Great video, showing also the so important grinding operation, done with Tyrolit creep feed grinding wheels :-) ! Proud to be part of this great Leap engine manufacturing process!
I remember the days, when a lot of jet engine and rocket engine parts manufacturing processes were top secret under. Some of those key manufacturing steps are still protected as classified under Missile Technology Control Regime (MTCR) even for parts destined for the civilian aerospace industry. For this reason, I find videos like this a miracle of freedom of information.
Well, the overall production steps is kind of well-known at this point thanks to globalization. The trade secrets are the formulas, specific design of tools/procedures/etc, steps unique to each company, institutional knowledge, basically the small details making up the vague production steps in the video.
The process shown here is more or less same as car engine production. This is PROCESS. The real composition of metarials, desings, alloy metallurgy are obviously hidden. Hell no body even knows the exact angles at which blades cuts air. 😅
The title is wrong but they did mention it in the video. Tbh - these guide vanes get about as hot as the turbine blades so the manufacturing process overall probablybisn't that much different. Of course I'd still like to see it!
@@rkan2 I was an engineering intern at a plant that did the first few steps in the production of blades and vanes. We forged titanium and inconel rods up to the first machining step before we sold and shipped them out. It was an interesting process, and to see how something that sounds simple can quickly turn complex. For example how exactly does the metal flow in the die? If it folds over on itself it is problematic, not just because it can create voids in the part. Or did you think about the expansion, and therefore contraction after it cools back down? How does that influence the forging dies? Definitely was the most interesting job I've had.
@@m_a_t_t6098 Before you sold and shipped them out? May I enquire which manufacturer (or engine) if you are talking about "selling"? If you cannot tell maybe you can mention if it was current production turbine engine or not.
@@rkan2 we sold the forged blades or vanes. Some of the customers required you to sign an NDA so I can't tell you specifically. I think they were both current production and some were for replacement parts for slightly older engines.
It's interesting how "artisanal" it feels (despite the abundance of high tech tools) compared to high volume manufacturing such as car components, no wonder these engines cost so much.
Many test and certifications add a lot to the final cost, plus the extra care to make an Aviation Grade component with all the CoC and Form1 to be acceptable.
@@WilliamHelstad COC mean certificate of conformity and Form1 is an EASA or/and FAA document that certifies that the part is approved to be installed on an aircraft. It's illegal to install a part without CoC or Form1 and the aircraft becomes AOG due to loss of airworthiness.
We 🤔 should wonder why the cost of Industrial Foods and Beverages are so much because most of them are not healthy Foods!. But not Safran, GE, RR,...Jet Engines. 🤗🍎🍏Sure, these Jet Engines are reasonable costs for us to enjoy our Flights more safety, daily.🍹🍹🍹
@@WilliamHelstad as you move up the performance curve to approach what is just possible, the options to design around the problems become more limited and the safety factors smaller, hence you must compensate with careful process control and inspections.
Considering that the part is a single piece of metal (in a complex shape) I'm a little surprised that it requires so many steps to cast. No wonder additive manufacturing was generating so much hype some years ago.
Great video. Whenever I'm a passenger in a plane, I think about a blade that self destructs and causes massive engine failure and explodes and we're all gonna die. Now I feel better.
to be honest, in this highly connected modern world full of high level of complex technical ingenuity, most of the engineering achievement is result of several countries contributions combined.
And yet, this is nothing compared to the Safran episode titled: _How turbofan jet engines were made in the ’80s 🇬🇧 | Safran_ The metrology and process is almost more complex (at least, what's shown, perhaps bc they can be more explicit about retired techniques). But it's ABSOLUTELY AMAZING. Manufacturing to 100-thousandths of an inch!!! Or μm!!
Well done, this is the best vid of this process that I've seen to date! Full process spectrum in there, design, mold, investment cast, cmm, ndt. 👍 Give whoever made this an attaboy!
I am a investment casting mould manufacturer & I know how much work has gone in designing & manufacturing of both core & cavity moulds... Kudos Safran🎉🎉🎉🎉
Came here by chance while looking for information on how single crystal jet turbine blades are manufactured. This was one of the most interesting videos I have watched. What a process! Now off to find what brought me here.
That was fun and detailed enough to be a good introduction to a number of complementary technologies. You've raised investment casting from an art to a science here, particularly with the modelling of the complete wax assembly and the heat flow through the material.
Amazing video, super informative. Just imagine the blade is one of the several parts that goes into an engine. No wonder it is such a complex technology.
Manufacturing at it's best. Love the video, fun, informative, educational and engaging even for people who wouldn't give a f* for complicated processes- Nice!
It's incredible to think that eventually such complex parts will be 3D-printed at a much lower cost and possibly with even more complex features. Can't wait to be there.
@@moriarteaa4692 they already print rocket engines, and those have very complex small features. Besides, I'd be wary of predicting we can't do something eventually.
@@moriarteaa4692 yes and no. I suspect you may used to FDM 3D printers which, really, are hobby toys. Industrial 3D printers can produce titanium alloy parts using lasers, it's a totally different class of machine with a totally different price range. Combined printing / machining already exists as well but it may not allow you to make the part we just saw. Hard to tell. DMG Mori has been making that kind of machine for some years now : ua-cam.com/video/Fr_PneeyO34/v-deo.html you can print, machine, print again, etc... which means you can machine areas of a part that will be unreachable in the final part. My initial comment wasn't so much about technical possibility, but adoption and the certification of parts produced that way.
As Indian 🇮🇳 I imagining how challenging it was for our R&D to develop our first indegenius jet engine named "Kaveri" with such small budget Now India is in agreement with France USA UK to develop powerful jet engine
It's not necessarily an extremely hard task to develop a jet engine, but to make it to run reliably for a very long time is the secret. It's all in the complex material technology
Fantastique! Thank you for sharing. The engineering rigor that goes into keeping our engines burning and metal cans flying is nothing short of miraculous.
Looking here from America well, I am very impressed with the factory. I will never take a granted for things made out of investment cast that is just unbelievable. You guys do a phenomenal job and water clean factory and everybody’s safe got respirators on and the right close they wouldn’t be here in America. They would tell you to breathe that dirt again excellent I never knew how they made the inner parts of the turbine blades. I work on turbine engines and now I’ve learned something. Thank you very much for putting this video up. Excellent.
That’s why china is still working hard to do a advanced jet engine. Even they do lots of reverse engineering, the complexity and skill involved is way more difficult than simply getting the right dimensions. Amazing!
I think it's time we acknowledge that China's capabilities are way above reverse engineering by now. The education in China has become a lot better over the past decades, and by now China is among the strongest countries in reporting new patents. Also because pretty much every company in a first world country is too greedy they just outsource everything, so it's Chinese engineers doing a lot of the work already.
@@kalbsleber You might make something look as nice but then you would probably need to optimise it so that it was perfectly balanced at 11,000 rpm and could run continuously at 1,000°C while each one was being subjected to a stretching force equivalent to lifting a double-decker bus.
All good but the part being manufactured are segments of Nozzle Guide Vanes (NGV) and not turbine blades as you mention in the video. NGV's are fixed parts and the blades slides behind this leading to rotation of disk and shaft.
It's interesting to see some of the many steps in manufacturing and quality control for a part that is so small. I'm curious what a part like this would cost?
I heard from a CEO of engine manufacturer on interview that just each signle blade could cost minimum 5000$, and if we suppose like 40 of them in a single turbine, it can cost like 200k$ per turbine...
The best UA-cam videos Ive ever watched was three episodes on how the British built the Rolls Royce engine. What you never got to see was how they formed the high temperature fan blades. They use some kind of method that blows the blades up like a balloon. Totally a company secret. After that I got interested in how they make those crazy light, big headed golf drivers. I looked and could never find anything online about that process either.
Actually, it's called "brazing"... and is very common to close openings in the casting. This video uses some terminology that might be slightly simplified, but in essence, the "solder" is the brazing filler material, similar to the way a pipe fitter uses solder to braze water pipes together. You'll note that those parts are not on the hottest sections of the part, however.
@@williamsteele Thank you for replying, but as the video is entitled "The birth of a turbine blade" and often speaks of " turbines", where blades handle high flame temperatures, rather than blades on "compressors" where temperates still rise due to compression ratios, I thought that " the solder or even the brazing I know of", would be struggling to operate at those turbine temperatuires. I suppose the fusing brazing properties can be used on higher melting materials. Guess all materials can be brazed as you said. Apologies for picking up on the soldered part!
@@carmelpule1 So let me clarify a little more... when I said they're not in the hottest part, I actually mean of the actual turbine blade itself... those brazings are done on the bottom side (where the coolant side is) so they're not in the direct flow of the combustion gasses. That means they don't see the highest temperatures. Also, the metals actually do not experience the high combustion temperatures due to the cooling system, which allows a coolant (compressed air) to flow out and along the surface of the blades, keeping the hot gasses from actually coming in to direct contact with the blade.
@@williamsteele Thank you for replying. my brother and I made a few model jet engines and making the diffuser, the slowing down of air to keep a stable flame, the hot stator, and the turbine was not so easy, but they all worked for a few hours, as we did not have the right materials, nor did we cool the blades apart from feeding the bypass air to the hot stator. Seeing your video I just marveled at the method of producing what was shown, and I could imagine the responsibilities which you carry. Thank you for your assistance and all the best with your very interesting work. I am an old man now and did work on the installation of the first British Naval ship that had jet engines installed, HMS Exmouth and it had two Proteus and one Olympus jet engine. I worked on the overtemperature protection system, back in 1963 maybe. That was a long time ago, Thank you for respecting me with your replies. All the best.
i have perhaps missed something but anyone has understood at what point at how to get rid of the wax ? I guess during the heating, then why the ceramics keeps its shape if the wax is gone ?
Zero speed, it's a stationary part but the first part touched by combustion gasses so the hottest piece in the engine. The turbine blade behind it will get nearly as hot and turns around 20,000 rpm so has a force like a bus hanging off it.
I was wondering that too, and I think I figured it out if you look closely , part of the ceramic core is still sticking out when it comes out of the wax injection mold, so once it gets dipped in the ceramic slurry the outer part of the mold binds to the parts of the cores that are sticking out of the wax.
best corporate video ever made.
The style of this video - especially the interaction between the models and the narrator, was really watchable. Well put together!
they interrupted the video too many times.
Its how they use to be back when we try to inspire children.... Something that is hardly done any more.
Both informative and fun. Not sure why UA-cam's algorithm sent me here, but I'm looking forward to the next video Safran!
Me two
It seems UA-cam decided, that you need a new Rafale jet fighter. So it would be nice to let you know how turbine blades of its engine are made.
@@Weisior Dear Santa Clause: I want a Rafale jet fighter for Christmas.
Great presentation! Shows how much of advanced technologies are needed for a single component.
Great video, showing also the so important grinding operation, done with Tyrolit creep feed grinding wheels :-) ! Proud to be part of this great Leap engine manufacturing process!
I remember the days, when a lot of jet engine and rocket engine parts manufacturing processes were top secret under. Some of those key manufacturing steps are still protected as classified under Missile Technology Control Regime (MTCR) even for parts destined for the civilian aerospace industry. For this reason, I find videos like this a miracle of freedom of information.
Well, the overall production steps is kind of well-known at this point thanks to globalization. The trade secrets are the formulas, specific design of tools/procedures/etc, steps unique to each company, institutional knowledge, basically the small details making up the vague production steps in the video.
@@jac1207 you are right. Think that even you cannot buy these quality wax easly. It has district rules for each country and market.
The process shown here is more or less same as car engine production. This is PROCESS. The real composition of metarials, desings, alloy metallurgy are obviously hidden. Hell no body even knows the exact angles at which blades cuts air. 😅
The component isn't a turbine blade - it's a nozzle guide vane!
The title is wrong but they did mention it in the video. Tbh - these guide vanes get about as hot as the turbine blades so the manufacturing process overall probablybisn't that much different. Of course I'd still like to see it!
@@rkan2 I was an engineering intern at a plant that did the first few steps in the production of blades and vanes. We forged titanium and inconel rods up to the first machining step before we sold and shipped them out. It was an interesting process, and to see how something that sounds simple can quickly turn complex. For example how exactly does the metal flow in the die? If it folds over on itself it is problematic, not just because it can create voids in the part. Or did you think about the expansion, and therefore contraction after it cools back down? How does that influence the forging dies? Definitely was the most interesting job I've had.
@@m_a_t_t6098 Before you sold and shipped them out? May I enquire which manufacturer (or engine) if you are talking about "selling"? If you cannot tell maybe you can mention if it was current production turbine engine or not.
@@rkan2 they won't tell you
@@rkan2 we sold the forged blades or vanes. Some of the customers required you to sign an NDA so I can't tell you specifically. I think they were both current production and some were for replacement parts for slightly older engines.
I think on of the best "how it's made" videos I've ever seen!! great work
It's interesting how "artisanal" it feels (despite the abundance of high tech tools) compared to high volume manufacturing such as car components, no wonder these engines cost so much.
Many test and certifications add a lot to the final cost, plus the extra care to make an Aviation Grade component with all the CoC and Form1 to be acceptable.
@@WilliamHelstad COC mean certificate of conformity and Form1 is an EASA or/and FAA document that certifies that the part is approved to be installed on an aircraft. It's illegal to install a part without CoC or Form1 and the aircraft becomes AOG due to loss of airworthiness.
We 🤔 should wonder why the cost of Industrial Foods and Beverages are so much because most of them are not healthy Foods!. But not Safran, GE, RR,...Jet Engines. 🤗🍎🍏Sure, these Jet Engines are reasonable costs for us to enjoy our Flights more safety, daily.🍹🍹🍹
@@WilliamHelstad as you move up the performance curve to approach what is just possible, the options to design around the problems become more limited and the safety factors smaller, hence you must compensate with careful process control and inspections.
Considering that the part is a single piece of metal (in a complex shape) I'm a little surprised that it requires so many steps to cast. No wonder additive manufacturing was generating so much hype some years ago.
This was fun, and also fascinating. The intensity of the complexity and detail on which successful production depends is quite amazing.
Great video. Whenever I'm a passenger in a plane, I think about a blade that self destructs and causes massive engine failure and explodes and we're all gonna die. Now I feel better.
Fascinating, I never knew how much effort went into each turbine
A beautiful blend of old world and cutting edge technology working in harmony.
Turbine Blades....one great turn...deserves another.
Beautifully produced communication.
More of these "making of" videos please !
French engineering is excellent! Lots of love from a German to my French brothers and Sisters this festive season
to be honest, in this highly connected modern world full of high level of complex technical ingenuity, most of the engineering achievement is result of several countries contributions combined.
Whoever you hired to direct this video deserves every penny.
Amazing film. Super informative, agile, and fun. Beautiful production, narrated, and incredibly well edited as well.
It’s been a remarkable video ever.
And yet, this is nothing compared to the Safran episode titled:
_How turbofan jet engines were made in the ’80s 🇬🇧 | Safran_
The metrology and process is almost more complex
(at least, what's shown, perhaps bc they can be more explicit about retired techniques).
But it's ABSOLUTELY AMAZING. Manufacturing to 100-thousandths of an inch!!! Or μm!!
Well done, this is the best vid of this process that I've seen to date! Full process spectrum in there, design, mold, investment cast, cmm, ndt. 👍
Give whoever made this an attaboy!
Best video! hats off o the director, producer, actor
I am a investment casting mould manufacturer & I know how much work has gone in designing & manufacturing of both core & cavity moulds... Kudos Safran🎉🎉🎉🎉
So cute! 0:21 Damien: “Who, me?”
1:30 The mold for casting is designed to create four parts. How cool!
Wow this video is really well put together!
For me as an engineer still facinating and very interesting!
Honestly, with all the hype about metal 3d printing, this is as impressive.
great video!
Came here by chance while looking for information on how single crystal jet turbine blades are manufactured. This was one of the most interesting videos I have watched. What a process! Now off to find what brought me here.
To whom much is given, much will be required. The tremendous effort and expense that go into making these small parts isn't for nada. :)
The processes and this video were fascinating!
That was fun and detailed enough to be a good introduction to a number of complementary technologies. You've raised investment casting from an art to a science here, particularly with the modelling of the complete wax assembly and the heat flow through the material.
Loved the production! Very informative! It takes A LOT of work to make a plane stay in the air.
Wonderful video. It helps to illustrate why jet engines are so expensive.
Okay now I know why jet engines are so costly. This was so surreal to watch and understanding everything the video talks about is really satisfying
What a fantastic video! Its insane the brilliant people behind every piece of our society! This stuff just blows my mind!
Amazing video, super informative.
Just imagine the blade is one of the several parts that goes into an engine. No wonder it is such a complex technology.
Such a cheery narration.
Manufacturing at it's best. Love the video, fun, informative, educational and engaging even for people who wouldn't give a f* for complicated processes- Nice!
It's incredible to think that eventually such complex parts will be 3D-printed at a much lower cost and possibly with even more complex features. Can't wait to be there.
Yeah maybe, but I dont think we will get such a high precision in 3d printing
@@moriarteaa4692 they already print rocket engines, and those have very complex small features. Besides, I'd be wary of predicting we can't do something eventually.
Well this isnt Rocket science but aviation
Im sorry you May be right, but I am not sure how to get the position tolerances needed with 3d printing. Maybe a hybrid solution with machining?
@@moriarteaa4692 yes and no. I suspect you may used to FDM 3D printers which, really, are hobby toys. Industrial 3D printers can produce titanium alloy parts using lasers, it's a totally different class of machine with a totally different price range.
Combined printing / machining already exists as well but it may not allow you to make the part we just saw. Hard to tell. DMG Mori has been making that kind of machine for some years now : ua-cam.com/video/Fr_PneeyO34/v-deo.html you can print, machine, print again, etc... which means you can machine areas of a part that will be unreachable in the final part.
My initial comment wasn't so much about technical possibility, but adoption and the certification of parts produced that way.
Very informative video and good storytelling.
As Indian 🇮🇳 I imagining how challenging it was for our R&D to develop our first indegenius jet engine named "Kaveri" with such small budget
Now India is in agreement with France USA UK to develop powerful jet engine
It's not necessarily an extremely hard task to develop a jet engine, but to make it to run reliably for a very long time is the secret. It's all in the complex material technology
@@jaso5114 not to mention to make a lot of it on a consistent quality. So your QC and QA needs to also be thorough.
This is a fascinating insight into how computing (CFD), tooling technology and materials science have combined to LEAP fuel efficiency over the years.
Thank you, that was awesome 😊
Very informative. The Video covers stator blades(vanes) . Looking forward to see the Rotor blades video.
Fantastique! Thank you for sharing. The engineering rigor that goes into keeping our engines burning and metal cans flying is nothing short of miraculous.
Tons of work, steps, equipment, and people involved.
Great video, I really enjoyed it!
This gives you an insight into why aircraft parts are so expensive.
thank you. This was beautiful
6:31 God DAMN thats a clean cast holy fucking shit
Yeah that's amazing!
Looking here from America well, I am very impressed with the factory. I will never take a granted for things made out of investment cast that is just unbelievable. You guys do a phenomenal job and water clean factory and everybody’s safe got respirators on and the right close they wouldn’t be here in America. They would tell you to breathe that dirt again excellent I never knew how they made the inner parts of the turbine blades. I work on turbine engines and now I’ve learned something. Thank you very much for putting this video up. Excellent.
Loved this
That’s why china is still working hard to do a advanced jet engine. Even they do lots of reverse engineering, the complexity and skill involved is way more difficult than simply getting the right dimensions. Amazing!
I think it's time we acknowledge that China's capabilities are way above reverse engineering by now. The education in China has become a lot better over the past decades, and by now China is among the strongest countries in reporting new patents. Also because pretty much every company in a first world country is too greedy they just outsource everything, so it's Chinese engineers doing a lot of the work already.
Great, enjoyable video. Loved it. On long haul flights, few passengers think about the mazing technology that keeps those engines humming.
Crazy amount of effort for one small part. It sounds expensive.
@@kalbsleber You might make something look as nice but then you would probably need to optimise it so that it was perfectly balanced at 11,000 rpm and could run continuously at 1,000°C while each one was being subjected to a stretching force equivalent to lifting a double-decker bus.
Wow! Much more complex than one might think and I'm a retired pilot!
Computer, mold, wax,ruler. Looks easy enough for a weekend project.
Just very precision of techs, and very well presented 👍👍
Love this video !
With all those stages and measurements and hand work and personel involved, it's no wonder they cost a fortune each.
This was like how it’s made on steroids!, amazing video.
Шикарные изделия!!! А Главное !!! Очень интересный процесс!!! Интересные Материалы!!!
All good but the part being manufactured are segments of Nozzle Guide Vanes (NGV) and not turbine blades as you mention in the video. NGV's are fixed parts and the blades slides behind this leading to rotation of disk and shaft.
Very nice movie. Proud to make similar parts, also SX/DS.
Just amazing! If students can all watch this, we should have more STEM fans, and a whole lot of engineers
thank you for setting Safran factory in India
when the wax is melted out how are the cores held in the remaining ceramic mold?
Melted and vaporised
Sorry but the titles wrong. It's an NGV (nozzle guide vane), not a Turbine blade. The commentary says so as well.
wonderful video ❤❤
In the shake off operation stage, what is the machine used to and how does it work? Any data about the machine?
It's interesting to see some of the many steps in manufacturing and quality control for a part that is so small. I'm curious what a part like this would cost?
I heard from a CEO of engine manufacturer on interview that just each signle blade could cost minimum 5000$, and if we suppose like 40 of them in a single turbine, it can cost like 200k$ per turbine...
Its actually a Nozzle guide vane, not a Turbine blade. Turbine blades have to with stand high rpm, these are stationary.
damn, i know where im going to get my turbine blades from good job.
The best UA-cam videos Ive ever watched was three episodes on how the British built the Rolls Royce engine.
What you never got to see was how they formed the high temperature fan blades. They use some kind of method that blows the blades up like a balloon. Totally a company secret.
After that I got interested in how they make those crazy light, big headed golf drivers. I looked and could never find anything online about that process either.
@6:53 the part is being hand sanded. Why by hand and not an automated machine?
More videos like these please 😀
was the first video; searching under: single crystal super alloy turbine blades.
i'm very happy with what i found
It's a vane...it's static; a blade is a rotative. The cover plates are brazed on not soldered on.
Well done nice work and nice technology 🏅🏅🏅🏅🏅
What type of the ceramic that you use? Can you give the link information more?
Thanks for sharing this
does the welding process not cause a the formation of equaxed grains
I’ve always wondered how these were made. I assumed casting, but wasn’t sure how to properly control the metallurgical changes.
this video is excellent.
Interesting video. It's been said before in the comments , this isn't a blade , it's a vane ( a non moving part).
I like how the still most capable CAD software (CATIA) didn't undergo a GUI update for 20 years
That is why I use UGS NX, way better gui.
Did you put a camera in that heater thing?
Excellent video but I do not think that at 8:19 those blocking parts which operate at high temperature are attached by using a solder bead!
Actually, it's called "brazing"... and is very common to close openings in the casting. This video uses some terminology that might be slightly simplified, but in essence, the "solder" is the brazing filler material, similar to the way a pipe fitter uses solder to braze water pipes together. You'll note that those parts are not on the hottest sections of the part, however.
@@williamsteele Thank you for replying, but as the video is entitled "The birth of a turbine blade" and often speaks of " turbines", where blades handle high flame temperatures, rather than blades on "compressors" where temperates still rise due to compression ratios, I thought that " the solder or even the brazing I know of", would be struggling to operate at those turbine temperatuires. I suppose the fusing brazing properties can be used on higher melting materials. Guess all materials can be brazed as you said. Apologies for picking up on the soldered part!
@@carmelpule1 So let me clarify a little more... when I said they're not in the hottest part, I actually mean of the actual turbine blade itself... those brazings are done on the bottom side (where the coolant side is) so they're not in the direct flow of the combustion gasses. That means they don't see the highest temperatures. Also, the metals actually do not experience the high combustion temperatures due to the cooling system, which allows a coolant (compressed air) to flow out and along the surface of the blades, keeping the hot gasses from actually coming in to direct contact with the blade.
@@williamsteele But that filler doesn't look very metallic.. what kind of filler metal is liquid at room temperature?
@@williamsteele Thank you for replying. my brother and I made a few model jet engines and making the diffuser, the slowing down of air to keep a stable flame, the hot stator, and the turbine was not so easy, but they all worked for a few hours, as we did not have the right materials, nor did we cool the blades apart from feeding the bypass air to the hot stator. Seeing your video I just marveled at the method of producing what was shown, and I could imagine the responsibilities which you carry. Thank you for your assistance and all the best with your very interesting work. I am an old man now and did work on the installation of the first British Naval ship that had jet engines installed, HMS Exmouth and it had two Proteus and one Olympus jet engine. I worked on the overtemperature protection system, back in 1963 maybe.
That was a long time ago, Thank you for respecting me with your replies. All the best.
i have perhaps missed something but anyone has understood at what point at how to get rid of the wax ? I guess during the heating, then why the ceramics keeps its shape if the wax is gone ?
Great content.
Now we know why this Leap engine is so good and realible
nice job (including the blade manufacturing:)! keep up the good work!
What's the material. Aluminium alloy or Inconel?
I never know how many steps you need for such a little part! But I want to know wich speed, temperature and forced this part have to withstand.
Zero speed, it's a stationary part but the first part touched by combustion gasses so the hottest piece in the engine. The turbine blade behind it will get nearly as hot and turns around 20,000 rpm so has a force like a bus hanging off it.
It’s second stage vane, so around 1000degC
Can you please tell me which metal is loaded for casting?
5:37...can I PLEASE know what that metal is ??
I learn more here than in any of my MMM class
amazing
If these are not part of a rotating element , Is this a "nozzle ring" assembly ?
wow this video is awesome
How is the core held in place after the wax has melted? Pins?
I was wondering that too, and I think I figured it out
if you look closely , part of the ceramic core is still sticking out when it comes out of the wax injection mold,
so once it gets dipped in the ceramic slurry the outer part of the mold binds to the parts of the cores that are sticking out of the wax.