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Hi Everyone. I've been doing some testing of various configurations to try and help lower my CHTs. I've recently had a breakthrough so I thought I'd share.
First, a little background. I'm out in Arizona and in the summer I've struggled to keep my CHTs at anything reasonable. I have an O-540 turning 2700 rpm making 260hp. After reading Mike Busch, I've adopted 415F as my "do something now to fix it" temp even though Lycoming lists 500F as the max temp. To be honest, I'd be elated if I could keep them below 415.
Up until now, I haven't done a great job documenting with concrete numbers. I've read forums, talked with people and implemented what seemed to make sense. I double-checked all the baffeling. I increased my outlet area, then increased it again, then increased it again! I placed a lip at the front of the outlet area, then made that lip bigger. I added a "fence" from the cowl lip to the tunnel. I added a small 1" aluminum round (don't know what to call it, if anyone can tell me, I'll edit this description.) at the bottom of the firewall, at the front of the tunnel. Then I made it bigger. With still unacceptably high CHTs I decided to add louvers. I decided to either go big or go home. So I made large louvers on the sides of the cowling based on lots of reading.
After all of that, I could sometimes manage the CHTs... Until the summer days came.
So I decided to get scientific. I had a homemade manometer, but it's hard to read and bounces around a lot. So I found a monometer on Amazon. https://www.amazon.com/gp/product/B07K7HT3XJ/ It's not too expensive and measures the same as my homemade one. However, this one has an average feature. Which is perfect for our use. Hold an airspeed for a few minutes and look at the average reading.
For my baseline, I used the current configuration with a 1.5:1 outlet to inlet ratio, a 2" lip, fences, large firewall round, and large louvers.
At 92 KIAS it was pulling 3.50 inches of water.
At 105 KIAS it was pulling 5.10 inches of water.
I found that the size of the firewall round didn't make any difference at all. However, what was interesting was that my louvers were making the differential pressure worse. With the louvers removed:
At 92 KIAS it was pulling 3.69 inches of water.
At 105 KIAS it was pulling 5.15 inches of water.
So now on to what I discovered. I decided to replace the cowl opening and lip with a one-piece fixed cowl flap. Same exact outlet area.
At 92 KIAS it was pulling 4.20 inches of water.
At 105 KIAS it was pulling 5.70 inches of water.
For my installation, a large cowl flap seems to do a substantially better job of cooling. Especially at lower airspeeds. At a cruise yesterday at 2500ft, 23 squared, with 108F OAT, this configuration lowered my CHTs from 430F to 380F. This substantial!!! On the descent, the CHTs were falling to around 310F.
Since this fixed cowl flap is proof of concept, now I'm going to build a proper cowl flap that I can control.
If you're dealing with high CHTs with a big engine, don't take this as my recommendation on what to do. Just take it as a datapoint while you research solutions. YMMV. Figuring out what the air is doing inside your cowl is difficult. However, with my particular installation, this seemed to work!
IMG_3602.jpeg For reference, you can see the louvers that I had before (that only hindered) and the fixed cowl flap. Please excuse the dirty airplane!
First, a little background. I'm out in Arizona and in the summer I've struggled to keep my CHTs at anything reasonable. I have an O-540 turning 2700 rpm making 260hp. After reading Mike Busch, I've adopted 415F as my "do something now to fix it" temp even though Lycoming lists 500F as the max temp. To be honest, I'd be elated if I could keep them below 415.
Up until now, I haven't done a great job documenting with concrete numbers. I've read forums, talked with people and implemented what seemed to make sense. I double-checked all the baffeling. I increased my outlet area, then increased it again, then increased it again! I placed a lip at the front of the outlet area, then made that lip bigger. I added a "fence" from the cowl lip to the tunnel. I added a small 1" aluminum round (don't know what to call it, if anyone can tell me, I'll edit this description.) at the bottom of the firewall, at the front of the tunnel. Then I made it bigger. With still unacceptably high CHTs I decided to add louvers. I decided to either go big or go home. So I made large louvers on the sides of the cowling based on lots of reading.
After all of that, I could sometimes manage the CHTs... Until the summer days came.
So I decided to get scientific. I had a homemade manometer, but it's hard to read and bounces around a lot. So I found a monometer on Amazon. https://www.amazon.com/gp/product/B07K7HT3XJ/ It's not too expensive and measures the same as my homemade one. However, this one has an average feature. Which is perfect for our use. Hold an airspeed for a few minutes and look at the average reading.
For my baseline, I used the current configuration with a 1.5:1 outlet to inlet ratio, a 2" lip, fences, large firewall round, and large louvers.
At 92 KIAS it was pulling 3.50 inches of water.
At 105 KIAS it was pulling 5.10 inches of water.
I found that the size of the firewall round didn't make any difference at all. However, what was interesting was that my louvers were making the differential pressure worse. With the louvers removed:
At 92 KIAS it was pulling 3.69 inches of water.
At 105 KIAS it was pulling 5.15 inches of water.
So now on to what I discovered. I decided to replace the cowl opening and lip with a one-piece fixed cowl flap. Same exact outlet area.
At 92 KIAS it was pulling 4.20 inches of water.
At 105 KIAS it was pulling 5.70 inches of water.
For my installation, a large cowl flap seems to do a substantially better job of cooling. Especially at lower airspeeds. At a cruise yesterday at 2500ft, 23 squared, with 108F OAT, this configuration lowered my CHTs from 430F to 380F. This substantial!!! On the descent, the CHTs were falling to around 310F.
Since this fixed cowl flap is proof of concept, now I'm going to build a proper cowl flap that I can control.
If you're dealing with high CHTs with a big engine, don't take this as my recommendation on what to do. Just take it as a datapoint while you research solutions. YMMV. Figuring out what the air is doing inside your cowl is difficult. However, with my particular installation, this seemed to work!
IMG_3602.jpeg For reference, you can see the louvers that I had before (that only hindered) and the fixed cowl flap. Please excuse the dirty airplane!
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