From: Rotary motors in aircraft
[mailto:flyrotary@lancaironline.net] On
Behalf Of Al Gietzen
Sent: Sunday, August 06, 2006 6:45
PM
To: Rotary
motors in aircraft
Subject: ***SPAM*** [FlyRotary]
First flight - Oil temp
Thanks everyone for the congratulatory messages, and for
the support that is always so helpful. No pics to post yet because my
camera battery went dead after the first three shots, so I’m awaiting for
shots from my friend who took hundreds (OK, only about 150) and will be editing
for a while J.
The principal issue of the day was the higher than
comfortable oil temperature; most likely due to insufficient air flow through
the cooler. For anyone who would like to think aerodynamics for awhile
and give an opinion on the simplest and best approach to remedy; read on.
The custom cooler for this 265 hp engine is large.
The core here is about 5 ¼” wide, 22” long and 3 ¼”
thick. It is located in the wing root of the Velocity, behind the spar, with
inlet underneath and exit on the top. Alan Shaw, who I believe pioneered
this approach, found the location worked very well. When I discussed the
installation with him years ago, he opined that a scoop under the wing was
probably not necessary because of a pressure differential between bottom and
top surfaces. Since then, my investigations of pressure distributions,
and similar installations that aren’t working so well, make me wonder.
Photo 1 is a view under the wing showing the OC air
intake, wheel well, and the big armpit scoop for the coolant radiator in the
cowl. The inlet opening is about 1 1/8” wide and 23” long.
There really isn’t a scoop, just an opening with an extended
airfoil shaped lip which extends about ½” into the free stream. The
idea was to minimize drag, and assume a more negative pressure at the exit
would produce the necessary flow. Photo 2 shows a front view where you
see the wheel well and the inlet – very little extension into the free
stream. Analysis suggests that the turbulent boundary layer on a smooth
surface at the inlet location could be about 5/8 – 3/4” in thick.
The air exit fairing is shown in photo 3; and is shaped as
it is to maintain attached flow and cause minimal turbulence going aft.
The effective exit area is about 1.6 times the inlet area. The
thickness of the core suggests the need for pretty good pressure differential
for adequate flow.
Here are some options:
a) For the first flight the landing
gear was never retracted. Since the open wheel well forward of the inlet would
likely cause significant turbulence; try another flight with the gear retracted
to see if that improves the results.
b) Place
some VGs forward of the inlet to ‘energize’ the boundary layer, and
see if that helps.
c) Extend
the ‘lip’ of the inlet to form a proper ram scoop, possible also
with VGs forward to break up the boundary layer, and accept the slight increase
in drag.
d) Do
something at the exit ( local ‘expert’ suggests there may be flow
separation before the aft end of the fairing causing high pressure behind the
exit). Put VGs on the top of the exit fairing and/or reduce exit area.
e) None of
the above.
I suspect the normal aerodynamic pressure differential
between the inlet and outlet points is minimal; especially in level flight
where it could be near zero. Option c) seems the most sure-fire to me.
Thanks for input.
Al