Okay, I'll bite. Let's look at the solar-powered cruise thing.
The wingspan is ~100 meters, the aspect ratio looks to be ~8, so the total wing area is 1250 sq m. Let's assume the fuselage and tail have about the same area as the wing, so the total area available for solar cells is ~2500 sq m.
Also, let's assume that it's flying very, very high, so that only 5% of the sun's energy is lost in the atmosphere1, so the incident flux is 1.29 kW/sq m. Also, let's assume that we only fly when the sun's at least 60 deg above the horizon2, so our cosine loss is only ~13%. And let's assume our solar cells are 80% efficient.3 2500 x 1.29 x (1-0.05) x 0.866 x 0.8 gives us 2.24 MW to propel our totally-not-crazy airplane.4
Is that enough?
Well, a loaded-without-fuel A380F weighs 402,000 kg. The Sky Whale is much larger, but let's assume it has the same weight.5 A typical airliner has a lift/drag ratio of about 17, but this one has genuine cartoon aerodynamics so let's give it a L/D of 276. 402,000 x 9.8 / 27 gives us 146 kN of drag. To keep up with other airliners, we'll be cruising at about 800 km/hr = 222 meters/sec.
Thus the total power needed to maintain cruise is about 146,000 x 222 = 32.4 MW.
With 2.24 MW available, that means we need our engines to convert electricity to thrust with 1440% efficiency7.
I'm dubious.
1About 17,000 meters/55,000 feet, I think. This is higher than any current airliner but not crazy by itself.
2This will limit flight time based on direction, latitude and season. The best case is near the equator flying west, which will allow up to 5 hr/day of flying. At London's latitude it would be limited to ~2 hours on the best day (June 21) and wouldn't be able to fly at all for 46 weeks of the year (July 15 to May 28)
3Crazy. AFAIK the current world record is 44.4%
4That was sarcasm.
5A little crazy.
6Pretty crazy. That's the same aerodynamic efficiency as Rutan's Voyager.
7Absolute giant mutant batcrap crazy. You shouldn't need to be told this.
