The new ACS became effective May 31st 2024. Most of the changes have been made known by a wide variety of sources. (see stuff by Jason Blair and Max Trescott). Here are may take on them and some of the items that have not come up elsewhere.
Private and Commercial airplane: The FAA made some changes to the coding and clarified a few things but overall, not much has changed. Instrument Airplane: More coding changes and clarification of the use of RNAV approaches with DA could be used to demonstrate a precision approach on the checkride. The FAA also added requirements for non-precision approaches to be flown with a course reversal and one without the autopilot in a non-radar environment. Yes, the partial panel non-precision approach is still in the ACS. Instructor ACS: This is the new ACS everyone has been waiting for! How will it affect your CFI ride? In my opinion it could shorten the ride. How? Under the old PTS, a DPE had to test all the elements under the Task required and/or selected. However, under the ACS, the DPE can "sample" if you will. The requirement under the ACS is for the DPE to select one knowledge element, one risk management and all the skills under each required or selected Task. For example, under the CFI PTS, one required Task was runway incursions. That Task had 17 elements under it that were required to be evaluated. Under the CFI ACS, a DPE could develop a scenario that covers 1 Knowledge element, 1 risk management and all the Skills. So lets say the DPE give you a scenario like this......"Your student came back from his private pilot checkride with a notice of disapproval. Your student failed to write down the taxi instructions and almost crossed a runway without a clearance. The examiner had to stop the airplane as the hold short lines where reached." The DPE could ask you to take a few minutes to decide the necessary retraining and then provide it to him/her. There are a couple of new required Task in the CFI ACS. One is Risk Management. For those of you who took rides with me, odds where pretty high that we covered this. Well, now it's a required Task. Again, this is one where a scenario could be developed by the DPE for you to show your risk management teaching skills. When I did this on previous CFI rides, it was basically an academic discussion. Under the new CFI ACS I won't be doing it that way. The other new change is the applicant has to do either AOO X Task A "Maneuvering During Slow Flight" or Task B "Demonstration of Flight Characteristics at Various Configurations and Airspeeds". Task B is new. Unfortunately, the Airplane Flying Book doesn't give us step by step instructions on how to fly this maneuver but the ACS kind of eludes to how the FAA wants this maneuver to be conducted. I look at it as an energy management discussion/maneuver. Here's the problem with the ACS that may make your Ground/Oral longer, a poor score on the FOI or CFI Knowledge test. The DPE is required to include all the test codes on the knowledge test into the checkride. So if an applicant showed up with a 70% on the FOI, they will be tested on all those missed elements. You could see how this would add time. Instructor Multi Engine Add-on: First of all take a look at the Add-on Table on Page 98 of the ACS. Notice the minimum Task Required (Note, the DPE is authorized to add Tasks beyond the minimum required at their discretion. However most don't) Under AOO II Task C, K and P are required. Under the old PTS, we could skip the Runway Incursion Task under certain situation. That exception is gone. Also note that AOO XIII Task C is now required (most know this Task as the Drag Demo). Under the old PTS this maneuver was optional CFII: Well, look no ACS for the CFII? Yep. However, the FAA did do an update to it. Most of the update aligns the PTS with the requirements and policies of the Instrument ACS. Helicopter ACS: The PTS is gone and the long awaited ACSs are here. This is a major change to how helicopter check rides are conducted but overall the knowledge and Skill requirement remain the same. Except for the Autorotations. Take a look at those. I'll follow up with a more detail discussion on here shortly but for now, I recommend you give me a call to discuss. That way I can answer questions as they come up and hopefully eliminate confusion.
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New ACSs and PTS have been released by the FAA and are effective May 31,2024. Here's the link to the FAA website.
https://www.faa.gov/training_testing/testing/test_standards I'm seeing problems with the soft field landings. I'll save a bunch of work and just copy and paste right from the FAA's Airplane Flying Handbook. I will highlight some key point to keep in mind.
Soft-Field Approach and Landing Landing on fields that are rough or have soft surfaces, such as snow, sand, mud, or tall grass, requires unique procedures. When landing on such surfaces, the objective is to touch down as smoothly as possible and at the slowest possible landing speed. A pilot needs to control the airplane in a manner that the wings support the weight of the airplane as long as practical to minimize stresses imposed on the landing gear by a rough surface or to prevent sinking into a soft surface. The approach for the soft-field landing is similar to the normal approach used for operating into long, firm landing areas. The major difference between the two is that a degree of power is used throughout the level-off and touchdown for the soft-field landing. This allows the airspeed to slowly dissipate while the airplane is flown 1 to 2 feet off the surface in ground effect. When the wheels first touch the ground, the wings continue to support much of the weight of the airplane. This technique minimizes the nose-over forces that suddenly affect the airplane at the moment of touchdown. The use of flaps during soft-field landings aids in touching down at minimum speed and is recommended whenever practical. In low-wing airplanes, the flaps may suffer damage from mud, stones, or slush thrown up by the wheels. If flaps are used, it is generally inadvisable to retract them during the after-landing roll because the need for flap retraction is less important than the need for total concentration on maintaining full control of the airplane. The final-approach airspeed used for short-field landings is equally appropriate to soft-field landings. The use of higher approach speeds may result in excessive float in ground effect, and floating makes a smooth, controlled touchdown even more difficult. There is no reason for a steep angle of descent unless obstacles are present in the approach path. Touchdown on a soft or rough field is made at the lowest possible airspeed with the airplane in a nose-high pitch attitude. In nose-wheel type airplanes, after the main wheels touch the surface, the pilot should hold sufficient back-elevator pressure to keep the nose-wheel off the surface. Using back-elevator pressure and engine power, the pilot can control the rate at which the weight of the airplane is transferred from the wings to the wheels. Field conditions may warrant that the pilot maintain a flight condition in which the main wheels are just touching the surface but the weight of the airplane is still being supported by the wings until a suitable taxi surface is reached. At any time during this transition phase, before the weight of the airplane is being supported by the wheels, and before the nose-wheel is on the surface, the ability is retained to apply full power and perform a safe takeoff (obstacle clearance and field length permitting) should the pilot elect to abandon the landing. Once committed to a landing, the pilot should gently lower the nose-wheel to the surface. A slight addition of power usually aids in easing the nose-wheel down. The use of brakes on a soft field is not needed and should be avoided as this may tend to impose a heavy load on the nose-gear due to premature or hard contact with the landing surface, causing the nose-wheel to dig in. The soft or rough surface itself provides sufficient reduction in the airplane’s forward speed. Often upon landing on a very soft field, an increase in power may be needed to keep the airplane moving and from becoming stuck in the soft surface. Common Errors 1118 Common errors in the performance of soft-field approaches and landings are: Excessive descent rate on final approach.
I don't know how IFR fuel planning got so difficult but here's one one way.
1. Time & Fuel to destination 2. Time & Fuel for approach 3. Time & Fuel to Alternate 4. Time & Fuel for approach at Alt: 5. 45 Min FAA reserve 6. FAA Required fuel (the sum of 1-5) 7. Time and fuel for Holding (known delays) 8. Extra or Contingency fuel 9. Total fuel (Sum of 6-8) Number 6 is the fuel required by CFR 91.167*** Number 7 is used to account for any known delays. Number 8 is used for my personal minimums. Number 9 is my planned take off fuel. If you are using an EFB for flight planning, the program may hide some of this info in different places or calculate it as you think it should. So in my 182 you may see me have something written out like this for a trip from JVL to EAU with an Alternate of LSE. 1. Time & Fuel to destination 1+40 21.7 2. Time & Fuel for approach +15 3.5 3. Time & Fuel to Alternate +26 6.0 4. Time & Fuel for approach at Alt: +15 3.5 5. 45 Min FAA reserve +45 10.5 6. FAA Required fuel (the sum of 1-5) 2+36 45.2 7. Time and fuel for Holding (known delays) 0 0 8. Extra or Contingency fuel +45 10.5 9. Total fuel (Sum of 6-8) 3+21 55.7 ***Per an FAA legal interpretation fuel for the approach is required to be added. Putting this out there for everyone. I don't do check rides in experimental aircraft and I also don't do check rides in airplanes without shoulder harness.
Several problems have been occurring across all type of check rides. Some of them I thought were put to rest years ago. The biggest thing you can do to help yourself or your student (or Learner as the FAA wants these days) is to be familiar with the applicable ACS or PTS. Here is a quick rundown....
1. Using a POH/AFM that doesn't apply to the aircraft we are flying. For example, using a 172S model POH for performance data when we are flying 172M model. 2. Using generic weight and balance data instead of the actual empty weight and CG of the aircraft we are flying. This includes finding the Actual weight and balance in the aircraft POH/AFM. 3. Relying on EFB data too much. These are wonderful tools but they have limitations and can produce inaccurate information. Remember, garbage in equals garbage out. Be able to explain where the data going in came from and what are some of the ways that you verify the data is correct. 4. If the student is old school and uses paper, that's fine but again, be able to explain how you got your answers. For example, several applicants planned a cross country using a cruising speed in MPH, measured the distance in NM and the winds aloft in KTS. 5. Aircraft systems. Simply put, applicants don't know their aircraft. Sure you will be asked questions on systems but a lack of knowledge show up during preflights as well. 6. Stall and Spins. I ask a scenario question that a lot of people miss. That scenario is based on a real accident. Another easy question I ask, What's more important during stall recovery, Adding power or lowering the nose? You wouldn't believe the number of people that get that wrong. That's all for now. Fly Safe! Unfortunatly, I have had a number of "No Shows" or canceling with little notice happen recently. So, If I haven't work with you or your school in the past, or you are coming from a place far, far away, I maybe asking for a 50% deposit to hold a spot on the schedule. I will apply the deposit to the checkride fee. If you "no-show" or cancel within 24 hours I will keep the deposit. I know that aircraft break and people get sick, so I will extend the deposit if you reschedule with me.
I've used several scenarios in my check rides for over a decade. Here are are a few to think about. Note, you may or may not get one of these on your checkride with me. I do like to change things around as I don't like to get board!
Private pilot: You have been asked to do a Pilot and Paw’s trip to deliver a Golden Retriever puppy to its new family in KXYZ. The puppy and crate weigh 35 lbs. A handler will be going with who weighs 160 lbs. Plan the VFR cross country based on the current weather conditions. Instrument: You have volunteered to fly a trip for Angle Flight East taking a 55 year old man to RST so he can have some medical tests done at the Mayo Clinic. Pax weighs 160 lbs. Plan the IFR flight based on MVFR weather. Commercial: Doctor Sweet is a private pilot who owns the same type of airplane as you. She is planning a long weekend in the KXYZ area to do some shopping and see a baseball game with her daughter. Because she has surgeries scheduled all day, she doesn’t feel she will be fit to fly so she hires you. Her daughter weighs 120 lbs and the Dr. weighs 135lbs. She wants to depart your airport 5pm. The weather is forecast to be visual flight rules (VFR) all weekend. Multi Engine: You have been asked to fly this twin to KXYZ for a repurchase inspection. Prepare a cross country with all the performance planning you've been taught. The current owner is going with and he weighs 160 lbs. (Note: regarding the cross country, we will only be discussing the power settings, speed and fuel flow performance data you would use on a trip like this and nothing else). Initial CFI: You are the new CFI in Rapid City, SD (RAP). A young man walks into your part 61 flight school wanting to get his private pilot ASEL Rating. He already holds a private pilot glider rating. He signs on as your student. What training requirements will he need to accomplish to take his private pilot check ride? What endorsements are you going to give him? CFII: I am your Instrument student and today is the day to do my long IFR cross country per 61.65. Walk me through what requirements we must complete and how to plan the first leg of this IFR cross country. The weather is at VFR minimums throughout the trip. CFI-ME: Today is my first multi engine flight lesson with you. Let's talk about how your take off briefing correlates with the take off performance of a light twin engine airplane. |
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