>That could change, if batteries get a lot cheaper and lighter.
The batteries could be free. Until they literally burn up so the plane can get lighter and therefore can land, it's pretty much a non-starter for anything over a few hundred miles. The max takeoff weight of a Boeing 787 is 50 tons more than it's maximum landing weight, which will probably damage the gear in some capacity.
> The max takeoff weight of a Boeing 787 is 50 tons more than it's maximum landing weight
I honestly don't know, but could this be part of the design simply because the engineers know the plane will weigh less on landing? Seems like that design would change if so much mass from fuel was no longer lost/burnt.
This, but the reason it's engineered that way is because landing gear face far higher loads on landing. During takeoff, landing gear essentially only have to support the weight of the aircraft. During landing, the gear have to arrest the aircraft's descent (which may be momentarily 3 or 4 g's of acceleration if the aircraft encounters turbulence while landing); and then they need to brake the entire weight of the plane within the remaining length of the runway, which is a high loading in a different direction (along the aircraft's longitudinal axis). So maximum landing weight is set by the landing gear, while maximum takeoff weight is usually set by the wings and engines.
I didn't realize that most of the braking on landing was handled by the landing gear. I'd always assumed that the obvious sound of the engines reversing when we landed did most of the work, but some casual googling suggests that it's only supplementary, to reduce the load on the landing gear.
The stronger the gear needs to be, the heavier it becomes. Planes are optimized for safety first and foremost, but weight is a very close second. Heavier plane = more batteries = more weight = more batteries etc.
yes and no, because now it's a pain in the butt when there is a takeoff issue. If there is a tail strike, an engine issue on take off, or a passenger emergency early in the flight, now they have to loop around in circles for hours with a damaged airplane before landing. Or they have to dump fuel, but they do it extremely rarely, because most planes can't even do it, and it's a pain in the butt and actually quite slow for the planes that can do it.
All aircraft landing gear are certified for landing at MTOW, they just need inspected afterwards before the plane can re-enter service. The fact that frequently the captain's judgement is to prefer to land at a lower weight is a separate issue.
It is way more complicated than just altitude, with zones and procedures, incredibly long checklists and a bit of maths. But a plane that can't reach 4000ft is probably in a mayday situation, and there is absolutely no time to try to dump fuel, it's a slow procedure.
Just to put illustrative numbers on it and not to dispute the parent comment in any way, the big 787's (787-10) have 251 Mg max take-off weight and 202 Mg max landing weight.
In comparison the A380 has a max landing weight of 386 Mg. Clearly the 787 is not up against a hard practical limit in terms of landing weight. Yes, stronger gear weighs more.
We agree that weight of batteries impacts their usefulness for aircraft. That's why I mentioned it in the quoted sentence :-).
> The 787 can operate out of many airports the A380 cannot.
Yes? I said batteries would have to be a lot lighter and kerosene a lot more expensive before they are a practical replacement. I think we agree, but I think you think we disagree?
Managing a few hundred miles on electricity would in itself have a huge positive impact. Most of the busiest air routes in the world call under that heading.
The batteries could be free. Until they literally burn up so the plane can get lighter and therefore can land, it's pretty much a non-starter for anything over a few hundred miles. The max takeoff weight of a Boeing 787 is 50 tons more than it's maximum landing weight, which will probably damage the gear in some capacity.