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You are generally excellent, but here I must ask: "What are you talking about?!" I graduated in aeronautical engineering. Stability is determined for each axis of rotation by whether the total moment acting on the aircraft around that axis is such as to increase or decrease the angle of rotation, and it is defined for specific aircraft configurations (landing gear, flaps, spoilers, etc.) at specific flight speeds and density altitudes. When the Boeing 737 Max is flying within a certain part of its flight envelope and the pilots command pitch up, lift created by the engines beyond a certain alpha generates an unusual total net positive pitching moment that tends to lift the nose of the aircraft further. In this flight regime the Boeing 737 Max is by definition UNSTABLE IN PITCH. That's a mathematical fact. Boeing therefore introduced [faulty] software to correct this, so that pilots would not have to be retrained to cope with the instability. One reason for doing so was to prevent screw-ups where pilots would forget which model 737 they were flying and act inappropriately. Have you covered the Boeing 787 Dreamliner cockpit window cracking due to Boeing's abject failure to properly test the new curved panes for differential thermal expansion versus their frames before the aircraft entered service? That's a shocker!
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They launched the 737NG in 1993, well before the merger with McDonnell Douglas, and it entered service in 1997. It is difficult to imagine the old Boeing making the MAX, but replacing the 737 in the 1990s would have been difficult.
@@MentourNow The old Boeing would have made the MAX. They just would have prioritized safety and reliability over profits. That in mind, old Boeing 737 Max would have been radically different from what we have now, being a better developed (or outright omission of) MCAS, more redundant systems, fly-by-wire, and other important upgrades.
Using a single sensor for MCAS even though two were available and it really should have been three was criminally stupid. And not mentioning MCAS to the pilots seems actually criminal to me. Why was nobody sentenced to prison?
It was a very poor implantation. It switched from left to right AoA sensor every flight. That said, it's effectively auto-trim, and pilots train to recover from runaway auto-trim, so its not like its a totally new system.
Department of Justice announced today that it has opened a criminal investigation into Boeing regarding the door plug incident, and whether Boeing violated the terms of its settlement re: MCAS, by failing to document required safety work re: door plugs.
Search for "Boeing Charged with 737 Max Fraud Conspiracy and Agrees to Pay over $2.5 Billion" That is how American justice system works. You make a deal with the prosecutors to pay compensation and you are free to walk away.
My understanding is that the simulator test pilot for the max very pointedly made clear that the plane naturally pitches up way more than “slightly”. The MCAS was not there to simply make the plane more pre-Max-like, but to address a serious pitch up issue.
Because they are stupid civil servants with little aeronautical engineering expertise in aircraft flight controls on an unstable aeronautical airframe.
Absolutely. Mentour does not seem to understand the problem. The forward engines generate so much lift, at high angles of attack, that they can pitch the nose up to such an extent that the aircraft can flip onto its back. It is called a ‘deep stall’. Check out what can happen to Rutan canard designs, where the foreplane can again flip the aircraft onto its back. THAT is the problem they were grappling with. R
Have you even watch the video? on 21:10 it shows you still need to pull a lot hall on the yoke to keep increase the AOA,. Have you ever tried to stall a 737 in simulator or IRL? I have tried to deep stall a max on Lv-D simulator and I can barely keep it at edge of stall with full yoke back and constant back trim input, the nose just want drop at high AOA, even without MCAS.
I am a retired aerospace engineer and a sport pilot. Your videos provide the absolute best explanations of these issues. Thank you so much for making them.
Aerospace engineer? May I ask what your education is? Given that you find these 'journalist' level videos best, I am curious. I have a PhD in Aerospace Engineers. My PhD was sponsored by GE Aircraft Engines. There is a lot of misinformation about the Max, which is understandable from the laymen. As for the Max itself, ... Lufthansa ordered 100 in Nov last year. One can assume Lufthansa, ordering 737s for the first time in 30 years, did their homework, and are more knowledgeable than UA-cam specialists.
For many years in the 1980s I commuted to Deadhorse, Alaska on 737s that had a gravel kit. I might have even been on ones that I helped assemble the engines because I worked at P&WA on the assembly floor in the late 1970s and saw that the customers of many JT-8s were for the airlines I flew on. 3 of those same 737s I flew on then ended up with a mining company in Indonesia that I also flew on over there. These ones had cargo doors.
About placing the engines forward and under the wing. Some good points were mentioned. Throw in a few more. I think it causes the engine to aerodynamically interfere with the wing less. Which makes the wing more efficient and allows a smaller wing, less drag etc. Higher bypass engines also have different airflow characteristics than lower bypass engines, with the air going in, its got to be carefully designed so wing and engine don't interfere with each other too much. Placing the engine forward allows the weight of the engine to act as a mass balance which helps to reduce aerodynamic/aeroelastic flutter. Which helps to save structure weight. And the possibility of fire was mentioned. Also if theres a uncontained failure such as compressor or turbine blade it will be less likely to penetrate wing structure and damage crucial structure or fuel tank or system. So theres lots of benefits. As for the instability caused by larger engines. Yes its not because of the added weight forward of the wing I agree. It comes from a combination of things. Compared to previous 737 types. The engine has a larger diameter. Which means the thrust line tends to be further below the wing. It produces more thrust. The shape of the nacelle causes it to produce lift. And the engine is further forward. So all this means that the engine and nacelle are going to generate more pitch up moment. Thats means if you're in a high angle of attack situation with high thrust setting. It mite be harder to pitch the nose down. Hence taking away from the effect of natural longitudinal I think stability. Hence the need for all this MCAS crap to compensate. Not just to avoid potentially dangerous high angle of attack situations. But also to make the plane handle like previous 737s to please airlines and regulations and certification etc. etc. But ya the new engines do kinda make it unstable, but not because of weight and cg, because of thrust and aerodynamic effects and moments. Thanks for listening to my 2 cents good nite.
Correction maybe the engine thrust and aerodynamics doesn't actually make it unstable. Maybe just slightly interferes with the stability. Ok maybe there is no real danger for stall or difficulty in avoiding stall at lower speed higher pitch or higher angle of attack situations. Due to engines or otherwise. Maybe its just a relatively minor handling issue. It needed to handle similar to previous 737s so that discrepancy needed to be fixed, to meet regulations and what not. Also contributing to the pitch up moment is just the fact that the engine/nacelle is bigger, it has more area to produce lift. But also theres other aerodynamic reasons too it makes a big vortex something like that. Combination of a few things. I think the 737 MAX could have worked. They didn't need a all new design yet. But. I think they rushed it too fast, didn't take the time to develop it right.
Internal company documents released during the investigation reveal that in test flights, during high speed maneuvers, although rare, and outside the normal flight envelope, caused serious instability due to the nose pitching up. Boeing's engineers initially suggested a tail redesign as the best solution, but were overruled by managers due to the time and expense involved. Then, they decided to adapt MCAS from their fighter aircraft designs, but to ensure limits on the MCAS operation, the system was activated only when the angle of attack sensor detected a nose up condition in conjuction with high readings from the accelerometer (high speed maneuvers). Later, flight tests detected instability (high thrust causing nose up and stalls) in certain situations even during takeoff. So, to correct the instability at low speeds, Boeing allowed the MCAS to ignore accelerometer readings and work with just the angle of attack sensor, which of course, then became a single point of failure. An engineer did indeed raise this point with a supervisor, but his concerns were dismissed. To further compound matters, Boeing did not report this new change to the FAA at all even though it was required to do so. Company employees actively lied to the FAA about it.
You are absolutely right when you say that using heavier engines or moving the engines forward increases static longitudinal stability, but may create longitudinal controlability problems. However, the main problem with the 73 max is an inversion of the static longiitudinal stability at high angles of attack, probably caused by altered airflow patterns aft of the engines toward the horizontal tail. It is a solvable broblem. However the way Boeing implemented a solution was a disaster, and we do not understand why the FAA did not catch it: 1) MCAS based on a single alpha vane. An alpha vane has a probability of failure somewhere around 1 failure in 40000h. But the MCAS in a way affects primary flight controls. Failure of primary controls are catastrophic and the requirement is that catastrophic failures can only happen once in 1000000000 hours. (10-9), as per FAA AC 25.1309. Had they used two alpha vanes (deactivating the system if there is a discrepancy between them) the probability of both failing at the same time would be once in 1600000000h, which would meet the safety requirement. 2) The MCAS actuated the stabilizer at a very high speed, turning the stabilizer into a kind of primary control. 3) PIlots were totally unaware of all those differences.
The MCAS system was designed with redundant sensors. This was later made optional as a way of generating upsell revenue. Designers also repurposed the MCAS from the special use case described by Petter to a larger role in flight, and the either failed to tell their test pilots or the pilots later denied knowing that they had. All of this is criminal neglect of their responsibility to the airlines and passengers.
Together with Jean-Claude Malroux of Snecma, my father was part of the original marketing team for the CFM-56. The big break was the DC-8, which was an obvious easy re-engine, followed by the KC-135 and other 707 military variants. My father always felt that the 737 re-engine program was a rush job as Boeing tried to keep small Airbus variants from eating their lunch. Still, the 737-300 broke the Pratt stranglehold with Boeing and proved to be a launching point for both CFM and GE. That clever engineering you mentioned paid off hugely. Although long-retired by the time that the MAX line came out, Dad was still connected enough to know that one of Boeing’s major pitches for the LEAP-engined planes was to that they were to require minimum pilot retraining. And therein lies the rub and at least some of the design errors.
I never finish a full video on UA-cam or never watch a full tv show or movie. However with your videos I have never stopped it early and always watch it in its entirety. Thank you for the awesome consistent content.
@@Voyager.2 On the 737 Max 8, they didn't extend the length, but they did beefed up the supporting structure, fuselage skins and other changes to accommodate the heavier engines. It was part of the reason why the MCAS was not given as much attention since the FAA was focused on the updated landing gear and fly by wire spoilers. This was all reported in the FAA report AV2020037.
@@Voyager.2 I believe they extended the nose strut on all MAX variants. However, the main landing gear that expands during rotation to increase tail clearance is restricted to the MAX 10. I'm not 100% sure about this, so take it with a grain of salt. :)
@@ahndeux The MCAS wasn't given much attention by the FAA because Boeing intentionally hid the existence of the system, just as they hid it from pilots by choosing to remove it from the Aircraft Operating Manual to preserve the type rating.
Not exactly to keep regulators happy, was it... it was to persuade regulators to keep the same type rating so that airlines didn't have to do more pilot training. Or am I wrong?
Exactly, this is the crux of the problem, when is a 737 no longer a "737"? Of course planes should be allowed to change with advances in technology and requirements. But they also have to be classified as a different type when these changes are significant enough. Boeing tried to cheat on this latter part and it resulted in the deaths of 346 people.
Contrary to what Petter says, EASA believes MAX is unstable, or at least can go into an unstable condition in certain flight envelopes. That is why there is a *third AOA sensor* requirement. Do not forget that Boeing's own staff says: "designed by clowns who in turn are supervised by monkeys" Also former Boeing Manager Ed Pierson says "He Won't Fly on a Boeing Max Plane".
As a control engineer (we are the guys mostly obsessed with stability), I am horrified by how B737 was modified and the control system was augmented. The way this passed regulatory approval is scary. I will never willing fly B737 again.
Honestly I have been following this since the first incidents since I am an engineer in aerospace and focus on design changes. I know they have improved things but I will still never willingly fly on that thing.
@@luisurbina5115how can it be when obviously they did not care about safety standards even after the 737 max crashes? Even if the design is theoretically good, who is to say everything was assembled right? Boeing is not safe.
High, I’m a 737 veteran myself and quite familiar with the concept you are discussing. I flew most variants of the 73 and my flying came to a halt when the mcas mess came about a few years ago. I was in the middle of the type conversion in Singapore when it all happened. Anyways to the point, I firmly believe that it’s time for Boeing to say good bye to the 73 and maybe concentrate on the 75 comeback and making that model a better unit than the original was. I’m not an engineer but common sense tells us that shrinking an airframe is probably a little easier than trying to stretch it as in the max. The Russians have come up with an airframe around 210 pax and I think that’s a good size to have, which is why I think a redesign 75 makes a lot of sense. And knowing Boeing will do anything to screw this up, make it a totally new wing design instead of the bs job they did with the max which was the same airframe as the NG. A new design is a new aeroplane period.
@@roflchopter11Pilots take on new type ratings all the time. It isn't a big deal. A pilot will typically have three type ratings before they ever begin commercial training. Another one or two for mulri-engine. Probably another for instrument. Then one or two, or three at their first regional job. Then three or four more at the majors before retiring.
Well what then do you out of Airbus making the A321XLR MTOW above 101 ton, the wing was never ment to lift that weight. An updated 757 isn’t really a suitable way instead of the MAX. Most 737’s are as you probably know the 400/800/MAX8 as it is the most popular size.
You are correct regarding the reuction of the fan diameter on the CFM-56 engines powering the 737NG, but your explanation was incomplete. In addition to lowering its efficiency, this lowered its power too. The engine was derated from 24,000 lb of thrust to 20,000 of thrust. Also, your explanation of the MCAS is great. I would like to add that MCAS is not new to the 737MAX. An MCAS was implemented on the KC-46 (767) air refueling tanker. This much more robust MCAS was needed because a tanker's center of gravity is frequently changing during flight as the tanker offloads fuel to recipient jets requiring it, and as such, MCAS is more active on the refueling tanker. The KC-135 tanker and KC-10 Extender tanker had a Second Officer (flight engineer) who was in charge of fuel transfers between tanks (to manage the center of gravity) but the 767 tanker does not, and requires more robust computer functions to fly safely. The 737's MCAS was less robust, lacking sensor redundancy, to reduce its cost, because Boeing calculated that airline 737s would not need it often, only in specific situations. Boeing's assumption, while correct, led to a problem which not only caused two crashes, but also caused some incidents on US airlines that could have resulted in crashes, but did not.
I worked on the 757 as part of a team designing the PACS(Pitch Augmentation Control System) which was similar to MCAS. There was a concern that the plane was unstable in pitch due to the engines. After the plane flew, they deleted the PACS as it was deemed unnecessary.
@@deltaskyhawk Thank you for sharing that. Did you work under Phil Condit? I have read that Condit, who later was Boeing CEO, made a critically important contribution to the 757's engineering, fixing a problem - but I don't have the details. I also read that his work on wake turbulence for the 747 was groundbreaking, allowing the 747 to be included in a reasonable takeoff interval at the airport and the science he developed was adopted by the FAA. In contrast, the later Airbus A380 needed a longer interval to protect following jets from its wake turbulence. Can you correct me on any of these details?
@@ronaryel6445 The name is familiar ... but Boeing was a huge company and I was a contractor in a small corner of an engineering building in Renton. Early 80s. Boeing had an interesting approach to design. There was a whole group that designed just a window. Their approach was to solve problems by throwing a bunch of engineers at them. As a PP, wake turbulence from any of these heavies is dangerous.
Thank you for showing the photograph of the Air California 737 (time 5:02 in the video). My father was vice president of Air California starting in 1968 for several years. As a child I loved flying on those 737-200 airplanes. The paint job was golden yellow (for the Golden State) as were the flight attendant's uniforms (then known as stewardesses). I loved the sunflower on the nose of the airplane. It was a great logo. Air California ceased to exist when American Airlines purchase the company in 1987. They had one crash at John Wayne Airport in 1981. Thankfully everybody survived.
Actual aircraft designer and propulsion engineer here. Any change that results in a nose-up tendency at slow speeds is inherently less stable, and MCAS was intended to address it by inducing elevator deflections to keep the nose down. That's exactly what lead to the 737 Max 8 crashes. Additionally, the CFM56 redesigns also led to a greater risk of uncontained blade loss which also resulted in passenger injuries. Lastly, the worst problem is Boeing's repeated failure to report known safety issues, starting in the early 90s with a known issue with the rudder controls that eventually led to two fatal accidents, and ending up with unreported issues with the MCAS and it's single-point failure mode (which violates regulations for safety critical systems) and finally the recent quality escapes on the Max 9 and potentially other models. The 737 has become increasingly less safe with each generation and Boeing has repeatedly cut corners on safety.
As I had to do with nuclear power plants, there should be no discussion that this plane needed three angle-of-attack sensors with a discrimination unit that indicates when one of these sensors differs too much from the others.
@@faceless360 Mcas did not cause those crashes read the reports and dont listern to the bullshit media, Cos its just all lies and misleading information.
In my 30 years at a US major I never heard our 737-300's called the "classic" that was a southwest term. Also the "Jurassic jet" was uniquely a term for the 727, never used for the 737-200. When I bid up from the 737-200 to the 737-300 I was trained on how at hi nose & low speed the addition of thrust does input a bit of nose up pitch unlike the 200, exactly was you have addressed. Also the NG series again had bigger more forward engines, higher mounted engines and would input some nose up pitch more so than the 300. Thank you so much for addressing this misinformation propagated by lax/sloppy media reports.
Your callout to Stefan Drury's channel & encouragement to help him out: that was kind & generous. Thank you for being a friend to him. That small gesture is infectious - encourages community amongst us all, is an example of how we can all help each other. We need more of that. I've occasionally enjoyed your channel's posts, but am now subscribed to yours & his.
Great video again Petter! Don't know about the jurrasic 737 but the Classic already had the Speed Trim System which would act on the Stab position in Low speed, high AOA+High Thrust conditions, i.e. Take off and Climb phases. According to our course notes and instructors this was to counter the nose up tendency the aircraft would have in such conditions. This was a direct result of engine shape and placement. In other words, the issues with the Max were not exactly new ones. However, the course notes never went into depth about the exact characteristics of the systems (one in each FCC) and which inputs were actually used to control the Stab. Neither did the Aircraft Maintenance Manual. We just knew the system was there with a fault light on the overhead panel to prove it. To add a little more, the CFM56-7 wasn't the only upgrade on the NG, it too had a taller main gear (and re-designed wing) to accomodate the larger nacelle diameter compared to the CFM56-3 on the Classic. In other words, the issues with the Max were not exactly new ones.
At the 21:14 point, suffice to say that the wobbly (change in slope) of the Cm-alpha curve line near/at stall makes MCAS necessary from a human factors standpoint. Without MCAS nose-down trimming, it's trickier to fly near stall, meaning you can be in a full stall before you know it. The pilot would need to know to change back pressure on the stick as stall nears, which is possible, but a little startling. Never startle a pilot near stall !!! Actually, technically the part where Cm-alpha has a slight positive slope (the no-MCAS line) near/at stall, is the definition of "unstable". It is slightly unstable near stall, not dramatically, but slightly.
MCAS is all about one small paragraph in 14CFR25. The real problem was the single point of failure of the AoA vane. “25.203 Stall characteristics. (a) It must be possible to produce and to correct roll and yaw by unreversed use of the aileron and rudder controls, up to the time the airplane is stalled. No abnormal nose-up pitching may occur. The longitudinal control force must be positive up to and throughout the stall. In addition, it must be possible to promptly prevent stalling and to recover from a stall by normal use of the controls.”
Faulty pitch sensor? Why did it indicate Unreliable Airspeed? If the AoA stuck at a high angle, there would have been a stall warning condition for BOTH landing and takeoff
Now if MCAS was integrated into the autopilot sensor suite, engaging the autopilot, would automatically trigger the MCAS even if it had previously been turned off
@@luislongoria6621 There was. On takeoff roll in both crashes the captains AoA vain deviated, so when the plane rotated the stick shaker immediately activated.
I'm a private pilot, (love the decathlon for the upside down silly stuff), and obviously never flown the big guys but I love hearing the technical stuff about how these huge metal boxes fly.
Excellent video as usual! You mentioned the "speed trim system" very briefly, however a little more information about the Mach/Speed Trim features on the 737-300 would be useful. The Mach and Speed Trim system along with the Elevator Feel system operating through the trim system were all designed to 'augment' the feel of the pitch during manual flight. I flew the Jurassics, and Classics. When I first flew the -300 after years on the -100 and -200 Basic and -200 Advanced, the Mach/Speed Trim and Elevator Feel system were very prominent during hand flying. While pitching up in manual flight, the trim wheel would actually trim nose down while pulling the yoke nose up. A curious thing for the a pilot new to the 737-300. The very light feeling of the yoke in pitch is not new and began with the -300. The trim system was used to augment the pitch feeling from the very first installation of the CFM-56 onto the airframe.
Your videos are always clear, fascinating, and watch-friendly. I have to compare the Max issues with my experience in military aircraft, where we were instructed that we would compensate for wild changes in handling characteristics in various routine flight regimes (not just takeoff and landing) simply by learning to anticipate that the plane would attempt to surprise, annoy, resist, or depart from controlled flight. We also had cutout switches for multiple automated systems in case we suspected the automation had somehow taken on a life of its own...including stab trim, anti-skid, stability augmentation, autopilot (of course) and others. Finally, we also had many, many restrictions on engine anti-icing, which became an onerous addition to workload when it was in use. I can really appreciate the comparatively modest enhancement that MCAS makes, and I hope more of your viewers come to understand that the terrible results stem from Boeing's corporate (Chicago) decisions regarding the profit implications of how they addressed transition training, rather than from the engines or the MCAS engineering (Everett).
@berkeleyfuller-lewis3442 I'm struggling not to resort to ranting about the catastophic results of the merger with McDonnell-Douglas...to include their behavior in the next-generation fighter, tanker, and SAOC competitons! Reprehensible. Chicago is trying hard to singlehandedly destroy yet another pillar of the US economy.
My son is passionate about pilot and aviation. So I started to search a good channel about aviation finally I found it. Sir, your are doing great work and your creating curiosity but you are explain about technical side. I am really impressed. Who wants become a pilot must follow this channel can learn lot. this channel should be dubbed in other languages also. (Consider)But English is the priority. I really appreciate your efforts. ❤
I love the way you make your explanation as simple as possible for the average layman. I also like that you aren’t afraid to admit that you maybe wrong on something.
One thing comes to mind is flying down the north coast of New Guinea at midday listening to the Goon Show in a 707 and watching the engines contra rotating on their fairings.
Another major issue with MCAS is that it was not implemented as designed. The engineers designed its ability to change trim to be very minor. In this way tying it to a single angle of attack sensor was not a big deal as if it went off the rails due to bad input MCAS' ability to endanger a flight was almost nonexistent. Later on however management dictated that MCAS needed to be much more aggressive in order to ensure that they could tell airlines that no simulator training would be required for pilots of earlier 737s. It was a perfect storm. A system that was not designed to be redundant because it wasn't seen as necessary due to the relatively minor fight inputs it was capable of making, which was then altered to be able to make extreme changes, and then pilots were not informed about the system.
The original design did not link it to just to AoA sensor. It was much more for the higher speed manouver where the aerodynamic effect of the engine meant the stick pressure reduced - the regulatory requirement. Later it was found that to keep the handling feel the same it was needed at slower speeds. In this phase of flight the second sensor (I thick it was an accelerometer but I could be wrong there) would not be effective - so the use of a second sensor was removed - without adequate risk analysis of what would happen should the AoA sensor become defective. This is the root cause.
Hmm, I am not surprised based on Boeing's management structure. The entire line of management is non-technical and that has major consequences. They should not be making decisions, and not even be with the company. It needs to go to a unified engineering group, where the managers are still still leads or individual contributors and no on the other side of the union wall. This is the way many other engineering firms are
As someone who works ramp, let me tell you, even if I don't notice any other difference between the Max & NG, you will notice the taller landing gear. It sits noticeably higher off the ground, and you can tell when you go to plug in ground power or plug in a headset for pushback. Even better, since the Max9 is prone to tail-tipping when unloading (even the Max8 tips back a bit, but don't worry we use a tail stand to prevent this), and due to how much higher off the ground the aircraft is, sometimes you can barely reach the panel for ground power if it tips back just a little. The Max is a beautiful aircraft, but I do wish they'd moved that panel down just a bit for us on the ramp 😅 I'll still take it over the panel mounted directly under the fuselage on the A320 family, that is kinda annoying to work with.
Maybe I'm the odd one out here, but I really enjoyed flying the DC-9/MD-8X/MD-9X/717 family of aircraft. I always found them to be smoother in flight and less affected by turbulence, the major negative being the noise level if you were seated in the rear, adjacent to the engines.
I was fine with flying in the "A" seat of those, but I found the pressurization system to be kind of herky jerky, more often causing ear problems than any other airliner I flew often. And I did fly into Detroit in one, looking down at the wreckage of another one. It also had the least desirable seat on a commercial flight, the one in the rear which is a window seat without a window, because if the engine flies apart, that's where it is aimed. The only takeoff roll I experienced being rejected at high speed, was also on one. One engine wasn't developing full power, which is a pretty rare thing to take that long to figure out. For a year or two after the DC-9 Super 80 came out, every time I was on one, I hoped it didn't buckle and almost fold in half if we had a hard landing, like the one did when they were testing minimum landing distance over a 50ft obstacle. Having said all that, it seemed like a super solid plane for what it was, a real workhorse. And it was the only airliner I got to sit in the co-pilot's seat of during a flight delay. Ahhh, aviation before 9/11.
The knocks against MD were really on the DC/MD-10 and MD-11, which had major problems that got ironed-out too late. MD had overpromised and underdelivered on those jets. But the DC-9 series (MD-80s, 90s, now 717s) were super high quality builds. The 2+3 seating configuration was my absolute favorite in the air. The rides on the MD-90/95 just couldn't be beat for quietness and power. Fortunately, the X-66A seems to be bringing a lot of these possibilities back to us. I hope it is a success.
It didn't make it unstable. It made it different. So came the MCAS, which nobody knew about. The FAA didn't know about it, the pilots didn't know about it. Never mentioned in the Max manuals. THIS is the outrageous part. Profits were put above safety. Boeing should have worked on a new 737 since the 80s, or at least early 90s, to take full advantage of composite materials, more efficient engines, fly by wire technology... They're at least 30 years late.
Its functionality equivalent to auto-trim, which pilots and the FAA did known about. In fact, pilots have a memory procedure for handling runaway trim. The procedure works, as other pilots used it to recover from MCAS anomalies on the same aircraft that later crashed. Those airlines failed to record and repair the AoA sensors that caused the anomaly. The implementation was very sloppy, but the pilots were trained in recovering and failed to do so.
@@daftvader4218 I do have a clie actually. You should listen to the flight safety detectives and also familiarize yourself with stab trim cut-out switches that may only on the ground may be placed back as well as memory items, the fact that the two crashes aren't exactly for companies that do well. Also, the most of the a/c flew with MCAS w/o any problems. both totally were avoidable. yes there were maintenance issues at one of the planes but with capable pilots it would never have happened. Also, when it comes to news: even if a maintenance guy forgets to install a wheel correctly, it's still in the news of being Boeing's fault. Ayways, I do have clue. Good moment for you to dive in what really happened on two flights and ask a few people who actually fly a/c with MCAS. The grounding is due to people that -indeed- have no clue.
Going back in time, way back, I grew up in Chicago and remember some interesting sights. This was back in the early and mid+ 60s. I remember seeing a DC-8 fly over our house (going East) and one could hear it for 20 minutes or so but see the black exhaust for at least half an hour or so. Another thing was I saw a DC-3 painted with orange stripes or tips and Dad told me it was the FAA doing checks on the O'Hare landing radios. I did have a DC-3 right in front of me at Palwaukee, coming right at me but then turned and scared me to death. I was about 5. After that, I end up getting a license in a 152, and was in aviation for 45 years until retirement. Love you channels!
Just to add to the points made: the mcas worked by moving the trim leadscrew in the horizontal stabilizer. This system would be way to slow to actually correct any aerodynamic instability.
I would love to see you make a video on the History of pilot training. Who was the first pilot that the wright brothers trained? How did they train early pilots? When was the first flight simulator used? What was it like? How has pilot training evolved? Sure someone else might be able to read the Wikipedia article on it but you have the insider insight into this specific topic that I think would be extremely interesting to have that viewpoint.
MCAS and Trim runaway are delt with in the same way. I got an MCAS situation on my Checkride and delt with it. Got out of it and walked away with mt Type Rating back in early 2019.
Mentour Pilot's students must be the luckiest to have such an instructor. They get to learn History, Engineering and Navigation all at the same time. There's never a boring class when he's the tutor.
I have flown most 737 models except the 200 and the MAX and have thousands and thousands of hours on the type. For the last 15 years I have been flying the Airbus A320 series and the NEO. From being an absolute Boeing fan, after changing to the Airbus, as I see it, the 737 is a totally outdated product, and should’ve been scrapped years ago. (Sorry Petter). In my opinion, the A321 NEO is the best plane you can buy in the narrow buddy segment. Flying with 240 passengers, it burns less fuel than an old A319 with 156 passengers, on the same route. So quiet and so powerful. What a machine. Petter, work on one of these for a while and you would never want put your feet in a Boeing again, I promise, from experience. 😊
Probably. But they are much smaller and can only compete with the A319 NEO . The A220 if for sure better, the E2 is again an old plain with new engines and wings, and I think is less appealing in this market segment.
In the gravel age, the 1980s, I commuted to my job flying Twin Otter and DC-3 in Resolute Bay, NWT, Canada from Toronto. My ride in and out on our rotation was a "Jurassic" 737. I always felt it was awesome of Boeing to produce a gravel kit for the 737-200. It would have been a drag to do the Iqaluit-Resolute leg in a 748. For that reason alone I've always had a fondness for that airplane. I want you to know I feel this is one of the best aviation videos I've seen. I like it so much that I'm going to your Patreon.
I remember that I read that tendency of the aircraft to increase the input of desired maneuver without increasing control input is also called "instability". Instability in yaw, pitch, roll, etc. Now, there is no perfect airframe and those instabilities exist almost in any airplane, and such non-linear characteristic are carefully implemented in flight controls, speeds placarded, pilot trained for such regimes etc. This way or another, those are dealt with in almost any airplane. The problem of MCAS was that discovered "instability" (because by the upper definition, it is THE instability), one that was acceptable by itself IF pilots got warned and trained, got to get "smoothed out" to approximate previous behaviour by totally inappropriate methods from the standpoint of safety and relability.
Max is not unstable. You let go of the controls while it is still pre stall, and the plane will return to level flight. The force on the stick always remains positive. It just fails to increase linearly as required by regulation.
The bottom line is because the MAX hasn't got a FBW system, there needs to be this supplementary MCAS system. Airbus' have FBW and also has this over rotation/ stall prevention but the key thing is that it's built into the control laws and isn't some add on. The other thing is that all the AoA sensors are working all the time...
I'd say a clean design is long overdue ;) and I always understood what MCAS was designed for. The 737 Max would have been a safe aircraft to fly on even if MCAS was never installed. But the system was designed to prevent the requirement of simulator training for pilots, which was also the reason why it also was using the input of a single AOA sensor because to be dependable, it requires all AOA sensors which would have made it a safety critical system which would have brought back the simulator training even though Boeing was selling the aircraft to airlines with the promise of not needing sim training. At the end of the day, the problem with the entire thing is that Boeing sold an aircraft with a promise that it couldn't keep. What many people also don't know is that the 737 Max was not the first aircraft to get an MCAS system. A variation has been used on the KC-46 refueling aircraft as the balance of the aircraft shifts during refueling. While the system is also called MCAS, it does serve a different, but similar function.
As much as people would like to, and have, dump this on Boeing I see a systemic problem that caused all these issues to line up and crash not one but 2 airplanes. Is a system that favors less simulator time is broken. If the difference is so minor pilots can turn off MCAS, did a 737 MAX w/o it need a unique type certificate? This needs to be looked at from the top level.
You actually think that Boeing would have LESS problems with a clean sheet design than one that is almost 20+ years old and had stellar safety record up to the redesign? I would argue their problems would increase by 10 fold or more with more design changes. The engineers that work on the redesign are not the same as the ones who did the previous generations. I think your assessment is completely flawed. What it might have done with a total redesign is to force the FAA to pay more attention to the entire design than with the update from the 737NG generation. Boeing flagged the fly by wire spoiler update and the landing gear reinforcement as a high risk change and that was where the FAA spent most of their focus on. There is an old saying in engineering. The issues that you spent the most time on due being assessed as a high risk are usually not the ones end up biting you in the rear. Its the "low risk" items which fell through the cracks. A lot of bad assumptions were made to determine it to be low risk and that's what bites you in the end. It always has and always will be.
Nobody ever blames the irresponsible airlines like Southwest that hammered and hammered and hammered on Boeing to avoid requiring the flight simulator time until Boeing relented. There's plenty of blame to go around.
@@ahndeux finally some common sense here in the comments! Frankly nothing scares me more than the phrase "All new!" ... I'd rather prefer a refinement of the previous version. Boeing know knows the weakness of the 737 airframe due to its history, hopefully it has address the issues with each version/iteration.
I am of the belief that the 737 MAX should have its own type rating. When a plane doesn’t behave like its predecessors, it needs to be treated a new design entirely with pilots specifically trained for it, not using a system as a crutch for poor design. It may not be “unstable” if we really want to split hairs here, but it behaves differently in the most critical stages of flight: Takeoff and Landing.
In a perfect world that's exactly what would happen, but the 737 Max was designed specifically for airlines who wanted to effortlessly transition their pilots from the older NG models to a newer, more fuel efficient plane. Creating a new type rating was unacceptable for low carrier airlines whose entire fleet consisted only of 737s, as well as other airlines who weren't interested in adding a new type to their existing fleet. Basically they wanted the same plane with lower costs, which is technically impossible due to the low profile of the 737. MCAS was basically a compromise allowing the FAA to certify the Max as a 737 despite the engines causing it to handle differently from a traditional 737.
@@jb8331Yeah, Boeing wanted to skip 10 or more years of making, testing and certifying a new aeroplane. The cost would be gigantic. Human lives one the other hand, are expendable 🤔
A part in this video reminded me of a flight when I was a kid. Then that reminded me of another part of that flight or another flight. I remember seeing the bucket reversers, as you just called them, deploy on landing and I thought the plane was falling apart. On a flight from DTW to San Diego when I was somewhere around 5 years old I think, I was afraid to use the toilet because I thought it was going to suck me out of the plane. Since then, I have been on many flights, including a single engine 4 seater prop plane around 3rd grade and one commercial flight in a puddle jumper flight. It was a VERY loud twin engine prop plane that I think were turbo props. I couldn't even stand up in it and they told us where to sit for weight distribution. Another commercial flight was in a more modern twin engine turbo prop that I could stand up in. It had just one seat on either side of the aisle and a curtain to the cockpit that was left open for the night flight. That was cool seeing into and through the cockpit while flying. And one memorable flight was Alaskan. It was a flight from California to Oregon and it had a capacity of around 50-100. It had top mounted wings and there was only 4 passengers on board. We got to drink for free. I remember getting a Craft Beer that was an Alaskan Brewery. I still have that can, empty of course. But with all the problems Boeing is having now and the whistle-blower taking his own life, allegedly, during his deposition, I will NEVER fly on a Boeing ever again. I just can't trust them anymore.
Thorough as usual Mentour. I flew all versions of the 737 from the 200 thru the 800. With each new variant, Boeing increased the size of the horizontal tail surface. The result was a jet that was fun to fly. After the McDonnell Douglas merger, Boeing broke with tradition. No longer were engineering decisions made be engineers. The Bean Counters had taken over. They thought the flight characteristics could be "smoothed out" with software and refused to mod the tail. Yes, the MAX can be flown without MCAS, but MCAS caused the two accidents.
As I recall, the only engineer on the Boeing Board of Directors was the CEO. If it can be flown "safely" without MCAS, it should have been taken out or better yet not installed in the first place. Concerns about wanting to avoid pilot type-training sounds exactly like something a bean counter would come up with. All this reminds me of the Challenger Space Shuttle disaster.
Obviously, the MAX had a longitudinal stability problem in some parts of the flight envelope. Yes, increasing the tail size is the logical solution. A trim workaround like MCAS as a concept is a questionable solution. As originally Implemented with a single point failure mode, it violates the most fundamental principle of transport category aircraft design, which you would think any Boeing engineer should know very well.
@@nathanaligizakis760 It looked to me to be a hurried last minute modification where corners were cut in terms of safety analysis and engineering supervision. According to FAA regs, yoke pullback force has to continuously increase up to the point of stall. Should be easy to verify with MCAS deactivated. I’d imagine it might also be detectable with the wind tunnel model.
As a programmer, it baffles me that they didn't do simple saturation arithmetic to control the inputs. If the needed adjustment was very slight as said, it should've been capped, in order to not force the aircraft down even if the algorithm gets completely haywire.
@mentournow Your thorough approach is appreciated (with so much other information by other sources about Max/MCAS being wrong). You’re correct that the airplane is NOT unstable. In pitch there’s 4 types of stability…2 static and 2 dynamic. Big airplanes don’t typically have any issues with dynamic stability (short and long period) and the 737 is no exception. The two types of STATIC stability are speed stability (typically expressed as pilot pitch force vs speed) and maneuvering stability (typically expressed as pilot pitch force vs g) . Your video talks a lot about speed stability and kinda mixes it up with maneuvering stability. But you’re close enough for most non-aero engineering viewers. You mix the “see-saw” (which is speed stab) with Fs/g (man stab) and then you throw in stall characteristics (which is a totally different topic). Anyway, you’re close. Fs/g was predicted (from wind tunnel studies prior to the max ever flying) to not clearly meeting regulatory requirements (worst case aft cg) and this resulted in MCAS being implemented into the design (with fairly limited authority). Once the test airplanes started flying is when the stall identification characteristics (a wholly different regulation in part 25) were found to not clearly meet the regs and this is when MCAS was expanded to include the low speed (stall) region, and the authority was essentially multiplied by a factor of about 4. Add in the fact that a fail-safe feature incorporated in the prior generations of 737’s (column cutout) was bypassed for MCAS activations (necessiststed by the fact that MCAS works when the column is way aft) and the setup for disaster was sealed. The real miss (and it was missed not by anyone rushing, or being pressured or any of the other populist reasons offered by the media) was in evaluating the design against another regulation…25.1309(b) which concerns failure case analysis. In this case a failure which produced a single erroneous high angle of attack input into all the systems which use AOA information.
During certification, to stall an a/c, the pilot has to keep pulling on the yoke. This is mandatory. Otherwise a pilot might stall the thing inadvertantly. In the MAX (without MCAS) it became 'stick light' during the stall- so not acceptable. MCAS was the fix-trimming the a/c nose down, so the pilot still had to pull. MCAS augmented the manoevering characteristics during the stall, thus the name.
"A little knowledge can be a dangerous thing." And lately, thanks be to internet - there are a ton of people running around repeating false/misunderstandings base on "a little knowledge." Thanks for seeking to counteract some of this with Quality Information, Mentour Now!
When 737 MAX returned to service after being grounded for two years, its stab trim cutoff switches were not rewired to the NG configuration. As a consequence, in case of runaway trim, it is not possible to turn autopilot/STS/MCAS off and still use servos controlled with the buttons on the control wheel. It is much harder to recover the MAX compared to the NG if runaway trim happens.
The NG also fully disables the trim servos with the switches. The solution is to turn the cutout switched back to normal and yhr use the trim control. One of the 737 MAX incident pilots did that, but failed to set them back to cut out, resulting in the crash.
@@roflchopter11 No, and you would know it if you looked at the switches instead of recalling the runaway trim checklist, which instructs to turn both switches off. But on the NG the switches are different: one turns off autopilot/STS, another turns off electric trim servos. On the MAX both switches do the same thing and each of them turns off everything.
@@user-yt198 Yes, they could not recover, because the moment they turned electric trim back, MCAS would work against them, fast and relentless. And when they turned the switches off, they could not re-trim it manually, the other pilot pulling up did not help, but if he did not pull up, they would not have the altitude anyway to complete the "rollercoaster" maneuver, if they knew about it at all, because it was removed from the NG and MAX FCOM.
@@TinLeadHammerno, because the captain failed to retard thrust after he followed the procedure, leading to a rapid and extreme over speed, and therefore the inability to manually change the stab trim. Poor airmanship caused that crash.
@@escapetheratracenow9883 ?? Why are people so hell bent on defending a private corporation that has demonstrated again and again that they only care about money? Safety is important in any industry but Boeing builds commercial airliners and doesnt seem to have any culture of safety or responsibility.
@@thewaywardwind548 Thanks for the scoop. Boeing is a shadow of its former self, and its behavior regarding the Max is unacceptable and outrageous. Until their maintenance procedures are properly tightened up, their quality control standards improved, no I won't.
All current MAX aircraft have an ongoing and known issue with the engine anti-ice system! Left on too long in excess of five minutes the engine could fail and blow apart. The FAA has now required to redesign of the systems on the MAX 7 and 10 aircraft. Clearly, this says the FAA does not think the aircraft that are currently flying are safe however, they continue to allow them to fly. It’s only a matter of time before there is a major and accident involving them. The MAX needs to be grounded until they can redesign and fix all of these aircraft!
5:11 Similar to the Comet, Tupolev produced the TU-104, based on the TU-16 bomber with the engines incorporated into the wing. And after the Comets grounding was not just the only commercial jet powered airliner in service, but also the first to complete a trans Altantic flight.
I never was under the impression that MCAS was needed because otherwise it would've been 'dangerous'. Nor have I heard anyone say that, but that's just me. I heard basically the same thing you point out, that because of the positioning of the new engines, the characteristics of the plane had changed. But I'm inclined to agree with those who say this is not ideal.
Just a couple of weeks ago on a hugely popular "Last Week Tonight" show dedicated to Boeing problems they had some sort of engineer expert very confidently explaining exactly that. That 737Max needed MCAS, because after changing the engines from previous 737 models it basically became an unstable design and MCAS was introduced to fix that. I immediately noticed it and facepalmed myself, because I already knew it was complete rubbish that's very far from the truth. The truth is MCAS was never a necessity from standpoint of flying characteristics, it was a workaround to make it seem like it has the same characteristics (or behave very similar) as the previous models for other reasons that had very little to do with physics or aerodynamics and more to do with business and bottom line.
One thing I've never heard in any video is what the pilots think about the actual differences between the NG an MAX, the differences MCAS was supposed to eliminate. It really feels like Boeing was more concerned with satisfying the bureaucrats than the actual pilots. If the pilots are/were unaffected by the difference, then it's the FAA that's responsible for the crashes.
The pilots _are_ affected by the difference. It's not a big effect at all, but it's enough that it would have required simulator training for pilots moving from the NG to the MAX, and avoiding _that_ was the entire reason for the MCAS, and the deaths of several hundred passengers.
Remember, Boeing was allowed to use its own employees for FAA certification. Government agencies have been purposefully downsized to allow more latitude to private companies to ‘meet’ regulations. In my mind, this a clear systemic prejudice to eliminate or capture government oversight to the advantage of the firm, and not to the consumer. The old saw ‘we don’t need regulation as consumers wouldn’t stand for bad products’ is useless of there are only two producers of the item in question. However, this ‘efficiency’ has come home to roost for Boeing as airlines (especially foreign ones) are rethinking Boeing and going to Airbus and airline travelers can now eliminate Boeing models as part of their reservation searches. While some may see this a validation of the ‘less regulation’ mindset, the cost in lives, careers, and misallocation of capital has been higher than what keeping the old processes in place would have been.
@@Curt_Sampson Let me clarify, I've never heard a pilot describe _how much_ it affect their job and whether they consider it a meaningful difference, relative to all the other differences introduced through the 737's life span. Either way, engineering for a regulatory requirement is a problem hence the FAA is still responsible for the crashes. Meaning, without the FAA defining 'maneuvering characteristics', the airlines and pilots would have final say.
@@philiparonson8315 The problem is 'meets regulatory requirements' is a shield against liability, real or perceived. This is very convenient for the companies because it makes the Gov responsible and because the Gov is responsible, there is literally no responsibility because you can't sue the Government. Like how the airlines are unconcerned about the ineffectiveness of the TSA because when something happens, DHS will simply declare their 'procedures were followed' and too bad, so sad.
@@rapunzel1701 I believe that Petter is wrong when he says that MCAS was necessary to meet regulatory requirements about maneuvering characteristics. (It was instead implemented to _avoid_ a requirement for some relatively minor simulator retraining, though the FAA should not have let that through.) I discuss this in more detail in another comment thread on this video that starts with a comment from me.
Moe to the point about MCAS, it was put into the MAX to make the aircraft fly as if were a standard 737 to eliminate any requirement for pilots be retrained and recertified as if it were a different aircraft. Boeing did this to make the aircraft more marketable to the airlines And they didn't bother to disclose that to the airlines and their pilots. And who in their right mind would design a system that could fail from ONE malfunctioning sensor, the AOA sensor? Military aircraft the Boeing makes have flight control computers that use multiple sensor inputs to mitigate against this precise scenario.
That is wrong. Boeing's internal discussions state that the reason for the change to MCAS design was flight test findings which would have been uncertifiable otherwise, albeit not necessarily dangerous. The Canadian regulators have stated after the fact that Boeing could have pursued an equivalent safety finding as the issue was so benign. Simulator training was NEVER a reason for implementing MCAS. The only discussion about simulator training were centered on the RCAS and RSAT features.
I have followed you for some time now and have watched nearly all of your videos regarding the 737 and still I learned a few things from this video that were new to me. Thank you so much for continuing to produce high quality and informative content!!!
I was always under the impression that MCAS was there to readjust the C.G. which was impaired by moving the new engines forward and upward. I also did not realise they had lengthened the nose wheel leg. Thank you for explaining, so I even I, just an enthusiast understands. Really great content as usual. Stay safe. All the best. Mick🇬🇧
Yes, retire them because consumer confidence is on a downward spiral on the plane and is affecting the company too. Consider the Hindenburg. One horrible crash pretty much stopped LTA transport for a hundred years. Now even though airships are made that can not go up in a ball of flame, the collective memory has deemed them unsafe, so the industry remains sidelined. Perception is everything.
I am very glad you pointed out the differences in the engines that Airbus and Boeing put under their wings. The plane you fly (and I live directly under the approachroute to Schiphol runway 06) is one of the noisiest, the 737-8. The newer models are already quieter, but the difference in noiselevel is remarkable. The lowpitched noise that the engines on the 737-8 or 737-9 make is thunderous. Where as the newer engines are highpitched and less noisy, mostly on Airbus neo-planes. I love the RR Trent engines, with their high bypass high pitched sound. Especially on the 350 and the 380.
Thanks for your thorough analysis. I flew the 737-200 amongst other types. So far, my preferred aeroplane from a handling characteristics point of view. A real pilot aircraft!
You are wrong about the reasons for the engine placement. A wing in flight creates two forces - lift and drag. But it also creates a torque or twist. By placing the engines forward of the leading edge, they act as counterweights to the aerodynamic torque on the wing, allowing for a lighter structure. Boeing did this first on the B-47. It's a very clever thing to do, using the weight of the engines for something positive. Airbus copied it. The engine placement of the 'Jurassic' 737 is simply a matter of the engine being longer than the wing chord. They couldn't put it anywhere else. Also, placing the engine forward without a pylon would lead to heat issues on the wing - you don't want anything touching that hot exhaust. So the 737 wing was designed to handle the aerodynamic torque by itself, without counterweights. The plane is small and the weight penalty was probably not much. Fuel was cheap back then. The reason for the engine placement on the newer 737s is that the entire design is a kludge. By lining up the top of the cowling with the wing and squashing the lower part, they barely got the fan to fit, almost scraping on the runway. The only way to do this is to move the engine forward. Together with the shortness of modern fanjets, this places almost the entire engine forward of the wing, but not for the reason it was originally done. Boeing may have been able to lighten the wing structure a bit, I don't know. The alternative would have been to lengthen the undercarriage, but on the 737, that would amount to a complete redesign, might as start over clean. Incidentally, Boeing had an aircraft just like this, the wonderful 757, but the bean-counters killed it. Boeing is now reaping the rewards of decades of short-sighted accounting decisions. I wouldn't worry about them though, the military division can carry the wayward airliner group for a long time. Boeing didn't buy McD for their airliners. Every time I look at a 'fat-engine' 737 plowing down a runway, I wince. FOD must be a major problem that gets swept under the rug. How Boeing got away with such a mess is beyond me. They obviously have the FAA and NTSB in their pocket. As for the old thrust reversers being pointed at the fuselage, I can't imagine a good reason. I may have mis-remembered the part about the torque on the wing, or 'aerodynamic pitch moment'. It's been a long time. The discussions I find online only talk about straight wings, not swept. There are other reasons to hang the engines out front, the most important being to get clean undisturbed airflow, but also for flutter. And mounting the engines directly on the wings results in an overall lighter airframe. This gets pretty technical: agodemar.github.io/FlightMechanics4Pilots/mypages/pitching-moment/ At any rate, Boeing had good reasons for mounting the engines the way they did, even if my old brain is addled by covid. Engines are typically mounted below the wing for maintenance reasons. It was easier for ground crews, although modern engines are so huge that it is much less help today. The HondaJet mounts its tiny engines on pylons above the wing.
Absolutely no one on the internet gives us aircraft and commercial information as detailed, informative, understandable and fun than Mentour. Cannot thank you enough.
If the 737-MAX had a fly by wire system (which it doesn't it only has FADEC which is just engine control)), the pitch up tendency at low speed high thrust setting could have been simply dialled out. But it still uses a 1960s mechanical direct link control system which needs a supplementary control device (MCAS) to prevent a pitch up under those conditions. Airbus also have a system which prevents over-rotation/pitch up situations. But the key thing is its fully integrated into the electronic FBW system. Not only that, but the Airbus' always run two AoA sensors at the same time, and if there is a disagreement between them, the system disconnects automatically. It's just a smarter plane, not a Frankenstein 1967 design.
Continue to love your work!! An interesting tidbit of information for you: The very first jet aircraft in the world (while definitely NOT a commercial airliner) the Messchershmidt ME-262 fighter/interceptor had its engines mounted directly underneath the wings without pylons. They extended both fore and aft of the wings. Hope this helps! Looking forward to your next instalment. Cheers from Canada!
I can't believe I am hearing the conclusions I am hearing from the Mentor Pilot 😮 The positions of the engines on NG were already enough of a problem during go-arounds (not some abstract "high angle of attack" scenarios mentioned in the video) as, depending on the configuration, the pitch up tendency was sometimes very difficult to handle, and this is part of the reason why pilots on 737 hate go-arounds, btw. And this is precisely the reason for the introduction of MCAS, as Boeing was sure that the number of incidents during go-arounds related to this issues will only increase with more powerful engines. As for choosing to rely on what the name of the system says -"augmentation" -rather than what it actually does - move the stabilizers - as Mentor Pilot does - well, this is reliance is exactly what killed those pilots on the two fatal flights. To repeat this now once we know all the facts is something unbelievable!
Yeah, I'm horrified by the campaign to downplay the serious issues. The wind tunnel tests in the very beginning told them this thing was going to be a handful at high angles of attack-- and the more you pitch up? The more Center of Life moves forward. It is a terrible trait.
I am surprised that Boeing did not place the engines above the wing like the Hondajet designers did. That would most certainly negate the pitch up problem (Bugs Bunny ‘he,he,he,he, laugh).
@@ryanlittleton5615 The "experts" who have never actually taken any aerospace engineering coursework? The "expert pilots" who were so quick to blame "bad foreign pilot training" after Lion Air and ET? Sure. Being able to run the controls doesn't mean you understand control system theory. The definition of "aerodynamic instability" is well understood. Dynamically moving forward of the Center of Lift, during pitch maneuvers? Is textbook.
@@atlascruiser1456 I believe the dude that not only flies the 737 but is also qualified to teach the 737 and is rated to teach the 737. BTW the "bad pilots" theory was pushed by Boeing. I've followed this since it happened.
It's not that it made it unstable, it is that it made it a *different* aircraft with a different type rating. The problem is, they tried to hide that fact so that aircrews did not need to get a different type rating.
And a different type rating meant higher training costs for thousands of 737 pilots across the globe. And that made the Max more expensive and thus less competitive. And THAT is why the bean counters ignored safety concerns raised by engineers. This is a great technical analysis and debunking of the 'instability' myth, but there is much more to the wider story than 'making regulators happy'
Keep doing what you do, you should actually be a consultant to the airlines and manufacturers. Everything you mention is super solid and you have a dream team as well as a tone of other pilot paying attention. Perhaps they should buy a mug and listen up.
I don’t agree with your conclusion. You have no explanation supporting your affirmation that the pitch up effect is only minimal and unimportant. The problem is not about weight distribution affecting the stability which is relatively constant in a small time frame, but it’s all about the change of pitching force during a pitch up manoeuvre at slower speed (higher angle of attack) and how it becomes out of trim in this situation. The 737 NG is already difficult after a go around. The pilots have to push the yoke forward after the initial pull up with a strong tendency to pitch up by itself due to increased thrust located lower from the CG and some pitch up effect due to “lift” of the engine nacelles at higher angle of attack as explained in your video, and raising the flap up one notch. 3 pitch up forces happening simultaneously and suddenly. And that’s the problem with the MAX if one of those pitch up force is also increasing. It’s cumulative. The pilots then was trimming the nose down to level of. If the pilots was “flying the trim” to level off, they were sometimes over trimming down and producing a loss of control and subsequently a crash (CFIT) immediately after the go around. The fact that the max have bigger and more forward engines increased the change in pitch up forces after a go around. The pilots have to push down with more forces after a go around, increasing the risk of pilot over trimming down. Boeing had to increase the efficiency of the MCAS (and hiding it to the FAA) during the conception the MAX for a reason. The reason is probably that a stronger MCAS WAS actually NEEDED due to the pitch effect being a bigger problem than expected. I don’t buy the idea that the MCAS was only to make if feels more like the previous versions of 737. It was to fix a pitch up effect problem that was getting too problematic. Reducing the effectiveness of the MCAS (after the 2 crashes) is only a compromise between two problems. It’s helping to fix one issue by making an other one worse.
First, Petter flies the 737 MAX8, and does know a thing or two about how it handles. It handles just fine. MCAS is a Stability Augmentation System, designed to deal with a stick-force issue during aggressive maneuvering, which would have prevented the airplane’s certification under FAR Part 25. It basically senses when the airplane is being maneuvered aggressively and uses the airplane’s electric stabilizer trim to dial in some nose-down trim to artificially make the stick feel heavier to the pilot, when the airplane would not naturally exhibit the correct characteristics. You may want to read the documents that FAA released when the airplane was recertified. There is a lot of detail in those documents that explains everything and puts to bed a lot of the BS that was promulgated in the mainstream press.
Your videos have really helped with my previous fear of flying. I am no longer gripping the seats like a madman with sweat pumping from my cold forehead
if u used to be scared of flying then your should be having a heart attack in a car lol there wasn't a single passenger plane crash in 2023, but there is over 5,000 car crashes a day in the country that i live in. the chance ur flight crashes is essentially impossible
With Boing's management now fully in the hands of the bean counters, spending huge sums of money of money to develop a new more modern plane will be a hard pill to swallow. There needs to be a change in management philosophy back to the day when Boeing was primarily an engineering first company not stock prices first. Current events dramatically show how short sighted that management style is. I hope they retrench, rebuild their reputation not fade away!
Great video (as always) ! I think that you didn't go too much in details about the MCAS system , to keep more insights for the video of the 2 crashes related to this system. You didn't mention the origin (or genesis) of this system. I read that the MCAS came from some engineers working in Boeing Military Division and suggesting this system to their colleagues working in the Civil division of Boeing. In the 70" it seems that Boeing developed this system to ease the job of the military pilots flying Boeing refuelling tankers. The system was designed to adjust dynamically and "transparently" the center of gravity of the tanker to keep it steady at the same point during the all duration of the mission, when meanwhile the tanks were getting more and more empty by keeping feeding the "clients" just below behind.
Actually you can see how they made the mistake with MCAS in the first place from the name. Because it’s an “Augmentation” system intended to supplement the feel of handling the aircraft. Someone most likely listed MCAS incorrectly as “non critical” or “non-safety related” system that does not required to have backup or redundancy built in. Hence, its ended up only using a single angle of attack sensor. If MCAS was listed as critical or safety related, it would definitely use more than just a single sensor for redundancy. Of course this is not 100% certain but i think this is the most plausible how they ended up with only a single sensor for MCAS. The name “Augmentation” might’ve trigger the chain of events leading to the disasters.
Did a northbound t/o at MCO. Used TO2, but wanted normal climb, not reduced climb due to Orlando Exec. There was a definite increase in pitch moment due to the increased thrust.
Cheap poorly thought out solutions are rarely a solution but problems that can cause more detriment. my uncle worked for Boing and told me that after the merger with mcdonnell douglas quality went into the toilet and became more focused on cheaper everything including labor of all sorts. me personally if I had to fly I would only use a European made air bus whos company focuses on quality to a noticeable degree does not overlook possible flaws in the pursuit of profit.
Fwiw, Aviation Week did a test flight years ago, and identified the tendency for the nose-up. But the pilots said it was easily corrected using pitch, and otherwise stable and easily handled. It was the MCAS software that gave it a black eye, especially without telling the pilots.
You make a good point that there is nothing wrong with the basic aircraft design. Problem is, that cannot be said of MCAS design . Boeing put a system in that had the ability of rendering the aircraft unflyable if it received faulty data, with no cross check or redundency, an ammazingly bad design decision, based on money and sales. THAT should never happen, any system that can crash an aircraft, unless the pilots act promptly, should be as safe as technically possible. If you need to reference the QRH, if it involves flight controls, you're running out of time.
@@henson2k Did you even watch the video? The plane flies normally, maybe even more "normal" than the old one, But it was DIFFERENT and they didn't want to train people so they made it behave like the old model. Which was clearly a mistake.
@@rasta77-x7o the plane is already normal, but they added MCAS for no good reason and it backfired. It's safer to just remove unnecessary component and retrain the pilot for every new airplane.
Thanks for a very informative video, I have rather a mundane question? At 21:21 what is the ball on a string stretched out behind the aircraft from the top of the tail?
Till the door plug incident, I quite believed that 737Max series 7/8/9/10 were quite a good aircraft. My gripe is, that they shouldn't have been the same type rated at 737NG or previous 737s.
Airlines should not be put in the position where they can make more money by not training pilots. The system is broken. Using the plug incident to change your opinion regarding the 737 MAX is wrong. The plane was not designed to operate w/o these bolts. It is fair to say you don't trust Boeing to assemble airplanes.
They are still good aircraft. But it is similar to finding a good product at Ikea -- it will only be as good as the person assembling it. Boeing has serious issues in this regard.
Why? Would you refuse to fly in a 747, 757, 767, 777 or 787 because they're Boeing airplanes? Remember YOU said: "If it's Boeing, I'm not going." You might have noticed -- or, come to think of it, perhaps you don't care -- that there are many hundreds 737 MAX airplanes flying passengers on many thousands of flights every day and these airplanes get their passengers to their destinations safely and generally on time. They make money for their owners and do so while saving fuel compared to older airplanes. Yeah, I noticed that there were two crashes of MAX airplanes but I also noticed that airlines based here in the US with crews trained here in the US didn't lose ANY. I believe that the European version of the American FAA was coerced by Airbus to ground the 737 MAX in Europe to give the A-320 a competitive advantage and the FAA followed by grounding the MAX airplanes in America because they were afraid to be seen as allowing what some people considered an unsafe airplane to fly. I wonder how many A-320's Airbus sold while the 737 MAX was grounded.
@@thewaywardwind548 you think the FAA should have kept the defective 737 Max flying in United States while the rest of the world grounded it? Do you honestly think not appearing biased was the only reason the FAA should have grounded them? You know they were defective, right? Boeing designed a defective and dangerous MCAS system and tried to hide the risks associated with it. We know this now. The investigations of the 2 737 Max crashes did not conclude with "pilot error". Are you saying they should have kept flying the 737 Max even while the MCAS was defective and pilots were still not trained properly on how quickly they need to shut the piece of crap off when MCAS starts diving the jet into the ground?
In your March 15, 2019 video titled, "Boeing 737 Stall Escape manoeuvre, why MAX needs MCAS!!," you explained the necessity for MCAS in terms of an obviously safety-critical function of assisting the MAX in getting out of a stall - apparently in contrast to your present video wherein you explain that the MAX would be safe without MCAS. In any case, as you may know, the Boeing 737 MAX Flight Control System Joint Authorities Technical Review (JATR) rendered its final submittal to the FAA on October 11, 2019. Do you (or does anyone) know whether the FAA has implemented any or all of the JATR recommendations in respect of the Boeing 737 MAX, and in particular Recommendation R3.5 which states: “The FAA should review 14 CFR 25.201 (Stall Demonstration) compliance for the B737 MAX and determine if the flight control augmentation functions provided by STS/MCAS/EFS constitute a stall identification system.”?
Another important reason engines are out on pylons is to control oscillatory wing flex behaviour of swept flexible wings, and its coupling to yaw induced roll. This was a Boeing innovation that was a key enabler for flexible swept wings, and all modern jet airliners. Their insight was that they could control the period and amplitude of wing flex by placing a large mass on an arm extending out from the wing. Which is of course the engine on a pylon. The visible slight nodding behaviour of engines in flight is the visible confirmation of the desired result. Wings still flex, but the flex doesn't couple well to forces on the swept wing geometry when the aircraft yaws, thus leading to a stable wing and aircraft. The engines on a 737 are so close to the wing root that it probably doesn't matter nearly so much, if at all. But on larger aircraft with long slender wings, this makes the design viable.
Is the rudder jam issue inherent to the 737 airframe design, or is it poor quality again? Time and time again, issues with the max show to be quality or specific sub system design flaws, not flaws inherent to the overall design of the airframe. Boeing could have relatively easily made the MAX a safe, efficient, and prosperous family, and have simply failed in implementation. In other words, a lot of these issues could have happened just as well with a clean sheet design, and these days, probably more issues.
@@davidcole333 now that's nonsense. A plane in service for what, 6 months, doesn't rudder jam due to "poor maintenance". Edit - ok fine, it has been in service for a year. I still doubt it's a "maintenance" issue.
This is not a problem of the B737Max specifically, other airlines have technical issues from time to time. I think the crashes with the B737Max in a short period of time, due to the lack of communication about the MCAS to the pilots, directed the focus to that specific type. So issue reports on the B737Max get more attention. But I think it is an indication of a deeper lying problem at Boeing, especially their quality management and the focus on the stock price at any cost of the upper management at Boeing.
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You are generally excellent, but here I must ask: "What are you talking about?!" I graduated in aeronautical engineering. Stability is determined for each axis of rotation by whether the total moment acting on the aircraft around that axis is such as to increase or decrease the angle of rotation, and it is defined for specific aircraft configurations (landing gear, flaps, spoilers, etc.) at specific flight speeds and density altitudes. When the Boeing 737 Max is flying within a certain part of its flight envelope and the pilots command pitch up, lift created by the engines beyond a certain alpha generates an unusual total net positive pitching moment that tends to lift the nose of the aircraft further. In this flight regime the Boeing 737 Max is by definition UNSTABLE IN PITCH. That's a mathematical fact. Boeing therefore introduced [faulty] software to correct this, so that pilots would not have to be retrained to cope with the instability. One reason for doing so was to prevent screw-ups where pilots would forget which model 737 they were flying and act inappropriately. Have you covered the Boeing 787 Dreamliner cockpit window cracking due to Boeing's abject failure to properly test the new curved panes for differential thermal expansion versus their frames before the aircraft entered service? That's a shocker!
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Imagine an alternate world where Boeing didn't merge with Mcdonald Douglas. And instead just made a successor to 737 in 90s.
They launched the 737NG in 1993, well before the merger with McDonnell Douglas, and it entered service in 1997. It is difficult to imagine the old Boeing making the MAX, but replacing the 737 in the 1990s would have been difficult.
Same world where the 757 was successful
A better world
@@MentourNow The old Boeing would have made the MAX. They just would have prioritized safety and reliability over profits. That in mind, old Boeing 737 Max would have been radically different from what we have now, being a better developed (or outright omission of) MCAS, more redundant systems, fly-by-wire, and other important upgrades.
If we ever invent time machines that merger should be high on the list of things to go back and stop from happening.
Using a single sensor for MCAS even though two were available and it really should have been three was criminally stupid.
And not mentioning MCAS to the pilots seems actually criminal to me. Why was nobody sentenced to prison?
Nope ..Boeing owns the government they probably would of gave Boeing a medal of bravery if they could of
It was a very poor implantation. It switched from left to right AoA sensor every flight.
That said, it's effectively auto-trim, and pilots train to recover from runaway auto-trim, so its not like its a totally new system.
Department of Justice announced today that it has opened a criminal investigation into Boeing regarding the door plug incident, and whether Boeing violated the terms of its settlement re: MCAS, by failing to document required safety work re: door plugs.
@@roflchopter11 It is easy to talk from your warm armchair. They could recover only if they knew what the problem was.
Search for "Boeing Charged with 737 Max Fraud Conspiracy and Agrees to Pay over $2.5 Billion"
That is how American justice system works. You make a deal with the prosecutors to pay compensation and you are free to walk away.
My understanding is that the simulator test pilot for the max very pointedly made clear that the plane naturally pitches up way more than “slightly”. The MCAS was not there to simply make the plane more pre-Max-like, but to address a serious pitch up issue.
they thought they made it safe with MCAS?
Because they are stupid civil servants with little aeronautical engineering expertise in aircraft flight controls on an unstable aeronautical airframe.
Also, if MCAS is only to improve the handling, why would a wrong implementation lead to crashes?
Absolutely.
Mentour does not seem to understand the problem.
The forward engines generate so much lift, at high angles of attack, that they can pitch the nose up to such an extent that the aircraft can flip onto its back.
It is called a ‘deep stall’.
Check out what can happen to Rutan canard designs, where the foreplane can again flip the aircraft onto its back.
THAT is the problem they were grappling with.
R
Have you even watch the video? on 21:10 it shows you still need to pull a lot hall on the yoke to keep increase the AOA,.
Have you ever tried to stall a 737 in simulator or IRL?
I have tried to deep stall a max on Lv-D simulator and I can barely keep it at edge of stall with full yoke back and constant back trim input, the nose just want drop at high AOA, even without MCAS.
I am a retired aerospace engineer and a sport pilot. Your videos provide the absolute best explanations of these issues. Thank you so much for making them.
Wow, thanks!
No your a liar
@@2popes-w2cI think you mean "you are" or "you're"
You’re*
Aerospace engineer? May I ask what your education is? Given that you find these 'journalist' level videos best, I am curious. I have a PhD in Aerospace Engineers. My PhD was sponsored by GE Aircraft Engines. There is a lot of misinformation about the Max, which is understandable from the laymen. As for the Max itself, ... Lufthansa ordered 100 in Nov last year. One can assume Lufthansa, ordering 737s for the first time in 30 years, did their homework, and are more knowledgeable than UA-cam specialists.
I’ve flown on a 737 with gravel kit. Canadian North retired them only after the pandemic. Air Inuit still has one.
(Oh I just noticed you featured that very airframe in your video!)
Awesome!
Chrono aviation still flies one
I thought Buffalo Airways was looking for a gravel kit for their 737?
For many years in the 1980s I commuted to Deadhorse, Alaska on 737s that had a gravel kit. I might have even been on ones that I helped assemble the engines because I worked at P&WA on the assembly floor in the late 1970s and saw that the customers of many JT-8s were for the airlines I flew on. 3 of those same 737s I flew on then ended up with a mining company in Indonesia that I also flew on over there. These ones had cargo doors.
About placing the engines forward and under the wing. Some good points were mentioned. Throw in a few more. I think it causes the engine to aerodynamically interfere with the wing less. Which makes the wing more efficient and allows a smaller wing, less drag etc. Higher bypass engines also have different airflow characteristics than lower bypass engines, with the air going in, its got to be carefully designed so wing and engine don't interfere with each other too much. Placing the engine forward allows the weight of the engine to act as a mass balance which helps to reduce aerodynamic/aeroelastic flutter. Which helps to save structure weight. And the possibility of fire was mentioned. Also if theres a uncontained failure such as compressor or turbine blade it will be less likely to penetrate wing structure and damage crucial structure or fuel tank or system. So theres lots of benefits. As for the instability caused by larger engines. Yes its not because of the added weight forward of the wing I agree. It comes from a combination of things. Compared to previous 737 types. The engine has a larger diameter. Which means the thrust line tends to be further below the wing. It produces more thrust. The shape of the nacelle causes it to produce lift. And the engine is further forward. So all this means that the engine and nacelle are going to generate more pitch up moment. Thats means if you're in a high angle of attack situation with high thrust setting. It mite be harder to pitch the nose down. Hence taking away from the effect of natural longitudinal I think stability. Hence the need for all this MCAS crap to compensate. Not just to avoid potentially dangerous high angle of attack situations. But also to make the plane handle like previous 737s to please airlines and regulations and certification etc. etc. But ya the new engines do kinda make it unstable, but not because of weight and cg, because of thrust and aerodynamic effects and moments. Thanks for listening to my 2 cents good nite.
Correction maybe the engine thrust and aerodynamics doesn't actually make it unstable. Maybe just slightly interferes with the stability. Ok maybe there is no real danger for stall or difficulty in avoiding stall at lower speed higher pitch or higher angle of attack situations. Due to engines or otherwise. Maybe its just a relatively minor handling issue. It needed to handle similar to previous 737s so that discrepancy needed to be fixed, to meet regulations and what not. Also contributing to the pitch up moment is just the fact that the engine/nacelle is bigger, it has more area to produce lift. But also theres other aerodynamic reasons too it makes a big vortex something like that. Combination of a few things. I think the 737 MAX could have worked. They didn't need a all new design yet. But. I think they rushed it too fast, didn't take the time to develop it right.
Internal company documents released during the investigation reveal that in test flights, during high speed maneuvers, although rare, and outside the normal flight envelope, caused serious instability due to the nose pitching up. Boeing's engineers initially suggested a tail redesign as the best solution, but were overruled by managers due to the time and expense involved. Then, they decided to adapt MCAS from their fighter aircraft designs, but to ensure limits on the MCAS operation, the system was activated only when the angle of attack sensor detected a nose up condition in conjuction with high readings from the accelerometer (high speed maneuvers). Later, flight tests detected instability (high thrust causing nose up and stalls) in certain situations even during takeoff. So, to correct the instability at low speeds, Boeing allowed the MCAS to ignore accelerometer readings and work with just the angle of attack sensor, which of course, then became a single point of failure. An engineer did indeed raise this point with a supervisor, but his concerns were dismissed. To further compound matters, Boeing did not report this new change to the FAA at all even though it was required to do so. Company employees actively lied to the FAA about it.
You are absolutely right when you say that using heavier engines or moving the engines forward increases static longitudinal stability, but may create longitudinal controlability problems. However, the main problem with the 73 max is an inversion of the static longiitudinal stability at high angles of attack, probably caused by altered airflow patterns aft of the engines toward the horizontal tail. It is a solvable broblem. However the way Boeing implemented a solution was a disaster, and we do not understand why the FAA did not catch it: 1) MCAS based on a single alpha vane. An alpha vane has a probability of failure somewhere around 1 failure in 40000h. But the MCAS in a way affects primary flight controls. Failure of primary controls are catastrophic and the requirement is that catastrophic failures can only happen once in 1000000000 hours. (10-9), as per FAA AC 25.1309. Had they used two alpha vanes (deactivating the system if there is a discrepancy between them) the probability of both failing at the same time would be once in 1600000000h, which would meet the safety requirement. 2) The MCAS actuated the stabilizer at a very high speed, turning the stabilizer into a kind of primary control. 3) PIlots were totally unaware of all those differences.
How is it you know ALL this, but Boeing Engineer's and the FAA doesn't my friend?
Could you describe in more details what is inversion of longitudinal stability and why this happens when engines are moved forward?
Moving the engines forward must change the centre of gravity, let alone all sorts of other considerations.
The MCAS system was designed with redundant sensors. This was later made optional as a way of generating upsell revenue.
Designers also repurposed the MCAS from the special use case described by Petter to a larger role in flight, and the either failed to tell their test pilots or the pilots later denied knowing that they had.
All of this is criminal neglect of their responsibility to the airlines and passengers.
@@norlockv what do you mean MCAS was repurposed? Can you explain?
Together with Jean-Claude Malroux of Snecma, my father was part of the original marketing team for the CFM-56. The big break was the DC-8, which was an obvious easy re-engine, followed by the KC-135 and other 707 military variants. My father always felt that the 737 re-engine program was a rush job as Boeing tried to keep small Airbus variants from eating their lunch. Still, the 737-300 broke the Pratt stranglehold with Boeing and proved to be a launching point for both CFM and GE. That clever engineering you mentioned paid off hugely.
Although long-retired by the time that the MAX line came out, Dad was still connected enough to know that one of Boeing’s major pitches for the LEAP-engined planes was to that they were to require minimum pilot retraining. And therein lies the rub and at least some of the design errors.
I never finish a full video on UA-cam or never watch a full tv show or movie. However with your videos I have never stopped it early and always watch it in its entirety. Thank you for the awesome consistent content.
I never knew they extended the gear length. Every other source concentrated only on engine placement. Thank you.
Only on the 737 MAX 10.
@@Voyager.2 On the 737 Max 8, they didn't extend the length, but they did beefed up the supporting structure, fuselage skins and other changes to accommodate the heavier engines. It was part of the reason why the MCAS was not given as much attention since the FAA was focused on the updated landing gear and fly by wire spoilers. This was all reported in the FAA report AV2020037.
@@Voyager.2 I believe they extended the nose strut on all MAX variants. However, the main landing gear that expands during rotation to increase tail clearance is restricted to the MAX 10. I'm not 100% sure about this, so take it with a grain of salt. :)
Extended gear length you said.... ua-cam.com/video/Q8oCilY4szc/v-deo.html
@@ahndeux The MCAS wasn't given much attention by the FAA because Boeing intentionally hid the existence of the system, just as they hid it from pilots by choosing to remove it from the Aircraft Operating Manual to preserve the type rating.
Not exactly to keep regulators happy, was it... it was to persuade regulators to keep the same type rating so that airlines didn't have to do more pilot training. Or am I wrong?
Exactly, this is the crux of the problem, when is a 737 no longer a "737"? Of course planes should be allowed to change with advances in technology and requirements. But they also have to be classified as a different type when these changes are significant enough. Boeing tried to cheat on this latter part and it resulted in the deaths of 346 people.
It was both..but mostly your second point. Boeing would've been on the hook for the pilot training if a new type cert was required.
The latter is what mostly is meant by the former. Yes and yes. They also wanted to keep airlines happy.
Boeing was trying to keep the airlines happy by not having them spend money on training and sims i guess
Contrary to what Petter says, EASA believes MAX is unstable, or at least can go into an unstable condition in certain flight envelopes. That is why there is a *third AOA sensor* requirement.
Do not forget that Boeing's own staff says: "designed by clowns who in turn are supervised by monkeys"
Also former Boeing Manager Ed Pierson says "He Won't Fly on a Boeing Max Plane".
As a control engineer (we are the guys mostly obsessed with stability), I am horrified by how B737 was modified and the control system was augmented. The way this passed regulatory approval is scary. I will never willing fly B737 again.
Actually, I would think the Max is probably much safer now, than it ever was.
thnx for the tip... i wont be telling my mother in law
Honestly I have been following this since the first incidents since I am an engineer in aerospace and focus on design changes. I know they have improved things but I will still never willingly fly on that thing.
@@allthatsheiz
100% agree
@@luisurbina5115how can it be when obviously they did not care about safety standards even after the 737 max crashes? Even if the design is theoretically good, who is to say everything was assembled right? Boeing is not safe.
High, I’m a 737 veteran myself and quite familiar with the concept you are discussing. I flew most variants of the 73 and my flying came to a halt when the mcas mess came about a few years ago. I was in the middle of the type conversion in Singapore when it all happened. Anyways to the point, I firmly believe that it’s time for Boeing to say good bye to the 73 and maybe concentrate on the 75 comeback and making that model a better unit than the original was. I’m not an engineer but common sense tells us that shrinking an airframe is probably a little easier than trying to stretch it as in the max. The Russians have come up with an airframe around 210 pax and I think that’s a good size to have, which is why I think a redesign 75 makes a lot of sense. And knowing Boeing will do anything to screw this up, make it a totally new wing design instead of the bs job they did with the max which was the same airframe as the NG. A new design is a new aeroplane period.
Enjoy the joys of heterogenous fleets, expensive training to change airframes, etc.
@@roflchopter11Pilots take on new type ratings all the time. It isn't a big deal.
A pilot will typically have three type ratings before they ever begin commercial training. Another one or two for mulri-engine. Probably another for instrument. Then one or two, or three at their first regional job. Then three or four more at the majors before retiring.
Well what then do you out of Airbus making the A321XLR MTOW above 101 ton, the wing was never ment to lift that weight.
An updated 757 isn’t really a suitable way instead of the MAX. Most 737’s are as you probably know the 400/800/MAX8 as it is the most popular size.
Juan likes the 75. That is good enough for me. Dust it off. Fly it.
@@HaroldBrice so does Trump
You are correct regarding the reuction of the fan diameter on the CFM-56 engines powering the 737NG, but your explanation was incomplete. In addition to lowering its efficiency, this lowered its power too. The engine was derated from 24,000 lb of thrust to 20,000 of thrust. Also, your explanation of the MCAS is great. I would like to add that MCAS is not new to the 737MAX. An MCAS was implemented on the KC-46 (767) air refueling tanker. This much more robust MCAS was needed because a tanker's center of gravity is frequently changing during flight as the tanker offloads fuel to recipient jets requiring it, and as such, MCAS is more active on the refueling tanker. The KC-135 tanker and KC-10 Extender tanker had a Second Officer (flight engineer) who was in charge of fuel transfers between tanks (to manage the center of gravity) but the 767 tanker does not, and requires more robust computer functions to fly safely. The 737's MCAS was less robust, lacking sensor redundancy, to reduce its cost, because Boeing calculated that airline 737s would not need it often, only in specific situations. Boeing's assumption, while correct, led to a problem which not only caused two crashes, but also caused some incidents on US airlines that could have resulted in crashes, but did not.
I worked on the 757 as part of a team designing the PACS(Pitch Augmentation Control System) which was similar to MCAS. There was a concern that the plane was unstable in pitch due to the engines. After the plane flew, they deleted the PACS as it was deemed unnecessary.
@@deltaskyhawk Thank you for sharing that. Did you work under Phil Condit? I have read that Condit, who later was Boeing CEO, made a critically important contribution to the 757's engineering, fixing a problem - but I don't have the details. I also read that his work on wake turbulence for the 747 was groundbreaking, allowing the 747 to be included in a reasonable takeoff interval at the airport and the science he developed was adopted by the FAA. In contrast, the later Airbus A380 needed a longer interval to protect following jets from its wake turbulence. Can you correct me on any of these details?
@@ronaryel6445 The name is familiar ... but Boeing was a huge company and I was a contractor in a small corner of an engineering building in Renton. Early 80s. Boeing had an interesting approach to design. There was a whole group that designed just a window. Their approach was to solve problems by throwing a bunch of engineers at them. As a PP, wake turbulence from any of these heavies is dangerous.
@@deltaskyhawk Thank you.
Thank you for showing the photograph of the Air California 737 (time 5:02 in the video). My father was vice president of Air California starting in 1968 for several years. As a child I loved flying on those 737-200 airplanes. The paint job was golden yellow (for the Golden State) as were the flight attendant's uniforms (then known as stewardesses). I loved the sunflower on the nose of the airplane. It was a great logo. Air California ceased to exist when American Airlines purchase the company in 1987. They had one crash at John Wayne Airport in 1981. Thankfully everybody survived.
I believe that the ME262 was the aircraft that inspired the original B737's wing & engine layout!
Actual aircraft designer and propulsion engineer here. Any change that results in a nose-up tendency at slow speeds is inherently less stable, and MCAS was intended to address it by inducing elevator deflections to keep the nose down. That's exactly what lead to the 737 Max 8 crashes. Additionally, the CFM56 redesigns also led to a greater risk of uncontained blade loss which also resulted in passenger injuries. Lastly, the worst problem is Boeing's repeated failure to report known safety issues, starting in the early 90s with a known issue with the rudder controls that eventually led to two fatal accidents, and ending up with unreported issues with the MCAS and it's single-point failure mode (which violates regulations for safety critical systems) and finally the recent quality escapes on the Max 9 and potentially other models. The 737 has become increasingly less safe with each generation and Boeing has repeatedly cut corners on safety.
As I had to do with nuclear power plants, there should be no discussion that this plane needed three angle-of-attack sensors with a discrimination unit that indicates when one of these sensors differs too much from the others.
Exactly. Very disappointed with Mentour here
@@faceless360 Cos its fact maybe your not ready for it ...... Nothing wrong with the max.
@@ShaunHensley Its fact...
@@faceless360 Mcas did not cause those crashes read the reports and dont listern to the bullshit media, Cos its just all lies and misleading information.
In my 30 years at a US major I never heard our 737-300's called the "classic" that was a southwest term. Also the "Jurassic jet" was uniquely a term for the 727, never used for the 737-200. When I bid up from the 737-200 to the 737-300 I was trained on how at hi nose & low speed the addition of thrust does input a bit of nose up pitch unlike the 200, exactly was you have addressed. Also the NG series again had bigger more forward engines, higher mounted engines and would input some nose up pitch more so than the 300. Thank you so much for addressing this misinformation propagated by lax/sloppy media reports.
Your callout to Stefan Drury's channel & encouragement to help him out: that was kind & generous. Thank you for being a friend to him. That small gesture is infectious - encourages community amongst us all, is an example of how we can all help each other. We need more of that.
I've occasionally enjoyed your channel's posts, but am now subscribed to yours & his.
Agreed. Stef is a great creator, and wish him a speedy recovery
Great video again Petter! Don't know about the jurrasic 737 but the Classic already had the Speed Trim System which would act on the Stab position in Low speed, high AOA+High Thrust conditions, i.e. Take off and Climb phases. According to our course notes and instructors this was to counter the nose up tendency the aircraft would have in such conditions. This was a direct result of engine shape and placement. In other words, the issues with the Max were not exactly new ones. However, the course notes never went into depth about the exact characteristics of the systems (one in each FCC) and which inputs were actually used to control the Stab. Neither did the Aircraft Maintenance Manual. We just knew the system was there with a fault light on the overhead panel to prove it.
To add a little more, the CFM56-7 wasn't the only upgrade on the NG, it too had a taller main gear (and re-designed wing) to accomodate the larger nacelle diameter compared to the CFM56-3 on the Classic. In other words, the issues with the Max were not exactly new ones.
At the 21:14 point, suffice to say that the wobbly (change in slope) of the Cm-alpha curve line near/at stall makes MCAS necessary from a human factors standpoint. Without MCAS nose-down trimming, it's trickier to fly near stall, meaning you can be in a full stall before you know it. The pilot would need to know to change back pressure on the stick as stall nears, which is possible, but a little startling. Never startle a pilot near stall !!!
Actually, technically the part where Cm-alpha has a slight positive slope (the no-MCAS line) near/at stall, is the definition of "unstable". It is slightly unstable near stall, not dramatically, but slightly.
Yup. If it was stable, there wouldn't be a MCAS. It's unstable
MCAS is all about one small paragraph in 14CFR25. The real problem was the single point of failure of the AoA vane.
“25.203 Stall characteristics.
(a) It must be possible to produce and to correct roll and yaw by unreversed use of the aileron and rudder controls, up to the time the airplane is stalled. No abnormal nose-up pitching may occur. The longitudinal control force must be positive up to and throughout the stall. In addition, it must be possible to promptly prevent stalling and to recover from a stall by normal use of the controls.”
Faulty pitch sensor? Why did it indicate Unreliable Airspeed? If the AoA stuck at a high angle, there would have been a stall warning condition for BOTH landing and takeoff
Now if MCAS was integrated into the autopilot sensor suite, engaging the autopilot, would automatically trigger the MCAS even if it had previously been turned off
@@luislongoria6621 There was. On takeoff roll in both crashes the captains AoA vain deviated, so when the plane rotated the stick shaker immediately activated.
I'm a private pilot, (love the decathlon for the upside down silly stuff), and obviously never flown the big guys but I love hearing the technical stuff about how these huge metal boxes fly.
Excellent video as usual! You mentioned the "speed trim system" very briefly, however a little more information about the Mach/Speed Trim features on the 737-300 would be useful. The Mach and Speed Trim system along with the Elevator Feel system operating through the trim system were all designed to 'augment' the feel of the pitch during manual flight. I flew the Jurassics, and Classics. When I first flew the -300 after years on the -100 and -200 Basic and -200 Advanced, the Mach/Speed Trim and Elevator Feel system were very prominent during hand flying. While pitching up in manual flight, the trim wheel would actually trim nose down while pulling the yoke nose up. A curious thing for the a pilot new to the 737-300. The very light feeling of the yoke in pitch is not new and began with the -300. The trim system was used to augment the pitch feeling from the very first installation of the CFM-56 onto the airframe.
Your videos are always clear, fascinating, and watch-friendly. I have to compare the Max issues with my experience in military aircraft, where we were instructed that we would compensate for wild changes in handling characteristics in various routine flight regimes (not just takeoff and landing) simply by learning to anticipate that the plane would attempt to surprise, annoy, resist, or depart from controlled flight. We also had cutout switches for multiple automated systems in case we suspected the automation had somehow taken on a life of its own...including stab trim, anti-skid, stability augmentation, autopilot (of course) and others. Finally, we also had many, many restrictions on engine anti-icing, which became an onerous addition to workload when it was in use. I can really appreciate the comparatively modest enhancement that MCAS makes, and I hope more of your viewers come to understand that the terrible results stem from Boeing's corporate (Chicago) decisions regarding the profit implications of how they addressed transition training, rather than from the engines or the MCAS engineering (Everett).
@berkeleyfuller-lewis3442 I'm struggling not to resort to ranting about the catastophic results of the merger with McDonnell-Douglas...to include their behavior in the next-generation fighter, tanker, and SAOC competitons! Reprehensible. Chicago is trying hard to singlehandedly destroy yet another pillar of the US economy.
My son is passionate about pilot and aviation. So I started to search a good channel about aviation finally I found it. Sir, your are doing great work and your creating curiosity but you are explain about technical side. I am really impressed. Who wants become a pilot must follow this channel can learn lot. this channel should be dubbed in other languages also. (Consider)But English is the priority. I really appreciate your efforts. ❤
Thank you! I’m so happy you find it helpful and send my best regards to your son.
Good luck to your son. I think this channel will prove to be an excellent resource for him.
No one cares about your son
Shutup
If you are in the US, check out the Civil Air Patrol and Young Eagles
I love the way you make your explanation as simple as possible for the average layman. I also like that you aren’t afraid to admit that you maybe wrong on something.
One thing comes to mind is flying down the north coast of New Guinea at midday listening to the Goon Show in a 707 and watching the engines contra rotating on their fairings.
Another major issue with MCAS is that it was not implemented as designed. The engineers designed its ability to change trim to be very minor. In this way tying it to a single angle of attack sensor was not a big deal as if it went off the rails due to bad input MCAS' ability to endanger a flight was almost nonexistent. Later on however management dictated that MCAS needed to be much more aggressive in order to ensure that they could tell airlines that no simulator training would be required for pilots of earlier 737s. It was a perfect storm. A system that was not designed to be redundant because it wasn't seen as necessary due to the relatively minor fight inputs it was capable of making, which was then altered to be able to make extreme changes, and then pilots were not informed about the system.
The original design did not link it to just to AoA sensor. It was much more for the higher speed manouver where the aerodynamic effect of the engine meant the stick pressure reduced - the regulatory requirement.
Later it was found that to keep the handling feel the same it was needed at slower speeds. In this phase of flight the second sensor (I thick it was an accelerometer but I could be wrong there) would not be effective - so the use of a second sensor was removed - without adequate risk analysis of what would happen should the AoA sensor become defective. This is the root cause.
Hmm, I am not surprised based on Boeing's management structure. The entire line of management is non-technical and that has major consequences. They should not be making decisions, and not even be with the company. It needs to go to a unified engineering group, where the managers are still still leads or individual contributors and no on the other side of the union wall. This is the way many other engineering firms are
As someone who works ramp, let me tell you, even if I don't notice any other difference between the Max & NG, you will notice the taller landing gear. It sits noticeably higher off the ground, and you can tell when you go to plug in ground power or plug in a headset for pushback. Even better, since the Max9 is prone to tail-tipping when unloading (even the Max8 tips back a bit, but don't worry we use a tail stand to prevent this), and due to how much higher off the ground the aircraft is, sometimes you can barely reach the panel for ground power if it tips back just a little. The Max is a beautiful aircraft, but I do wish they'd moved that panel down just a bit for us on the ramp 😅 I'll still take it over the panel mounted directly under the fuselage on the A320 family, that is kinda annoying to work with.
Very swenglish centimeters, but i love the work going in to the channels. Firm knuten näve i bröstet, and the Robert Redford nod meme
The most amazing aspect about the 737 is that they still fly with the original ceretification
Is that true? I thought they were waiting on certification for the MAX7 and MAX10 variants?
@@JackS425 I think he meant pre-max models, especially 737 classics.
The -300 through the -900ER have the same type rating I believe.
Maybe I'm the odd one out here, but I really enjoyed flying the DC-9/MD-8X/MD-9X/717 family of aircraft. I always found them to be smoother in flight and less affected by turbulence, the major negative being the noise level if you were seated in the rear, adjacent to the engines.
I was fine with flying in the "A" seat of those, but I found the pressurization system to be kind of herky jerky, more often causing ear problems than any other airliner I flew often. And I did fly into Detroit in one, looking down at the wreckage of another one. It also had the least desirable seat on a commercial flight, the one in the rear which is a window seat without a window, because if the engine flies apart, that's where it is aimed. The only takeoff roll I experienced being rejected at high speed, was also on one. One engine wasn't developing full power, which is a pretty rare thing to take that long to figure out. For a year or two after the DC-9 Super 80 came out, every time I was on one, I hoped it didn't buckle and almost fold in half if we had a hard landing, like the one did when they were testing minimum landing distance over a 50ft obstacle.
Having said all that, it seemed like a super solid plane for what it was, a real workhorse. And it was the only airliner I got to sit in the co-pilot's seat of during a flight delay. Ahhh, aviation before 9/11.
The knocks against MD were really on the DC/MD-10 and MD-11, which had major problems that got ironed-out too late. MD had overpromised and underdelivered on those jets. But the DC-9 series (MD-80s, 90s, now 717s) were super high quality builds. The 2+3 seating configuration was my absolute favorite in the air. The rides on the MD-90/95 just couldn't be beat for quietness and power. Fortunately, the X-66A seems to be bringing a lot of these possibilities back to us. I hope it is a success.
Thanks
Thanks for your support!!
It didn't make it unstable. It made it different. So came the MCAS, which nobody knew about. The FAA didn't know about it, the pilots didn't know about it. Never mentioned in the Max manuals.
THIS is the outrageous part. Profits were put above safety.
Boeing should have worked on a new 737 since the 80s, or at least early 90s, to take full advantage of composite materials, more efficient engines, fly by wire technology... They're at least 30 years late.
Its functionality equivalent to auto-trim, which pilots and the FAA did known about. In fact, pilots have a memory procedure for handling runaway trim. The procedure works, as other pilots used it to recover from MCAS anomalies on the same aircraft that later crashed. Those airlines failed to record and repair the AoA sensors that caused the anomaly.
The implementation was very sloppy, but the pilots were trained in recovering and failed to do so.
System differences manual, page 734. Go look for yourself.
Mcas isn't the problem with such crashes I believe. Lack of being able to understand flying was more the case.
@@daftvader4218 I do have a clie actually. You should listen to the flight safety detectives and also familiarize yourself with stab trim cut-out switches that may only on the ground may be placed back as well as memory items, the fact that the two crashes aren't exactly for companies that do well. Also, the most of the a/c flew with MCAS w/o any problems.
both totally were avoidable. yes there were maintenance issues at one of the planes but with capable pilots it would never have happened.
Also, when it comes to news: even if a maintenance guy forgets to install a wheel correctly, it's still in the news of being Boeing's fault.
Ayways, I do have clue. Good moment for you to dive in what really happened on two flights and ask a few people who actually fly a/c with MCAS.
The grounding is due to people that -indeed- have no clue.
@@RoelandJansenyou are insane if you said the system that killed over 500 people is not the problem smh……
Going back in time, way back, I grew up in Chicago and remember some interesting sights. This was back in the early and mid+ 60s. I remember seeing a DC-8 fly over our house (going East) and one could hear it for 20 minutes or so but see the black exhaust for at least half an hour or so. Another thing was I saw a DC-3 painted with orange stripes or tips and Dad told me it was the FAA doing checks on the O'Hare landing radios. I did have a DC-3 right in front of me at Palwaukee, coming right at me but then turned and scared me to death. I was about 5. After that, I end up getting a license in a 152, and was in aviation for 45 years until retirement. Love you channels!
This video is probably more in-depth than the official iPad conversion training. Very good work Mentour
Thanks!
Just to add to the points made: the mcas worked by moving the trim leadscrew in the horizontal stabilizer. This system would be way to slow to actually correct any aerodynamic instability.
I would love to see you make a video on the History of pilot training. Who was the first pilot that the wright brothers trained? How did they train early pilots? When was the first flight simulator used? What was it like? How has pilot training evolved?
Sure someone else might be able to read the Wikipedia article on it but you have the insider insight into this specific topic that I think would be extremely interesting to have that viewpoint.
MCAS and Trim runaway are delt with in the same way. I got an MCAS situation on my Checkride and delt with it. Got out of it and walked away with mt Type Rating back in early 2019.
Mentour Pilot's students must be the luckiest to have such an instructor. They get to learn History, Engineering and Navigation all at the same time. There's never a boring class when he's the tutor.
Right!? I often think about this whenever I watch one of his videos.
He's not an instructor. He's a check pilot.
@@SpicyTexan64 HE IS AN INSTRUCTOR HE RUNS THE SIMS
I have flown most 737 models except the 200 and the MAX and have thousands and thousands of hours on the type. For the last 15 years I have been flying the Airbus A320 series and the NEO.
From being an absolute Boeing fan, after changing to the Airbus, as I see it, the 737 is a totally outdated product, and should’ve been scrapped years ago. (Sorry Petter). In my opinion, the A321 NEO is the best plane you can buy in the narrow buddy segment. Flying with 240 passengers, it burns less fuel than an old A319 with 156 passengers, on the same route. So quiet and so powerful. What a machine.
Petter, work on one of these for a while and you would never want put your feet in a Boeing again, I promise, from experience. 😊
Wouldn’t the E195 E2 or A220 be more modern designs?
Probably. But they are much smaller and can only compete with the A319 NEO . The A220 if for sure better, the E2 is again an old plain with new engines and wings, and I think is less appealing in this market segment.
In the gravel age, the 1980s, I commuted to my job flying Twin Otter and DC-3 in Resolute Bay, NWT, Canada from Toronto. My ride in and out on our rotation was a "Jurassic" 737. I always felt it was awesome of Boeing to produce a gravel kit for the 737-200. It would have been a drag to do the Iqaluit-Resolute leg in a 748. For that reason alone I've always had a fondness for that airplane. I want you to know I feel this is one of the best aviation videos I've seen. I like it so much that I'm going to your Patreon.
I remember that I read that tendency of the aircraft to increase the input of desired maneuver without increasing control input is also called "instability". Instability in yaw, pitch, roll, etc. Now, there is no perfect airframe and those instabilities exist almost in any airplane, and such non-linear characteristic are carefully implemented in flight controls, speeds placarded, pilot trained for such regimes etc. This way or another, those are dealt with in almost any airplane.
The problem of MCAS was that discovered "instability" (because by the upper definition, it is THE instability), one that was acceptable by itself IF pilots got warned and trained, got to get "smoothed out" to approximate previous behaviour by totally inappropriate methods from the standpoint of safety and relability.
Max is not unstable. You let go of the controls while it is still pre stall, and the plane will return to level flight. The force on the stick always remains positive. It just fails to increase linearly as required by regulation.
The bottom line is because the MAX hasn't got a FBW system, there needs to be this supplementary MCAS system. Airbus' have FBW and also has this over rotation/ stall prevention but the key thing is that it's built into the control laws and isn't some add on. The other thing is that all the AoA sensors are working all the time...
I'd say a clean design is long overdue ;) and I always understood what MCAS was designed for. The 737 Max would have been a safe aircraft to fly on even if MCAS was never installed. But the system was designed to prevent the requirement of simulator training for pilots, which was also the reason why it also was using the input of a single AOA sensor because to be dependable, it requires all AOA sensors which would have made it a safety critical system which would have brought back the simulator training even though Boeing was selling the aircraft to airlines with the promise of not needing sim training. At the end of the day, the problem with the entire thing is that Boeing sold an aircraft with a promise that it couldn't keep.
What many people also don't know is that the 737 Max was not the first aircraft to get an MCAS system. A variation has been used on the KC-46 refueling aircraft as the balance of the aircraft shifts during refueling. While the system is also called MCAS, it does serve a different, but similar function.
As much as people would like to, and have, dump this on Boeing I see a systemic problem that caused all these issues to line up and crash not one but 2 airplanes.
Is a system that favors less simulator time is broken.
If the difference is so minor pilots can turn off MCAS, did a 737 MAX w/o it need a unique type certificate?
This needs to be looked at from the top level.
You actually think that Boeing would have LESS problems with a clean sheet design than one that is almost 20+ years old and had stellar safety record up to the redesign? I would argue their problems would increase by 10 fold or more with more design changes. The engineers that work on the redesign are not the same as the ones who did the previous generations. I think your assessment is completely flawed. What it might have done with a total redesign is to force the FAA to pay more attention to the entire design than with the update from the 737NG generation. Boeing flagged the fly by wire spoiler update and the landing gear reinforcement as a high risk change and that was where the FAA spent most of their focus on.
There is an old saying in engineering. The issues that you spent the most time on due being assessed as a high risk are usually not the ones end up biting you in the rear. Its the "low risk" items which fell through the cracks. A lot of bad assumptions were made to determine it to be low risk and that's what bites you in the end. It always has and always will be.
Nobody ever blames the irresponsible airlines like Southwest that hammered and hammered and hammered on Boeing to avoid requiring the flight simulator time until Boeing relented. There's plenty of blame to go around.
@@matthewhall5571 "The customer is always right."
@@ahndeux finally some common sense here in the comments! Frankly nothing scares me more than the phrase "All new!" ... I'd rather prefer a refinement of the previous version. Boeing know knows the weakness of the 737 airframe due to its history, hopefully it has address the issues with each version/iteration.
I flew on one yesterday, it was really nice flight but neos are just more comfortable
I've never flown on either the MAX or NEO but the NG and CEO I've never noticed much of a difference.
I am of the belief that the 737 MAX should have its own type rating. When a plane doesn’t behave like its predecessors, it needs to be treated a new design entirely with pilots specifically trained for it, not using a system as a crutch for poor design. It may not be “unstable” if we really want to split hairs here, but it behaves differently in the most critical stages of flight: Takeoff and Landing.
In a perfect world that's exactly what would happen, but the 737 Max was designed specifically for airlines who wanted to effortlessly transition their pilots from the older NG models to a newer, more fuel efficient plane. Creating a new type rating was unacceptable for low carrier airlines whose entire fleet consisted only of 737s, as well as other airlines who weren't interested in adding a new type to their existing fleet. Basically they wanted the same plane with lower costs, which is technically impossible due to the low profile of the 737. MCAS was basically a compromise allowing the FAA to certify the Max as a 737 despite the engines causing it to handle differently from a traditional 737.
@@jb8331Yeah, Boeing wanted to skip 10 or more years of making, testing and certifying a new aeroplane. The cost would be gigantic. Human lives one the other hand, are expendable 🤔
Well it doesn’t fly very differently, actially i hardly notice any difference when flying the MAX, compared to the NG, i also fly.
@@ACPilot I feel like that's literally the whole point of MCAS. But we shouldn't be relying on crutches for poor design choices.
@@ChrisSnowFox It is not a cruch. Other aircraft have something similar, just called something else, or embedet in another system.
Just flew in one of the 737 Max8's and really loved how the engines just barely clear the ground if the plane has any lateral rocking when landing.
A part in this video reminded me of a flight when I was a kid. Then that reminded me of another part of that flight or another flight. I remember seeing the bucket reversers, as you just called them, deploy on landing and I thought the plane was falling apart. On a flight from DTW to San Diego when I was somewhere around 5 years old I think, I was afraid to use the toilet because I thought it was going to suck me out of the plane.
Since then, I have been on many flights, including a single engine 4 seater prop plane around 3rd grade and one commercial flight in a puddle jumper flight. It was a VERY loud twin engine prop plane that I think were turbo props. I couldn't even stand up in it and they told us where to sit for weight distribution.
Another commercial flight was in a more modern twin engine turbo prop that I could stand up in. It had just one seat on either side of the aisle and a curtain to the cockpit that was left open for the night flight. That was cool seeing into and through the cockpit while flying. And one memorable flight was Alaskan. It was a flight from California to Oregon and it had a capacity of around 50-100. It had top mounted wings and there was only 4 passengers on board. We got to drink for free. I remember getting a Craft Beer that was an Alaskan Brewery. I still have that can, empty of course.
But with all the problems Boeing is having now and the whistle-blower taking his own life, allegedly, during his deposition, I will NEVER fly on a Boeing ever again. I just can't trust them anymore.
Thorough as usual Mentour. I flew all versions of the 737 from the 200 thru the 800. With each new variant, Boeing increased the size of the horizontal tail surface. The result was a jet that was fun to fly. After the McDonnell Douglas merger, Boeing broke with tradition. No longer were engineering decisions made be engineers. The Bean Counters had taken over. They thought the flight characteristics could be "smoothed out" with software and refused to mod the tail. Yes, the MAX can be flown without MCAS, but MCAS caused the two accidents.
As I recall, the only engineer on the Boeing Board of Directors was the CEO. If it can be flown "safely" without MCAS, it should have been taken out or better yet not installed in the first place. Concerns about wanting to avoid pilot type-training sounds exactly like something a bean counter would come up with. All this reminds me of the Challenger Space Shuttle disaster.
@@Tom-tk3du Silly.
Obviously, the MAX had a longitudinal stability problem in some parts of the flight envelope. Yes, increasing the tail size is the logical solution. A trim workaround like MCAS as a concept is a questionable solution. As originally Implemented with a single point failure mode, it violates the most fundamental principle of transport category aircraft design, which you would think any Boeing engineer should know very well.
@@nathanaligizakis760 It looked to me to be a hurried last minute modification where corners were cut in terms of safety analysis and engineering supervision. According to FAA regs, yoke pullback force has to continuously increase up to the point of stall. Should be easy to verify with MCAS deactivated. I’d imagine it might also be detectable with the wind tunnel model.
@@Tom-tk3du And in fact the original issue of not meeting the regulation you allude to was in fact found in wind tunnel tests.
As a programmer, it baffles me that they didn't do simple saturation arithmetic to control the inputs. If the needed adjustment was very slight as said, it should've been capped, in order to not force the aircraft down even if the algorithm gets completely haywire.
they did and estimated a very low probability of catastrophic failure.
@mentournow Your thorough approach is appreciated (with so much other information by other sources about Max/MCAS being wrong). You’re correct that the airplane is NOT unstable. In pitch there’s 4 types of stability…2 static and 2 dynamic. Big airplanes don’t typically have any issues with dynamic stability (short and long period) and the 737 is no exception. The two types of STATIC stability are speed stability (typically expressed as pilot pitch force vs speed) and maneuvering stability (typically expressed as pilot pitch force vs g) . Your video talks a lot about speed stability and kinda mixes it up with maneuvering stability. But you’re close enough for most non-aero engineering viewers. You mix the “see-saw” (which is speed stab) with Fs/g (man stab) and then you throw in stall characteristics (which is a totally different topic). Anyway, you’re close. Fs/g was predicted (from wind tunnel studies prior to the max ever flying) to not clearly meeting regulatory requirements (worst case aft cg) and this resulted in MCAS being implemented into the design (with fairly limited authority). Once the test airplanes started flying is when the stall identification characteristics (a wholly different regulation in part 25) were found to not clearly meet the regs and this is when MCAS was expanded to include the low speed (stall) region, and the authority was essentially multiplied by a factor of about 4. Add in the fact that a fail-safe feature incorporated in the prior generations of 737’s (column cutout) was bypassed for MCAS activations (necessiststed by the fact that MCAS works when the column is way aft) and the setup for disaster was sealed. The real miss (and it was missed not by anyone rushing, or being pressured or any of the other populist reasons offered by the media) was in evaluating the design against another regulation…25.1309(b) which concerns failure case analysis. In this case a failure which produced a single erroneous high angle of attack input into all the systems which use AOA information.
During certification, to stall an a/c, the pilot has to keep pulling on the yoke. This is mandatory. Otherwise a pilot might stall the thing inadvertantly. In the MAX (without MCAS) it became 'stick light' during the stall- so not acceptable. MCAS was the fix-trimming the a/c nose down, so the pilot still had to pull.
MCAS augmented the manoevering characteristics during the stall, thus the name.
Exactly
Pilots still have to pull. Even when MCAS activates, it’s a very subtle change in column force required. Coming from repeated, frequent experience.
"A little knowledge can be a dangerous thing." And lately, thanks be to internet - there are a ton of people running around repeating false/misunderstandings base on "a little knowledge." Thanks for seeking to counteract some of this with Quality Information, Mentour Now!
I just love the 737s.
I hope this aircraft will stay with us for decades to come.
I'd just wanted to see those "eyebrows "windows back.
When 737 MAX returned to service after being grounded for two years, its stab trim cutoff switches were not rewired to the NG configuration. As a consequence, in case of runaway trim, it is not possible to turn autopilot/STS/MCAS off and still use servos controlled with the buttons on the control wheel. It is much harder to recover the MAX compared to the NG if runaway trim happens.
The NG also fully disables the trim servos with the switches.
The solution is to turn the cutout switched back to normal and yhr use the trim control. One of the 737 MAX incident pilots did that, but failed to set them back to cut out, resulting in the crash.
@@roflchopter11 No, and you would know it if you looked at the switches instead of recalling the runaway trim checklist, which instructs to turn both switches off. But on the NG the switches are different: one turns off autopilot/STS, another turns off electric trim servos. On the MAX both switches do the same thing and each of them turns off everything.
That is why Ethiopian crash happened, right? Contrary to Lion Air pilots, they knew about MCAS, but still they could not recover the aircraft.
@@user-yt198 Yes, they could not recover, because the moment they turned electric trim back, MCAS would work against them, fast and relentless. And when they turned the switches off, they could not re-trim it manually, the other pilot pulling up did not help, but if he did not pull up, they would not have the altitude anyway to complete the "rollercoaster" maneuver, if they knew about it at all, because it was removed from the NG and MAX FCOM.
@@TinLeadHammerno, because the captain failed to retard thrust after he followed the procedure, leading to a rapid and extreme over speed, and therefore the inability to manually change the stab trim. Poor airmanship caused that crash.
If it’s a Boeing I ain’t going.
Good luck with that.
@@adamhurst9491 It’s going fine, Boeing can bugger off.
@@escapetheratracenow9883 ?? Why are people so hell bent on defending a private corporation that has demonstrated again and again that they only care about money? Safety is important in any industry but Boeing builds commercial airliners and doesnt seem to have any culture of safety or responsibility.
So you would't fly on a 747,757,767,777 or 787? They're Boeings as well.
@@thewaywardwind548 Thanks for the scoop.
Boeing is a shadow of its former self, and its behavior regarding the Max is unacceptable and outrageous.
Until their maintenance procedures are properly tightened up, their quality control standards improved, no I won't.
As a retired aeronautical engineer and airline pilot I found this video to be an excellent explanation for the average person. Great job
All current MAX aircraft have an ongoing and known issue with the engine anti-ice system! Left on too long in excess of five minutes the engine could fail and blow apart. The FAA has now required to redesign of the systems on the MAX 7 and 10 aircraft. Clearly, this says the FAA does not think the aircraft that are currently flying are safe however, they continue to allow them to fly. It’s only a matter of time before there is a major and accident involving them. The MAX needs to be grounded until they can redesign and fix all of these aircraft!
I still remember the explosive decompression of Aloha Airlines flight 243 in the late 80s
Oh yes.. I have a video about that, over on Mentour Pilot
Ah yes, the one time production in flight of the 737 Cabriolet!
yea but that was an old plane, and was already breaking IIRC.
30 year old plane, metal fatigue. Today have better technology to inspect metal fatigue not only on fuselage but engine fan blades .
exactly, and if i recall it was at its limits for pressureizations too, since it was a very common flight done a few times a day.@@alexrebmann1253
5:11 Similar to the Comet, Tupolev produced the TU-104, based on the TU-16 bomber with the engines incorporated into the wing. And after the Comets grounding was not just the only commercial jet powered airliner in service, but also the first to complete a trans Altantic flight.
I never was under the impression that MCAS was needed because otherwise it would've been 'dangerous'. Nor have I heard anyone say that, but that's just me.
I heard basically the same thing you point out, that because of the positioning of the new engines, the characteristics of the plane had changed. But I'm inclined to agree with those who say this is not ideal.
I heard this all the time.
Just a couple of weeks ago on a hugely popular "Last Week Tonight" show dedicated to Boeing problems they had some sort of engineer expert very confidently explaining exactly that. That 737Max needed MCAS, because after changing the engines from previous 737 models it basically became an unstable design and MCAS was introduced to fix that. I immediately noticed it and facepalmed myself, because I already knew it was complete rubbish that's very far from the truth. The truth is MCAS was never a necessity from standpoint of flying characteristics, it was a workaround to make it seem like it has the same characteristics (or behave very similar) as the previous models for other reasons that had very little to do with physics or aerodynamics and more to do with business and bottom line.
@@kosmosyche Exactly this bullshit has been published all around the world.
One thing I've never heard in any video is what the pilots think about the actual differences between the NG an MAX, the differences MCAS was supposed to eliminate.
It really feels like Boeing was more concerned with satisfying the bureaucrats than the actual pilots.
If the pilots are/were unaffected by the difference, then it's the FAA that's responsible for the crashes.
The pilots _are_ affected by the difference. It's not a big effect at all, but it's enough that it would have required simulator training for pilots moving from the NG to the MAX, and avoiding _that_ was the entire reason for the MCAS, and the deaths of several hundred passengers.
Remember, Boeing was allowed to use its own employees for FAA certification. Government agencies have been purposefully downsized to allow more latitude to private companies to ‘meet’ regulations. In my mind, this a clear systemic prejudice to eliminate or capture government oversight to the advantage of the firm, and not to the consumer. The old saw ‘we don’t need regulation as consumers wouldn’t stand for bad products’ is useless of there are only two producers of the item in question. However, this ‘efficiency’ has come home to roost for Boeing as airlines (especially foreign ones) are rethinking Boeing and going to Airbus and airline travelers can now eliminate Boeing models as part of their reservation searches. While some may see this a validation of the ‘less regulation’ mindset, the cost in lives, careers, and misallocation of capital has been higher than what keeping the old processes in place would have been.
@@Curt_Sampson Let me clarify, I've never heard a pilot describe _how much_ it affect their job and whether they consider it a meaningful difference, relative to all the other differences introduced through the 737's life span.
Either way, engineering for a regulatory requirement is a problem hence the FAA is still responsible for the crashes. Meaning, without the FAA defining 'maneuvering characteristics', the airlines and pilots would have final say.
@@philiparonson8315 The problem is 'meets regulatory requirements' is a shield against liability, real or perceived. This is very convenient for the companies because it makes the Gov responsible and because the Gov is responsible, there is literally no responsibility because you can't sue the Government.
Like how the airlines are unconcerned about the ineffectiveness of the TSA because when something happens, DHS will simply declare their 'procedures were followed' and too bad, so sad.
@@rapunzel1701 I believe that Petter is wrong when he says that MCAS was necessary to meet regulatory requirements about maneuvering characteristics. (It was instead implemented to _avoid_ a requirement for some relatively minor simulator retraining, though the FAA should not have let that through.) I discuss this in more detail in another comment thread on this video that starts with a comment from me.
Geat video, correctly explaining the story without taking sides
Moe to the point about MCAS, it was put into the MAX to make the aircraft fly as if were a standard 737 to eliminate any requirement for pilots be retrained and recertified as if it were a different aircraft. Boeing did this to make the aircraft more marketable to the airlines And they didn't bother to disclose that to the airlines and their pilots.
And who in their right mind would design a system that could fail from ONE malfunctioning sensor, the AOA sensor?
Military aircraft the Boeing makes have flight control computers that use multiple sensor inputs to mitigate against this precise scenario.
To answer your question, someone whose bonus depended on the cost of the aircraft.
Absolutely.
That is wrong. Boeing's internal discussions state that the reason for the change to MCAS design was flight test findings which would have been uncertifiable otherwise, albeit not necessarily dangerous. The Canadian regulators have stated after the fact that Boeing could have pursued an equivalent safety finding as the issue was so benign. Simulator training was NEVER a reason for implementing MCAS. The only discussion about simulator training were centered on the RCAS and RSAT features.
I have followed you for some time now and have watched nearly all of your videos regarding the 737 and still I learned a few things from this video that were new to me. Thank you so much for continuing to produce high quality and informative content!!!
Great to hear, thank you!
I was always under the impression that MCAS was there to readjust the C.G. which was impaired by moving the new engines forward and upward. I also did not realise they had lengthened the nose wheel leg. Thank you for explaining, so I even I, just an enthusiast understands. Really great content as usual. Stay safe. All the best. Mick🇬🇧
The main selling point of MCAS was that pilots would not need to be re-trained, correct?
Yes, retire them because consumer confidence is on a downward spiral on the plane and is affecting the company too. Consider the Hindenburg. One horrible crash pretty much stopped LTA transport for a hundred years. Now even though airships are made that can not go up in a ball of flame, the collective memory has deemed them unsafe, so the industry remains sidelined.
Perception is everything.
I am very glad you pointed out the differences in the engines that Airbus and Boeing put under their wings. The plane you fly (and I live directly under the approachroute to Schiphol runway 06) is one of the noisiest, the 737-8. The newer models are already quieter, but the difference in noiselevel is remarkable. The lowpitched noise that the engines on the 737-8 or 737-9 make is thunderous. Where as the newer engines are highpitched and less noisy, mostly on Airbus neo-planes. I love the RR Trent engines, with their high bypass high pitched sound. Especially on the 350 and the 380.
Thanks for your thorough analysis. I flew the 737-200 amongst other types. So far, my preferred aeroplane from a handling characteristics point of view. A real pilot aircraft!
You are wrong about the reasons for the engine placement. A wing in flight creates two forces - lift and drag. But it also creates a torque or twist. By placing the engines forward of the leading edge, they act as counterweights to the aerodynamic torque on the wing, allowing for a lighter structure. Boeing did this first on the B-47. It's a very clever thing to do, using the weight of the engines for something positive. Airbus copied it.
The engine placement of the 'Jurassic' 737 is simply a matter of the engine being longer than the wing chord. They couldn't put it anywhere else. Also, placing the engine forward without a pylon would lead to heat issues on the wing - you don't want anything touching that hot exhaust. So the 737 wing was designed to handle the aerodynamic torque by itself, without counterweights. The plane is small and the weight penalty was probably not much. Fuel was cheap back then.
The reason for the engine placement on the newer 737s is that the entire design is a kludge. By lining up the top of the cowling with the wing and squashing the lower part, they barely got the fan to fit, almost scraping on the runway. The only way to do this is to move the engine forward. Together with the shortness of modern fanjets, this places almost the entire engine forward of the wing, but not for the reason it was originally done. Boeing may have been able to lighten the wing structure a bit, I don't know.
The alternative would have been to lengthen the undercarriage, but on the 737, that would amount to a complete redesign, might as start over clean. Incidentally, Boeing had an aircraft just like this, the wonderful 757, but the bean-counters killed it. Boeing is now reaping the rewards of decades of short-sighted accounting decisions. I wouldn't worry about them though, the military division can carry the wayward airliner group for a long time. Boeing didn't buy McD for their airliners.
Every time I look at a 'fat-engine' 737 plowing down a runway, I wince. FOD must be a major problem that gets swept under the rug. How Boeing got away with such a mess is beyond me. They obviously have the FAA and NTSB in their pocket.
As for the old thrust reversers being pointed at the fuselage, I can't imagine a good reason.
I may have mis-remembered the part about the torque on the wing, or 'aerodynamic pitch moment'. It's been a long time. The discussions I find online only talk about straight wings, not swept. There are other reasons to hang the engines out front, the most important being to get clean undisturbed airflow, but also for flutter. And mounting the engines directly on the wings results in an overall lighter airframe. This gets pretty technical:
agodemar.github.io/FlightMechanics4Pilots/mypages/pitching-moment/
At any rate, Boeing had good reasons for mounting the engines the way they did, even if my old brain is addled by covid. Engines are typically mounted below the wing for maintenance reasons. It was easier for ground crews, although modern engines are so huge that it is much less help today. The HondaJet mounts its tiny engines on pylons above the wing.
Where could I find materials to learn all of the 73’s wing stuff in the your comment, Sir? So fascinating
Absolutely no one on the internet gives us aircraft and commercial information as detailed, informative, understandable and fun than Mentour. Cannot thank you enough.
Well, how do you define unstable? Would you define the pitch up event that MCAS was supposed to eliminate as an instability?
If the 737-MAX had a fly by wire system (which it doesn't it only has FADEC which is just engine control)), the pitch up tendency at low speed high thrust setting could have been simply dialled out. But it still uses a 1960s mechanical direct link control system which needs a supplementary control device (MCAS) to prevent a pitch up under those conditions. Airbus also have a system which prevents over-rotation/pitch up situations. But the key thing is its fully integrated into the electronic FBW system. Not only that, but the Airbus' always run two AoA sensors at the same time, and if there is a disagreement between them, the system disconnects automatically. It's just a smarter plane, not a Frankenstein 1967 design.
Continue to love your work!! An interesting tidbit of information for you: The very first jet aircraft in the world (while definitely NOT a commercial airliner) the Messchershmidt ME-262 fighter/interceptor had its engines mounted directly underneath the wings without pylons. They extended both fore and aft of the wings. Hope this helps! Looking forward to your next instalment. Cheers from Canada!
I can't believe I am hearing the conclusions I am hearing from the Mentor Pilot 😮 The positions of the engines on NG were already enough of a problem during go-arounds (not some abstract "high angle of attack" scenarios mentioned in the video) as, depending on the configuration, the pitch up tendency was sometimes very difficult to handle, and this is part of the reason why pilots on 737 hate go-arounds, btw. And this is precisely the reason for the introduction of MCAS, as Boeing was sure that the number of incidents during go-arounds related to this issues will only increase with more powerful engines. As for choosing to rely on what the name of the system says -"augmentation" -rather than what it actually does - move the stabilizers - as Mentor Pilot does - well, this is reliance is exactly what killed those pilots on the two fatal flights. To repeat this now once we know all the facts is something unbelievable!
Yeah, I'm horrified by the campaign to downplay the serious issues.
The wind tunnel tests in the very beginning told them this thing was going to be a handful at high angles of attack-- and the more you pitch up? The more Center of Life moves forward. It is a terrible trait.
I am surprised that Boeing did not place the engines above the wing like the Hondajet designers did. That would most certainly negate the pitch up problem (Bugs Bunny ‘he,he,he,he, laugh).
I'm going with the 737 Captain/Training Check Pilot in this one.
@@ryanlittleton5615
The "experts" who have never actually taken any aerospace engineering coursework? The "expert pilots" who were so quick to blame "bad foreign pilot training" after Lion Air and ET?
Sure. Being able to run the controls doesn't mean you understand control system theory.
The definition of "aerodynamic instability" is well understood. Dynamically moving forward of the Center of Lift, during pitch maneuvers?
Is textbook.
@@atlascruiser1456 I believe the dude that not only flies the 737 but is also qualified to teach the 737 and is rated to teach the 737. BTW the "bad pilots" theory was pushed by Boeing. I've followed this since it happened.
It's not that it made it unstable, it is that it made it a *different* aircraft with a different type rating. The problem is, they tried to hide that fact so that aircrews did not need to get a different type rating.
And a different type rating meant higher training costs for thousands of 737 pilots across the globe. And that made the Max more expensive and thus less competitive. And THAT is why the bean counters ignored safety concerns raised by engineers.
This is a great technical analysis and debunking of the 'instability' myth, but there is much more to the wider story than 'making regulators happy'
The need to hide is where one should start when looking at this problem.
@@daftvader4218 of course it isn't. It has some non optimal flight characteristics, but is absolutely not in any way, unstable.
Keep doing what you do, you should actually be a consultant to the airlines and manufacturers. Everything you mention is super solid and you have a dream team as well as a tone of other pilot paying attention. Perhaps they should buy a mug and listen up.
5:28
The Me-262. Granted… not exactly a commercial jet.
I don’t agree with your conclusion. You have no explanation supporting your affirmation that the pitch up effect is only minimal and unimportant. The problem is not about weight distribution affecting the stability which is relatively constant in a small time frame, but it’s all about the change of pitching force during a pitch up manoeuvre at slower speed (higher angle of attack) and how it becomes out of trim in this situation. The 737 NG is already difficult after a go around. The pilots have to push the yoke forward after the initial pull up with a strong tendency to pitch up by itself due to increased thrust located lower from the CG and some pitch up effect due to “lift” of the engine nacelles at higher angle of attack as explained in your video, and raising the flap up one notch. 3 pitch up forces happening simultaneously and suddenly. And that’s the problem with the MAX if one of those pitch up force is also increasing. It’s cumulative. The pilots then was trimming the nose down to level of. If the pilots was “flying the trim” to level off, they were sometimes over trimming down and producing a loss of control and subsequently a crash (CFIT) immediately after the go around. The fact that the max have bigger and more forward engines increased the change in pitch up forces after a go around. The pilots have to push down with more forces after a go around, increasing the risk of pilot over trimming down. Boeing had to increase the efficiency of the MCAS (and hiding it to the FAA) during the conception the MAX for a reason. The reason is probably that a stronger MCAS WAS actually NEEDED due to the pitch effect being a bigger problem than expected. I don’t buy the idea that the MCAS was only to make if feels more like the previous versions of 737. It was to fix a pitch up effect problem that was getting too problematic. Reducing the effectiveness of the MCAS (after the 2 crashes) is only a compromise between two problems. It’s helping to fix one issue by making an other one worse.
First, Petter flies the 737 MAX8, and does know a thing or two about how it handles. It handles just fine. MCAS is a Stability Augmentation System, designed to deal with a stick-force issue during aggressive maneuvering, which would have prevented the airplane’s certification under FAR Part 25. It basically senses when the airplane is being maneuvered aggressively and uses the airplane’s electric stabilizer trim to dial in some nose-down trim to artificially make the stick feel heavier to the pilot, when the airplane would not naturally exhibit the correct characteristics. You may want to read the documents that FAA released when the airplane was recertified. There is a lot of detail in those documents that explains everything and puts to bed a lot of the BS that was promulgated in the mainstream press.
@@kevinmadore1794 you comment is empty. It’s does not bring anything else than what we already know.
Your videos have really helped with my previous fear of flying.
I am no longer gripping the seats like a madman with sweat pumping from my cold forehead
if u used to be scared of flying then your should be having a heart attack in a car lol
there wasn't a single passenger plane crash in 2023, but there is over 5,000 car crashes a day in the country that i live in.
the chance ur flight crashes is essentially impossible
With Boing's management now fully in the hands of the bean counters, spending huge sums of money of money to develop a new more modern plane will be a hard pill to swallow. There needs to be a change in management philosophy back to the day when Boeing was primarily an engineering first company not stock prices first. Current events dramatically show how short sighted that management style is. I hope they retrench, rebuild their reputation not fade away!
Great video (as always) ! I think that you didn't go too much in details about the MCAS system , to keep more insights for the video of the 2 crashes related to this system.
You didn't mention the origin (or genesis) of this system. I read that the MCAS came from some engineers working in Boeing Military Division and suggesting this system to their colleagues working in the Civil division of Boeing.
In the 70" it seems that Boeing developed this system to ease the job of the military pilots flying Boeing refuelling tankers. The system was designed to adjust dynamically and "transparently" the center of gravity of the tanker to keep it steady at the same point during the all duration of the mission, when meanwhile the tanks were getting more and more empty by keeping feeding the "clients" just below behind.
Actually you can see how they made the mistake with MCAS in the first place from the name.
Because it’s an “Augmentation” system intended to supplement the feel of handling the aircraft. Someone most likely listed MCAS incorrectly as “non critical” or “non-safety related” system that does not required to have backup or redundancy built in. Hence, its ended up only using a single angle of attack sensor.
If MCAS was listed as critical or safety related, it would definitely use more than just a single sensor for redundancy.
Of course this is not 100% certain but i think this is the most plausible how they ended up with only a single sensor for MCAS.
The name “Augmentation” might’ve trigger the chain of events leading to the disasters.
Me-262 has a somewhat similar engine placement as the 100 and 200 series of the 737.
Yes! We thought of that afterwards, but that’s a fighter and not an airliner to be fair.
Did a northbound t/o at MCO. Used TO2, but wanted normal climb, not reduced climb due to Orlando Exec. There was a definite increase in pitch moment due to the increased thrust.
Cheap poorly thought out solutions are rarely a solution but problems that can cause more detriment. my uncle worked for Boing and told me that after the merger with mcdonnell douglas quality went into the toilet and became more focused on cheaper everything including labor of all sorts. me personally if I had to fly I would only use a European made air bus whos company focuses on quality to a noticeable degree does not overlook possible flaws in the pursuit of profit.
Mentour is my goto curiosity stream for aviation. Thank you, Mentour!
5:10 What about the Dassault Mercure 100? Very similar concept regarding engine placement.
Fwiw, Aviation Week did a test flight years ago, and identified the tendency for the nose-up. But the pilots said it was easily corrected using pitch, and otherwise stable and easily handled. It was the MCAS software that gave it a black eye, especially without telling the pilots.
no crashes were caused by nose-up. crashes were caused by MCAS pushing the nose down when it thought it was up but it actually wasn't.
You make a good point that there is nothing wrong with the basic aircraft design.
Problem is, that cannot be said of MCAS design . Boeing put a system in that had the ability of rendering the aircraft unflyable
if it received faulty data, with no cross check or redundency, an ammazingly bad design decision, based on money and sales.
THAT should never happen, any system that can crash an aircraft, unless the pilots act promptly, should be as safe as technically
possible. If you need to reference the QRH, if it involves flight controls, you're running out of time.
They can't be trusted that they won't do it again
Normally flying plane shouldn't have MCAS
@@henson2k Did you even watch the video? The plane flies normally, maybe even more "normal" than the old one, But it was DIFFERENT and they didn't want to train people so they made it behave like the old model. Which was clearly a mistake.
@@rasta77-x7o the plane is already normal, but they added MCAS for no good reason and it backfired. It's safer to just remove unnecessary component and retrain the pilot for every new airplane.
The poorly trained pilots crashed the aircraft after a minor sensor failure
Thanks for a very informative video, I have rather a mundane question? At 21:21 what is the ball on a string stretched out behind the aircraft from the top of the tail?
Till the door plug incident, I quite believed that 737Max series 7/8/9/10 were quite a good aircraft. My gripe is, that they shouldn't have been the same type rated at 737NG or previous 737s.
Airlines should not be put in the position where they can make more money by not training pilots. The system is broken.
Using the plug incident to change your opinion regarding the 737 MAX is wrong. The plane was not designed to operate w/o these bolts. It is fair to say you don't trust Boeing to assemble airplanes.
You're are falling for Boeing propaganda...they are a very dangerous company it's a ticking clock till the next disaster in my opinion
Incompetence is the door issue, someone didn't put in bolts, there is nothing unsafe about the aircraft structure if it's put together properly.
They are still good aircraft. But it is similar to finding a good product at Ikea -- it will only be as good as the person assembling it. Boeing has serious issues in this regard.
@@rasta77-x7o - MCAS was a design flaw, missing bolts an assembly failure.
"If it's Boeing, I'm not going."
How does that work? Do you always get refundable tickets? Do you buy flight tickets only if you see the type of airliner and know it isn't a Boeing?
Why? Would you refuse to fly in a 747, 757, 767, 777 or 787 because they're Boeing airplanes? Remember YOU said: "If it's Boeing, I'm not going." You might have noticed -- or, come to think of it, perhaps you don't care -- that there are many hundreds 737 MAX airplanes flying passengers on many thousands of flights every day and these airplanes get their passengers to their destinations safely and generally on time. They make money for their owners and do so while saving fuel compared to older airplanes. Yeah, I noticed that there were two crashes of MAX airplanes but I also noticed that airlines based here in the US with crews trained here in the US didn't lose ANY. I believe that the European version of the American FAA was coerced by Airbus to ground the 737 MAX in Europe to give the A-320 a competitive advantage and the FAA followed by grounding the MAX airplanes in America because they were afraid to be seen as allowing what some people considered an unsafe airplane to fly. I wonder how many A-320's Airbus sold while the 737 MAX was grounded.
@@thewaywardwind548 you think the FAA should have kept the defective 737 Max flying in United States while the rest of the world grounded it? Do you honestly think not appearing biased was the only reason the FAA should have grounded them? You know they were defective, right? Boeing designed a defective and dangerous MCAS system and tried to hide the risks associated with it. We know this now. The investigations of the 2 737 Max crashes did not conclude with "pilot error". Are you saying they should have kept flying the 737 Max even while the MCAS was defective and pilots were still not trained properly on how quickly they need to shut the piece of crap off when MCAS starts diving the jet into the ground?
Unless you are on the ISS, then you are not coming back.
I’ve been on them all plus the 727. I still can’t fly in a 737max. But that’s me.
In your March 15, 2019 video titled, "Boeing 737 Stall Escape manoeuvre, why MAX needs MCAS!!," you explained the necessity for MCAS in terms of an obviously safety-critical function of assisting the MAX in getting out of a stall - apparently in contrast to your present video wherein you explain that the MAX would be safe without MCAS. In any case, as you may know, the Boeing 737 MAX Flight Control System Joint Authorities Technical Review (JATR) rendered its final submittal to the FAA on October 11, 2019. Do you (or does anyone) know whether the FAA has implemented any or all of the JATR recommendations in respect of the Boeing 737 MAX, and in particular Recommendation R3.5 which states: “The FAA should review 14 CFR 25.201 (Stall Demonstration) compliance for the B737 MAX and determine if the flight control augmentation functions provided by STS/MCAS/EFS constitute a stall identification system.”?
Another important reason engines are out on pylons is to control oscillatory wing flex behaviour of swept flexible wings, and its coupling to yaw induced roll. This was a Boeing innovation that was a key enabler for flexible swept wings, and all modern jet airliners. Their insight was that they could control the period and amplitude of wing flex by placing a large mass on an arm extending out from the wing. Which is of course the engine on a pylon. The visible slight nodding behaviour of engines in flight is the visible confirmation of the desired result. Wings still flex, but the flex doesn't couple well to forces on the swept wing geometry when the aircraft yaws, thus leading to a stable wing and aircraft. The engines on a 737 are so close to the wing root that it probably doesn't matter nearly so much, if at all. But on larger aircraft with long slender wings, this makes the design viable.
Rudder jam is latest.
We must accept that B737MAX is NOT a designed aircraft but a "retrofit."
The same can be said of any airplane with new engines, wings, and etc.
Is the rudder jam issue inherent to the 737 airframe design, or is it poor quality again?
Time and time again, issues with the max show to be quality or specific sub system design flaws, not flaws inherent to the overall design of the airframe. Boeing could have relatively easily made the MAX a safe, efficient, and prosperous family, and have simply failed in implementation.
In other words, a lot of these issues could have happened just as well with a clean sheet design, and these days, probably more issues.
poor maintenance. quit dogpiling on boeing
@@davidcole333 now that's nonsense. A plane in service for what, 6 months, doesn't rudder jam due to "poor maintenance".
Edit - ok fine, it has been in service for a year. I still doubt it's a "maintenance" issue.
This is not a problem of the B737Max specifically, other airlines have technical issues from time to time. I think the crashes with the B737Max in a short period of time, due to the lack of communication about the MCAS to the pilots, directed the focus to that specific type. So issue reports on the B737Max get more attention. But I think it is an indication of a deeper lying problem at Boeing, especially their quality management and the focus on the stock price at any cost of the upper management at Boeing.