In case you missed it or wanted to refer to our slides, here is the rusty pilot’s presentation from our March 2016 event. Turnout was a HUGE success! We hope to see some of you join our club & get out there flying!
Download the file here.
Desert Flying Club, in conjunction with AOPA, is hosting a Rusty Pilot seminar. This a major event where you receive nearly 3 hours of FREE ground instruction, AND your endorsement for the ground portion of a flight review!
That’s right – come join us in a big hangar for a pancake breakfast, seminar, raffle prizes, and aircraft static displays! Here are the details:
When: Saturday, October 10th
Where: 1450 Jetstream Dr, Ste 100, Henderson, NV
How Much: FREE, but you have to register to attend.
Who: Any & all pilots. Get back into aviation, or just brush up on your knowledge & make friends!
AGENDA:
6:30am – 8:00am: Free pancake breakfast. Come hungry, stay for the event!
8:00am-11:00am: Presentations on private pilot material – Rusty Pilot presentations
11:00am-11:30am: Raffle & Prizes
11:30am-1:00pm: Aircraft static displays + hangar talk (Cirrus, Mooney, Archer + more on display!)
Don’t forget to tell all of your aviation friends who want to get back into flying or haven’t flown in a while. Also, any other pilots are welcome to attend this event. You don’t have to be rusty!
We look forward to seeing you there!
Many of our members attended a FAAST seminar about aircraft performance recently. It’s a very important subject, especially to those of us flying in mountainous terrain, in single-engine normally aspirated airplanes! Mr. Stephen Ruks did an excellent job, and agreed to share the powerpoint slides & notes with us to post here. Enjoy reading – and be safe!
The Nine Deadly Sins POWERPOINT:
Slide 2 – References
Pilots Handbook of Aeronautical Knowledge Ch. 7 & 10
Your AFM or POH
AC 00-6A Aviation Wx
AC 61-84B Role of Preflight Preparation
FAA-P-8740-2 Density Altitude Brochure
Slide 3 – Wings Program – What is one of the best things you can do to stay safe?
Chances are 97% greater that you won’t have an accident if enrolled in Wings
Slide 4 – Introduction – Misunderstandings or lack of knowledge about our atmosphere and how it affects aircraft performance is one of the leading causes of fatal aviation accidents. This seminar will remind you of some of the things you already know and maybe show you a few things you didn’t know.
Slide 5 – Altitude types – How many altitude definitions are there?
Read on your altimeter
Height above MSL
Height above ground level
Indicated altitude set at 29.92
PA corrected for non-standard temperature
Slide 6 – Pressure – How do we describe atmospheric pressure, what is it, and how does it affect us? ^ More importantly, how does it affect our airplanes?
Slide 7 – Pressure – What causes pressure variations?
^ Altitude – Pressure decreases approximately one inch of mercury per 1000 feet increase in altitude.
^ Temperature – The rate of decrease of pressure with altitude in warmer air is less than in colder air. You will have to climb higher in warm air to reach the same pressure altitude as in cold air. Temperature id the biggest factor affecting density altitude
Slide 8 – Pressure Gradient – Given the same change in pressure, the rate of change of pressure is greater in cold air than in warm air.
Slide 9 – Effect of non-standard temperature – Notice that True Altitude varies with variations in temperature along the same pressure line or gradient.
Slide 10 – Typical GA Pitot System – Explain disadvantage of having static port on only one side of aircraft. Briefly discuss effects of icing on pitot-static system. If both ram and drain holes freeze up with ice, airspeed indicator acts as an altimeter – the higher you go the higher the airspeed reads. If static port freezes up, altimeter and VSI remain constant and airspeed is not accurate.
Slide 11 – Altimeter – Give brief description of how an altimeter works.
Slide 12 – Altimeter Setting – Standard Atmosphere:
29.92 inHg or
1013.25 hPa (or mb)
at sea level @ 59º F (or 15º C)
One inch of mercury = 1000 feet
One hectoPascal = 100 millibars
1 inHg = 33.8653 hPa — Use this for conversion between inHg and hPa
Slide 13 – High Density Altitude
Three important factors contribute to high density altitude:
Reduced air density equates to decreased performance
Explain chart below:
Slide 14 – High Density Altitude
Warmer air will hold more water vapor than cooler air which affects engine performance more than aerodynamic performance.
With high humidity, expect longer take-off rolls and lower climb rates. Add 10% to take-off distance.
Slide 15 – The Nine Deadly Sins (and their unforgiveness)
Kurt Anderson, an NTSB Investigator, who has investigated more than 400 accidents, gave a seminar on the results of interviews with many of the pilots who survived accidents and discovered nine things that pilots learned and then forgot, never learned at all, or learned wrong. Those nine things have been dubbed “The Nine Deadly Sins.” Scott Gardiner of Seattle FSDO published, in FAA Aviation News, May-June 2004, the article discussing those nine deadly sins. Now I’m going to present them to you.
“Practical Density Altitude” by Scott Gardiner, FAA Aviation News, May-June 2004
Slide 16 – Sin #1 – Using Sea Level VSPEEDS
Slide 17 – Sin #1 – Using Sea Level VSPEEDS
If you mistakenly attempt to climb at your sea level indicated best angle of climb speed, you are probably four to seven knots too slow. You have taken an airplane whose climb performance may be poor at best and made it downright lousy! There is a really good chance the airplane will not climb at all and will simply mush into the obstacle as you will see later on in this presentation. You will also see later that combining techniques can prove to be hazardous. Use best rate of climb for the density altitude you are flying and never best angle of climb except for nearby obstacles.
There are some serious drawbacks to using best angle. A full power climb results in a high pitch angle (so much for see and avoid), poor engine cooling, close to stall speed, and may be uncomfortable for passengers. Avoid best angle of climb.
Slide 18 – Sin #2 – Using Gross Weight VSPEEDS
Vy decreases with decrease in gross weight
If you attempt to climb out of a high density altitude airport at a reduced gross weight while using your sea-level, maximum gross weight best rate of climb speed (indicated), you combine Sin#1 with Sin #2. The result can easily be that you are attempting to climb at a speed that could be 15 knots too fast! Such a mistake can turn minimal climb performance into negative climb performance! This deadly combination is precisely what is leading to our most common density altitude accidents!
Explain the effect of DA on TAS using above chart. See next page . . . .
Slide 19 – Sin #3 – Ignoring effect on TAS
Turn radius increases by the square of the TAS. The formula is TAS2/11.26 tan Θ. Assuming IAS of 150 @ sea level, standard temperature, the turn radius would be ≈ 2000’, or one-third of a mile, But at 8000’ with a temp of 95º your TAS is now 180 and the turn radius increases to ≈ 3000’. But remember! That’s turn radius – you have to double that for a 180º turn! You now need a full mile to turn around and that’s using a 45 bank angle for the maneuver. How much more power do you think you’ll need at 60 degrees of bank – remember the drag goes up 300%!
So you tell yourself, “Just slow down, turn radius will decrease.” But now with this increased AOA how much more drag are you adding. Remember, the slower you fly, the higher the induced drag, and it’s multiplied by 300%. Does your engine have enough power reserve? Very doubtful, that’s why we have the accidents.
IAS = 150
PA = 8000
Temp = 95ºF
TAS = 180
DA = 12,000
Looking at this Lift-Drag Chart, I want to throw an additional factor into it. Consider an airplane in a 30 degree bank. Induced drag increases by 33%. At 45 degrees, it increases by 100%, and at 60 degrees it increases by 300%. This is not shown on a normal L-D chart but imagine how much power your engine must now develop to maintain altitude in a 60 degree bank at a high DA (12,000’) where your engine is struggling to maintain power and altitude.
Slide 20-21 – Sin #4 – Ignoring the effects in mountainous terrain.
Considering all the information I’ve just presented to you, let’s look at the three airplanes flying straight out of the screen. Consider the effects of wind as depicted by the arrows Strong downdrafts for airplane #1 requiring additional power to maintain altitude. Airplane 2 is scooting along normally, and airplane 3 is enjoying the advantage of the updraft.
“Flying in the vicinity of a ridge results in downdrafts for the pilot of Airplane 1. Airplane 2 might escape the downdrafts, but a course reversal either to the right or to the left would leave little maneuvering room between the airplane and the ridge. Airplane 3 takes advantage of free lift from the up slope airflow and retains the advantage of an into-the-wind escape route.” The official explanation is technically correct, but it does not go far enough. Since it is questionable whether or not Airplane 2 can complete a 180-degree turn, we can assume this valley is not very wide. Most pilots choose to fly up the correct side of the valley (Airplane 3 in this case), but push on too far before deciding to reverse direction. As long as things are going well for Airplane 3, the pilot continues bravely on course. It’s only when things get tight that the pilot of Airplane 3 decides to make the 180 but turning around at this point results in a radius of turn that places the airplane somewhere between Airplanes 1 and 2. This is precisely the valley location described in the official explanation as an area of downdrafts! The trap has been sprung. Another aircraft smacks the terrain and often with fatal results.
Slide 22 – Sin #5 – Ignoring Effects on Landing Speed and Distance
Often times the discussion of density altitude is limited to takeoff distance and maybe even climb performance. But you have to think of what the airplane is doing when approaching to land as well. Remember the TAS is higher than IAS at density altitudes above sea level so that has to be considered. Imagine a worse case scenario of a runway at 8000’ elevation that downslopes to the edge of a cliff and is only 2500’ long and you have a 10 knot tailwind. So down you go to the landing. You get about halfway down the runway where you finally touch down and you realize that you may not be able to stop so smart pilot that you are you add power for a go-around forgetting that you placed the mixture in full rich for the landing. Are you going to have enough power for the go-around and be able to clear all obstacles in the process? Do you see how these hazards add up and why it is so important to plan ahead? Consider all the variables before operating in high density airports.
Slide 23 – Sin #6 – Ignoring Climb Gradient
When departing airports, be aware of your climb gradient. We are all familiar with aircraft rate of climb — it’s figured in terms of feet per minute. Climb gradient is figured in terms of feet per mile. Consider two airplanes, each climbing at 500 feet per minute. But one is climbing at 60 knots, and the other is climbing at 90 knots. Each will climb 500 feet in one minute. But the first will cover one mile during that minute, and the second will cover a mile and a half during the same minute. The first airplane is climbing 500 feet per mile, and the second is climbing only 333 feet per mile.
Remember that climb gradients are calculated in feet/nm not feet/min. And be sure to use TAS (or GS) for calculations not IAS.
Consider the ILS approach to Ketchikan, Alaska. Minimums are 288’ but the required climb gradient for the missed approach requires 335’/NM to miss a 4000’ mountain directly in front of you! Localizer circling minimums are 2440’.
Slide 24 – Sin #7 – Ignoring Runway Environment
Watch the video clip of the A36 takeoff and think about what might have gone wrong.
OAT = 97F, Field Elev =1293’ Altimeter 29.89”
Density Altitude = 4125’, Rwy 31 4000’ paved
1996 A36, Turbonormalized IO-550,
GTOW = 4095, CG = 86.15”
Different piloting techniques may have resulted in a much nicer outcome.
Now think of departing at our 8000’ elevation runway with the temperature at 95 degrees (DA 12,000’). How well is that going to go?
Slide 25 – Sin #8 – Using Incorrect Flap Settings
In the A36 incident, use of flaps may have made the situation even worse!
Use of the recommended flap setting works just fine when operating at near sea level altitudes but with non-turbocharged engines, there is a density altitude above which the use of takeoff flaps actually increases ground roll. Be sure to check the POH to ascertain if the use if flaps is recommended at high DA.
Page 26 of the A36’s POH Supplement stated, “However, when operating at the increased weights authorized when operations are conducted in the NORMAL CATEGORY expect the following:
Soft field techniques should be saved for soft fields. Just because the runway is of dirt or grass, it is not necessarily soft! Mud in which you leave 3” tracks, beach sand, 6” of snow, or 3” of sleet is a soft field.
Slide 26 – Sin #9 – Combining Soft-Field & Obstacle Techniques
Normally flaps are only used on soft field takeoffs but when used for obstacle clearance, the increase in drag drastically hinders climb performance.
There are numerous instructors out there who routinely combine obstacle takeoff techniques with soft-field takeoff techniques to save time during training. But in actual density altitude situations, a pilot should not combine the two in a normally aspirated, piston-engine airplane.
If we are trying to clear a 100’ tree, we are talking about obstacle clearance takeoffs
not minimum ground-run takeoffs.
For obstacle clearance takeoffs, follow the advice of your airplane manufacturer, which for the vast majority of non-turbocharged airplanes means flaps up and climb at best angle of climb speed for the density altitude.
Always follow manufacturer’s recommendation.
Slide 27 – Summary
Beware, better yet, be knowledgeable, of the Nine Deadly Sins of Density Altitude
Remember the effect of DA on TAS and the TAS effect on airplane performance and humidity on engine performance.
Engine performance degrades with altitude
Many members of Congress recognize the need for the legislative branch to be involved with general aviation (GA). The Federal Aviation Administrations (FAA) has an extensive rule making process that generally takes many years before guidelines change. During that time, new advancements in technology and other outside events require significant changes to the rules.
On August 3, 2012, Congress pass the first Pilot’s Bill of Rights, which was introduced by Senator James Inhofe (R-Oklamoha). This bill specifically focused on providing “fair treatment of pilots in FAA enforcement cases and NTSB reviews, streamlined the notam program, and required a review from the Government Accountability Office of the FAA’s medical certification process.” The bill was a great start to providing fairness to a dwindling and pilot population.
During the debate of the bill, Congress received many comments from pilots that the bill should be expanded to change the requirements for VFR and IFR flight by general aviation pilots. The requirement of receiving and 3rd class medical certificate is difficult, expensive and burdensome on many pilots. Additionally, the FAA has not seemed to keep up with advancements in medical science, including making arbitrary decisions on health issues.
Additionally, the safety record of the sport pilot program of self-certification using a valid state issued driver’s license has been outstanding compared with the general pilot population. What does not make sense is that there is an arbitrary gross weight limit on the aircraft that pilots can fly with a driver’s license, compare with other general aviation aircraft. There are many other options for pilots in proven air frames, such as Cessna 150/152 or 172, Piper Warrior or Cherokee, that are often cheaper to acquire, easier to maintain and often easier to fly.
Last year, Senator Inhofe started a new campaign to address the lingering concerns of pilots about the third class medical certificate requirement. On February 25, 2015, he sponsored the bill in the Senate and a similar bill was introduced in the House of Representatives. The bill lays out the following changes that are to be put into affect with 180 days of the bill passing:
The rule specifically for the self-certification using a driver’s license is far broader than the stalled FAA’s rule making process. Allowing pilots to fly with just a driver’s license in most GA aircraft is a game changer for the entire pilot population. Considering this change, there are many potential benefits, including:
There are some potential downsides to this new rule. Part of the push in the industry towards light-sport aircraft (LSA) is that a pilot can fly them without the 3rd class medical. Without that limitation on other GA aircraft, the demand for LSAs may decline, especially since the performance and capabilities of the aircraft do not often justify the cost of the new aircraft. For example, the average Cessna 150 can be purchased for $20,000-$30,000 that has similar performance characteristics of a used LSA that costs on average $60,000-$70,000. This change has the potential to stifle innovation in the LSA market unless manufacturers change quickly to offering higher performing models to compete in cost and capability with normally certificated GA aircraft.
In all, if this bill passes as-is, it will create a huge benefit for the private pilot population. Desert Flying Club encourages all its members to reach out to your congressional representatives and encourage them to support the Pilot’s Bill of Rights 2. It is possible that we could see this change happen in 2015, which would be an exciting change for general aviation!
As we start to get the word out, we’re getting some traction around the internet from other websites linking to us. You can see our listing below & see our competition – and why we’re the #1 way to learn to fly in Las Vegas or rent an airplane in Las Vegas!
Thanks to everyone that attended our very first inaugural meeting. We have 16 attendees, and a lot more people interested that weren’t able to make it! Here’s a little highlight of what we went over:
Congrats to Darcy Wood for being elected to the Board of Directors! Even though the turn-out was great, we still would be grateful for some volunteers needed to fill some of the various Club Officer Positions. Make sure you contact us if you’re interested in any one of the following positions:
All in all it was great! Thanks everyone for attending, and we’ll see you at our NEXT MEETING December 18th, at 7pm.
We have formally incorporated as a non-profit in Nevada, and our current acting Board of Directors have been meeting, discussing the formation and future of the club! It’s very exciting, and there is lots of work to do.
That’s why we need your help! There will be a lot of volunteer time & effort that goes into forming this organization and making it truly a great place to rent inexpensive airplanes, meet life-long friends, and become a more competent, safer pilot. So we’re searching for motivated people who can fill the following roles:
We have seen an immense amount of interest in the club so far. Get involved in the local aviation community & be part of something growing! You can email info@desertflying.club or use the contact us page to let us know if you or someone you know is interested in helping.
– DFC Board of Directors