Will the Lilium Jet Work? A detailed analysis by an independent expert.

its recommending it? thats great.

Some interesting information for you to consider: Building an aircraft is not close to building RC planes when it comes to processes. I have experience at Airbus. One of the biggest cost eaters is design changes, increasing with time within the process. Thus, its the complete opposite to your RC planes with the slogan "high developtment cost, low probability of failure or big design changes". About Lilium: changing their design shows uncertainty and is a cost eater.
The top down approach is also common at Airbus aircraft design, and with my experience id like to say that you are making the wrong argument.
But as a Startup Lilium makes something completly different than Airbus:
There is no fixed mission assigned before building the plane. The argument you make is about the order in which they calculate which is actually fine. What is not so much fine is:
1. As stated in the Video, after the first theoretical calculations there is yet lack of confirmation by proof of 1:1 scale flight test (lets see what this year brings).
2. The first theoretical calculations are used as data for investors, which is very risky.
3. The biggest risky thing to do in my opinion, there is no fixed mission. For example at Airbus, you would define the whole mission(s) of all possible customers, then do some basic calculations if those missions are even possible in theory, and if confirmed, THEN you would proceed. Lilium just changes their performance in the process, before having a fixed mission.
The argument you make is in my opinion worthy, but not factually correct. You are saying Liliums design process is risky and uncommon in the industry. Comparing RC planes to real planes is wrong on alot of levels, but your point in the end is valid in my opinion due to different facts then what you stated. Lilium takes alot of risks. LILIUM HAS TO TAKE RISKS. None company would develop such a design otherwise, which would maybe not push battery suppliers on the huge scale (you could argue with automobile here). So they are not "stupid", they are risky. Lilium is a Startup. Lets see what happens.

@@TecTrendsThank you for your answer, I appreciate it, after all, I know RC modeling is in no way to be equaled with real planes. I agree you need a top down approach for production, but you need a bottom up approach for development

@@TecTrends Small scale flying model prototypes have been used in industries since the dawn of aerospace development. It is just that such works are not well published and tend to be company internal information.

@@grasuh Considering what I already said, here my opinion which I try to express neutrally as an aerospace engineer, Airbus insider and privat pilot:
You did not understand what I said. Small models are used in different scenarios to get some information, eg at same Reynold Number windtunnel testing. But what I said is something completely different then what you inferred, even tho I have been more then clear.
I was talking about processes on how aircraft are developed. A model aircraft is, as the first commenter stated, built up by big radical steps, to cite him „make it crash and built it better“. It doesn’t fly straight, so you change the rudder.
Airplanes are NOT designed this way. Development changes are getting more and more expensive as development state rises. Thus, there are first made (even in times before computer) heavy calculations, which get iterative more and more advanced. A clear mission is defined and the physics need to align, meaning from that definition comes the powersystem, the wing design and everything else. After the physics align in some kind of calculated model, every single part is being optimized, BUT NOT YET BULILT as a WHOLE AIRPLANE. This is the huge difference which I was talking about. And trust me, I’ve seen Liliums early designs. Shown at a local conference, not allowed to talk about it. Like for everything it’s just to display the general form. A model airplane is BUILT and then OPTIMISED holistically by big changes. Opposed to airplanes which develop after the „physics fit model“ after heavy calculations in tiny steps.
That model approach is what we see from Lilium, which as a startup they kinda have to do but I still don’t think it’s optimal as stated. Because it’s a cost, time eater and high risk.
Please read all my lines carefully, it all makes sense.
Thank you.

@@TecTrends Here is an example of a scale model usage. Search Google for "ADAPT Scaled Demonstrator" and read the paper through ResearchGate, called "System Identification and Stitched...".

Lilium successfully passed their 4th & final DOA audit. It fully disproves John's lies about Lilium. Don't always go for the gut when Germans are engineering hm?

​@@robitwhisperr Good for them, and as might be expected from German engineering diligence. We can learn most from being proved wrong, so lets see if it passes the real World usability test.

This is a death trap.

@@denisw398 can this plane handle the weather, such as wind gusts working at high elevations I notice it to be always windy. massive gusts of winds at high altitude most likely is even more

@@rezasaba1602 wind is surprisingly a non-issue for aircraft, it only becomes a problem with crosswind landings. But crosswind landings are only performed because its physically impossible to reorient a paved runway to align with the prevailing wind. A VTOL aircraft can easily along itself into the wind and therefore doesn't need to perform a crosswind landing.

Thank you!

Hi there! Thanks for sharing this story and your comments. Sadly, I did not discuss the change from 36 to 30 EDF's in this video. But I have analyzed this change in my previous video. In hindsight, I should have included this detail for completeness...

@@zhihenglou Hey, you did yeoman's work in this long video. Don't worry about that one change. You can mention it, and its expected impact on the flight/range performance, in a follow-up video.
(Which I will watch. Duly subscribed, so I won't miss it)

Thanks for your positive feedback, Nicolas! This video analysis is based on the 7-seater with 30-motors (see Chapter 2), so the video's conclusion regarding flight performance should not be impacted by this change from 36 to 30 EDF's. But I should have explicitly mentioned this change in the timeline (Chapter 3). Thanks again for your comment and your sub! What would you like to see in my next video?

Great Video,
Keep up the good work!

A ballistics parachute is certainly possible. A ballistics parachute with rocket extraction and pyrotechnical instant inflation is possible to allow inflation at zero speed and zero altitude. A ballistics parachute with a high speed ribbon drogue is possible. I would argue only a plain simple parachute designed for low speed deployment at a modest altitude is required.
Ilium now has designed the Lilium Jet to land n a runway. This may mean that the aircraft no longer needs a ballistics parachute so long as it is in flying distance of a runway.
Ballistics parachute might be very expensive to develop and the weight will detract from other more important sofety factor.

in the case of vertical flight, really large propellers have an advantage, while this vehicle is supposed to fly like an airplane to make optimal use of the engines.

@@EverynyanSan The concept of using many small EDFs as opposed to a lesser number of fan-units with a larger diameter is still flawed. The "wetted area" of the ducting on those fan units is much greater per area of cross-section than would be the case with one or two larger-diameter fans producing the same amount of thrust and that means increased drag hence lower efficiency. There's a reason we're seeing a lot more twin-engine commercial airliners than four-engined ones and some of that is down to the greater efficiency of larger fans over multiuple smaller fans.
In the world of electric flight, efficiency is *everything* so this concept is immediately flawed through its use of many, many small (and thus less-efficient) fan units. There's a very good reason that all the other players are using lower disk-loadings than the Lilium -- they've prioritized efficiency over gimmicky styling.

@@xjet I guess lilium wanted to add extra lower pressure to the top of the wings to increase lift. I have no illusions that this project has no chance of success without a new type of batteries. I am not an aviation engineer but it seems to me that propellers powered only by electricity have certain limits that cannot be overcome compared to internal combustion engines.

The theoretical batteries and the theoretical motor bearings. "we will get it working when reality catches up with our fringe science" ( get Walter Bishop onto it ( Fringe ))

@@alanhilder1883 Walter would have it solved yesterday.

Thank you, Harry!

@@zhihenglou Pleasure man, really love this type of work and sometimes wish I was more an engineer than a marketer! It's pretty wild how all this new and increased battery density news is coming out a week after the release of this video. Let's see how long it takes to play out in reality for the leaders, I also think I've got the topic/title of your next analysis! aha.

Yes, I've been reading the news on CATL's 500Wh/kg battery. I haven't found any useful resources that describe the batteries in depth; I only found a few short news articles thus far. I'm still very intrigued about this new battery. What's your topic/title idea for my next analysis?

It's the same old story; design an airplane that's needs power that's currently beyond what's on the market!
Even military aircraft get caught in this cycle. One of the most famous experimental kit planes that did this was the BD-5 in the 70's. They sold lots of kits but most were never complete because a reliable, affordable and available motor never happened. Here we are 50 years later and there's still no motor that really checks all the boxes as a powerplant for those airplanes.

​@@harryseagar He deserves egg on his face at least. Lilium passed their 4th & final DOA audit from EASA. If verifies their battery tech & wing flight fully. So John here spent an hour successfully fooling you all.
This 2 mo video didn't age well 😂

Exactly my thoughts😂

Is it a flaw? Why should 175km not be possible?

yes, I noticed that too planes just like cars need to have some weight for basic stability, how much? am not sure ? more questions than answers came up after this review

That is an astute observation. What is most noteworthy about the Lilium YT channel is not what they show us of a big r/c model flying about with agility that would be underwhelming on the bridge of a super tanker, but the absence of a single flight in so much as a moderate wind. There is not one example of it performing a spot turn, nor even so much as a ground taxi. And yet they cling to the line that they are on track to have a 7 seat version certified and in commercial service within 2 years. It is deluded. We are seeing a version of ‘The Emperor’s new clothes’ fable play out in front of our very eyes, and it is apparent that most of the people watching are the idiots of that tale.

​@@XPLAlNSo what's the point of the flaw? Just that they are too late with the first flight and have 175 and not 300km?

@@jo21e6 the point here is that Lilium have not demonstrated the essential manoeuvres critical to VTOL operations. Range and and being 7 years behind their own service entry date are a whole other problem.

He fooled you I'm afraid. Lilium has been issued their long awaited DOA license from Europe. If John Lou was correct about anything he disparaged Lilium for, EASA would never have given them their DOA. It verifies everything from their battery to wing flight. It also allows them to scale up their craft without further approval because they have proven their engineering competency.
It in turn proves John Lou is incompetent and a pathological liar.

The financial failure of a company doesn't proof the claim that it's technological not working.

@NikoWeify it never worked

@NikoWeify they are going to get sued and maybe even criminal charges, so maybe we will get proof.

@@NikoWeify …true that financial failure is not proof of technical infeasibility, but neither is there any “proof” the Lilium was an aircraft with the performance the company claimed. The salient facts are this: they claimed service entry would be 2019, but 5 years later the company had not even completed its certification prototype, let alone managed a manned flight nor even permission for such. After receiving more than a $Bn. Therefore, the technical feasibility of the Lilium Jet will forever remain hypothetical and not supported by aerodynamic theory for the many reasons this video explains with great clarity.

​@@XPLAlNnever heard that they ever claimed 2019 as entry into service. Can't imagine that as the company was founded in 2015, which was way before they even knew how the final product could look like. It was just some prototyping of engines in a little drone. But anyway, for sure they often enough moved their timeline, that's true. I personally think that it was more a Management issue (uncontrolled expenses) than that it's technological not possible. There's more than enough simulation data which proofed that the concept is working (if the range claimed would be possible, is another question) from a physical point of view + flight data from technical demonstrators.

Which one could keep up with the EASA or FAA do you think?

Ballistic parachutes will also increase in quality and fall in price. Wright's Law will prevail...it's quite predictable

​@@davidantill6949Not everything has that much potential...

Exactly. 300km might be highly optimistic, but smaller fractions of this are absolutely possible with today's battery technology (which is pushing into the 300Wh/kg range). This can be commercially successful without hitting all the named goals.

Tencent, tech company and one of the top 10 biggest in the world and biggest in China does no due diligence? But you do right? Lol

@@octavicolom4562 why don't they take the lilium out for a fight and record it? they only show short clips of a short flight a couple of times a year.

@@octavicolom4562 Tencent is an IT company not an aviation company. It should be easy to attract non aviation investors with tiktok videos.

@@frankyflowers I've read the LILIUM can only fly for 15 minutes, thus the Lilium is a piece of junk. JOBY has already flew 1,000 of times and 150 minutes at up to 200 mph. JOBY is the West leading EVTOL. Thus JOBY is the world leader, and copy cat Archer is not far behind per my research.

Hi Brendan,
I am not doing further work on my project about Lilium, except for some light maintenance work, like replying to comments. Because I have other exciting ideas and projects coming up!
You can find a summary in 'Conclusion' (see 1:41:51). You can also find a PDF version of this video, which might help (see drive.google.com/drive/u/1/folders/16IEpl-tQwd244ZVuoIncWn4l8evGRIwH ).
Lastly, I must remind you of my disclaimer. I am not giving investment advice, so please read the disclaimer in full.
Best,
John

@@zhihenglou Thanks again John. Great content. Disclaimer noted and understood. Will look for your other content.

I haven't understand why it can't work. Building an airplane from scratch does take several years and much money, if it's the first one, one will make false assumptions. And of course they won't make 300km, but maybe 80,100km with the first battery, and in a few years they'll have better ones.

But aren't they nessessary for the lift on the upper side of the wing?

There are no doubt technical challenges. I've seen ilium go from being described as impossible by 'professors' in learned papers, to full fore and main plane transition (also said to be impossible). Aeronautical engineers are no more qualified to talk of battery tech than civil or mechanical. The batteries to make Lilliium achieve its performance goals already exist. Lilums economic success will depend on battery tech that allows much more than 600 cycles and battery tech scientists should be asked and they will probably say its a matter of when not if. It's eaither 3 years or 10 years.

What kind of battery exists today that can produce enough current for 10 turbine-looking motors? and how much do these batteries weigh?@@williamzk9083

Also curious on this. In Liliums last test flight, you could definitely see that the air "attached" to the wing in the last part of the vertical descent, so that would suggest that some lift might be generated by the fixed wing part.

​@@faluffelvery interesting. And are ducted fans better for hovering because of less induced drag or is a big prop better because of lower speed?

Hi there,
This detail regarding the ballistic parachute is something I have genuinely forgotten about! Thank you for bringing it up. I think other viewers will find your comment helpful in building a comprehensive picture of this story.
I have not worked with ballistic parachutes before, so I cannot comment on the technical details, but I read your comment with great curiosity and interest. Thanks again!
Best,
John

@@zhihenglou I'm just a light sport aircraft enthusiast and probably not qualified to comment on the technical details. But Lilium once stated they want to certify their vehicles as LSA. But whatever happened since then they never produced a prototype that could carry a test pilot (being it only for a short hover flight). That parachute issue just comes to my mind when I go through my everyday pre-flight checklist. That said I really enjoyed your technical analysis. I used to write software for the aircraft maintenance world and I always wanted to switch to engineering the other side that actually flies. In so far thanks for providing your educational outreach here.

When I was researching Lilium's history, I also found that the company wanted to certify its vehicles as LSA (see this German webpage: webarchiv.typo3.tum.de/AR/ls-id/id/design-fuer-startups/project-showcase/lilium-aviation/index.html ). I believe the initial concept was intended as a personalized air vehicle: an airplane with wings but also a ground vehicle that can be driven like a normal car. The wings could be folded to create a more space-efficient geometry (see this picture: th-cam.com/video/htaeARwse1w/w-d-xo.html ).
I know nothing about light sport aircraft. I assume you use a parachute there because you mentioned it in your checklist? Thanks again for your comments!

Ballistic whole-airframe parachutes are utilized on several aircraft that wouldn't make much sense unless you understand the philosophy of use.
E.g. Cirrus Jet has a parachute that has a maximum deployable airspeed so low that the aircraft would be well below its operating speed to utilize the chute in an emergency. It is completely and totally inadequate for most high speed scenarios.
But its there for one specific scenario that kills many private pilots. That is departure from controlled flight after exceeding the critical angle of attack while performing the base-final leg turn to landing at low airspeed and low altitude. Being high wing loaded and rather fast, that mistake will absolutely be fatal at traffic pattern altitudes. If the pilot is able to deploy the recovery parachute in time, it probably will be survivable. The most likely scenario is deploying the chute at an altitude of 500-1,000ft AGL, at a velocity of around 150ktas. Also, the vertical descent velocity in a fully developed spin is likely right around the parachutes maximum deployment speed, so in the case of a spin, it is recoverable with less risk of injury to passengers. Also, at high-altitude long range cruise/loiter velocity, the Dynamic Pressure may well be low enough to safely deploy the chute in the case of rapid cabin depressurization or pilot incapacitation being a single pilot certified aircraft. If one slowed down to a low indicated airspeed at 37,000' just above stall, the chute might work fine for that.
Same with this Vtol. Its not meant for maximum speed. Its meant to save lives if the power fails in a hover between around 250'-1,000ft AGL. An automatic deployment on power failure such as the F-35 ejection seat would be ideal.

@@zhihenglou Thanks to your reference, some details become clear. The propulsive efficiency of these small electric driven fans is rather poor due to Reynolds scaling, (Ackeret efficiency scaling formula) I have analysed solar cell powered aircraft like the Swiss one that did fly in sections around the world ( Piccard)
If you carry 2 persons , with today's storage batteries (4 kg/kwh) reaching 500 km seems inadequate or the reason, that a sufficient minimum reserve flight time must be provided any less requires a mayday call , that forces ATC to give priority. Even flying at altitude, the flight time with reserves is less than 2 hrs. Without a substantial increase in span, laminar airfoils, and optimal design, the range is not achievable.
New developments in boundary layer suction may overcome this problem . See University of Delft research. Have a tail dōng fēng in tropical latitudes.

Recharging times are going to be nightmare with lithium batteries. A modern fossil-fuelled commercial aircraft can achieve turn-round in half an hour.

Has anyone tried an e-gyrocopter yet? Still think they are the cinderella of the rotor aircraft industry. The other issue for me is, how much do we want vertical takeoff? There is a case for first responders, but for the rest of the world a 100 metre runway would be fine. Take offs from skyscraper roofs may still be possible, but I don't think apartment owners or office workers would want large amounts of traffic coming and going. Electric vtols are going to be noisy. OK for busy high income earners only, IMO.

@@travelbugse2829 There are several unmanned ones

@@sUASNews I will try to check them out - tks!

Add a parachute.

Conventional small airplanes can land safely without power. For example, airplanes like Cessna 150, 152, 170, 172, 182 and so forth. Typically they need 300 feet or so ... but that can be a dirt or paved road, often even a road with traffic on it, since you can lower yourself between cars to just above the road while flying at typical traffic speeds, then land between cars. Better is a school with a baseball or football field. In a message above I suggested that a better configuration for eVTOL (or other) "flying cab" aircraft would have the entire wings and canards capable of being rotated, which would make landing them in small places even easier ... a lot easier in fact, and in a much shorter landing area.

Not sure they were carrying any payload at all at the time?

​@@amazingdiyprojects From my observation and analysis, Lilium has not flown a full-scale prototype to date. As the video explains, the current prototype, the Phoenix 2, differs significantly in weight and the variable nozzle. The variable nozzle is critical for aircraft performance, as shown in Lilium's paper. Yet, the absence of the variable nozzle in Lilium's current prototype is seemingly missed by many other commentators.

So short the stock and get a billionair @@zhihenglou 👍

Check out Jeff Dahn's research. He's actively working on relatively high energy density batteries with a lifespan over 10,000 charge cycles. An actual test cell is demonstrating nearly zero degradation after thousands of cycles with a projected lifespan of a whopping 19,500 cycles!! The secret sauce is silicon carbide that allows for high energy density and long battery life.

The Lilium demonstator has flown with full transition of main and fore-wing now. Batteries are improving to allow the necessary performance and economics.

@@williamzk9083 Lilium has a design that potential customers far prefer to the likes of the Joby S4, Archer, Vertical VX4, etc. with their many exposed props flailing the air. Pass.
The efficiency and performance disadvantages are forgotten when the customer experience is superior. That's why regional jets are preferred over much more efficient turboprops. Batteries are only getting better and will make longer range flights a reality. It really is just a matter of time.

@@williamzk9083 "Batteries are improving to allow the necessary performance and economics" Practical examples please.
Or are you telling us your wishful thinking?

@@wolfgangpreier9160 There are laboratory devices available in small quantities and excess 400 what hours per kilogram. This is above the 300 watt hours per kilogram that Lilium needs to get its ranges objectives. In fact 500 hours per kilogram laboratory devices. Why don’t you spend some time researching batteries maybe take a positive mindset to things and stop listening to nonsense speculation by some aerodynamics Proffesor unqualified in the area of batteries, who wrote stuff five years ago.

Hi there,
Thanks for leaving so many detailed comments - I have read them all!
The final reserve energy, to which you are referring, is honestly a big elephant in the room, even for someone like me who is generally supportive of eVTOL development. There is no doubt that this problem will require changes to the regulation. Because removing 30 minutes (I do not think it is 20 minutes; I could be wrong here) from an eVTOL's cruise flight means there is essentially no battery energy left for revenue generation.
I think most eVTOL proponents are working on the assumption that battery technology will improve and regulations will change favourably. Whether these assumptions are realistic is another discussion (for example, if I am honest, battery improvement has been more sluggish in the last 5-10 years than I hoped).
Opinions change over time, often in light of new information. So you might see me change my mind about eVTOL, in one way or another!
Thanks again for all your comments. It is clear to me that you are very knowledgeable in this field.
Best,
John

@@zhihenglou thank you John. It has been refreshing to watch a video that does a rigorous and objective analysis. And I learned a thing or two which is the reason to watch.

The reserve energy has to be much enough for a 1) landing approach 2)go up when landing is not possible 3) go a certain distance further (I don't know how much) 4) make a second landing approach. That could easily take about 50% of the energy of today's batteries

@@jo21e6 hi, thanks for the reply. I am talking here about final landing reserve. For VFR, which in truth is the only realistic possibility for this concept, it is simply 20 minutes for helicopters. You need the amount of energy to fly to your destination, land and retain a nominal 20 minutes of energy at the ‘normal cruise’ consumption.
For IFR you require the reserve energy to: carry out a missed approach at the destination; cruise to the alternate; approach and land; plus xx final landing reserve. I don’t believe the final landing reserve has yet been specified for IFR EVTOL. It will not be less than 20 minutes but is a moot point because there is zero likelihood of any battery that could provide useful range plus IFR reserve. Note, no reserve “distance” can be specified, it just depends on how far away is the nearest suitable airport with forecast weather conditions compliant with regulated alternate minimums. Given that all the nearby airports to the destination are likely to have similar forecast conditions, the IFR reserve will, in practice, often end up doubling the energy requirement of these short range missions. “50% more” is unlikely to be enough anytime the forecast weather at destination requires the IFR reserve.
None of the start ups in this sector will admit to this elephant in the room.

@@XPLAlN How does other electric Airplanes deal with that? At example the Pipistrel Velis. It can fly about 40-45minutes with one charge. I don't think there's enough capacity for 20 minutes flight time

I completely agree, and this is my personal view as well. A cheap/compact ATOL/arrested landing ground module is much more feasible than all these VTOL concepts. If you are willing to accept aircraft carrier take off acceleration (3.5G), and Piper Cub take off speeds (14m/s), you can take off in under 10 ft. Relaxing the constraints a bit, you can take off/land in 20-40 ft, which would make it feasible to pack an entire ground module into a 20 or 40 ft container and install these ground modules anywhere where you have 1-2 cars worth of empty parking space and clear approach.

Nice to see someone is reading my commentary . The length of take off and landing runs need not be as short as you suggest and getting to such lengths imposes it's own energy demands which can be much lowered by relaxing the distances and minimum speeds somewhat more - at too low minimum speeds gust effects,wind gradient ,crosswind etc become more problematic also . Glider operational experience is the closest analog in my view , -the acceleration on a typical winch launch is not noticeably violent unlike aircraft carrier figures . Until the eVTOL 'rush' has played out I don't think the flaws in the whole eVTOL concept will be realized , if commercial operations do begin there will be pressure to operate in 'inclement' weather and the dangers of hovering in wild gusty winds with something having large exposed wing surfaces subject to blusters and 'upset' will become apparent. Helicopters can hover in 'weather' by not having fixed wing and tail surfaces -- normal aircraft have momentum and aerodynamic control - winged eVTOLs have the worst of both worlds.. The 'clear approches' issue is crucial and requires an apparatus to be above the local ground clutter of trees and buildings --ie elevated (ATOL should be EATOL -"Elevated Assisted T O L but putting "e" in front of something would be taken as "Electric' (even so eATOL is still much more doable than eVTOL and much safer quieter and more efficient ) cheers.@@jefferyzhang1851

He's a terrible con artist

Green politics and delusional denial of basic facts of physics as things scale. Dunning-Kruger ignorance coupled with wishful thinking.
Just look at current German politics, they want to electrify transportation plus heating which would require about 500GW additional power plus large amounts of minerals and materials like copper, lithium, neodymium etc but instead of expanding electricity production they are reducing it.
And no one even thinks about securing the minerals. No one is investing and building the new mines except for the Chinese. They don't care that solar output in the winter is low and sometimes PV might even be covered in snow when most power for heating will be needed. They don't care that wind power is negligible for weeks in the winter months in some years. They don't care that the storage needed will be gigantic if they don't use fossil fuel power or nuclear but they are neither allowing nuclear nor working on backup storage.
Green and electric is sexy and clean in the minds of the willfully ignorant woke left-green fascists and their sheep. The consequences will be great destruction of wealth. But in the end they will blame capitalism for their impoverishment and demand even more socialism and government intervention in the markets.

Because thats way more complicated. Hydrogen is a beast that is hard to tame. Batteries and electric engines are easy, as long as you stay below a certain power consumption and range

Me too. I've also wondered if these concepts could use spring loaded legs to help leap into the air?

This seems to be the approach that Eviation are taking, even though they're not an eVTOL company. Iterate the design, allow battery technology to mature.

18:1 is about normal for a modern jet airliner. A B787 perhaps 21:1.. The small wing area means parasitic drag is reduced.. The suction across the top of the wing ensures laminar flow.

@@williamzk9083 18:1 is in the region of a modern airliner but therein lies the issue, it is a bold claim for any eVTOL to achieve drag as low as an airliner. Saying “small wing reduces parasitic drag” is beside the point as the area reduction also reduces lift in the same proportion as drag so you cannot improve L/D that way.
The key parameter for good aerodynamic efficiency in the subsonic regime is high aspect ratio. The Lilium jet appears to have an aspect ratio that would be unremarkable on a typical light airplane (where 15:1 L/D would already be exceptionally good). They claim distributed thrust is going to make all the difference, but it is a stretch, and given the lack of evidence to back this rhetoric everyone should treat this number with great skepticism. The large array of ducted fans is extra drag. The bottom line here is those fans need to increase lift by 18 pounds, for every pound of nacelle drag, otherwise the airframe L/D ratio is degraded rather than enhanced. Nobody is denying that blowing the wing will increase lift - that isn’t new - but is that going to net you 18 pounds extra lift for every extra pound of drag? Particularly given it is meant to cruise at only 10% of rated power so high spillage drag is implied. It would be futile to try and estimate nacelle drag, suffice to say that those EDFs are likely to spill a lot of air in the cruise.

⁠​⁠@@williamzk9083….if 18:1 is normal for an airliner cruising with optimal spillage drag, how is the Lilium going to be able to match that with the extremely sub optimal spillage drag? The answer is it won’t. And why do you say “the suction across the top of the wing will ensure laminar flow”? The rhetoric rolls off the tongue easily but it requires a theoretical basis that may or may not be credible…

@@XPLAlN I don’t think there is any spillage drag as the Lillium jets electric ducted fans as there is no compressor that will need to reject excess air. It’s a fan and doesn’t have spillage drag.

@@williamzk9083 You get spill drag with or without a compressor. It depends on mass flow through the fan, airspeed and inlet area. The Lilium mass flow is 158 kg/s according to their white paper. They don’t state inlet area, but based on fan diameter they will need to spill 30 kg/s in the 300 km/h cruise. That is over 30 000 litres per second. The extra drag is anyone’s guess, which is effectively all they do. Coefficient of drag of the nacelle is, quote, “set at 0.017 because it is a lifting surface”, a number dropped into the paper without explanation. Just calling the nacelle a flap won’t make additive drag go away.
But that isn’t the biggest problem. The entire drag analysis of their white paper is full of holes. The claimed cruise L/D of 18.26 leads to an L/D max exceeding 20. Just no way is that credible with fixed gear at the aspect ratio of the Lilium. The Cirrus Vision Jet is a similar sized modern composite airframe with L/D max of 15 - gear up.
The canard is not included in the profile drag. Only its ‘flap’ is included. A plan view photo on their blog shows the flap is only 70% of the area of the canard assembly. Why is the rest not included?
The estimated ‘flap’ area is itself bogus. They simply multiply fan diameter by duct length and number of fans. But that ignores the nacelle surrounding the fan! Hence the ‘flap’ area used for the drag estimate is a clear and wilful underestimate.
I can get their induced drag estimate from the theory they cite. However, Lilium claim a span efficiency factor of 0.83 and I cannot get this without including the area of canard that is missing from the profile drag estimate. In other words, there is some real estate ignored to the benefit of the profile drag estimate that is then included to benefit the induced drag estimate. Dodgy.
Cooling drag is overlooked but will likely be significant. The all electric Pipistrel Velis has a 13% deficiency in L/D max to its piston sibling - due in all likelihood to the extra cooling air scoops.
Lilium estimate induced drag is only 36% of total drag in the 300 km/h cruise. But L/D max occurs when induced drag is 50% of total drag, so using Lilium’s claimed Cdo and efficiency factor the L/D max ends up being an astonishing 20.4! We are expected to believe this thing with its fixed gear is going to be more slippery than the best airliners out there.
A favourable estimate of the wetted aspect ratio is around 2.4 which suggests an L/D max of about 14 based on extrapolation from the known L/Ds of fixed gear airplanes (re Raymer’s Aircraft Design fig 3.6). With a modern composite airframe they may exceed 14 but getting to 20.4 is fantasy land.
The white paper in no way validates the suspiciously low drag count claimed for this concept. On the contrary, it shows all they did was ignore multiple sources of drag. Nonetheless, the elephant in the room remains the battery specific energy.

Yes, SUPER STOL is a lot better to handle and achievable than VTOL

Engines to the front, high lift design, some sacrifice in cruise but a totally valid and safe concept. 30 ft take-off and 50 ft landing.

​@@Ozbird-72Its electric Motors, you can probably program them for reverse thrust. Even shorter landing!

They want to takeof from a helipad, that's a big difference in usecase

@@jo21e6 a lot of super STOL aircraft could take off in the width of a helipad.

…first manned flight has quietly been slipped back to 2025. Service entry 2026, but that won’t happen either.

​@@XPLAlNwhy do you think that? What's so complicated to fly 5 more kilometers then they did at the first flight?

@@jo21e6 I think the first manned flight has been slipped back to 2025 because Lilium have now quietly admitted to it. Sorry if this does not answer your question but I don’t understand your reference to 5 km?

@@XPLAlN They flew a few meters a few years ago with no people on board, maybe a little mass.
It couldn't bee toooo complicated to make a short flight (5 km), why do you don't think that's possible?

@@jo21e6 I am not saying they can’t in theory fly 5 km in the certification prototype they are supposed to be building. I am saying they have already failed on the timeline, it isn’t built yet, they have delayed the first piloted flight to next year. The boss was “100% certain” that they would be certified and in service by 2025. When the guy with every single piece of information about this aircraft is 100% certain, and turns out to be 100% wrong, it should sound alarm bells with investors about the competency and/or credibility of the organisation. The first in service date was 2019. Lilium were quite insulting toward skeptics of that claim, and yet here we are with them 7 years behind their own schedule, so skepticism of all the failed projections so far has been been vindicated.

I fully accept your point that Lilium did not achieve full transition at the time stamp you mentioned. This is a fair comment, thanks for raising this point!

Isn't the speed more realistic with the Airbus manager?

@@jo21e6 sorry but it took me a while to figure what you meant. Here I presume you are referring to the former Airbus guy who became the boss of Lilium. This is referenced in the video but we are more than another year on from that now. The short answer is no. The reason is: as of March 2023 that guy was, quote “100% confident of service entry in 2025”. And yet 18 months on this has officially been superseded by the estimate of first flight in 2025 and the estimate for service entry in 2026. And yet still no prototype rolled out.
“Realistic” is subjective but dates are objective. The fact is that guy’s timeline from 2023 has been proven wrong. Imo, this delay could be seen as poor judgement but not inconsistent with “75% confidence”. But relative to “100% confidence” it is an abject failure and therefore the timelines provided by the ‘airbus manager’ have to be treated as unrealistic. I don’t think he even believes his own timeline, it is just what he has to say to prevent the stock market from cutting away. It is the ‘fake it til you make it’ mindset, it is ‘full self driving next year’ - every year for the last 10 years, it is right out of the Elizabeth Holmes ‘book of engineering the future’.

Who said Tesla is impossible? There are electric cars on the road since decades

Watching this in 2024, CATL has just introduced 500 wh/kg batteries. Might be an interesting option if they can mass produce them.

​@@derkatzenfuerst6077do you have a link to a video where catl shows it's tech?

Hi Marvi,
I agree that the lift motors of other concepts (such as the lift + cruise concept) become redundant during cruise flights. The lift rotors add drag, too, which other studies have found to be significant. So, in theory, we can expect a tilt concept, such as Lilium's, to have better aircraft performance.
But, on the other hand, the lift + cruise concept has a benefit: it can simplify the rotor design. Because you have dedicated lift rotors for hover flights and then you have dedicated thrust rotors for cruise flights. So you do not need to worry (as much) about variable pitch rotors or variable nozzles (see the explainer at 35:05).
Generally, I think it is too early to tell which eVTOL concept is the right one. After all, none of them are certified yet! So take comments about aircraft design, including mine, with a healthy pinch of salt. Let the test data speak.
Thanks for viewing the video and your comment!
Best,
John

@@zhihenglou i saw a drone where the propellers were attached to the wings like a normal airplane and the whole wing would tilt instead of the motors. that looks like it would be better.

The other thought would be that quoted range should not be considered as a metric of success. If the Lilium jet can fly only 50Km then it is already a success as it can fly from JFK to downtown New York, from Oxford to Cambridge, from Tallinn to Helsinki and many more routes globally that would be commercially viable. With increased range then just comes further market opportunities and further "success".@@zhihenglou

If there was a battery paradigm shift then we wouldn't need lilium because could make one.

the place where people are supposed to sit has a forklift battery in it.

like a diagram of a helicopter or f22?

He'd fail like he did in this video

@@EarthCreature. Unsure about who "He's" refers to -most likely John Lou but could be me in context - too criptic to tell . For my part I believe John Lou's assessment of Lilium is objective and mathematically valid -the paucity of actual information or data, even dimensioned drawings leads to unavoidable 'imprecision' in estimating anything but the magnitude of the 'power ratings from take off to wing flight modes' are certainly well enough known from calculation and actual released figures from lilium itself - we are not interested in potential errors to the third decimal place or even of a few tens , or perhaps hundreds of horsepower (KW etc) when the base figure is around 3300 installed HP . In comparison two seater sailplanes of the modern era consume around 5 to 10 HP at speeds of ca, 120 kph --and that figure has reduced by only two,three or less horsepower in the last 70 plus years --these are not even rounding errors compared to the gross wastage of power by Lilium and the sailplane performance is established by very careful actual flight test ,independently verified . Perhaps you (Earth Creature) are referring to the anonymous analysis in Aerokurier that spurred the "Architecture of..." paper that John L critiqued and which Lilium commissioned to debunk it's findings --they and John indeed took issue with some of the 'back of the envelope' figures in the first article published by Aerokurier and which that magazine also had independently assessed and broadly confirmed .
"A Joby bagholder' is an unflattering accusation unsupported by facts in my knowledge -he has separately critiqued various other eVTOLS having the fixed trailing edge/tilting leading edge wing mounted lift/propulsion props (eg Archer,Wisk, VX4 et al ) but again uses factual argument in doing so and some of the arguments against 'dual mode' props certainly apply to Joby as well - in fact the paper on the Joby S2 specifically condems the configuration that merely tilts the lift fans to become propellers in forward flight as being grossly over propped in forward flight (as is the Joby S4) -hence Joby condemns his own design
If you are 'talking' to me about MY critiquing 'this' (presumably JohnL's -above this, YT ) -then I will continue my evaluation of it when time permits but it will not be a refutation or anything of the kind if thatr is what you expect . The present 'situation' with regard to what are being termed "air taxis' or 'flying cars' is almost out of control and has lost engineering integrity to say the least - the corrupting inflence of easy money perhaps . I can post published evidence of my work in this field going back thirty plus years -long before the madhouse started or even before some of the present players were even born . The Wisk versus Archer lawsuit has finally been set down for a court hearing but the depositions by Wisk reveal a very sordid tale to say the least (for my part I think that they are ALL wasting their time and other's money on a basically flawed approach to the original aim of achieving better mobility - I likened their squabble and the whole undignified scramble for unnschooled investor's cash as like two bald men fighting over a comb - when It comes to actual intellectual property it can be shown from long dead patents that the overall configuration of any of them ,including Wisk/Archer has long been disclosed and not patentable --as to the electrical connections and so forth I have no specific skill in that area but would presume that any trained electrical engineer would arrive at similar solutions so that 'obviousness' would rule out 'ringfencing' type patents at least (these two things are the basis for the Wisk legal case) Poaching of each other's employees and 'leakage' of knowhow seems unavoidable amidst the dirty tricks and disloyalty involved. Efficiency as such, in terms of kilowatthours consumed in ten minute flights (a trivial cost) or the theoretical reliability against failure ("One in a billion"...ha ) of electrical components IF everything goes according to plan , seem to be 'non issues' . Perhaps power CAN be instantly shut down if any prop fails or birdstrike etc before a pylon can rip off the wing - perhaps the in flight fire danger is 'solved' (unlike some well known cases from 787 to laptops or scooters EVs or eVTOLs...) and maybe running out of power mid air "doesn't happen any more' ..... but also perhaps not.
This whole "eVTOL" thing arose from the appearence of model quadcopters using artificial stabilization and new batteries and motors ( the true inventive phase -40 plus years ago ) -- and the intervention of ,mainly MarkMoore - pushing "DEP" Distributed Electric Propulsion - itself often a misnomer as for example with Wisk Cora - PROPULSION ONLY on the centreline with distrtibuted SUSTENTATION (lift) along the wings -same for Autoflight et al -- the clumsy, inelegant and unsafe configurations that can ONLY be 'distributed' that result are grossly wasteful and unable to do anything significant to improve urban, or any other, traffic or transport problems even if only because of the extreme diseconomy embodied in them and inability to 'scale' to any meaningful market/operational size .
Whilst valuable of itself ,scrutinizing the misbegotten raft of copycat designs presently in contention ,for minor discrepencies in one or another calculated values is relatively inconsequential --they are all still bald men -the 'comb' is irrelevant ; HOW the almost THREE BILLION DOLLARS "invested' in these contraptions is going to be ever recouped - or written off more likely - or how personal aviation -the dream of what could be, at least can survive the 'wreck' to come is the real question.

joby never demonstrated its range just said they did. where is the demonstration of the range? they are both scams and vaporware

…yes, battery life is a big problem (I think he did touch on it). It is most likely that EASA will impose short battery ‘TBO’ based on the 700 hour limit they slapped on the Pipistrel with its relatively tried and tested battery technology. Compared with the equivalent piston engine, that battery replacement costs more than the 2000 hr engine overhaul and needs done 3 times as often. So even if a new type of battery becomes available for Lilium that can provide the performance, there will be no operational experience to prove its safety and longevity. They will have the devil’s own job trying to convince the powers that be to certify it, in this post 787 Dream-burner battery fiasco and post 737 MCAS debacle certification environment.

Ducted fans are known to be inefficient which is why the competitors don't use it. The test data is poorly documented so I'm not sure how you figured out the design is valid.

@@ziad_jkhan it is flying and looking functionally beautiful. That’s a valid design to me. may not be the most efficient yet, but they’ll improve it. May be they could strap 2 rockets on the top to get to 300 miles range :D

@@forest42821 It's a company that focuses on creating hype, hence the emphasis on beauty, not the actual science behind which, btw, has not been duely documented thus far. There is no mention concerning the load during the tests so nothing yet confirms it's validity. If you have to believe in it then it's basically just a religion.

@@ziad_jkhan I still have lots of doubt but yet I don’t want to count it out. Will it work if they can use a Quantum Scape or better battery?

Its not “valid” if it does not do what was promised to the folks who put up the cash as an investment. That is, Transport 5 people 300 km in 1 hour. Theranos’ ‘concept’ of doing multiple blood tests from a small sample of blood was a valid ‘concept’ given what CAN be done with small samples… but there is a wide gulf between a great concept, and something that is actually doable with the technology we have or can develop within the scope of a return on investment.

…a stream of videos about batteries isn’t going to get this thing certified.

@@XPLAlN
That's true. They expect it can be certified with existing battery technology. New batteries may open up more possibilities.

Hi Huck,
In your view, how much time can an aircraft save (compared to a regular car) for a 100-200km range?
We must consider that the aircraft must land at airports (or other designated areas). So passengers would need to spend time to get to their departure airport. And they need time to get from their arrival airport to their final destination. There will likely be a security check at the airport, too, costing more time. Cars do not have these time costs. Lastly, airspace is regulated, so we often cannot fly from point A to point B in a straight line. We might have to take less efficient air routes.
How would you weigh these factors in your estimation?
Thanks for your comment and the constructive discussion!

Another point that we should consider is the travel price. For an aircraft, we will need a professional pilot. Is it worth hiring a professional pilot for a 100-200km trip range?

@@zhihenglou Valid concerns. Lilium is targeting inter city vs intra city in order to increase time savings. Many other operators believe they can make money even flying within a city, Ehang, Joby, and Archer, for example. They plan to fly initially where there is already heavy taxi demand from downtown to the airport. Back to Lilium, a rough estimation of a 100 mile trip in a car to a nearby city could take 1.5 hrs with good traffic conditions. Flying you could make it in 40 minutes + time to-and-from airport/vertiport on each end. So, roughly a half hour of time savings based on some assumptions of how long the ground piece takes which we don't know for sure. If you add in that you can work while you fly, you're getting the experience of flying, and time savings could be greatly amplified in the case of heavy traffic, or water/mountain obstacles for example, the proposition gets better. A lot of these aircraft operators have preliminarily agreed to purchase the 640 Lilium Jets will have to work out appropriate pricing and pilots pay. Definitely will be challenges though in terms of infrastructure, atc, demand, pilot training, and pricing, but they should be solvable. Also, what I really want to see is what announcements Lilium makes in the coming months about closing the funding gap as they were down to 206 million Euros to start this year I believe.

@@zhihenglou Hello John, with newly released battery with energy density up to 500 Wh/kg from CATL can be operating range doubled (to 350km).

@@zhihenglou in a mountainous country, a lot!

Thanks, Chris!

Are they actually claiming that? I've seen claims of around $2,20 per seat-mile, quite a different figure and for longer trips it's in line with the $3 / seat-mile estimated for more traditional quadcopter-style e-vtol designs (given Lilium's much better cruise efficiency). And it's still an attractive price point if you're competing with helicopters.

That's it. They should be jailed a.s.a.p.. nearly a billion(!) wasted and stolen !

It's completely fraudulent and always has been.

No your wrong Lilium to the moon 🚀🚀🚀🚀🚀🚀

Faith>>>Facts

That what i love with Liliums concept instead of all others. Lilium is optimized for efficient cruise flight. Such every additional percent of higher battery capacity goes directly into cruise flight and thus range - while others still waste it in hover flight.

I think its fair to say that the batteries Lilium needs to achieve its performance objectives (range, VTOL) are already available. Over 300WHr/kg energy density, over 2500 W/kg power density and the ability to provide that power down to about 20% SOC state of Charge.
-What is missing is a battery that can do this economically. If this battery has a cycle life of 600 it is perfect for a car but the economics for a eVTOL suggest it would do a 60% charge every flight ie life of 1000 flights which might exhaust the batteries in l0.5 to 1 year pending on use. The batteries will still be usable but will have a 0.2% reduced range after each flight thereafter. I assume an aerial taxi will need to perform an average of 10 flight/day. It looks like there are batteries that may offer 3000 cycles possible so technical advances are needed to make economics viable.

@@williamzk9083 Thank you for elaborating on this, very helpful