Ethiopian airliner down in Africa
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Stabilizer Trim Runaway. a malfunction which occurs when the Trimmable Horizontal Stabiliser (THS), or tailplane, on the aircraft tail fails to stop at the selected position and continues to deflect up or down.
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A stab trim runaway affecting the fly ability of the aircraft is no time to “figure out “ anything. The figuring out happens back on terra firma. Whether the source of the runaway is a short circuit in a switch or motor, MCAS or anything other source, when the aircraft experiences uncommanded flight control movements in pitch it’s a stab trim runaway for which there is a clear and simple memory drill. The instinctive thing would to pull or push to restore the desired path then trim for it with the electric trim switches, even if it means long burst of trim. Whatever it takes. If the trim continues to be uncontrollable, turn it off and manually trim with the wheel, however one has to be flying at something less than Vmo to do that which means controlling the thrust or, in other words, flying the airplane.
Press play below before reading on...
This was not a classic runaway trim. No trim issues were encountered until the flaps were retracted. Retract flaps, now some forward trim starts, trim back with the electric trim and everything is good for 5 seconds, just enough time to start thinking about else, there goes the trim again, fix it with electric trim, all good for 5 seconds, repeat until end of sequence. You are also dealing with an airspeed unreliable. Not easy with that racket going on the background.
To the pilots in all three event flights, this was a trim fight, not a continuous runaway in the QRH condition statement for a Runaway Stabilizer. Judge for yourself from a current in-service document:
Condition: Uncommanded stabilizer trim occurs continuously
The Lion Air crews were in the worst position, they had no prior knowledge of the subtle system changes and faults that had led them to trim fight, not a runaway.
I am not disagreeing with you but if it was a trim fight, then why could they not keep the aircraft flying (albeit very untidily), and keep on feeding opposing trim inputs to return to land?
Why were the pilots in fear and panicked? Why did they not run their memory drills?
I would like to think that faced with this problem, I would think right bugger this : “pitch - power - speed”, now what the hell is going on? But would I ?
I think SIM training needs to be seriously looked at. UAS (and trim runaway) drills are pre-briefed, and the actions explained. Then into the SIM and a UAS event occurs. Unsurprisingly, the pilots do the drill and recover the aircraft. Tick. Next item.
But UAS is not done every SIM visit every 6 months. It might only be done once every 2 or 3 years, as the training cycle rotates. Even then, it will be one of several training elements the pilots will do in that SIM session, and each pilot will typically fly just one of each exercise each, then move on to the next training item.
Just as we always have to do an engine failure at take-off, a single engine ILS to a go-around, then a single engine NPA, I think that we should always practice situations where we have to revert to basic pitch - power - speed. No autopilots, no flight directors, no auto-thrust, no speed reading/UAS. And it should be sprung on us with no prior warning. Recovery from UAS or unusual aircraft behaviour needs to be an instinctive reflex.
(For Single engine, read OEI.)
Why were the pilots in fear and panicked? Why did they not run their memory drills?
I would like to think that faced with this problem, I would think right bugger this : “pitch - power - speed”, now what the hell is going on? But would I ?
I think SIM training needs to be seriously looked at. UAS (and trim runaway) drills are pre-briefed, and the actions explained. Then into the SIM and a UAS event occurs. Unsurprisingly, the pilots do the drill and recover the aircraft. Tick. Next item.
But UAS is not done every SIM visit every 6 months. It might only be done once every 2 or 3 years, as the training cycle rotates. Even then, it will be one of several training elements the pilots will do in that SIM session, and each pilot will typically fly just one of each exercise each, then move on to the next training item.
Just as we always have to do an engine failure at take-off, a single engine ILS to a go-around, then a single engine NPA, I think that we should always practice situations where we have to revert to basic pitch - power - speed. No autopilots, no flight directors, no auto-thrust, no speed reading/UAS. And it should be sprung on us with no prior warning. Recovery from UAS or unusual aircraft behaviour needs to be an instinctive reflex.
(For Single engine, read OEI.)
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I am not disagreeing with you but if it was a trim fight, then why could they not keep the aircraft flying (albeit very untidily), and keep on feeding opposing trim inputs to return to land?
Why were the pilots in fear and panicked? Why did they not run their memory drills?
I would like to think that faced with this problem, I would think right bugger this : “pitch - power - speed”, now what the hell is going on? But would I ?
I think SIM training needs to be seriously looked at. UAS (and trim runaway) drills are pre-briefed, and the actions explained. Then into the SIM and a UAS event occurs. Unsurprisingly, the pilots do the drill and recover the aircraft. Tick. Next item.
But UAS is not done every SIM visit every 6 months. It might only be done once every 2 or 3 years, as the training cycle rotates. Even then, it will be one of several training elements the pilots will do in that SIM session, and each pilot will typically fly just one of each exercise each, then move on to the next training item.
Just as we always have to do an engine failure at take-off, a single engine ILS to a go-around, then a single engine NPA, I think that we should always practice situations where we have to revert to basic pitch - power - speed. No autopilots, no flight directors, no auto-thrust, no speed reading/UAS. And it should be sprung on us with no prior warning. Recovery from UAS needs to be an instinctive reflex.
(For Single engine, read OEI.)
Why were the pilots in fear and panicked? Why did they not run their memory drills?
I would like to think that faced with this problem, I would think right bugger this : “pitch - power - speed”, now what the hell is going on? But would I ?
I think SIM training needs to be seriously looked at. UAS (and trim runaway) drills are pre-briefed, and the actions explained. Then into the SIM and a UAS event occurs. Unsurprisingly, the pilots do the drill and recover the aircraft. Tick. Next item.
But UAS is not done every SIM visit every 6 months. It might only be done once every 2 or 3 years, as the training cycle rotates. Even then, it will be one of several training elements the pilots will do in that SIM session, and each pilot will typically fly just one of each exercise each, then move on to the next training item.
Just as we always have to do an engine failure at take-off, a single engine ILS to a go-around, then a single engine NPA, I think that we should always practice situations where we have to revert to basic pitch - power - speed. No autopilots, no flight directors, no auto-thrust, no speed reading/UAS. And it should be sprung on us with no prior warning. Recovery from UAS needs to be an instinctive reflex.
(For Single engine, read OEI.)
Unfortunately executive level management across the industry have seen automation as their nirvana, it reduces training costs if you get a pilot to stick in an autopilot at 500' and disconnect at the minima. It can be a measured skill, and therefore converted into a KPI for automated compliance monitoring, which equates to a the safest possible operation in the executives mind. The issue is the industry has deskilled it's pilots in the quest for the minimum training footprint. It works until those rusty or non-existent skills are required on a dark and stormy night. Loss of control is the major source of fatalities in the industry. Until there is a genuine commitment to keeping up the basic flying skills, these type of accidents will occur. Boeing didn't help with the MAX.
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That’s a fair point. My response and likely that of my “cohorts” is this: what was presented to the three crews upon lift-off was a classic Unreliable Airspeed (UAS) scenario which is a an emergency that any B737 type rated pilot ought to have seen in a simulator complete with all the bells, whistles and other distractions. The fidelity of simulators is really quite amazing.
So how is it that 1/3 crews did the drill and saved the aircraft (by controlling and flying the aircraft including a managing its speed thanks to doing the UAS drill) while the other 2 crews did not do the drill which ultimately lead to an uncontrollable aircraft as speed was so high that no human could manually trim the aircraft?
Once we have addressed that issue then the next one is how is it that the successful Lion Air crew needed a jumpseat pilot to point out that they had a runaway stab trim and the fatal Lion Air crew was thumbing through the checklist looking for a memory item when they lost control of the aircraft.
To me, this points to a serious training issue at both of these airlines.
Like, the first step in response is probably to ensure that pilots' rational minds do indeed know how to recover the aircraft in a classroom setting. If that's missing then yeah, incompetence, basic training issue, needs fixing immediately. It's possible that this was missing in all three of these cases. It's also possible, based on available evidence, that it wasn't; in this scenario, we proceed to the next step.
If the pilots' rational minds have the solution but they're not applying it, then my understanding of human factors suggests that the likely problem is that their reacting minds - Mark Levy's "chimpanzee brain" from the video linked earlier - is siezing control, in keeping with a few billion years of evolutionary training, and letting the aircraft fly itself into the ground, because chimpanzees can't fly jet aircraft.
There's a couple of obvious approaches to deal with this scenario. The first is to figure out what stimuli are causing the chimpanzee to take over, and removing those stimuli. This is classic human factors work. For example, the stick shaker is AIUI a nice bit of human factors design that is intended to reliably break the pilot's concentration and draw attention to the fact that the aircraft is approaching a stall. Probably there is an amount of time it needs to run before 99.9% of humans have consciously noted it, and that's probably single-digit seconds. Having it drop down to an insistent throb after that point might maintain the information while allowing the pilot to concentrate again. (Maybe this is the wrong fix; the point is that this is the *class* of solution you'd be looking for.)
The second one is to actively train the chimpanzee to sit down and shut up, which probably requires replicating the systems' conditions more faithfully in training. Yes, a simulator captures the aircraft system's condition very accurately, I'm not disputing that, but it's not obvious that it's capturing the human system's condition. Specifically, I would imagine that the chimpanzee learns very quickly that the simulator is essentially safe and it has nothing to worry about, so it doesn't flip out if it suspects the simulator is about to crash. In a real in-flight emergency, that's not going to be the case, so pilots probably should be explicitly trained to manage their own minds and bodies in emergency situations to prevent the chimp from taking over.
One possible solution (on which there is probably a bunch of research that may show it to be a very poor idea) would be to hook crews up to an IV line in sim training, and give them a massive slug of adrenaline when they first realise something is wrong. Their body is then going to want to drop into a classic fight-or-flight response; given that a stall can neither be run away from nor punched to death, this is unproductive, so you'd want to train pilots to manage this physiological process so they can get back to applying their rational-mind training as quickly as possible, and fly the damn plane. If they don't have this training, it's not surprising that they're failing at this in real life, and if that's the case then all the sim time and process-knowledge in the world isn't going to save them.
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I confess I have not read ALL the previous posts. I trust I am not treading on anyone's toes here. Pitch-power-speed is the go-to mantra for most of us who learned to fly with an AVGAS engine, a fixed pitch propeller in front of us and an instructor to our right. However, when the aircraft misbehaves in an unexpected fashion not mentioned in any QRH or training manual then the sense of disorientation, surprise, incredulity, inadequacy, anger, and frustration will swamp the brain and preclude all rational thought. Disengaging the auto-pilot, leveling the wings, looking for the horizon, and applying 75% of available power will still appear to the observer as a failed exercise and lead to further confusion etc, intensifying the cycle until utter hopelessness swamps the poor pilot. Imho, these two MAX 8 crashes were design faults and Boeing is squarely to blame for the failure to engage with owners regarding the subtle changes to the anti-stall system. I am glad I was not on board because even though we can all sit here and imagine that we would have done it differently, many of us might not.
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An undocumented system of which the pilots have no clue it even exists can interrupt airplane trim. If the pilot doesn't want to end in a coffin corner, they need to figure out on the spot that:
- this is not STS
- because it's not STS it must be either a bug or an undocumented system
- to save their lives they need to return the trim manually to a low/zero column force each time the undocumented command is triggered.
Despite facing those conditions, the Lion Air crew managed to react appropriately about 2 dozen cycles. Fighting the unknown system raised pilot's adrenaline and fear and induced panic. Thus, incapacitated by stress put on them, they no longer managed to manually correct the erroneous system input that was trying to - and succeeded to - kill them.
- this is not STS
- because it's not STS it must be either a bug or an undocumented system
- to save their lives they need to return the trim manually to a low/zero column force each time the undocumented command is triggered.
Despite facing those conditions, the Lion Air crew managed to react appropriately about 2 dozen cycles. Fighting the unknown system raised pilot's adrenaline and fear and induced panic. Thus, incapacitated by stress put on them, they no longer managed to manually correct the erroneous system input that was trying to - and succeeded to - kill them.
Regarding your last paragraph, one theory is that for some reason the pilot who had been successfully countering MCAS for 24 cycles transferred control to the other pilot, who did not put in sufficiently large opposite trim inputs and lost it in three cycles.
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Sorry, but your wrong. I’ve been flying 737’s for the last 28+ years. That covers the 200, 300, 500, 700, 800 and I have about a dozen flights in the Max8. You could take about 70-80% of just the -200 cockpit and use it for spare parts on a Max8. Same switches, gauges, lights, etc. The list goes on.
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@SystemsNerd
That kind of intensive training was used for early astronauts (The Right Stuff), since the risks were very high, but the dropout rate was very high. Some of today's veteran pilots with military fast-jet experience, might also have gone through that process. In the current era of widespread passenger jet transportation, I don't think that kind of training is viable.
One possible solution (on which there is probably a bunch of research that may show it to be a very poor idea) would be to hook crews up to an IV line in sim training, and give them a massive slug of adrenaline when they first realise something is wrong. Their body is then going to want to drop into a classic fight-or-flight response; given that a stall can neither be run away from nor punched to death, this is unproductive, so you'd want to train pilots to manage this physiological process so they can get back to applying their rational-mind training as quickly as possible, and fly the damn plane. If they don't have this training, it's not surprising that they're failing at this in real life, and if that's the case then all the sim time and process-knowledge in the world isn't going to save them.
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In the isolation of a simulator session where the sim instructor selects a runaway trim malfunction, fully agree with you.
Press play below before reading on...
https://youtu.be/TrjTUvhpBlE
This was not a classic runaway trim. No trim issues were encountered until the flaps were retracted. Retract flaps, now some forward trim starts, trim back with the electric trim and everything is good for 5 seconds, just enough time to start thinking about else, there goes the trim again, fix it with electric trim, all good for 5 seconds, repeat until end of sequence. You are also dealing with an airspeed unreliable. Not easy with that racket going on the background.
To the pilots in all three event flights, this was a trim fight, not a continuous runaway in the QRH condition statement for a Runaway Stabilizer. Judge for yourself from a current in-service document:
The trim worked as they expected, sort of. If English was not your first language, it would be even more difficult.
The Lion Air crews were in the worst position, they had no prior knowledge of the subtle system changes and faults that had led them to trim fight, not a runaway.
Press play below before reading on...
https://youtu.be/TrjTUvhpBlE
This was not a classic runaway trim. No trim issues were encountered until the flaps were retracted. Retract flaps, now some forward trim starts, trim back with the electric trim and everything is good for 5 seconds, just enough time to start thinking about else, there goes the trim again, fix it with electric trim, all good for 5 seconds, repeat until end of sequence. You are also dealing with an airspeed unreliable. Not easy with that racket going on the background.
To the pilots in all three event flights, this was a trim fight, not a continuous runaway in the QRH condition statement for a Runaway Stabilizer. Judge for yourself from a current in-service document:
Condition: Uncommanded stabilizer trim occurs continuously
The Lion Air crews were in the worst position, they had no prior knowledge of the subtle system changes and faults that had led them to trim fight, not a runaway.
In November 2018, after Lion Air, some (or all) operators, changed the checklist list and removed the word “continuous”.
Last edited by Lost in Saigon; 3rd May 2019 at 12:40.
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Hard to keep up ...
But this comes from the Wall Street Journal:
Boeing test pilots lacked key details of 737 MAX flight-control system
Boeing limited the role of its own pilots in the final stages of developing the 737 MAX flight-control system implicated in two fatal crashes, departing from a longstanding practice of seeking their detailed input, people familiar with the matter said.
As a result, Boeing test pilots and senior pilots involved in the MAX’s development didn’t receive detailed briefings about how fast or steeply the automated system known as MCAS could push down a plane’s nose, these people said.
But this comes from the Wall Street Journal:
Boeing test pilots lacked key details of 737 MAX flight-control system
Boeing limited the role of its own pilots in the final stages of developing the 737 MAX flight-control system implicated in two fatal crashes, departing from a longstanding practice of seeking their detailed input, people familiar with the matter said.
As a result, Boeing test pilots and senior pilots involved in the MAX’s development didn’t receive detailed briefings about how fast or steeply the automated system known as MCAS could push down a plane’s nose, these people said.
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Hard to keep up ...
But this comes from the Wall Street Journal:
Boeing test pilots lacked key details of 737 MAX flight-control system Boeing limited the role of its own pilots in the final stages of developing the 737 MAX flight-control system implicated in two fatal crashes, departing from a longstanding practice of seeking their detailed input, people familiar with the matter said.
As a result, Boeing test pilots and senior pilots involved in the MAX’s development didn’t receive detailed briefings about how fast or steeply the automated system known as MCAS could push down a plane’s nose, these people said.
But this comes from the Wall Street Journal:
Boeing test pilots lacked key details of 737 MAX flight-control system Boeing limited the role of its own pilots in the final stages of developing the 737 MAX flight-control system implicated in two fatal crashes, departing from a longstanding practice of seeking their detailed input, people familiar with the matter said.
As a result, Boeing test pilots and senior pilots involved in the MAX’s development didn’t receive detailed briefings about how fast or steeply the automated system known as MCAS could push down a plane’s nose, these people said.
Summary:
- Mistakes began nearly a decade ago when Boeing was caught flat-footed after its archrival Airbus announced a new fuel-efficient plane that threatened the company’s core business. It rushed the competing 737 Max to market as quickly as possible.
- In developing the Max, Boeing not only cut corners, but it touted them as selling points for airlines. Since the 737 Max was the same plane type as its predecessors, pilots would only need a 2.5-hour iPad training to fly its newest iteration.
- MCAS is the new software system blamed for the deadly Lion Air and Ethiopian Airlines crashes. But its failure in both crashes was the result of Boeing and the Federal Aviation Administration’s reluctance to properly inform pilots of its existence or to regulate it for safety.
- The FAA has admitted to being incompetent when regulating software, and, as a policy, it allows plane manufacturers to police themselves for safety. Nowhere in its amended type certification of the 737 Max is MCAS mentioned.
- Even still, Boeing only recommends a 30-minute self-study course for pilots on MCAS, rather than additional simulator or classroom instruction.
- Despite the two crashes, neither Boeing nor the FAA believes they’ve done anything wrong. A Boeing spokesperson said the company believes the system is still “a robust and effective way for the FAA to execute its oversight of safety.”
- In developing the Max, Boeing not only cut corners, but it touted them as selling points for airlines. Since the 737 Max was the same plane type as its predecessors, pilots would only need a 2.5-hour iPad training to fly its newest iteration.
- MCAS is the new software system blamed for the deadly Lion Air and Ethiopian Airlines crashes. But its failure in both crashes was the result of Boeing and the Federal Aviation Administration’s reluctance to properly inform pilots of its existence or to regulate it for safety.
- The FAA has admitted to being incompetent when regulating software, and, as a policy, it allows plane manufacturers to police themselves for safety. Nowhere in its amended type certification of the 737 Max is MCAS mentioned.
- Even still, Boeing only recommends a 30-minute self-study course for pilots on MCAS, rather than additional simulator or classroom instruction.
- Despite the two crashes, neither Boeing nor the FAA believes they’ve done anything wrong. A Boeing spokesperson said the company believes the system is still “a robust and effective way for the FAA to execute its oversight of safety.”
And many pilots felt that, for the first new 737 in over 20 years, Boeing seemed to be oddly reluctant to prep them for it.
Captain Laura Einsetler, who’s flown for over 30 years, including on 737s, considers an all-computer-based course to be completely inadequate as an introduction to a new airplane.
“I don’t have the schematics. I don’t have the cockpit panels. I don’t have an instructor that I can ask questions to,” she says. “You’re hoping that the first time you see the Max is on a nice clear day. But sometimes it’s not, and you’re showing up at night or in bad weather into an airplane that has all these changes.”
Captain Laura Einsetler, who’s flown for over 30 years, including on 737s, considers an all-computer-based course to be completely inadequate as an introduction to a new airplane.
“I don’t have the schematics. I don’t have the cockpit panels. I don’t have an instructor that I can ask questions to,” she says. “You’re hoping that the first time you see the Max is on a nice clear day. But sometimes it’s not, and you’re showing up at night or in bad weather into an airplane that has all these changes.”
The subtext: pilots were on a need-to-know basis about MCAS, and until the Lion Air crash, Boeing felt that they hadn’t needed to know.
Einsetler strongly disagrees. “We need to have the understanding and knowledge of how everything works on the jet, so that we can command the jet to do what we need it to do, not just be along for the ride,” she says.
“Not a lot of information got out there in a timely fashion,” concurs Juan Browne, a 777 pilot with over 40 years of flying experience. “It almost makes me wonder, did Boeing engineers themselves really understand how much power and authority they built into this system?”
Einsetler strongly disagrees. “We need to have the understanding and knowledge of how everything works on the jet, so that we can command the jet to do what we need it to do, not just be along for the ride,” she says.
“Not a lot of information got out there in a timely fashion,” concurs Juan Browne, a 777 pilot with over 40 years of flying experience. “It almost makes me wonder, did Boeing engineers themselves really understand how much power and authority they built into this system?”
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Quote:
Originally Posted by SystemsNerd Thus, when asking "why didn't they just fly the plane?", one possible answer is undoubtedly some variant on "they were incompetent". But another possible answer is "they were put into a scenario in which any human being would consistently fail to solve the problem, regardless of competence". Probably the truth is somewhere between those two points.
So if you are running through memory items of an NNC - and you read the EICAS you may miss NNC items or not understand the EICAS - if the PM is shouting at you it may just be noise - if there is sufficient noise that channel stops completely and you do not even hear/comprehend the PM or that cavalry charge.
Mixed into this is the effect of the level of stress/alertness. This is normally referred to as an 'inverted U'.
from MindTools.com
So when you are bored with low stress your performance is actually poor, A little pressure / stress and your performance is ideal, but too much high stress and your performance will drop off rapidly.
Putting all that into an aviation perspective, A well trained pilot with experience of things going pear shaped and operating under pressure will not feel so much stress and concentrate on one item at a time and a lot of what will be done will be (what is called here ) muscle memory - innate training like stamping on a brake or steering a bike to stay balanced - or trimming an aircraft - it requires no thought as it is second nature. This is the importance of training - with not so much training it is easy to get into the overstressed very low performance state and 'get behind the aircraft'. The more inputs you are given the higher the stress and the less you are able to process and the normal human reaction to that is what is known as attentional or cognitive tunneling - a concentration on one aspect of what is happening that you _do_ think you can control and a total disregard of anything else. Everyone is different in this regard and the only way to avoid getting into the wrong side of the U is training, repeated training to get that muscle memory. Unfortunately, there is always a beancounter standing in the way of that.
Yo gums,
Further to my comments on your additional request for ‘aero’ explanation ( Ethiopian airliner down in Africa) see the following:-
‘During design of the MAX, Boeing added two more leading-edge vortilons [generating vortices over the top of the wing at high AOA] in 2018, for a total of six per side and also lengthened and raised the inboard leading-edge stall strips to assure stall behavior would be as docile as that of the NG’.
(https://www.twu557.org/index.php/new...x-new-software)
This suggests that Boeing had identified issues earlier than I suggested; also because of the nature of the changes the aero effects were more significant than currently being discussed for MCAS.
The use of vortilons might be a simple alternative to adding many more vortex generators, but stall strips to reinforce the inner-wing stall before outboard sections, opposing pitch up, is more like ‘a new aircraft’ fix.
A very crude comparison of the effects of nacelle lift might be made with military blended wing / fuselage, or leading edge extensions; what ever these provide for the fighter world then its not helpful in commercial aviation - or at least a same type rating for the 737 MAX.
Also, Boeing ‘Commenting on criticism of the single string failure potential of the AOA input to MCAS, a Boeing official said the original design was based on a standard industry process of hazard classification which defined the potential failure as one that could be mitigated “very quickly performed by a trained pilot using established procedures”.
Add to that, a remarkable comment from the FAA; “Pilots of large aircraft are trained from Day 1. When the pitch of the aircraft is doing something you’re not telling it to do, you do a runaway pitch trim checklist,” Acting FAA Administrator Dan Elwell, a former airline pilot …
This does not add confidence that the FAA have a good understanding of training, nor the much wider safety aspects of loss of control (for wind-shear / turbulence pitch up - do we always inhibit trim ! )
https://www.twu557.org/index.php/new...-human-factors
Then re the training discussion:-
‘Pilots for three U.S. air carriers tell … that during their sim training they had never been exposed to extreme and continuous AOA indication errors, they’ve not experienced AOA induced airspeed and altitude deviations on PFDs and have not had to deal with continuous stall-warning stickshaker distractions. They also note that they have never been required to fly the aircraft from the point at which a runaway stab trim incident occurred all the way to landing using only the manual trim wheels. “We’re just checking boxes for the FAA,” says one Seattle-based pilot’.
P.S. some web links may be transposed, or changed by the host site - search news items (I’m working on it).
Further to my comments on your additional request for ‘aero’ explanation ( Ethiopian airliner down in Africa) see the following:-
‘During design of the MAX, Boeing added two more leading-edge vortilons [generating vortices over the top of the wing at high AOA] in 2018, for a total of six per side and also lengthened and raised the inboard leading-edge stall strips to assure stall behavior would be as docile as that of the NG’.
(https://www.twu557.org/index.php/new...x-new-software)
This suggests that Boeing had identified issues earlier than I suggested; also because of the nature of the changes the aero effects were more significant than currently being discussed for MCAS.
The use of vortilons might be a simple alternative to adding many more vortex generators, but stall strips to reinforce the inner-wing stall before outboard sections, opposing pitch up, is more like ‘a new aircraft’ fix.
A very crude comparison of the effects of nacelle lift might be made with military blended wing / fuselage, or leading edge extensions; what ever these provide for the fighter world then its not helpful in commercial aviation - or at least a same type rating for the 737 MAX.
Also, Boeing ‘Commenting on criticism of the single string failure potential of the AOA input to MCAS, a Boeing official said the original design was based on a standard industry process of hazard classification which defined the potential failure as one that could be mitigated “very quickly performed by a trained pilot using established procedures”.
Add to that, a remarkable comment from the FAA; “Pilots of large aircraft are trained from Day 1. When the pitch of the aircraft is doing something you’re not telling it to do, you do a runaway pitch trim checklist,” Acting FAA Administrator Dan Elwell, a former airline pilot …
This does not add confidence that the FAA have a good understanding of training, nor the much wider safety aspects of loss of control (for wind-shear / turbulence pitch up - do we always inhibit trim ! )
https://www.twu557.org/index.php/new...-human-factors
Then re the training discussion:-
‘Pilots for three U.S. air carriers tell … that during their sim training they had never been exposed to extreme and continuous AOA indication errors, they’ve not experienced AOA induced airspeed and altitude deviations on PFDs and have not had to deal with continuous stall-warning stickshaker distractions. They also note that they have never been required to fly the aircraft from the point at which a runaway stab trim incident occurred all the way to landing using only the manual trim wheels. “We’re just checking boxes for the FAA,” says one Seattle-based pilot’.
P.S. some web links may be transposed, or changed by the host site - search news items (I’m working on it).
Last edited by PEI_3721; 3rd May 2019 at 13:01. Reason: P.S.
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Originally Posted by 737 Driver
I have no doubt that this is true, but it is also largely irrelevant from a procedural viewpoint. The pilots don’t need to be able to read a wiring diagram and tell you all the things that happens when they throw the cutout switches. They just need to know when they need to throw the cutout switches - as in the case of the runaway stab trim procedure.
When I was taught to fly, PPL through CPL etc, it was instilled in me to understand what every switch/knob did before I played with it (initial thanks to Norman Buddin, ex Hunter pilot and CFI). We were not in the business of altering things without understanding the impact.
So, please correct me if I am wrong, but earlier versions of the 737 had two distinct outcomes associated with the two stab trim switches whilst the Max basically has two switches in series? Somewhere along the line a change operating procedures seem to have pre-dated the wiring change. I’m trying to understand why pre-Max pilots didn’t know, or weren’t told about, the difference between the switches. Isn’t it better airmanship to understand why, what and how when managing aircraft systems, or are we witness to the pre-cursor of ‘Children of the Magenta’ in pilots who never questioned why they threw two switches and what each did?
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"In November 2018, after Lion Air, some (or all) operators, changed the checklist list and removed the word “continuous”."
"By this definition, isn't any STS operation a trim runaway? "
“Pilots of large aircraft are trained from Day 1. When the pitch of the aircraft is doing something you’re not telling it to do, you do a runaway pitch trim checklist,” Acting FAA Administrator Dan Elwell, a former airline pilot …"
Cool. Looks like we're finally going to get my F/Os some experience in using the manual trim wheel.
When I was taught to fly, PPL through CPL etc, it was instilled in me to understand what every switch/knob did before I played with it (initial thanks to Norman Buddin, ex Hunter pilot and CFI). We were not in the business of altering things without understanding the impact.
Cows Getting Bigger (best username ever!), I agree with you 100%...and would add my thanks to Swede Gamble ("Know Gamble in Aviation").
"By this definition, isn't any STS operation a trim runaway? "
“Pilots of large aircraft are trained from Day 1. When the pitch of the aircraft is doing something you’re not telling it to do, you do a runaway pitch trim checklist,” Acting FAA Administrator Dan Elwell, a former airline pilot …"
Cool. Looks like we're finally going to get my F/Os some experience in using the manual trim wheel.
When I was taught to fly, PPL through CPL etc, it was instilled in me to understand what every switch/knob did before I played with it (initial thanks to Norman Buddin, ex Hunter pilot and CFI). We were not in the business of altering things without understanding the impact.
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MCAS can be interrupted with the electric trim switches on the yoke each time it activates, and trim can be returned to a low/zero column force state each time if the pilot puts in adequate opposite trim inputs. That is what the Lion Air crew did for approximately 2 dozen cycles of MCAS before the final few cycles, where the pilot flying at that point failed to put in an adequate amount of opposite trim in those final cycles, allowing the out of trim condition to increase to the point where they couldn't recover in the altitude available.
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@PEI_3721 - I was looking at a MAX video and noticed, next to the usual big strake at about 10 o'clock on the center of the cowling, a set of 2 smaller longitudinal white painted vanes/strakes on the inside of the engine on the sliding part of the thrustreversers. When the reversers slid back after TD, the vanes/strakes did not hit the leading edge of the wing, because a kind of small 'trapdoor' opened upward to let them pass through. On sliding forward the vanes/strakes became visible again and the 'trapdoor' closed behind them. Would be interesting to hear from you what their purpose is in the aerodynamic context that you were just posting about ;-)
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Yes, the overhead panel is 1960’s but the cockpit displays, FMS, engines, wings, and other major components sure aren’t. The point is not a part by part count but the major components of the MAX are completely different than the -100 even to the extent that one could legitimately not call it a B737.
No EICAS , no FBW (with resultant large pitch /power couple, defo not good news on manual go arounds), only two hydraulic systems, no effective autopilot go around (Cat3 excepted) etc etc, not even auto generator switching!
Most of the design changes apart from maybe the nice big screens seem to be all about economic improvements, not safety improvements, ie thinner more efficient but less speed stable wing, longer fuselage with resultant higher approach speed to prevent tail strikes on landing.
I could list more, it's a real shame they didn't build a new modern aircraft from the ground up (like the 777/787) but that would have really hit profits in the short term, I'm sure Boeing wish they had now.