote">On Mon, Dec 14, 2009 at 3:51 PM, George Lendich =
<span dir=3D"ltr">&lt;<a title=3D"mailto:lendich@aanet.com.au" href=3D"mail=
to:lendich@aanet.com.au" target=3D"_blank">lendich@aanet.com.au</a>&gt;</sp=
an> wrote:<br>

<blockquote class=3D"gmail_quote" style=3D"PADDING-LEFT: 1ex; MARGIN: 0px 0=
px 0px 0.8ex; BORDER-LEFT: #ccc 1px solid">
<div bgcolor=3D"#ffffff">
<div><font face=3D"Arial" size=3D"2">=A0Mark/ Jeff,</font></div>
<div><font face=3D"Arial" size=3D"2">I hadn&#39;t bothered to check the siz=
e before as the Mazda oil cooler is known to be more than adequate. If your=
 using over=A0the Mazda=A0size in cu&quot;=A0then your over sized. Both you=
r cooler areas are well over sized. I seen one chap used two Mazda coolers =
when taking off on water using NOs, but he admitted it was over cooling.</f=
ont></div>

<div><font face=3D"Arial" size=3D"2">George ( down under)</font></div>
<blockquote style=3D"PADDING-RIGHT: 0px; PADDING-LEFT: 5px; MARGIN-LEFT: 5p=
x; BORDER-LEFT: #000000 2px solid; MARGIN-RIGHT: 0px">
<div>George, </div>
<div><font face=3D"Arial" size=3D"2"></font>=A0</div>
<div>I&#39;m not at the hangar today, but off the top of my head, they are =
about 4 1/2=A0x 18 x 2.=A0 I had considered using two RX-7 coolers arranged=
 in a wedge configuration.=A0 But I=A0ended up=A0going with a=A0large recta=
ngular unit which I chose because the air would not have to=A0change direct=
ions=A0to get through the core.=A0 Hopefully, that would provide lower cool=
ing drag.=A0=A0</div>

<div>=A0</div>
<div>Mark<br><br></div>
<div class=3D"gmail_quote">On Mon, Dec 14, 2009 at 1:50 PM, George Lendich =
<span dir=3D"ltr">&lt;<a title=3D"mailto:lendich@aanet.com.au" href=3D"mail=
to:lendich@aanet.com.au" target=3D"_blank">lendich@aanet.com.au</a>&gt;</sp=
an> wrote:<br>

<blockquote class=3D"gmail_quote" style=3D"PADDING-LEFT: 1ex; MARGIN: 0px 0=
px 0px 0.8ex; BORDER-LEFT: #ccc 1px solid">
<div bgcolor=3D"#ffffff">
<div><font face=3D"Arial" size=3D"2">Mark /Jeff,</font></div>
<div><font face=3D"Arial" size=3D"2">What is the Mazda cooler size., in com=
parison?</font></div>
<div><font face=3D"Arial" size=3D"2">George ( down under)</font></div>
<blockquote style=3D"PADDING-RIGHT: 0px; PADDING-LEFT: 5px; MARGIN-LEFT: 5p=
x; BORDER-LEFT: #000000 2px solid; MARGIN-RIGHT: 0px">
<div style=3D"FONT: 10pt arial">----- Original Message ----- </div>
<div style=3D"BACKGROUND: #e4e4e4; FONT: 10pt arial"><b>From:</b> <a title=
=3D"mailto:msteitle@gmail.com" href=3D"mailto:msteitle@gmail.com" target=3D=
"_blank">Mark Steitle</a> </div>
<div style=3D"FONT: 10pt arial"><b>To:</b> <a title=3D"mailto:flyrotary@lan=
caironline.net" href=3D"mailto:flyrotary@lancaironline.net" target=3D"_blan=
k">Rotary motors in aircraft</a> </div>
<div style=3D"FONT: 10pt arial"><b>Sent:</b> Tuesday, December 15, 2009 3:3=
4 AM</div>
<div style=3D"FONT: 10pt arial"><b>Subject:</b> [FlyRotary] Re: Oil Cooling=
</div>
<div><br></div>
<div>Jeff,</div>
<div>=A0</div>
<div>I doubt an air lock is/was the problem as it was oriented with the inl=
et/outlet=A0on the side.=A0 If there was an air lock, I would think that at=
 least part of the other end tank would get warm (which it doesn&#39;t).=A0=
 Good suggestion though.=A0 </div>

<div>=A0</div>
<div>This single cooler is almost twice the size as one of your coolers.=A0=
 So, it should be up to the task at hand.=A0 This is assuming that it is wo=
rking as designed.</div>
<div>=A0</div>
<div>Mark=A0=A0=A0</div></blockquote></div></blockquote></div></blockquote>=
</div></blockquote></div></blockquote></div></div></div></blockquote>
<div>=A0</div>
<div>Oil is a poor conductor of heat. It does not absorb heat readily and o=
nce heated does not give up heat readily. So, compared to a water radiator =
the oil cooler must be much larger than one would think. </div>
<div>=A0</div>
<div>The rotor exposes a huge amount of iron to the fires of combustion. Fr=
om that stand point the piston engine, with just the piston crown involved =
starts to look pretty clever.</div>
<div>=A0</div>
<div>The rotor is cooled by the incoming fuel air mixture which expands vio=
lently when it &quot;sees&quot; the straight line infr-red 350 to 400 degre=
es of the rotor face. This expansion slows the incoming charge and in effec=
t reduces the displacement of the engine. This is why the=A0turbocharged en=
gine works so well. The losses</div>

<div>in charge volume are overcome by the=A0turbo.=A0</div>
<div>=A0</div>
<div>So, the remaining cooling is by spraying hot oil into the rotor throug=
h those jets in the crank. The hot oil picks up some additional temperature=
 and is whipped into a Mirical Whip like foam and it then drops into the pa=
n through the center iron drain back cavity.=A0</div>

<div>=A0</div>
<div>Most oils do not give up those air bubbles (foam) very readily. And th=
at air is an insulator, and that </div>
<div>(in effect) makes your oil coolers smaller.=A0</div>
<div>=A0</div>
<div>This also affects oil pressure. As the oil is heated, non multi grades=
 become thinner and develop higher leak rates, so the oil pump becomes just=
 a bit less effective, and oil pressure drops a bit from the cold oil or co=
ol oil numbers. </div>

<div>=A0</div>
<div>The milti grade oils contain polymers (long strings of plastic) that l=
ink up when heated and this overcomes the thinning effect seen in straight =
weight oils. So you will see oil pressure increase with oil temperature. Fo=
r a while. Over time the strings will be chopped up so many times the linki=
ng effect will become less appearant, and peak oil pressure will be lower. =
The polymer chains linking up makes foamed oil hold the air bubbles longer,=
 and increases oil temperatures.=A0</div>

<div>=A0</div>
<div>If you have a margenal oil cooling system, you can control oil temps w=
ith the throttle. Less throttle =3D less temperature. More throttle =3D mor=
e temperature. The closer to the cooling limit you operate the more obvious=
 the effect. Once heated it takes longer time wise to get back to a lower t=
emperature.=A0</div>

<div>=A0</div>
<div>Plain bearings rely on an oil wedge that forms just in front of the lo=
aded side of a bearing. Since combustion is only on one side of the engine,=
 the oil wedge in the rotary and most engines is generally in one place on =
each main bearing. The oil temperature in the wedge is very much higher tha=
n the oil temperature gage will report to you. So the most important oil te=
mperature is never reported.=A0</div>

<div>=A0</div>
<div>Oil pressure is used to move this superheated wedge oil off of the bea=
ring, so as to keep the soft silver bearing stuff out of the oil filter and=
 oil pan. This is why racers jack up the oil pressure. It has almost no aff=
ect on lubrication, just cooling the bearings.=A0</div>

<div>=A0</div>
<div>Oil weights are a measure of how fast they drain out of a little funne=
l. This has almost nothing to do with how good=A0any particular oil will be=
 at protecting bearings.=A0</div>
<div>=A0</div>
<div>Rotaries are difficult to start when cranking speeds are low. So a mul=
tigrade oil in very cold weather is helpful in this regard.=A0</div>
<div>=A0</div>
<div>The smaller number in a multi grade oil is the pour rate of the base s=
tock oil. Like 5W-50. The big number is what the oil acts like (pours) when=
 at operating temperature. The polymers in oil take up volume, so there is =
less oil in each can of a multi grade.</div>

<div>=A0</div>
<div>Street oils have chemicals that neutralize acids generated from sulfer=
 compounds in combustion. So sulfuric acid will not gobble up the bearings =
and aluminum stuff in you engine. Some oils have so much of this stuff that=
 they claim you can go 7,000 miles between changes. So those cans have even=
 less oil in them.</div>

<div>Racing oils have few such chemicals but do have more anti scuff (zink =
compounds) and anti foamng compounds. Racing oil cans in straight weights h=
ave lots of oil in each can.=A0 Nonsynthetic racing oils are cheap and can =
be changed often without breaking the bank.=A0</div>

<div>=A0</div>
<div>So, high oil temps endanger bearings. Produce even more foam, leading =
to more overheating. Oil temps above 160 degrees cost HP on the dyno.=A0</d=
iv>
<div>=A0</div>
<div>The very best oils for film strength and lubricity are the synthetics.=
</div>
<div>=A0</div>
<div>There is no such thing as excessive=A0 cooling capacity.</div>
<div>=A0</div>
<div>Lynn E. Hanover=A0=A0=A0</div>
<div>=A0</div>
<div>=A0</div>
<div>=A0</div>
<div>=A0</div>
<div>=A0</div>
<div>=A0</div>
<div>=A0</div>
<div>=A0</div></div></blockquote></div>
<div>Lynn,</div>
<div>=A0</div>
<div>Thanks for the excellent lesson on oils and oil cooling.=A0 I&#39;m=A0=
optimistic that my oil temps will come down substantially with the=A0new oi=
l cooler.=A0 Ground running has been=A0encouraging.</div>
<div>=A0</div>
<div>What do you consider an optimum temperature for the water?</div>
<div>=A0</div>
<div>Mark S.=A0 <br></div>

--0015175cab14bb99d6047ac52c9a--