FLYING LESSONS for March 14, 2023

FLYING LESSONS uses the past week’s mishap reports to consider what might have contributed to accidents, so you can make better decisions if you face similar circumstances.  In many cases design characteristics of a specific make and model airplane have little direct bearing on the possible causes of aircraft accidents, so apply these FLYING LESSONS to any airplane you fly.  However, verify all technical information before applying it to your aircraft or operation, with manufacturers’ data and recommendations taking precedence.  You are the pilot-in-command, and are ultimately responsible for the decisions you make. 

This week’s LESSONS

In the February 29th Mastery of Flight report we discussed the significant, negative performance impact of taking off and landing with a tailwind. Using Cessna and Beechcraft performance charts as examples, we postulated that tailwinds have a roughly three to five times greater impact on takeoff and landing performance, negatively, than do headwinds improve takeoff performance. In other words, a little headwind helps a little, but a little tailwind hurts a lot.

But sometimes it makes sense to intentionally take off or land with a tailwind. For one, the runway may be so long that there is no doubt the airplane will become airborne or come to a stop on landing in the available runway length even with a tailwind. In that case it may be better to conform to ATC’s direction, local noise abatement procedures or other airplanes’ traffic patterns with a tailwind than it is to go against the grain just to have a headwind component. 

Another case when intentional tailwind takeoffs and landings make sense are so-called “one-way” airports, those that because of local terrain or obstacles require taking off and landing in one compass direction—landing to the west and taking off to the east to avoid a hill off the west end of the airport, for instance.  

A third situation is when there is a significant slope to the runway.  A runway that climbs or descends steeply with horizontal distance will adversely affect airplane performance with or without a wind. The slope may be enough to make an airport a “one-way” strip, at least for some airplanes, with or without obstacles close to the departure ends.  

So how can you decide whether a runway is one-way because of runway slope?  Most Pilot’s Operating Handbooks assume a level runway surface on their Takeoff and Landing Performance charts…in other words, you’re on your own to predict performance when the runway has a slope. 

Diamond Aircraft’s DA-40-180 POH, however, does give us some guidance. Look at this Caution. A 2% up slope (a change in elevation of two feet per 100 feet of horizontal distance, or two meters for each 100 meters) creates a 10% increase in takeoff distance. The effect on the takeoff roll may be even greater, i.e., the distance to take off and clear an obstacle increases 10% with a 2% slope but the airplane will roll even more above “book” distance before the wheels leave the surface. The POH doesn’t tell us, but it’s not too much of a stretch to expect the performance to increase by a similar percentage if you take off downhill on a 2% slope. Certainly it would be worth experimenting under controlled conditions with a very light airplane and a long, downward-sloping runway before tacking a short, downhill runway for real.

Diamond has a similar note in the DiamondStar’s landing performance discussion, identical except that it replaces “take-off” with “landing” as appropriate.  

Now let’s consider winds from last week’s discussion. Two knots of tailwind component is worth roughly 10% change in airplane performance (using the Cessna and Beech charts as examples). Consequently it takes about two knots of tailwind component to balance the effect of taking off downhill on a 2% slope or landing up a 2% slope (using the Diamond Aircraft POH as a single data point). 

 

What’s the practical application of this estimate? Conventional wisdom is that it’s better to take off downhill and land uphill than to take off and land into the wind on sloping runways.  However, this (very) preliminary correlation of various POH data suggests that the amount of tailwind it takes to make even a downhill landing or uphill takeoff a bad idea is very slight—just a couple of knots. It seems a good idea to take off and land into to wind even with a 2% runway slope.

Sometimes, with safe experimentation, we learn the limits of POH-derived performance when the charts don’t cover all the variables. Then we can make our own, informed decisions about what works for us in our airplanes. For example, for a few years I flew a turbocharged Baron from a short runway (3400 feet, short in 58TC terms, anyway) with a little more than a 3% slope. With practice at weights as light as I could get, I found that it indeed was more comfortable landing uphill and taking off downhill from that airport, with tailwind components up to as much as about 10 knots.  

Perhaps some readers are more familiar with the physics than I and have done the math, and can provide definitive answers. It seems likely, however, that the degradation in performance working against a runway slope is not additive, but instead multiplicative with slope. Regardless, empirical data told me it made sense to take off and land with slight tailwind components on that particular runway. Regardless, I tried to fly the airplane as light as safely possible, especially on landing—the turbo Baron has a lot of inertia that makes landing distance more critical than takeoff in that specific model.

I strongly suspect, however, that simply flying the airplane at the appropriate speeds for liftoff and final approach will do more to assure you can use a runway that meets your airplane’s needs than any additional benefit that derives from playing the tailwind-vs-runway slope game. With or into the wind, apply no less than a 50% margin to what you calculate, and 100% additional buffer if you don’t use maximum performance, short-field technique.

Are you faced with a similar decision? Don’t “wing it,” don’t do it because someone on the internet (like me) or the local ace tells you to, and certainly don’t try it simply hoping you’ll get the performance you need. Gather as much available information as possible, using data from your POH as primary but not completely discounting very general rules of thumb from others to help you fill the gaps. Then conduct some controlled experiments at light airplane weights and varying the variablesas few at a time as possible, being ready to chop the power and abort a takeoff early if you don’t get the initial performance you need, and to power up and go around at all points of the landing attempt, including after the wheels are on the runway if necessary.

If you’re not willing to educate yourself and conduct controlled experiments, doing your homework, calculating the performance, then reducing the margins of wind, weight, slope and distance only a little at a time, then don’t try the unusual at all.  

Airplanes usually fly extremely well in the middle of their approved performance ranges.  For almost all of us, almost all of the time, there’s no need to get close to the edges of the envelope.

Questions? Comments? Supportable opinions? Let us know at m[email protected]

Debrief

Readers write about recent FLYING LESSONS:

Reader Dave Murlin writes about last week’s discussion about bounced landings and my One Bounce Rule:

The NTSB report that was inspiration for last week’s LESSONS tells us the 55 year old Private Pilot had, at the time of the crash:

I’ll leave it to you to decide whether that means “low time” or if the fact almost all his flying experience was in the same make and model aircraft (likely, the accident airplane). We won’t know how he controlled the airplane as it drifted to the left unless the pilot volunteers the information beyond what he apparently told the NTSB. 

But you’re right. If the airplane was to be controllable after the bounce the pilot would have to have aggressively manage pitch for airspeed and control authority, and rudder to turn that potential control authority into aircraft command. I agree, Dave: I hope he continues to fly as well. Thank you.

Reader Mark Finkelstein continues on the main topic of last week’s LESSONS, pilot induced oscillation (PIO):

I believe your instincts are correct: establish the pitch and feed in the power. You were doing something right to manage pitch as the Jaribu settled back into control to touch down without damage. Good job, Mark. 

Well-known instructor Mike Jesch adds:

That’s a good point, but also requires additional thought and planning. Can you give us an example of how you make the decision? Is it solely based on remaining runway length? Thanks very much, Mike.

Tailwheel and high-performance instruction specialist Brian Sagi wraps up this week’s Debrief:

I did the same thing when I conducted primary training, and when I also provided tailwheel endorsement training. I need to include potential landing errors in recurrent and Flight Review instruction. Thanks for prompting me, Brian, and for letting us all learn from your experience.

More to say? Let us learn from you, at [email protected]

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Disclaimer

FLYING LESSONS uses recent mishap reports to consider what might have contributed to accidents, so you can make better decisions if you face similar circumstances. In most cases design characteristics of a specific airplane have little direct bearing on the possible causes of aircraft accidents—but knowing how your airplane’s systems respond can make the difference in your success as the scenario unfolds. Apply these FLYING LESSONS to the specific airplane you fly.

Verify all technical information before applying it to your aircraft or operation, with manufacturers’ data and recommendations taking precedence. You are pilot in command, and are ultimately responsible for the decisions you make.