The 777X is a program, covering two (or more) models: the 777-8 and 777-9. The one that flew yesterday was the first 777-9 -- a replacement for the 777-300ER, with significantly increased range, a stretched fuselage (it's slightly longer than the 747-8), and up to 426 seats. Increased use of lightweight materials and those whizzy folding winglets mean it's no heavier than its predecessor.
Maximum cargo capacity is roughly three-quarters that of a 747-8 by weight.
There's also a possible 777-10X model that will seat up to 450 passengers and is being pitched as a rival to the A-380 superjumbo.
The real miracle here is that the big four-engine jumbos are being replaced by a twin-jet. (This says something profound about advances in engine technology since 1970. Or even 1990.)
Yeah, Boeing gets (and rightfully deserves) a lot of flak these days but updating the 20-year-old 777 is very different from updating the 50-year-old 737.
More specifically, the 737 design had so little ground clearance that the bigger, more efficient engines used in the Max had to be mounted in a different position than before. This change resulted in different maneuvering characteristics that Boeing tried to patch with crappy software. The 777, on the other hand, is a much bigger plane with plenty of clearance and the new engines are only marginally larger than the old ones. I don't see Boeing messing with the engine positioning needlessly here, especially in the wake of the 737 Max fiasco.
Technology dramatically changes in 20 years. Would you be happy to drive around in a 20 year old car design? I for sure would feel a little uneasy about the rather basic airbags, and the lack of proper FEA modelling of the crumple zone.
Same applies for planes.
Now remember these planes will probably be produced for 30 years, and then maybe in service for a further 20 years. Will you be happy to know that safety critical design decisions were made to standards of 90 years ago?
I crashed a gen 2 Ford Explorer (first production year 1995) head on at about 35-40 MPH and wouldn't be scared to drive one around today. The other driver crossed the centerline directly in front of me and I crashed into the rear of their gen 2 Ford Explorer (so a medium-large vehicle striking a medium-large vehicle).
It didn't have airbags, I was wearing the seat belt, I had a slightly sore neck for a couple months (not like bothersome sore, I noticed it when doing higher impact things).
Which isn't to say I'm opposed to updated safety features, rather that 20 years ago wasn't that bad, even without air bags.
A head on crash is very different from an offset crash, which are supposedly much more common, and much more likely to cause injuries compared to a full head on crash where forces are (relatively) easier to be dissipated. When the IIHS started testing small-overlap crashes, many vehicles failed, receiving a score of "marginal" or "poor", including cars such as the c-class.
Later models of those cars were improved. But then a similar story happened when the IIHS started testing small overlap for passenger-side crashes, until again newer models were reinforced.
OT: I would also prefer a 20 yr old car design then a modern 'smart screens everywhere let the car drive for you because it is safer'. Cars were just finoshed back then, but in comes the age of 'Everything as a service'. Cars today are crap. Maybe in another 20 when they fix the batteries.
I drive a 23-year-old car design and have zero qualms about it.
Commercial aviation is one of the safest modes of transportation there is. That’s due to the safety procedures practiced by the operators, not faster FEA modeling. It’s far safer than even the latest cars, when driven by amateurs on public roads.
Is there some specific “safety critical design decision“ you think was lacking in the 777 era?
Newer cars are provably much safer compared to older models. They have both active safety systems, such as pre-collision braking, lane tracking, etc. as well as passive systems such as airbags and superior crumple zones. Not to mention they're much more efficient when it comes to fuel consumption.
I don't know what your financial situation is, but I recommend that you research the issue. You can buy a good, safe, and reliable second hand car from a manufacturer like Toyota, Honda, etc.
Just because it looks the same, does not mean that it's the same under the hood. Designs are constantly improved and re-worked for safety. Look up what happened when the IIHS introduced the small overlap test. Several manufacturers (including luxury brands like Mercedes-Benz) failed the test before re-enforcing the same design to make it pass. Not to mention active safety systems such as pre-collision braking and the like, which don't exist on older models.
I've a Defender, a '66 VW Beetle, a Fiat 500 and a Volvo XC40 with adaptive and predictive everything and I'll only take my kids out in the latter. Heritage vehicles have their place but they're harmful to the occupants and harmful to the other party in an accident. I wouldn't use one as a daily for that reason.
One interesting thing about the Beetle is that despite retaining the same basic shape and construction over the entire run a lot changed to significantly improve relative safety: collapsible steering columns, the change to Macpherson strut suspension, door handles with the opening mechanism shielded in a roll-over and so-on.
My 25 and 30 year old cars don't fall out of the sky if the engine stops working, and even if I do wreck I'm not looking at guaranteed death like that in a typical plane accident.
Good lord... I realize my plane is 64 years old now. I was able to solo with about 8 hours of training (a few takeoff and landings by my lonesome).
Most of getting licensed is learning how to deal with bad situations. Engine out, getting lost, that sort of thing. Every biennial flight review, at some point, the engine will 'fail'. The plane may or may not belong to the insurance company after in a real event but most engine out scenarios should be survivable. I can't think I've even seen an aircraft that is without 4 point shoulder straps.
Sure, I was being hyperbolic. But all of those are emergencies that require technical training and a cool head to evade - and not everyone is capable of flying a plane. Contrast that to a car where the worst that can happen is you roll to a stop. Hell, during near misses, you can panic brake and lock the steering wheel and that's it, your ride is safely over. No need to hit a runway with just enough glide left within a speed range with some special configuration of control surfaces.
Sounds like a cool plane though, clearly I appreciate old mechanical technology!
> I'm not looking at guaranteed death like that in a typical plane accident.
I don't have the numbers handy, but most plane accidents are survivable. In fact, there are many crashes where everyone survived (like the Gimli Glider).
> More specifically, the 737 design had so little ground clearance that the bigger, more efficient engines used in the Max had to be mounted in a different position than before.
And this issue was already stark on the NG, which had to use these weird flattened turbofan nacelles in order to get enough ground clearance despite its much larger engines:
Now this looks a lot like an A320 where the engine is also ahead of the wing[0] but notice how the engine "strut" goes downwards on the 320 but has to "wave up" on the 737NG.
"the NG, which had to use these weird flattened turbofan nacelles in order to get enough ground clearance"
I believe your picture actually shows the 737-300 (Classic), which had a very obvious flat-spot in it's nacelles. The NGs do also have a slight "flat spot", but it's much less obvious.
If the cultural problems at Boeing led to the issues with the 737 then perhaps they would also manifest themselves on this plane, just in some other part of the aircraft.
There is a similar example for the 777X though. The new folding wingtips to fit into the existing gate sizes seems like a potential new failure mode like moving the 737Max engines forward. No evidence it won’t work fine but it feels like a hack.
That’s closer to the type of iterative change one might expect from a new model of the same type. As long as they’re structurally sound, the folding wingtips present more of a maintenance risk than a safety risk.
Boeing was required to prove the load-bearing of the hinges on the wings and what types of alerts that the crews receive should a wingtip fail to lock prior to takeoff. More than one means must be available to alert the flight crew that the wingtips are not properly positioned and secured prior to takeoff. If the wingtip is not locked prior to takeoff, the plane is prevented from taking off.
They even required that the electric circuit that unlocks the wingtips be automatically isolated from the circuit that folds and locks the wingtips and that that circuit cannot be re-powered during flight.
Did they show simulations about what would happen if they fold during flight? Is it just rougher flight with less lift or would they severely impact the pilot's ability to steer the plane?
why don't Boeing leave wingtips vertical like on A350 or 737? A feet of vertical winglet replaces 3 feet of horizonal wingtip. So with 3 feet high winglets Boeing cold have just avoided the need for folding.
vertical winglets are ways to get more lift:drag out of a wing that's constrained by some width limit (airport gate spacing) or an existing wing design that you don't want to redo. they don't generate lift. for a clean sheet design you can do better with a "scimitar" wingtip that actually provides some lift and might weigh the same as a winglet. see 787. also the navy p8 which has the most efficient wing of any existing 737, and doesn't have vertical winglets (because it doesn't typically park at a gate they could go wider with these little triangular extensions)
Doesn't that make a plane less engine-fault tolerant? Completely noob here, but I would feel better if I flew in a 4-engine plane than 2-engine. In a 4-engine plane, even if 2 engines faults (like, bird strike), the other 2 will still make the plain airbone.
A bird strike (keep in mind birds fly in flocks) I'm guessing would either take out 1 engine (which is fine on a new 2 engine plane even during takeoff) so no benefit or take out all engines (or all engines on one side which again means just 1 engine on a 2 engine plane). A flock big enough to take out both engines on a 2 engine would be big enough I presume to take out all 4 on a 4 engine.
Four engines just means there's 4 things that can catastrophically fail and potentially damage the plane rather than 2.
You don't necessarily lose engines instantly to bird strikes, they're most likely to happen at takeoff and landing, and it hasn't been an issue for the massive fleet of twin-engine short-haul jets.
The real concern is trans-oceanic long-haul. Supposedly modern engine failure rates have improved to the point that you're less likely to have problematic engine failures than a four-engine 70s-era 747.
Which is shown by statistics. There are thousands of daily flights over Atlantic & Pacific. Engine failures over the ocean are incredibly rare (I couldn't find any recent ones). Most reasons why airliners choose to divert at this stage are medical issues nowadays. And for the plane to crash not one but both engines would have to fail.
> for the plane to crash not one but both engines would have to fail
I recently rode in a 2-person jet. The pilot said the only reason we might bail out is an engine fire. If the engine fails, the plane's an excellent glider, and we'll glide to an airport/airstrip. Now, this was somewhere with airports all over, not an ocean.
That really depends on the minimal number of engines needed for safe operation.
Say that you need 50% of the engines on the plane to be able to fly safely, then having more engines is actually safer. For example, supposing that engine failures occur 1% of the time, with four engines there are 3.97 three and four engine failures per million flights. For a two engine plane, there are 100 two engine failures per million flights.
There's correlation involved with other factors however. If I'm not mistaken, things like maintenance are relatively easier (and cheaper) on a 2 engine aircraft compared to a 4 engine aircraft. So we cannot consider failure rates as an abstract measure.
I agree, and it's also very unlikely that engine failures are independent, since they're the same model, coming from the same manufacturer, and the same maintenance procedures.
There's probably less drag from two engines than four as well.
Engine failure can be more than just quitting. It can catch fire and burn the wing, it can throw turbine blades around, it can shake itself violently. These can cause other damage to the airplane. It can even tear itself off, surge forward, fall back and hit the wing. These things have all happened. I remember a DC-10 that crashed losing everyone in it when one
engine came off and took out the flight controls with it. Then there's the Sioux City crash where the compressor disintegrated and took out all three hydraulic systems.
That's what I meant by "collateral damage".
Doubling the number of engines doubles that risk.
On the other hand, a failure that would take out both engines on a twin jet is likely to take out 4 engines. Failures such as running out of fuel, ingesting a flock of geese, and ingesting hail.
The associated concept in regulation is a certification (by plane model, e.g. for all Airbus A321) called ETOPS¹ (Extended Operations). The cert applies to twin engines and basically tells you that a plane can fly up to XXX minutes on 1 functional engine only (e.g. ETOPS = 60, then you have ETOPS 120, ETOPS 180 and currently ETOPS 240 is permitted on a case-by-base basis). Note that "ETOPS-180 and ETOPS-207 cover about 95% of the Earth" (how much you can reach while staying 180-207 minutes from an airport at normal altitude/speed).
The rational justification is not merely technical but rather empirical, proven by real-world data. Certifications usually because companies can demonstrate e.g. "N years of trouble-free XXX-minutes ETOPS experience". In other words, we've been doing it for this long and it works so there's statistically ever-less reasons to believe the certification is flawed.
So, despite all the stats you may collect about birds, and physical + ethological models to estimate how much chance there is it will happen twice to a twin engine plane on both reactors before it can land, it would only prove reality: it just doesn't happen. Or not in ways that more engines would solve. (Birds are a bigger problem for cockpit windows, though.)
Now, another additional bit of safety: all jetliner planes have a "fixed-wing" design, allowing "deadstick landing"². From wiki:
> All fixed-wing aircraft have some capability to glide with no engine power; that is, they do not sink straight down like a stone, but rather continue to glide moving horizontally while descending. For example, with a glide ratio of 15:1, a Boeing 747-200 can glide for 150 kilometres (93 mi) from a cruising altitude of 10,000 metres (33,000 ft).
More recent planes are usually ever better (the OG 747 is from 1969!) At the very least it allows the pilot to 'land' on sea and wait for evacuation in zodiacs. So even in the extremely unprobable event that ETOPS failed (the statistical outlier where a plane loses both engines), you'd probably just glide to the ground 100-200km away at most to reach some landing spot.
There are reasons why air travel is so safe, the safest of all, and most of those are empirical, real, tested then validated. That's why it was such a shame what Boeing did to the 737 MAX; and I hope the 777X program yields the safest planes we've ever seen from them, that they actually innovate in that respect.
> More recent planes are usually ever better (the OG 747 is from 1969!) At the very least it allows the pilot to 'land' on sea and wait for evacuation in zodiacs. So even in the extremely unprobable event that ETOPS failed (the statistical outlier where a plane loses both engines), you'd probably just glide to the ground 100-200km away at most to reach some landing spot.
While I agree with the rest, landing on sea is a terrible idea. That can work on rivers where you have no waves. But gliding onto an ocean with waves will likely be fatal. Luckily, there is no recent case of a double engine failure where landing on sea was necessary (apart from maybe MH370 but we don't know that).
Oh I totally agree. Thanks for clarifying this point! I honestly didn't mean to say that you would choose to land of sea if you had any alternative... just that if you must, it's a last resort.
The main argument was really about not dying from engine failure (i.e. from falling) since planes glide — knowing this totally changed my impression of "safety" wrt riding planes, for the better: “planes can't fall!”.
Actually the opposite. Had 737MAX gone the way of 777, there would have been no MCAS - but it would involve significant rework of control system, new avionics, and a lot of training.
The core difference is that even the original 777 is a Fly-By-Wire system with programmed behaviour, in fact it was a well known case study in building civilian safe FBW systems.
Because of that, there's no need to "patch over" differences like it was done with MCAS, as the minute adjustments can be done across the whole flight envelope protection system that is already there since first 777. In fact, 787 controls are derived from that and use software adjustment extensively in order to make control surface generate less drag yet still be usable.
It is very easy to make a new thing behave like the old thing for the standard use case. The problems lie all the corner cases. In some cases making the standard case even more perfect can make the corner cases even worse (737 MAX). These airplanes are complex and flying exposes them and their crew to wide variety of stresses.
Just the fact that these planes are getting longer and longer will have some side effects on how they handle. Maybe more caution is required when taking off, maybe the body vibrates very differently. While weight may be the same it is also further out which changes the handling dynamics. These make be small matters which may not matter until they do.
Not really. The 777 has Fly-By-Wire controls with all the envelope protection and redundancies that comes with that. I.e. failing safely but step by step offering less protections to the pilot the more it fails, until you are down to the few essentially mechanical ways of controlling the aircraft. The only reason a 777 felt like 777 is because it was programmed to be one.
Compare this to the 737 MAX which still relies on mechanical linkages and two different flight computers with the pilot supposed to be the safety when they disagree, there any change introduces differences in the feeling and handling at the pilots hands.
Question Boeing's recent engineering and similar all you want, but this is completely different.
The issue is not the name, it is the comprehensiveness of the training required. The MAX had iPad training only, and MCAS wasnt even in the manual, let alone the differences course.
Besides, the 777 wasn't designed for low loading at small airports.
It’s their risk minimisation strategy. If they call it something new, it would be perceived as a higher risk development. If they keep the existing name, it’s viewed as a mere improvement on the existing model.
In reality, the only parts that are different are the wings and the engines. The rest of the systems are essentially the same.
The fuselage has the same diameter and design (just slightly longer).
Most people would not be able to tell the difference between a 777-9 and a 777-300ER.
They can ride quite a while due to the fact that there is only one alternative in commercial flight (Airbus). I hope there is not a time when both companies have such an issue at the same time. That would disrupt travel.
Neither. The main delay is due to a problem with the GE9X engines. Some of the internal components were wearing out faster than expected so they had to redesign them.
I am fascinated by the wings, you can see that they have been heavily optimised and wonder how much compute time went into perfecting them. I'd love to see a documentary on the design & construction. I have a carbon-fibre road bike and it is incredible how much they can tune the materal. Where it is rigid and where/ even how it flexes to dampen vibrations.
Interestingly, most of that article is about the 737 Max issues (the MCAS software is a disaster, it's a push to even call it engineering).
Recently I've been doing a teeny tiny bit of CFD again. You might be amazed at how little CFD goes in to wings. It's still a huge amount, but tunnel testing still wins. I was kind of surprised.
As best I can tell, CFD is still kind of like impedance-based home body fat scales. They're kind of directionally accurate but have a pretty high error.
I thought CFD would be a solved thing by now, but then I remembered how good (e.g. bad) weather prediction still is.
Some people think that wind tunnels will be obsoleted by computational fluid dynamics within the decade. Others think that the problems with CFD are not a lack of compute power but a lack of comprehensive understanding and modeling of the physics at play, and expect that wind tunnels will be with us for quite a while. (Personally, I believe in the progress of technology and expect an eventual if not near-term breakthrough in CFD software will eventually obsolete the wind tunnel, but I also think that institutional inertia will keep a lot of wind tunnels and businesses that purchase time in them in operation for a decade or more after CFD's big breakthrough...)
F1 teams spend a lot of time in wind tunnels looking for correlation between CFD and Reality. If there isn't any then the year is almost lost, usually.
Did the military division of Boeing have a hand in engineering the folding wingtips? It would make sense since McDonnell Douglas/Boeing have decades of experience doing this with the F-18. Then again it wouldn’t surprise me if the 777X team reinvented the wheel on this point.
A crucial difference is that, ultimately, 777X is a much smaller plane with easier operations compared to huge A380.
It needs no new special handling compared to the existing 777, which already had a higher amount of airports available as destinations, if only because it didn't need two-level tunnels for speedy embarkation/disembarkation.
Also, 777 has always served the long distance market, and this plane is essentially an extension for it without many of the downsides of both A380 and 747
It's not the capacity of the A380 that airlines dislike; it's that operating a heavy, double-decker quad-jet is expensive. It's estimated that A380s have an hourly operating cost that is double (or more) that of a 777. Which isn't surprising, considering an empty A380 weighs in at about 280 tons. An empty 777-300 weighs in somewhere around 180 tons.
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[ 4.8 ms ] story [ 142 ms ] threadMaximum cargo capacity is roughly three-quarters that of a 747-8 by weight.
There's also a possible 777-10X model that will seat up to 450 passengers and is being pitched as a rival to the A-380 superjumbo.
The real miracle here is that the big four-engine jumbos are being replaced by a twin-jet. (This says something profound about advances in engine technology since 1970. Or even 1990.)
Complete noob here, so I am trying to improve my understanding.
Well that depends what you mean by "need" specifically. The point of being the same type is that regulations-wise they don't.
More specifically, the 737 design had so little ground clearance that the bigger, more efficient engines used in the Max had to be mounted in a different position than before. This change resulted in different maneuvering characteristics that Boeing tried to patch with crappy software. The 777, on the other hand, is a much bigger plane with plenty of clearance and the new engines are only marginally larger than the old ones. I don't see Boeing messing with the engine positioning needlessly here, especially in the wake of the 737 Max fiasco.
Same applies for planes.
Now remember these planes will probably be produced for 30 years, and then maybe in service for a further 20 years. Will you be happy to know that safety critical design decisions were made to standards of 90 years ago?
It didn't have airbags, I was wearing the seat belt, I had a slightly sore neck for a couple months (not like bothersome sore, I noticed it when doing higher impact things).
Which isn't to say I'm opposed to updated safety features, rather that 20 years ago wasn't that bad, even without air bags.
Later models of those cars were improved. But then a similar story happened when the IIHS started testing small overlap for passenger-side crashes, until again newer models were reinforced.
[1] https://www.cars.com/articles/mercedes-lexus-and-audi-fail-l...
[2] https://jalopnik.com/the-toughest-car-crash-test-is-about-to...
I'm not sure why I didn't take pictures of the drivers side, but the front panel wasn't nearly as damaged.
Commercial aviation is one of the safest modes of transportation there is. That’s due to the safety procedures practiced by the operators, not faster FEA modeling. It’s far safer than even the latest cars, when driven by amateurs on public roads.
Is there some specific “safety critical design decision“ you think was lacking in the 777 era?
I don't know what your financial situation is, but I recommend that you research the issue. You can buy a good, safe, and reliable second hand car from a manufacturer like Toyota, Honda, etc.
Er yes I’d be fine with it.
My current car is from 2009, looks and works almost the same as the same model from 1999, and I’m not planning to change it.
Lol I don’t think my 2009 Defender was - doesn’t even have airbags. Pretty sure it has zero crumble zone either. And no adaptive anything.
But I wouldn’t swap it for anything - it’s a timeless heritage piece and represents something about who I am.
One interesting thing about the Beetle is that despite retaining the same basic shape and construction over the entire run a lot changed to significantly improve relative safety: collapsible steering columns, the change to Macpherson strut suspension, door handles with the opening mechanism shielded in a roll-over and so-on.
One of them doesn't even have airbags!
Live a little.
Most of getting licensed is learning how to deal with bad situations. Engine out, getting lost, that sort of thing. Every biennial flight review, at some point, the engine will 'fail'. The plane may or may not belong to the insurance company after in a real event but most engine out scenarios should be survivable. I can't think I've even seen an aircraft that is without 4 point shoulder straps.
Even big stuff can do that sort of landing. (Your call on if you consider that gliding, or just falling with style) https://en.wikipedia.org/wiki/Gimli_Glider https://en.wikipedia.org/wiki/US_Airways_Flight_1549
Sounds like a cool plane though, clearly I appreciate old mechanical technology!
I don't have the numbers handy, but most plane accidents are survivable. In fact, there are many crashes where everyone survived (like the Gimli Glider).
And this issue was already stark on the NG, which had to use these weird flattened turbofan nacelles in order to get enough ground clearance despite its much larger engines:
* 737-NG https://upload.wikimedia.org/wikipedia/commons/c/ce/CFM_56_L...
* 787 https://upload.wikimedia.org/wikipedia/commons/7/70/787_-_Fl...
And even with that they also had to mount the engines way ahead of the wing, clear off of it: https://en.wikipedia.org/wiki/File:N707SA_Southwest_Airlines...
Now this looks a lot like an A320 where the engine is also ahead of the wing[0] but notice how the engine "strut" goes downwards on the 320 but has to "wave up" on the 737NG.
It's very clear on the side-view drawings:
* A30x https://upload.wikimedia.org/wikipedia/commons/9/92/A32XFAMI...
* 737 https://upload.wikimedia.org/wikipedia/commons/b/bc/B737Fami...
where you can also see the side-structure of the original 737 and its low-bypass turbofan (0.96:1 compared to 5:1 to 6:1 for the NG's engine).
[0] https://en.wikipedia.org/wiki/Airbus_A320_family#/media/File...
I believe your picture actually shows the 737-300 (Classic), which had a very obvious flat-spot in it's nacelles. The NGs do also have a slight "flat spot", but it's much less obvious.
https://www.federalregister.gov/documents/2018/05/18/2018-10...
Boeing was required to prove the load-bearing of the hinges on the wings and what types of alerts that the crews receive should a wingtip fail to lock prior to takeoff. More than one means must be available to alert the flight crew that the wingtips are not properly positioned and secured prior to takeoff. If the wingtip is not locked prior to takeoff, the plane is prevented from taking off.
They even required that the electric circuit that unlocks the wingtips be automatically isolated from the circuit that folds and locks the wingtips and that that circuit cannot be re-powered during flight.
ETOPS is the general set of rules for how far a plane with two engines can be from an airport. https://en.m.wikipedia.org/wiki/ETOPS
Four engines just means there's 4 things that can catastrophically fail and potentially damage the plane rather than 2.
The real concern is trans-oceanic long-haul. Supposedly modern engine failure rates have improved to the point that you're less likely to have problematic engine failures than a four-engine 70s-era 747.
I recently rode in a 2-person jet. The pilot said the only reason we might bail out is an engine fire. If the engine fails, the plane's an excellent glider, and we'll glide to an airport/airstrip. Now, this was somewhere with airports all over, not an ocean.
https://en.wikipedia.org/wiki/ETOPS is a good read.
Good to know that the squishy contents of the aluminum can are the least reliable part of the system.
I guess that also limits the size for planes, but probably to 10,000+, so it's not something we're likely to hit.
Say that you need 50% of the engines on the plane to be able to fly safely, then having more engines is actually safer. For example, supposing that engine failures occur 1% of the time, with four engines there are 3.97 three and four engine failures per million flights. For a two engine plane, there are 100 two engine failures per million flights.
There's probably less drag from two engines than four as well.
That's what I meant by "collateral damage".
Doubling the number of engines doubles that risk.
On the other hand, a failure that would take out both engines on a twin jet is likely to take out 4 engines. Failures such as running out of fuel, ingesting a flock of geese, and ingesting hail.
https://www.youtube.com/watch?v=HSxSgbNQi-g
The rational justification is not merely technical but rather empirical, proven by real-world data. Certifications usually because companies can demonstrate e.g. "N years of trouble-free XXX-minutes ETOPS experience". In other words, we've been doing it for this long and it works so there's statistically ever-less reasons to believe the certification is flawed.
So, despite all the stats you may collect about birds, and physical + ethological models to estimate how much chance there is it will happen twice to a twin engine plane on both reactors before it can land, it would only prove reality: it just doesn't happen. Or not in ways that more engines would solve. (Birds are a bigger problem for cockpit windows, though.)
Now, another additional bit of safety: all jetliner planes have a "fixed-wing" design, allowing "deadstick landing"². From wiki:
> All fixed-wing aircraft have some capability to glide with no engine power; that is, they do not sink straight down like a stone, but rather continue to glide moving horizontally while descending. For example, with a glide ratio of 15:1, a Boeing 747-200 can glide for 150 kilometres (93 mi) from a cruising altitude of 10,000 metres (33,000 ft).
More recent planes are usually ever better (the OG 747 is from 1969!) At the very least it allows the pilot to 'land' on sea and wait for evacuation in zodiacs. So even in the extremely unprobable event that ETOPS failed (the statistical outlier where a plane loses both engines), you'd probably just glide to the ground 100-200km away at most to reach some landing spot.
There are reasons why air travel is so safe, the safest of all, and most of those are empirical, real, tested then validated. That's why it was such a shame what Boeing did to the 737 MAX; and I hope the 777X program yields the safest planes we've ever seen from them, that they actually innovate in that respect.
Safe travels!
[1]: https://en.wikipedia.org/wiki/ETOPS
[2]: https://en.wikipedia.org/wiki/Deadstick_landing
While I agree with the rest, landing on sea is a terrible idea. That can work on rivers where you have no waves. But gliding onto an ocean with waves will likely be fatal. Luckily, there is no recent case of a double engine failure where landing on sea was necessary (apart from maybe MH370 but we don't know that).
The main argument was really about not dying from engine failure (i.e. from falling) since planes glide — knowing this totally changed my impression of "safety" wrt riding planes, for the better: “planes can't fall!”.
Has Boeing learned anything from the past 12 month ?
The core difference is that even the original 777 is a Fly-By-Wire system with programmed behaviour, in fact it was a well known case study in building civilian safe FBW systems.
Because of that, there's no need to "patch over" differences like it was done with MCAS, as the minute adjustments can be done across the whole flight envelope protection system that is already there since first 777. In fact, 787 controls are derived from that and use software adjustment extensively in order to make control surface generate less drag yet still be usable.
Just the fact that these planes are getting longer and longer will have some side effects on how they handle. Maybe more caution is required when taking off, maybe the body vibrates very differently. While weight may be the same it is also further out which changes the handling dynamics. These make be small matters which may not matter until they do.
Compare this to the 737 MAX which still relies on mechanical linkages and two different flight computers with the pilot supposed to be the safety when they disagree, there any change introduces differences in the feeling and handling at the pilots hands.
Question Boeing's recent engineering and similar all you want, but this is completely different.
Besides, the 777 wasn't designed for low loading at small airports.
Is that related to the recent MAX issues, or to the fact shipping such a large aircraft on two engines only was much harder than expected?
Interestingly, most of that article is about the 737 Max issues (the MCAS software is a disaster, it's a push to even call it engineering).
As best I can tell, CFD is still kind of like impedance-based home body fat scales. They're kind of directionally accurate but have a pretty high error.
I thought CFD would be a solved thing by now, but then I remembered how good (e.g. bad) weather prediction still is.
http://longbets.org/753/
Some people think that wind tunnels will be obsoleted by computational fluid dynamics within the decade. Others think that the problems with CFD are not a lack of compute power but a lack of comprehensive understanding and modeling of the physics at play, and expect that wind tunnels will be with us for quite a while. (Personally, I believe in the progress of technology and expect an eventual if not near-term breakthrough in CFD software will eventually obsolete the wind tunnel, but I also think that institutional inertia will keep a lot of wind tunnels and businesses that purchase time in them in operation for a decade or more after CFD's big breakthrough...)
https://en.m.wikipedia.org/wiki/Computational_fluid_dynamics
“21st Century Jet” is a documentary about the building of the 777. Looks like it’s available on YouTube.
https://www.seattletimes.com/business/boeing-aerospace/massi...
The wings are assembled horizontally similar to the to A350.
https://www.youtube.com/watch?v=yYXiz7GX4FI
https://leehamnews.com/2020/01/25/third-time-is-the-charm-77...
It needs no new special handling compared to the existing 777, which already had a higher amount of airports available as destinations, if only because it didn't need two-level tunnels for speedy embarkation/disembarkation.
Also, 777 has always served the long distance market, and this plane is essentially an extension for it without many of the downsides of both A380 and 747