The Incredible Technology Behind Jet Engines

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The pace of early aircraft development is still one of the most unbelievable human achievements. To go from the the Kittyhawk to jet planes in under 40 years was insane.

As an aerospace engineer who specialized in propulsion, this video is very nice. Very comprehensive way to explain in layman's terms an extemely complicated topic. A quick detail on turbofans, they are substantially quieter than a regular turbojets due to the air bypass, which is nother advantage and quite a massive on at that. Approved!

I've got a topic for you: the Internet! Everybody uses it but very few people knows _how_ it works: how the "network of networks" work and what it does really mean, the various services (e-mail, the Web, FTP), what's really a VPN.... It's a vast subject, but it should also be possible to reduce it to layman's terms without wandering too much or go too deep into the intricate technicalities - just like you did in this video.

This video provided about 75% of the information on turbine engines that we covered in my Aircraft Systems class way back in 1999, and did it in a lot less time. Lots of excellent information here, particularly for folks who aren't aviation/aerospace professionals. Well done, Simon.

Steam power technology would be pretty cool in a video. Locomotives, steam turbines, air ejectors.
Amazing what you can do with a bit of boiled water.

Small correction, at 4:12 you say the 'gas wants to diffuse'. This is the wrong term. The hot gas wants to expand, not quite the same thing. Diffusion is the net movement from a region of higher concentration to a region of lower concentration, nothing to do with temperature. Keep up the good work!

Excellent video but you neglected to mention the key technologies that makes modern jet engines so efficient. Thermodynamics requires the engine be run at higher temperatures to improve efficiency and the blades in the turbine section bear the brunt of these high temperatures. In some of these engines the blades actually run at temperatures ABOVE the melting point of the metal they are made from. The two key technologies that allow for this are are cooling channels within the blades to air cool them so they don't melt. The other key technology is single-crystal turbine blades. In short, typical alloys begin to deform under heat and stress and turbine blades are under a lot of heat and stress (from spinning so fast) so they want to elongate, or "creep" to use the metallurgy term. To get around this problem the blades where heat treated to directionally re-crystalize the grain structure which worked for a while until they wanted to run the engines even hotter. To solve that problem they figured out a way to make the turbine blades as a single crystal with no grains, hence no grain boundaries and therefore no creep. This is a key technology that is highly guarded trade-secret and only a few companies in the world know how to do this. Materials Science to the rescue!

More, please! There are other channels that cover similar topics, in similar easy-to-understand ways, but I appreciate your guys' take!

Love the new content, let’s hear about lasers and the future applications of them

Definitely a great format! Would love more of this

This RUclips channel, along with Biographics and Into The Shadows seriously deserve more subscriptions... absolutely outstanding content

Definitely like this new video idea Simon and Co! Would love a video on the inner workings of a standard/typical vehicle engine

Great overview! I'll add that high bypass turbofans actually get the majority of their thrust from the big fan in front, very little of it is from exhaust gasses.

21:00 The X-43 refers to the entire hypersonic test vehicle, not just the engine. It was an integrated system where the airframe itself functioned as part of the scramjet engine.

Great video, it could have been a proper 90min deep dive epic and we would all enjoy it!

Awesome how you successfully "expanded" on the basic concept of "suck - squeeze - bang - blow" for a basic jet engine.
Love Megaprojects content, look forward to more of "How it (really) Works", cheers Simon & team!

I want to give this video a mega thumbs up. I've been waiting on this one. I was hoping it was maybe like 4 hours, but I'll settle for 20 minutes! Thanks again for bringing this to us.

0:40 - Chapter 1 - The basic principles
1:10 - Mid roll ads
2:25 - Back to the video
9:35 - Chapter 2 - Turbojets & turbofans
14:30 - Chapter 3 - Turboprops & turboshafts
17:40 - Chapter 4 - The ones with no or few moving parts

I work in aviation and I absolutely love this video. We're actually having a CFM56-3 engine being built and we're expecting delivery within the next couple weeks.

This is more like what I thought Megaprojects would be like when it started. I do like the historical perspective you usually provide, but I also enjoy engineering/science focused videos.

This was great Simon! More of this style video please.

Great video -- like Tim Hunkin of "The Secret Life of Machines" you cut it in half to explain how things work. Keep more coming!

As an aspiring A&P with my powerplant written test in a week. This is a nice refresher

I’ve watched a few other jet turbine explanation videos but this by far was the best and easiest to understand. Thank you!

I think the two World Wars that would sadly occur in the first half of the 20th century definitely acted as a catalyst to powered flight, specifically the developments made around the time of World War II, as necessity is the mother of invention. Particularly the contributions of Sir Frank Whittle, and his efforts to create the first jet engine as a major innovation in the history of aviation. Receiving a patent for his design for the turbojet engine in 1930 and then founding Power Jets LTD in 1936 to further develop his ideas. Leading to the first successful jet engines being tested in 1937 and, although disputed, still one of the first jet powered aircraft, utilizing Whittle’s Jet engine in the Gloster E.28 & E.29, with them first taking to the skies in 1941. Obviously, Germany’s efforts cannot be ignored, with the Heinkel HE 178, designed by Ernst Heinkel. With his prototype jet aircraft first flying in August on 1939. The U.S. can certainly not be ignored in terms of contributions to the field of jet powered aviation, with the Bell P-59 twin jet engine powered aircraft that took its maiden flight on October 1st 1942. Although impressive, all three of these aircraft didn’t really see much, if any action during World War II but, what followed would set off the biggest change in commercial aviation in the history of jet powered flight with the advent of massive Jet powered passenger planes, like the British built De-Havilland Comet taking its maiden flight in 1952 and the American built Boeing 707, first taking flight in 1954 and entering into commercial passenger use in 1958 with PAN-AM. De-Havilland obviously then suffered issues with the Comet, due to its design leading to the forming of stress crack in the fuselage after cycles of pressurization and depressurization, causing it to break up mid flight on multiple occasions. This then caused the British to loose their lead to Boeing, McDonnell Douglas, Lockheed etc. However, the joint venture between BAC and Aérospatiale to design and build the magnificent Concorde. Quite possibly, one of the most advanced, safest and definitely, the fastest and most beautiful (imo) commercial aircraft ever build but, despite these accolades, it was technically a financial failure. Due to legislation restricting supersonic flight over land and its one crash that was as a result of a freak accident causing a fuel leek in the left wing fuel tank when a huge piece of a blown 747 tire from the plane taking off before it, being left of the runway, was then thrown up, hitting the left wing with sufficient force to rupture the left wing fuel tank causing it to burst the plastic welds. Fuel leaked out of the left wing and into the hot jet exhaust of the two left engines, igniting it and causing a fire that consumed the plane until it finally crashed only shortly after takeoff. That combined with increased fuel prices due to the then recent breakout of war in the Middle East, was the death knell in that magnificent aircraft’s illustrious history. Now we have the duopoly of Boeing and Airbus and innovation has seemingly stagnated and as an American, it pains me to see the serious decline of the once great Boeing Company. I hope that serious innovation will soon return to the field of passenger jet aircraft design and production.

fantastic video and format! It's always fun and interesting to learn how technology work on a basic level. Hoping for more of this type of content!

The name Frank Whittle comes to mind!
Oh and Rolls Royce! 👌

I love this style of video. Learning about how complex things work in a simple way is the bessst

Thank you for creating this video. It cleared up a lot of debates made in the comments of your other videos on jet engines

Avid listener to your channels, I love the idea of these ‘How this Works’. I’d also love to hear some cold read versions!

One of your clips is the T-9 test cell at Dyess AFB running an f101-ge102 B-1 engine. My old test cell. I now work for RR as an SME for the BA engines, specifically Pearl 700, 15, and now 10X. As mentioned, you were a little off on diffusion, but pretty good video... Think of the diffuser as the exit of the compressor, thats where we need the HIGHEST pressure, so we avoid a surge. Surge is bad. Overall, good job. Gas Turbine Engines are VERY complex devices, so to get decent info across in 15-20 minutes is excellent.

Yes, I would like to see occasional videos of this type. Thanks to this video I feel that I now know the basics of jet engines.

Hats off to all those highly-knowledgeable people who explain things to those of us outside the Knowledgeable group.

Nice video Simon, more of this type of material please!

I like the new format - and would also like some more of this type :) A mix between "Our own Devices" and "Real Engineering" :)

I think good candidate for this "series" would be stealth technologies. Air and maybe underwater, too. Very nice video, thanks .

A video all about the engines on the sr-71 would be awesome. They are truly a marvel of jet engineering and a wonder to behold for sure

Im here for the breakdowns on how thing tik, Id love for this to be a recurring thing on this channel :)

Nice video!
One topic to break down, the difference between an Afterburner and an Augmentor. This would further separate the differences between the turbojet and the low ratio, fully ducted, turbofan.
Thanks for the video.

17:27 holyy crap bro!! That is the coolest Bike ever!!

Totally something I wanted to know about. Thanks!

Really enjoyed this,look forward to many more

12:45 Bypass air is unfortunately not "free" thrust. The Fan part of Turbo Fans draw their power from the exhaust gases of the jet's turbine. This necessarily reduces the exhaust velocity of the engine. It does make the engine more efficient, though, since jet engines are most fuel-efficient the closer their exhaust velocity is to the aircraft's airspeed; they move a greater volume of air at a lower average velocity, producing more thrust for less fuel.

17:30 You could also mention the M1 Abrams being powered by the Honeywell AGT 1500 multi-fuel turbine engine. Jet-powered tonk go wheeeeeeee

Megaprojects usually has reasons for the thing being done or made, with failures and successes, plus budgets and maybe notable figures - i feel like this series would be difficult to really implement that without a longer format video, but its worthwhile either way

Great video. Very clearly explained. Nice.

My brother in law works on jet engines and he loves it, he's sent me some videos over the years of how complicated they are and testing etc, mental stuff.

If you threw a turbojet onto one of those styrofoam airplane models with the plastic propellers you get at the dentist office, you'd essentially have a turbo fan

Isn't it fun that even though it's a turbine, and not a bunch of cylinders, it still operates to the rule of "suck, squeeze, bang, blow"?

Great piece. Disappointed the Whittle jet engine wasn't discussed in detail although the axial engine "won" in the end, it's not like Whittle was a flash in the pan. Maybe another piece comparing the two.

It is crazy that you upload this around the time I begin studying to be an aerospace engineer you cheeky bugga

We want more of this kind of video

Do a video in this style on the colossal marine diesel engines found in the biggest container ships!

great video. looking forward to this as a series :)

Really like this idea for videos.

I hope for many videos in this series!

Well lets jet on then shall we?

I really like these dives into technology. Today I found out😂. Seriously though this could be a good addition to the channel. How about a dive in to electric vehicles?

9:55 Turbojets are thus called because they use exhaust gas pressure to drive their intake compressors. This is the similar concept behind an internal combustion turbo-charger system that uses the engine exhaust pressure to drive intake impellers. A non-turbo jet would not have an exhaust-driven turbine (or at least one that doesn't use an exhaust-driven intake compressor), and can be seen in many simple pulse-jets and ram-jets.

Well done Simon! I actually understood all that! Please keep up the excellent work!

Thanks, liked the new format!

Next to the gas turbine, another little thing that would have been worthy of note is the supercruise as you mentioned F22, Typhoon and Concorde. In particular for the concorde because only uses the afterburner at take off and transsonic region. Then it continues accelerating until cruise speed, without the afterburners.

Pretty cool Simon.
Maybe do the inter workings of a cell phone and or GPS

Jet engines can be broken down to 3 basic components: a sucker, a burner, and a blower. Great video!

Pretty good, especially appreciate the small but important distinction between airflow and gas flow once the air is mixed with fuel, sure that would have been picked up on my fitters oral exam if I got that wrong! No mention of centrifugal compressors (just showing axial flow which I guess is fair enough), or turbo fan bypass air also cooling the exhaust gas and reducing noise from the core making them better choices for passenger aircraft, but overall you achieved in 20 minutes what took a total of 6 months for my mechanics course to fully explain (though they only had OHP’s to work with!).

I really liked this one. I think it's a great idea. Maybe do one about the Internet next? ^_^

I share these types of videos to my friends so they can finally understand my fascination with these sorts of things

Great Video! I'm always looking forward to more!

Yes more like this please

I don’t know how many million miles I’ve flown in over 50 years, averaging a quarter million miles for at least half of them and I continue to marvel at two aspects: 1. How these many tons of metal (and now carbon fibre), people, fuel and cargo stay up there, and 2. Why these engines don’t melt down or compressor blades fracture?
I know the physics of lift and thrust but still think it’s magic…and a helluva leap in technological expertise: so many parts that could fail but don’t to an amazing level of reliability and how airframes can withstand the stress of severe turbulence I’ve experienced more times than I’d like to recall!
Thanks for this deep look at a true engineering accomplishment that most people overlook when they reflect on what marvels planes like the B747 or A380 “jumbos”.

A great video.👍👍.

Can you do a video like this on radar technology, possibly branching out on LIDAR/ hydro acoustic systems?

Another video idea is ultra mega examples of the simple machines we learned about in middle school/secondary school

This is a good video but should include the difference between one-spool and two-spool engines and the battle for efficiency between composite blades (GE/CFMI), three-spool engines (Rolls Royce), and Geared Turbofan (Pratt and Whitney). Also, the difference between an afterburner, which goes on a turbojet versus an augmentor which goes on a turbofan.

I was quite surprised they day I figured out that a Turbofan engine was basically just a giant air compressor and that the whole point of the central combustion chamber is to spin the fan to draw in bypass air. It was blitheringly simple!

As an avid AVgeek, I didn’t really learn much - BUT as an avid follower of your channels, I enjoyed the video nonetheless. Good job!

What makes jets so complicated and expensive is metallurgy, weight savings, and fuel control. The blades on the compressor are such a major component, where it used to be the turbine blades in the hot section for obvious reasons, all whilst giving longevity and safety and a lower rate of fuel burn. Something a jet engine will probably never be good at as they love to consume a lot of fuel.

That was a great explanation

Excellent video! Thank you for your hard work 🤘😝👍

Afterburners are frequently referred to as 'reheat'.
TheHarrier DID use thrust vectoring during the Falklands war to shoot down several Argentinian aircraft!!
Turboshaft engines are also being used to power smaller US Navy vessels.

Yeah, more like this please.

If you do a series about jet engines, please mention the coming generation of open fan jet engines - like the CFM RISE

One major design aspect that is a little beyond the scope of this video is nozzle design (and engine geometry in general). This is especially true if the air transitions between subsonic and supersonic anywhere in the engine, because unexpected shockwaves could cause damage or disruption, and because subsonic and supersonic gas flows behave very differently when it comes to compression and expansion.
Also, another odd place to find a turboshaft engine: a tank! Specifically the M1 Abrams

A&P working for an airline here... good job.

Warped Perception put a transparent housing on a small jet engine. Definitely worth a watch.

11:30 turbofan doesn’t get turned “for free”. It absorbs power from the turbines. It is simply more efficient at utilising that energy that a turbojet.

Wings are interesting with many types and profiles. Some for slow and some for very fast. Some stick out straight, some sweep back, few sweep forward and one X plane with one side swept forward with other side swept back.

I'm surprised the Batmobile replica Casey Putsch built wasn't mentioned. That has a turboshaft engine bolted to a GM 4-speed automatic that was modified to be manual shift only, and it's COOL. It was sold at a Barrett-Jackson auction, but I don't know who bought it or how much it sold for.

My husband and i love this kind of series. I feel like steam engines would be a really interesting one because of the time and scale of impact on the modern world...might be longer than 22 mins though lol

there was a couple experimental gliders made by darpa that used scramjet engines. usually brought up to initial operational speed by another helper aircraft or propulsion system, if not the atmosphere re-entry strategy for gained speed in the range of mach 10. there’s been talk of research and development to pursue the technology in both jets and also for hypersonic missiles. unrelated, the sr71 turboramjet combination engine should be an honorable mention here. and i’m pretty sure the x43’s engine itself was rocket powered instead of any jet involved, possibly using a scram affect with its airframe design for air flow on top of its propulsion. another possible mention is the unique new propulsion system on the experimental plane that we’re not entirely sure actually exists yet (top secret and all) lol

That was well done.

There are a couple of important points about the operation of all turbine engines (whether turbojet, turboprop, turbofan or turboshaft) which are the most common misunderstandings many people have about how these engines work. This is often a result of people who do understand how piston engines (whether petrol or diesel) work, but then try to apply this to turbine engines. Which is understandable, since both are internal combustion engines, and both use the same "induction, compression, combustion, exhaust" sequence - but accomplish this in rather different ways. The biggest single difference is that piston engines do this literally as a sequence (piston strokes doing each part, one after the other, in the order quoted above), a turbine does all of them continuously and simultaneously - in the same order but starting at the front of the engine and finishing at the back.
(1). In a piston engine, the majority of the oxygen in the air drawn into the cylinders is consumed during combustion, with very little oxygen remaining in the exhaust. However, turbine engines draw in far more air than is necessary for combustion alone. By this I am talking about the air which goes through the engine core and therefore through the compressor (not the bypass ratio which only applies to turbofan engines), so this is the same for any of the turbine engine varieties mentioned above. The vast majority of the compressed air is not used for combustion, and is used mostly to mix with and cool down the high temperature combustion products, though some is also routed into the cooling channels inside the turbine blades.
This is also why afterburners can be fitted to the engine downstream of the turbine stage - because the exhaust still has enough oxygen content to support further combustion of fuel. If all the oxygen was consumed in the core combustion section, an afterburner on a turbojet would not be possible.
(2).In a piston engine, the pressure inside the cylinder increases a great deal when the fuel-air mixture is ignited, and it is this large pressure increase acting upon the piston which generates the power. However, in a turbine engine the highest pressure is just downstream of the compressor known as the compressor discharge pressure. The combustion of fuel does not increase the pressure at all. What does increase is the volume and the velocity of the gases, since the combustion products from the burning fuel are all gases, and of course the combustion adds a great deal of energy.
This is also true for rocket engines, in which the highest pressures are just downstream of the fuel pumps: This pressure is what forces the fuel and oxidiser through the injectors at the top of the combustion chamber. A common error is the assumption that the pressure increases in the combustion chamber of a rocket engine - but if this was the case, then the higher pressure would prevent the propellants from flowing through the injectors and into the combustion chamber. What actually happens is similar to the combustion chamber of a turbine engine - the volume and velocity of gases both increase enormously, and are then accelerated even further when the hot combustion products flow through the nozzle. The difference being that the temperature can be much higher, since there is no turbine downstream of the combustion chamber in a rocket engine.

Thanks! That was great :)

"Shoutout to today's sponsor, Hair Club For Men. I'm not just the president, I'm also a client."
Simon, you have a gorgeous bald head. I'm jealous. I shaved mine, and it looks partly like a relief map of the moon, and partly like a missile testing range. It kinda looks like excavator training-school grounds.

Our lecturer explained the compressor turbine relationship as trying to pick yourself up by you shoelaces, but actually succeeding. Obviously, adding fuel is the tric, but you get what I mean.

Rather than "normal" turbojet vs turbofan, one might identify them as pure jet vs turbofan. The distinguishing feature of the pure jet is that all of the air entering the engine passes through the compressor, combustion chamber, and turbine(s) and thrust is derived from the energy remaining in the gas after exiting the turbine section. The distinguishing feature of the turbofan, by contrast is that the turbine section is designed to extract more energy from the exhaust, converting it into the mechanical energy needed to drive the fan, reducing the thrust contributed by combustion gases exiting the turbine section. In a high-bypass turbofan, the goal is to extract as much energy as possible from the exhaust gas so that almost all of the engine's thrust comes from the fan's interaction with the bypass air.
FWIW: a jet engine compresses air for a few reasons... the increased pressure improves combustion, so fuel burns more completely, but just as importantly, when the gas temperature is raised by combustion, it wants to expand; the higher the pressure at which this occurs, the more work this equates to.

I would love to see a deep dive into how torpedo's work. On the surface they seem rather simple but if I am not mistaken they are actually quite complex. At least modern ones are I would imagine.

If you are looking for any other non-aircraft uses of turboshaft engines, they are often used as back up emergency generators in situations where you need it to kick in fast - gas pipelines in remote areas is one such use. The benefit is that the turboshaft engine can go from start to full power in an incredibly short time. One of the more querky applications, similar to the video's example of a motorcycle, was done by Pratt & Whitney Canada in 1967. They put a turboshaft engine in an Indy 500 car. Unfortunately it never finished the only race it was in (and it was leading at the time) because a component of the transmission burnt out. It could not handle the immense acceleration and power. Sadly the ruling body modified the rules in a way they made them unworkable in subsequent years.

8:53 The illustration labeled 'Rolls-Royce Pegasus' - isn't. That's the Yak-38's engine layout, with separate lift engines. The Pegasus is a 'four-poster' with two nozzles after the fan and two after the turbine. Also, the Harrier can use thrust vectoring for maneuvering - the USMC developed the tactic of 'VIFFing' - Vectoring In Forward Flight to take advantage of the thrust vectoring to make the Harrier even more agile.