As a mechanical engineer, I have to say that my selection process always starts with how it's used then to look at properties. I think about stuff like, "is this part ok to fail/sacrifice to save other parts?" "Which part should fail first?" "Is rigidity a good thing or bad thing?" "Can the system be compliant?" "Is the environment harsh?" There are a lot of things to consider, but I always like to think of which part is the 'mechanical fuse' of the system.
Thank you for sharing your thought process! Just out of curiosity, what sorts of things are you designing that might need to function as a “mechanical fuse”. The closest example I can think of like that in kit aircraft is shear pins in autopilot servos which are meant to fail first.
@@DarkAeroInc I do mechanical design and engineering for large automated industrial equipment. And you're definitely on the right track about shear pins being a mechanical fuse. Besides failing, the thought of which wears first when you think about service. You don't want to replace a giant weldment when it just needs a new bushing or something. I do a lot of design with flexures (which are awesome) they can be designed to be ridged in one direction but compliant in another and at a certain point it will bend or break protecting the rest of the system. AND it's a single piece. They're so cool. You can also think about which part fails first when designing your parts. I forget the term, but it's like strain energy balance, essentially if you design a part or assembly that has a uniform stress throughout then the failure mode is the entire part or assembly. However, if you tip that balance so the stress is higher in the cheaper easier to replace part, the cheaper part is the "fuse". And you can save the more expensive part or be able to still function at a reduced capacity. There's plenty of design philosophies out there, my favorite being the Gene Kranz school, "a preoccupation with failure results in highly reliable systems."
@@DarkAeroInc It is typical in automotive engine design to make rocker arms out of relatively weak cast material that will break first if a valve hits a piston. If the valve breaks the whole engine is likely ruined. A broken rocker arm usually leads to a moderate cost repair of the engine. The rocker design is “sacrificial”.
LOL exactly! Just wrap some plastic in a carbon fiber skin. That's usually good for another 20hp. ;) Kidding aside, BMW has some pretty amazing composite work on their i3.
these are the things i like about your channel, the inside/engineering thoughts in design and construction i want more videos like this, because there aren´t many who explain the way you do
It's also worth mentioning that composites are not very good at taking load concentrations (rivets, bolts). Metal being isotropic, it spreads the load much better. It's not just about the through thickness stress.
True! Are you encountering many bolted or riveted joints in composite parts on your projects? Most of our mechanically fastened composite parts sit firewall forward. Good examples would be the spinner and cowling.
@@DarkAeroInc Well where I work most cowls are indeed flush bolted or bear nutplates so although not ideal it's not a big deal. I have just seen bad things happen when holes are too close to edges because composite will tear (cleavage strength) easier than metal. But things go real ugly when you need to bolt structural elements such as spars because our structures are too large to be made or bonded in one single piece. There, you have to pad up an insane amount to make up for the lack of bearing strength of composite and aluminum starts to catch up in the weight contest !
@@maxhugen typically you add composite plies just in that area. Bonding metal is not as reliable as bonding composite, and the joint between materials of dissimilar CTE and modulus will be the weak link. Corrosion must also be prevented, whether bonded or bolted or riveted. Sometimes is is the only way, the wing spar cap of the F/A18 for instance is a unidirectional carbone laminate bonded to a titanium fitting with a scarf joint.
A great example of concentrated stress and high cyclic loads is the old way the Firewall was reinforced for the Engine Mount Bolts on the MX/MX2 aircraft. It's since been updated and I believe retroactivity addressed. The pilot walked away, but he was incredibly lucky and talented. But simply viewing pictures on the backside of the firewall where the bolts, nuts and washers were claiming the motor mount (Google it for images) you can only shake your head like how any engineer would think that was adequate for a world class Aerobatic aircraft, that specializes in the four minute freestyle is beyond me. A high schooler would have known it was sketch. Maybe thats why Walter Extra sells so many more planes. Their engines don't fall off. aviation-safety.net/wikibase/178764
I also tend to weigh in budget and weight constraints into my decision process. Carbon is lightweight but there is a point that for a small weight penalty the same thing can be made from say traditional fiberglass or aluminum for a fraction of the cost with similar strength specs. Love your content gentlemen👍 Keep- em coming!
Weight and cost are important, especially in the realm of building an aircraft, so thank you for pointing out that these factors should be included in the discussion! It’s always a balancing act trying to create strong, lightweight parts without the cost getting out of control. We have a few spreadsheets where we track the part weights and costs. This way it’s easier to identify where to focus your effort when trying save weight by spending more money. For example, we could save a few grams by converting some of the landing gear components from aluminum to carbon, but this would be really inefficient from a cost perspective. A higher priority item might be converting the aluminum oil pan to carbon fiber which would save a few pounds without being crazy costly to manufacture and test. Also, we’ve been enjoying following the progress you’ve been making on your project! Keep it up!
I subscribe to several aviation channels. How I haven’t ran across yours until this evening is baffling. I have watched about 10 episodes thus far and am extremely impressed! I really enjoy your episodes in all their various iterations. I believe this keeps everything fresh and engaging. So far, I am most impressed with you all being brothers and working on this amazing venture together! Very well mannered, educated, polite and kind gentleman! My brother and I would have already exchanged gunfire two or three times! Great show! i just subscribed!!! 👍🏼
One small addition - there are alternative ways of making CFC parts for other applications, for example "forged" carbon fiber. They consist of chopped carbon fiber fragments and resin, typically 5-15mm in length. The manufacturing process is somewhere inbetween what you're used to from carbon fiber and injection molding. That means you can make a lot more intricate shapes than you could with normal CF mats. Less ultimate strength than carbon fiber mats, but still very light and pretty strong, and more isotropic material properties since all the fibers are oriented differently.
Good point! We’ve experimented with “forged” carbon a little bit to make carbon fiber tube connectors. It definitely has the potential to create more intricate parts that can handle z-component stresses. One part that would be cool to try to make forged would be our nose gear trunnion halves.
@@DarkAeroInc , and your polymer is also an issue/opportunity. You can design into your composites temperature constraints, as well as friction coefficients, hardness and other properties.
Machinist here. I use aluminum for random stuff with loose tolerancing, for soft vise jaws that don't have to last long, and as a non-maring barrier when clamping things. I hate trying to hold tolerance with Al. Cold rolled steel is my go to for stuff that has to last, like soft jaws for longer production runs and general fixturing. Hot rolled steel gets used whenever warping must be kept to a minimum as it has far less internal stress than cold rolled. Medium carbon steel, especially 1144, is my favorite for anything with tight tolerancing. You can hold 5 microns all day with that stuff. Case hard is our go-to for tooling that must last in long production runs. Brass is shockingly good at absorbing vibration, which is occasionally very useful when designing fixturing for parts prone to tool chattering.
The honeycomb mentioned in the video is aluminum but we also use quite a bit of aramid honeycomb core. In production we are planning on using all aramid honeycomb core. Thanks for watching!
@@DarkAeroInc if memory serves you made sandwich panels for some parts to be cut out of. Are you able to find commercially available stock for those applications in production?
Hi Tim! We make two main types of flat panel stock: honeycomb sandwich panels and solid carbon plate/billet. We wanted to use commercially available honeycomb panels but we couldn’t find any standard panels that were right for our needs so we built our own. We plan to stick with our own in-house panels for production. The solid carbon plate we make is more ubiquitous so we might offload that in production. Some of the parts we currently make from solid carbon plate could be converted to phenolic plate which is readily available, inexpensive, and easy to machine.
Carbon fibre in general has higher toughness for part weight, compared to other materials. (given the geometry is in line with its suitable aplications). However metals are by far tougher for part size. Such as, a tough stainless steel rod hard or flexible,, (based on purpose) is going to be tougher to flex, bend ,or break, in comparison to titanium alumilnium or carbon-fibre rods. (in correct relation). In general, toughness by part weight: Carbon>titanium>alumilnium>steel tougness by part size: steel>alumilnium>titanium>carbon Obviously these materials come in their specific alloys. There is a range of allumilnium alloys, which expands further out in both directions (toughness per size and weight), than any titanium alloy does. So, there is a lot of variety between specific material alloys, but ^ this would be a general mind set. Then there are things such as toughness by part geometry, as guys in the video said, non monolithic parts aren´t very suitable for 3d force aplication scenarios, they also have a minimum size requirement (fibre bundle size). Also toughness by temperature aplication was a correct thing to point out too. Firstly because carbon fibre has much more temperature-strenght ratio variety than any of these other materials (on a scale from failure by low to high flexibility yield due to temperature) - Carbon fibre becomes brittle at relatively low negative temperatures and it melts at relatively low positive temperatures, and even then between these two fail points, it´ s strengths change drastically. Its not even isn´t fire resistant, metals and more specifically steels are. Some metals also have specific properties,, such as Titanium could be considered somewhat heat retardant, but not resistant or reflective as ceramics are. Stainless steel 303 seems to be the most tough readily available material on this planet - in general and at various temperatures across its temperatiure spectrum. All of the mentioned materials vary in these properties, with various trends. It is thus a valid concern to pick and choose which material is used for which part, as the toughest most flexible and heat resistant material, may fail in the least distinguished stress aplication, simply due to some particular condition as: "The bundle size of a material only holds strength with parts with a consistent crossection twice the width of that of the bundle." or "the lighest toughest most energy absorbant material on earth may not be suitable due to its low density, and therefore required high volume"
Very nice presentation! One thing I noticed when Doing ramp inspections in Stansted was the frequent flap delaminations because of the cfm56 exhaust in 737NG.
Excellent point! Thank you for bringing that up! Cost is often another important variable that factors into the material selection process, and it's definitely something we look at. Many of the aluminum alloys we work with are relatively inexpensive for the raw stock, but when you start looking at titanium alloys or even certain stainless alloys, the cost of material can get crazy! Carbon fiber material cost often lands somewhere between aluminum and titanium. Once you start factoring manufacturing costs like labor or CNC machining, the cost comparison starts to get pretty muddy. Thanks for watching and for the comment!
Weakness in the Z direction might apply to CFRP billet, but you could assemble such a flange with reasonable strength if you applied the layers in a non-planar fashion.
One thing you might want to consider is chemical resistance. I recently found out you can make gas tight 3d prints on a home resin printer, only to realize that EPDM o-rings aren't suitable for propane gas. Things like this don't come up very often, but finding out your fuel dissolves your carbon fiber matrix in a wet wing design is something you wouldn't want to learn the hard way.
have you seen the new ul520ist? Having a turbo normalized motor is intresting. Not sure if it will fit,but if it would the extra 30# for an extra 20 hp at all flight levels would be nice
👍 As an amateur interested in racing sailboat design, such as the America's Cup AC75 and the SailGP F50, I've been really enjoying your series. Thanks for taking the time to make these videos, and best wishes for your project. 😎 🇦🇺
Another great video - succinct while having enough detail and technical content. I’m looking forward to the stage when we can see how the finished product performs against specification.
When i was building formula student car; for the upright, along with the strength i was trying to reduce unsprung mass on the wheel,that was one of many criteria,and finally set on 7075.so weight in the application also servse very important roll.
Good piece on material design considerations. Just to add...carbon fiber structures do not fatigue like metal structures-an important consideration in wing design. This recent video release teaser looks like it was actually captured a year ago. Am I correct? What’s happening now?
Yes, corrosion is an important consideration as well! Composite parts, in general, are mostly immune to the corrosion processes you see with metal alloys, so composites are well suited for corrosive environments like coastal or marine applications with salt spray. When we do use metallic components we try to select alloys that have good corrosion resistance like stainless steels, titanium alloys, or 6061 aluminum. Thanks for watching and for the question!
I know exhaust headers have become something of a sacrosanct industry standard, but it seems like if you’re trying to reduce weight, larger manifolds would provide more volumetric flow throughput with fewer components. In other words, you can get more flow through a single 3” manifold than through two 2” headers.
The reason explained for CF parts not able to take up loads in Z direction can be better explained by the fact that the fibres run along one direction or are planar therefore if force arises parallel to the fibres then the component of force parallel to the fibres creates shear stress in the matrix of the composite, rather than fibre(reinforcement) rendering it less resilient to these forces
Hey Fellas, if I may preface by saying I love and admire what you guys are doing. I’m not sure how you guys take advice or ideas but from experience aluminum doesn’t like that circular or radial movement. Industry usually adds stainless bushings to it (never stainless on stainless) but since you’re using Cad plated NAS bolts CRES would work. On another note, CAD plated fasteners should never be in any contact with carbon something to keep in mind. I hope this helps and doesn’t get dogged in the comments just trying to help. Super excited to see this project fly. Wish it had two brothers to do something like this 💪🏻👍🏻🤙🏻
Man you guys are really hitting this thing out of the park. The whole process/determination/professionalism. Speaking of shapes, what was the reason for the large-tall-narrow vertical stab vs small-low-wide style (lancair / glasair). I imagine there were discussions. Between you guys and Mike Patey we're covered.
You mentioned heat and headers. Something to look into is having them ceramic coated. It can lower engine compartment temps by a lot simply by keeping heat inside the header until it exits the exhaust rather than heat soaking the whole engine compartment. Another route is header wrap.
That's a good point. I once came across a guy experimenting with aluminium headers containing a ceramic internal coating. No idea how it was done but just incredible the way he could hold his hand on them with minimal noticeable heat.
Nice summary. Other points to consider are susceptibility to damage, repairability, strength vs stiffness, fatigue cycles, and even direction of stresses. Bare carbon fibre is vulnerable to impact damage, so very expensive bicycle frames can be broken by small pieces of gravel. Fokker ran into this problem with forward-facing partrs like radomes, and came up with fibre/metal composite structures. If a part does get damaged, how do you repair it? In an aluminum structure, small patches get riveted on, large panels get rivets drilled out and the whole sheet replaced. Metal can be welded. Composites might seem to be fixed with glued on patches and bondo, but that would probably compromise the entire structure. Direction of loads (tension vs compression) can be significant, especially if a structure has to be thin and light. An empty aluminum beer can may be crushed between the fingers, but I defy anyone to tear off the entire top with both hands. A structure can be strong enough to withstand loads, but not stiff enough to hold its own shape; think of a balloon. That may be more a matter of structural form, rather than material strength, per se. Think corrugated cardboard, (basically paper.) The examples he shows in the video also illustrate that. Cycles of load application, leading to fracture, may be an issue. Steel can resist repeated modest loading better than aluminum (which may harden and crack), while composites may de-laminate. The Lotus Elite sports car had glass-fibre cones in which the suspension struts hammered away until the tops came off, usually in mid-corner, rather spoiling the handling. How things are joined may differ, depending on the material. In a composite, a tension load would require a splayed fibre joint, (like a duck's foot), where a metal to metal one might work well with a bolt or pin. Finally, there's corrosion. Is it going to be subject to water, oil, (both hot and cold), UV, or bird poo? All affect choices. "Stuctures" by J.E. Gordon www.springer.com/gp/book/9781461590767 and its companion on materials www.goodreads.com/book/show/230510.The_New_Science_of_Strong_Materials are great introductions to the topic. Don't pay the Springer price, there are plenty of cheaper sources.)
I love the attention to detail of this company, and this specific project is very well organized. Can't wait to see the real world flight performance and handling qualities. I think the estimates are absolutely spot-on for top speed and range. Stall speed might be cutting it close, as the empty weight target is pretty aggressive and builders like stuffing in stuff they dont weigh.
There is a means of making some fine and or dimensionally precise carbon fiber parts. Depending on the weight strength heat requirements the carbon fibers are either mixed with a high strength plastic and injection moulded or mixed with a resin as a type of slurry then pressed into a mould and subjected to high pressure clamping forces to compact it to the correct size etc.Then there is Carbon Carbon ceramic
I think this is so great you three are building an airplane. Not just an airplane, but a fantastic one. I love watching you. I would love to fly one of these if the Feds would let me. Too old. Oh well, I can still dream watching you.
Akrapovic might be able to make you a titanium exhaust. Cost will be high, but they do beautiful welding. I have a race exhaust on my BMW HP4 and it is gorgeous, And light as a feather.
True! Metal parts can often be manufactured using very cost effective processes. Looking at examples from kit aircraft, a sheet metal wing skin is almost always going to come in at a lower cost than an equivalent carbon fiber wing skin. In our design we are prioritizing structural optimization over cost which results in a tradeoff of a higher cost kit relative to a riveted aluminum equivalent.
I want to build a kitfox made out of carbon fiber. So a carbon fiber shell without a metal frame. Just the carbon fiber shells ridgity to support the load. I can only imagine the weight savings.
G,day Riley and DA team from Sydney Australia. Material selection (me) * cost * performance * availability * engineering process * health and safety Q2. The firewall on DA, will smoke be eliminated from the cockpit? 🌏🍧 *I
One of the requirements of the firewall is to keep both flames and hazardous gases from passing through so we are taking the necessary measures to seal out smoke.
surprised you didn't discuss toughness for choosing metal versus carbon fiber. Or stiffness when choosing carbon fiber versus metal. Also the spinner was probably the worst example for compound curves because that shape can be done very well with a metal spinning process. Non uniform compound shapes carbon fiber has an advantage.
It would be great to have an explanation of your evaluation for a petrol vs electric engine. E.g sample configurations for different battery sizes with performance and range estimates. E.g with Ampruis 450w/kg batteries that are commercially available. And motors like those from H3X, MITs motor, kite magnetics etc. MIT's motor apparently packs 17kW per kg of power.
NOTE!!! Carbon fibre does not like lightning strikes one little bit ! A mitigation technique used in aviation is to run a fine copper mesh over the outer layer with special conductors in areas where that is not possible or to channel the electricity to emitters. Fuel tanks wiring and structural areas like wing roots are especially susceptible to damage that could result in loss of the aircraft. I would glue that plate to the carbon paneling as well as bolt it on as the bolts are very likely work loose due to the different flex patterns on the materials so by using a moderate (removable) strength panel bonding agent the flexing will be made uniform across the whole surface reducing point loads.
Naveen we appreciate the feedback, and we are very thankful for all our CZcams community members. :) It's challenging to find time to make more videos. We hope to release more videos to Mach 1 in the future.
Usually we use hardpoint, which is really just a small area that is locally reinforced. In the example from the video, (the drag link mount with six bolts) each bolt travels through a hardpoint in the honeycomb sandwich panel that the mount is bolted onto. The hardpoint is a cylindrical puck of phenolic plate that replaces the honeycomb core to prevent the core from being crushed by the bolt clamping loads. Over the puck are additional layers of carbon fiber that cover the puck and overlap onto the surrounding sandwich panel skins. This transfer the loads from the puck into the skins of the honeycomb sandwich panel. Thanks for watching and for the good question!
@@DarkAeroInc In the production kits would you cut out the honeycomb BEFORE you layup the sandwich panel, insert the phenolic plate into the honeycomb layer as part of the layup? This would eliminate a lot of steps in the build process wouldn't it? Just need to drill out the hole and the hardpoint is already there!
Hi Richard! We would like to integrate the hard points into the honeycomb panels but the manufacturing process we use right now prevents that. Luckily the installation of the hard points isn’t too challenging, even though it does add another step. This is something we are still sorting out but a good compromise might be installing the hard points in the bulkheads when they are still laying flat at the factory rather than when they are installed in the fuselage and positioned more upright.
Thanks for the video. I wanna add a few things, carbon fiber and fastener interaction (mostly made of aluminum) can cause corrosion. So you need to seal the fastener. Then, carbon is sensitive to machining, you may damage to part and weaken to composite. Lastly, carbon has high cost :D. I have 2 question as well. How about their fatigue life performance? What precautions you take for the lightning protection of carbon? Best Regards :)
Titanium is not a suitable metal for exhaust pipes, it suffers from thermal fatigue and oxidization at high temperatures, 321 is aircraft grade exhaust material, or if you want lighter, inconel is what is used. Another benefit of an aluminium frame is it does not burn as easily as carbon fibre. The resin is flammable.
I'm really curious how much torque approximately the bolt can be tightened before breaking or crumbling the carbon fiber? That's a very crucial point when comparing to steel righr?
I have a question. Carbon fibre is not good for lightning strikes (in essence, lightning will travel through and not around like metal... bad news for passengers!), large aircraft manufacturers are investing heavily in research into copper mesh to cover carbon fibre used on aircraft exterior. Has this been considered in the Dark Aero, or is it just an acceptable risk? I'd imagine a one man cockpit would be relatively easy to insulate sufficiently. Enjoying the videos guys! 👍🏻
The reasoning for going to titanium would be to reduce weight since titanium is roughly 60% the density of the 304 stainless steel that is currently used for our exhaust pipes. This would shave a couple pounds off the firewall forward weight.
I think the failure mode is also a very important criteria. Something like glass may be hard and stiff, but when it breaks it breaks catastrophically. Metal will bend while CF composites will splinter and fail suddenly and more or less completely. Glass fiber is a little bit better in this regard because it will bend and stretch a little more before failure. Also RF properties are a think, as you see when you hide the antennas behind it.
How does carbon fiber skin compare to aluminum skin with regard to radiation? Specifically, how will it hold up to UV radiation if it was to live out on the ramp instead of in a hanger? Will it last as long as conventional aluminum skin aircraft?
As a mechanical engineer, I have to say that my selection process always starts with how it's used then to look at properties. I think about stuff like, "is this part ok to fail/sacrifice to save other parts?" "Which part should fail first?" "Is rigidity a good thing or bad thing?" "Can the system be compliant?" "Is the environment harsh?" There are a lot of things to consider, but I always like to think of which part is the 'mechanical fuse' of the system.
Thank you for sharing your thought process! Just out of curiosity, what sorts of things are you designing that might need to function as a “mechanical fuse”. The closest example I can think of like that in kit aircraft is shear pins in autopilot servos which are meant to fail first.
@@DarkAeroInc I do mechanical design and engineering for large automated industrial equipment. And you're definitely on the right track about shear pins being a mechanical fuse. Besides failing, the thought of which wears first when you think about service. You don't want to replace a giant weldment when it just needs a new bushing or something. I do a lot of design with flexures (which are awesome) they can be designed to be ridged in one direction but compliant in another and at a certain point it will bend or break protecting the rest of the system. AND it's a single piece. They're so cool. You can also think about which part fails first when designing your parts. I forget the term, but it's like strain energy balance, essentially if you design a part or assembly that has a uniform stress throughout then the failure mode is the entire part or assembly. However, if you tip that balance so the stress is higher in the cheaper easier to replace part, the cheaper part is the "fuse". And you can save the more expensive part or be able to still function at a reduced capacity. There's plenty of design philosophies out there, my favorite being the Gene Kranz school, "a preoccupation with failure results in highly reliable systems."
@@DarkAeroInc It is typical in automotive engine design to make rocker arms out of relatively weak cast material that will break first if a valve hits a piston. If the valve breaks the whole engine is likely ruined. A broken rocker arm usually leads to a moderate cost repair of the engine. The rocker design is “sacrificial”.
@@rickhearn5899 ooooh that’s a good example!
@@rickhearn5899 so that's why Pontiacs always had rocker arm issues.
From the automotive world: Carbon fiber where it can be seen, whatever is cheapest everywhere else.
LOL exactly! Just wrap some plastic in a carbon fiber skin. That's usually good for another 20hp. ;) Kidding aside, BMW has some pretty amazing composite work on their i3.
@@DarkAeroInc And i8. Alfa Romeo on their 4C. Then all the exotic car tubs.
I’m more concerned with function rather than looks….. looks are for posers, function for performance
@@DarkAeroInc Did you get Munro's report for 10$ on i3? czcams.com/video/OCDamRUFHYs/video.html&ab_channel=MunroLive
@@grandenauto3214 : 1000% !!!!
Its like I'm in a science class but learning the aspects of something actually interesting! Love what you're doing with the plane and your YT channel.
I can't wait to see this beauty fly...
these are the things i like about your channel, the inside/engineering thoughts in design and construction
i want more videos like this, because there aren´t many who explain the way you do
It's also worth mentioning that composites are not very good at taking load concentrations (rivets, bolts). Metal being isotropic, it spreads the load much better. It's not just about the through thickness stress.
True! Are you encountering many bolted or riveted joints in composite parts on your projects? Most of our mechanically fastened composite parts sit firewall forward. Good examples would be the spinner and cowling.
@@DarkAeroInc Well where I work most cowls are indeed flush bolted or bear nutplates so although not ideal it's not a big deal. I have just seen bad things happen when holes are too close to edges because composite will tear (cleavage strength) easier than metal. But things go real ugly when you need to bolt structural elements such as spars because our structures are too large to be made or bonded in one single piece. There, you have to pad up an insane amount to make up for the lack of bearing strength of composite and aluminum starts to catch up in the weight contest !
@@SuperYellowsubmarin Do you bond in metal substrates to the layup, in areas where you need to fasten, say, a cowling to framework?
@@maxhugen typically you add composite plies just in that area. Bonding metal is not as reliable as bonding composite, and the joint between materials of dissimilar CTE and modulus will be the weak link. Corrosion must also be prevented, whether bonded or bolted or riveted. Sometimes is is the only way, the wing spar cap of the F/A18 for instance is a unidirectional carbone laminate bonded to a titanium fitting with a scarf joint.
A great example of concentrated stress and high cyclic loads is the old way the Firewall was reinforced for the Engine Mount Bolts on the MX/MX2 aircraft. It's since been updated and I believe retroactivity addressed. The pilot walked away, but he was incredibly lucky and talented. But simply viewing pictures on the backside of the firewall where the bolts, nuts and washers were claiming the motor mount (Google it for images) you can only shake your head like how any engineer would think that was adequate for a world class Aerobatic aircraft, that specializes in the four minute freestyle is beyond me. A high schooler would have known it was sketch. Maybe thats why Walter Extra sells so many more planes. Their engines don't fall off. aviation-safety.net/wikibase/178764
If I had kids, this would be mandatory viewing. Great content as usual!
I also tend to weigh in budget and weight constraints into my decision process. Carbon is lightweight but there is a point that for a small weight penalty the same thing can be made from say traditional fiberglass or aluminum for a fraction of the cost with similar strength specs.
Love your content gentlemen👍 Keep- em coming!
Weight and cost are important, especially in the realm of building an aircraft, so thank you for pointing out that these factors should be included in the discussion! It’s always a balancing act trying to create strong, lightweight parts without the cost getting out of control. We have a few spreadsheets where we track the part weights and costs. This way it’s easier to identify where to focus your effort when trying save weight by spending more money. For example, we could save a few grams by converting some of the landing gear components from aluminum to carbon, but this would be really inefficient from a cost perspective. A higher priority item might be converting the aluminum oil pan to carbon fiber which would save a few pounds without being crazy costly to manufacture and test.
Also, we’ve been enjoying following the progress you’ve been making on your project! Keep it up!
Came from JerryRigEverything, very interesting videos you guys got there.
I can stay in this classroom for the whole day! Keep it up guys! Cheers from Texas.
i came here after jerryrigeveryting
and imm a fan of planes and carbon fiber
cant wait to start it flying
Love your content! Greetings from Germany
I subscribe to several aviation channels. How I haven’t ran across yours until this evening is baffling. I have watched about 10 episodes thus far and am extremely impressed! I really enjoy your episodes in all their various iterations. I believe this keeps everything fresh and engaging. So far, I am most impressed with you all being brothers and working on this amazing venture together! Very well mannered, educated, polite and kind gentleman! My brother and I would have already exchanged gunfire two or three times! Great show! i just subscribed!!! 👍🏼
Thank you for the kind words and for subscribing! 🙂🚀
Here after Jerry's new carbonfibre smartphone video :D
One small addition - there are alternative ways of making CFC parts for other applications, for example "forged" carbon fiber. They consist of chopped carbon fiber fragments and resin, typically 5-15mm in length. The manufacturing process is somewhere inbetween what you're used to from carbon fiber and injection molding. That means you can make a lot more intricate shapes than you could with normal CF mats. Less ultimate strength than carbon fiber mats, but still very light and pretty strong, and more isotropic material properties since all the fibers are oriented differently.
Good point! We’ve experimented with “forged” carbon a little bit to make carbon fiber tube connectors. It definitely has the potential to create more intricate parts that can handle z-component stresses. One part that would be cool to try to make forged would be our nose gear trunnion halves.
@@DarkAeroInc , and your polymer is also an issue/opportunity. You can design into your composites temperature constraints, as well as friction coefficients, hardness and other properties.
That plane looks sick. who else is here from Jerry Rigs Everything
Machinist here. I use aluminum for random stuff with loose tolerancing, for soft vise jaws that don't have to last long, and as a non-maring barrier when clamping things. I hate trying to hold tolerance with Al. Cold rolled steel is my go to for stuff that has to last, like soft jaws for longer production runs and general fixturing. Hot rolled steel gets used whenever warping must be kept to a minimum as it has far less internal stress than cold rolled. Medium carbon steel, especially 1144, is my favorite for anything with tight tolerancing. You can hold 5 microns all day with that stuff. Case hard is our go-to for tooling that must last in long production runs. Brass is shockingly good at absorbing vibration, which is occasionally very useful when designing fixturing for parts prone to tool chattering.
Love your videos. Quick question, what material is the honeycomb made from?
The honeycomb mentioned in the video is aluminum but we also use quite a bit of aramid honeycomb core. In production we are planning on using all aramid honeycomb core. Thanks for watching!
@@DarkAeroInc if memory serves you made sandwich panels for some parts to be cut out of. Are you able to find commercially available stock for those applications in production?
Hi Tim! We make two main types of flat panel stock: honeycomb sandwich panels and solid carbon plate/billet. We wanted to use commercially available honeycomb panels but we couldn’t find any standard panels that were right for our needs so we built our own. We plan to stick with our own in-house panels for production. The solid carbon plate we make is more ubiquitous so we might offload that in production. Some of the parts we currently make from solid carbon plate could be converted to phenolic plate which is readily available, inexpensive, and easy to machine.
Carbon fibre in general has higher toughness for part weight, compared to other materials. (given the geometry is in line with its suitable aplications). However metals are by far tougher for part size. Such as, a tough stainless steel rod hard or flexible,, (based on purpose) is going to be tougher to flex, bend ,or break, in comparison to titanium alumilnium or carbon-fibre rods. (in correct relation).
In general,
toughness by part weight: Carbon>titanium>alumilnium>steel
tougness by part size: steel>alumilnium>titanium>carbon
Obviously these materials come in their specific alloys. There is a range of allumilnium alloys, which expands further out in both directions (toughness per size and weight), than any titanium alloy does. So, there is a lot of variety between specific material alloys, but ^ this would be a general mind set.
Then there are things such as toughness by part geometry, as guys in the video said, non monolithic parts aren´t very suitable for 3d force aplication scenarios, they also have a minimum size requirement (fibre bundle size). Also toughness by temperature aplication was a correct thing to point out too. Firstly because carbon fibre has much more temperature-strenght ratio variety than any of these other materials (on a scale from failure by low to high flexibility yield due to temperature) - Carbon fibre becomes brittle at relatively low negative temperatures and it melts at relatively low positive temperatures, and even then between these two fail points, it´ s strengths change drastically. Its not even isn´t fire resistant, metals and more specifically steels are. Some metals also have specific properties,, such as Titanium could be considered somewhat heat retardant, but not resistant or reflective as ceramics are. Stainless steel 303 seems to be the most tough readily available material on this planet - in general and at various temperatures across its temperatiure spectrum.
All of the mentioned materials vary in these properties, with various trends.
It is thus a valid concern to pick and choose which material is used for which part, as the toughest most flexible and heat resistant material, may fail in the least distinguished stress aplication, simply due to some particular condition as: "The bundle size of a material only holds strength with parts with a consistent crossection twice the width of that of the bundle." or "the lighest toughest most energy absorbant material on earth may not be suitable due to its low density, and therefore required high volume"
jerry rig everything’s video brought me here!
But will it scratch at level 6 with deeper grooves at level 7?
😂
Great content guys!!!!! Thx from Germany
Very nice presentation! One thing I noticed when Doing ramp inspections in Stansted was the frequent flap delaminations because of the cfm56 exhaust in 737NG.
So you have seen it first hand that heat can have an impact on composite materials! Thank you for watching!
i hope all is going well with your project, we are all dying for a new video ! you guys are an inspiration, keep it coming !
What about cost? Greetings from Turkey, love your content.
Excellent point! Thank you for bringing that up! Cost is often another important variable that factors into the material selection process, and it's definitely something we look at. Many of the aluminum alloys we work with are relatively inexpensive for the raw stock, but when you start looking at titanium alloys or even certain stainless alloys, the cost of material can get crazy! Carbon fiber material cost often lands somewhere between aluminum and titanium. Once you start factoring manufacturing costs like labor or CNC machining, the cost comparison starts to get pretty muddy. Thanks for watching and for the comment!
Weakness in the Z direction might apply to CFRP billet, but you could assemble such a flange with reasonable strength if you applied the layers in a non-planar fashion.
One thing you might want to consider is chemical resistance. I recently found out you can make gas tight 3d prints on a home resin printer, only to realize that EPDM o-rings aren't suitable for propane gas.
Things like this don't come up very often, but finding out your fuel dissolves your carbon fiber matrix in a wet wing design is something you wouldn't want to learn the hard way.
have you seen the new ul520ist?
Having a turbo normalized motor is intresting. Not sure if it will fit,but if it would the extra 30# for an extra 20 hp at all flight levels would be nice
👍 As an amateur interested in racing sailboat design, such as the America's Cup AC75 and the SailGP F50, I've been really enjoying your series. Thanks for taking the time to make these videos, and best wishes for your project. 😎 🇦🇺
Great video! But what about the thermal expansion difference when combining carbon fiber and metal?
Good question!!!!
Hoping to get an answer, and also a sample demonstration!
Another great video - succinct while having enough detail and technical content.
I’m looking forward to the stage when we can see how the finished product performs against specification.
When i was building formula student car; for the upright, along with the strength i was trying to reduce unsprung mass on the wheel,that was one of many criteria,and finally set on 7075.so weight in the application also servse very important roll.
So freaking smart 🥰 🔥 keep the videos coming !!!
Good piece on material design considerations. Just to add...carbon fiber structures do not fatigue like metal structures-an important consideration in wing design.
This recent video release teaser looks like it was actually captured a year ago. Am I correct? What’s happening now?
Great info just wondered if corrosion or oxidation is a meaningful consideration for your choice
Yes, corrosion is an important consideration as well! Composite parts, in general, are mostly immune to the corrosion processes you see with metal alloys, so composites are well suited for corrosive environments like coastal or marine applications with salt spray. When we do use metallic components we try to select alloys that have good corrosion resistance like stainless steels, titanium alloys, or 6061 aluminum. Thanks for watching and for the question!
@@DarkAeroInc why not powder coat or anodize the aluminum?
I know exhaust headers have become something of a sacrosanct industry standard, but it seems like if you’re trying to reduce weight, larger manifolds would provide more volumetric flow throughput with fewer components. In other words, you can get more flow through a single 3” manifold than through two 2” headers.
Always very interesting content. Thanks 🙏 🇨🇦
You guys rock. You have one of the best explanations about the suitability of carbon fiber.
Realy good explanation . Thank’s a lot.
The reason explained for CF parts not able to take up loads in Z direction can be better explained by the fact that the fibres run along one direction or are planar therefore if force arises parallel to the fibres then the component of force parallel to the fibres creates shear stress in the matrix of the composite, rather than fibre(reinforcement) rendering it less resilient to these forces
Outstanding videos. Thank you.
Learned so Much! Love these videos!
Hey Fellas, if I may preface by saying I love and admire what you guys are doing. I’m not sure how you guys take advice or ideas but from experience aluminum doesn’t like that circular or radial movement. Industry usually adds stainless bushings to it (never stainless on stainless) but since you’re using Cad plated NAS bolts CRES would work. On another note, CAD plated fasteners should never be in any contact with carbon something to keep in mind. I hope this helps and doesn’t get dogged in the comments just trying to help. Super excited to see this project fly. Wish it had two brothers to do something like this 💪🏻👍🏻🤙🏻
Excellent lecture, thanks!
Man you guys are really hitting this thing out of the park. The whole process/determination/professionalism. Speaking of shapes, what was the reason for the large-tall-narrow vertical stab vs small-low-wide style (lancair / glasair). I imagine there were discussions. Between you guys and Mike Patey we're covered.
Excellent video. Keep up the engineering oriented content.
Outstanding presentation. 👍
You mentioned heat and headers. Something to look into is having them ceramic coated. It can lower engine compartment temps by a lot simply by keeping heat inside the header until it exits the exhaust rather than heat soaking the whole engine compartment. Another route is header wrap.
That's a good point.
I once came across a guy experimenting with aluminium headers containing a ceramic internal coating. No idea how it was done but just incredible the way he could hold his hand on them with minimal noticeable heat.
Nice summary. Other points to consider are susceptibility to damage, repairability, strength vs stiffness, fatigue cycles, and even direction of stresses.
Bare carbon fibre is vulnerable to impact damage, so very expensive bicycle frames can be broken by small pieces of gravel. Fokker ran into this problem with forward-facing partrs like radomes, and came up with fibre/metal composite structures.
If a part does get damaged, how do you repair it? In an aluminum structure, small patches get riveted on, large panels get rivets drilled out and the whole sheet replaced. Metal can be welded. Composites might seem to be fixed with glued on patches and bondo, but that would probably compromise the entire structure.
Direction of loads (tension vs compression) can be significant, especially if a structure has to be thin and light. An empty aluminum beer can may be crushed between the fingers, but I defy anyone to tear off the entire top with both hands.
A structure can be strong enough to withstand loads, but not stiff enough to hold its own shape; think of a balloon. That may be more a matter of structural form, rather than material strength, per se. Think corrugated cardboard, (basically paper.) The examples he shows in the video also illustrate that.
Cycles of load application, leading to fracture, may be an issue. Steel can resist repeated modest loading better than aluminum (which may harden and crack), while composites may de-laminate. The Lotus Elite sports car had glass-fibre cones in which the suspension struts hammered away until the tops came off, usually in mid-corner, rather spoiling the handling.
How things are joined may differ, depending on the material. In a composite, a tension load would require a splayed fibre joint, (like a duck's foot), where a metal to metal one might work well with a bolt or pin.
Finally, there's corrosion. Is it going to be subject to water, oil, (both hot and cold), UV, or bird poo? All affect choices.
"Stuctures" by J.E. Gordon www.springer.com/gp/book/9781461590767 and its companion on materials www.goodreads.com/book/show/230510.The_New_Science_of_Strong_Materials are great introductions to the topic. Don't pay the Springer price, there are plenty of cheaper sources.)
Cool, may it be totally finishes this week to find out all things that needs to be found out.
God bless innovation.
Hear after Jerryrigeverything
Can u make the video on, ur planning about how will you going to test it, and about the production planning, please
I love the attention to detail of this company, and this specific project is very well organized.
Can't wait to see the real world flight performance and handling qualities.
I think the estimates are absolutely spot-on for top speed and range. Stall speed might be cutting it close, as the empty weight target is pretty aggressive and builders like stuffing in stuff they dont weigh.
Roll with inconel for the exhaust if weight is what you want to save.
I came here after jerryrigeverything recommendation
You guys are doing great job👍
Great video- so well explained. Thank you very much 👏👏👏
Thanks Manju for checking out the video and for the support! :)
Excellent information and presentation. Thank you.
Michael, thank you for checking out the video and the kind words! :)
Inconel exhausts to save weight? They use that in some race cars Iirc?
Awesome video. Thanks for sharing.
There is a means of making some fine and or dimensionally precise carbon fiber parts.
Depending on the weight strength heat requirements the carbon fibers are either mixed with a high strength plastic and injection moulded or mixed with a resin as a type of slurry then pressed into a mould and subjected to high pressure clamping forces to compact it to the correct size etc.Then there is Carbon Carbon ceramic
I think this is so great you three are building an airplane. Not just an airplane, but a fantastic one. I love watching you. I would love to fly one of these if the Feds would let me. Too old. Oh well, I can still dream watching you.
Congratulations on the video. Very interesting!
Are you planning on having a display at AirVenture at Oshkosh later this month?
Like always, awesome and interesting video! 👍🏻
Akrapovic might be able to make you a titanium exhaust. Cost will be high, but they do beautiful welding. I have a race exhaust on my BMW HP4 and it is gorgeous, And light as a feather.
We ought to make metal parts sometimes just for the cost. Some catbon fiber parts can not be justified, just from a cost point of view..
True! Metal parts can often be manufactured using very cost effective processes. Looking at examples from kit aircraft, a sheet metal wing skin is almost always going to come in at a lower cost than an equivalent carbon fiber wing skin. In our design we are prioritizing structural optimization over cost which results in a tradeoff of a higher cost kit relative to a riveted aluminum equivalent.
DarkAero School! Love it.
You are Professor level ! Impressive !
Thanks for sharing information
Metal as a firewall is nice but how about some insulation or a gap until the next component?
good explanation
I want to build a kitfox made out of carbon fiber. So a carbon fiber shell without a metal frame. Just the carbon fiber shells ridgity to support the load. I can only imagine the weight savings.
Engine blocks should not be made out of carbon fiber. Great to see those fancy college edumacayshuns weren't wasted.
G,day Riley and DA team from Sydney Australia.
Material selection (me)
* cost
* performance
* availability
* engineering process
* health and safety
Q2. The firewall on DA, will smoke be eliminated from the cockpit?
🌏🍧
*I
One of the requirements of the firewall is to keep both flames and hazardous gases from passing through so we are taking the necessary measures to seal out smoke.
fantastic explanation
surprised you didn't discuss toughness for choosing metal versus carbon fiber. Or stiffness when choosing carbon fiber versus metal. Also the spinner was probably the worst example for compound curves because that shape can be done very well with a metal spinning process. Non uniform compound shapes carbon fiber has an advantage.
"To give anything less than your best is to sacrifice the gift." -Steve Prefontaine
It would be great to have an explanation of your evaluation for a petrol vs electric engine.
E.g sample configurations for different battery sizes with performance and range estimates.
E.g with Ampruis 450w/kg batteries that are commercially available.
And motors like those from H3X, MITs motor, kite magnetics etc.
MIT's motor apparently packs 17kW per kg of power.
We made a video that touches on many of those topics here: czcams.com/video/LdSnHQtoVTI/video.htmlsi=07q8IKkxWLUCtymV
Great video
NOTE!!!
Carbon fibre does not like lightning strikes one little bit !
A mitigation technique used in aviation is to run a fine copper mesh over the outer layer with special conductors in areas where that is not possible or to channel the electricity to emitters. Fuel tanks wiring and structural areas like wing roots are especially susceptible to damage that could result in loss of the aircraft.
I would glue that plate to the carbon paneling as well as bolt it on as the bolts are very likely work loose due to the different flex patterns on the materials so by using a moderate (removable) strength panel bonding agent the flexing will be made uniform across the whole surface reducing point loads.
How do you bond stiffeners to carbon fibre parts
It would be nice if you release more videos for mach 1 members...
Naveen we appreciate the feedback, and we are very thankful for all our CZcams community members. :) It's challenging to find time to make more videos. We hope to release more videos to Mach 1 in the future.
How do you resolve the 3D stresses at the point of load transfer where the metal components are fastened to the planar carbon shell?
Usually we use hardpoint, which is really just a small area that is locally reinforced. In the example from the video, (the drag link mount with six bolts) each bolt travels through a hardpoint in the honeycomb sandwich panel that the mount is bolted onto. The hardpoint is a cylindrical puck of phenolic plate that replaces the honeycomb core to prevent the core from being crushed by the bolt clamping loads. Over the puck are additional layers of carbon fiber that cover the puck and overlap onto the surrounding sandwich panel skins. This transfer the loads from the puck into the skins of the honeycomb sandwich panel. Thanks for watching and for the good question!
@@DarkAeroInc In the production kits would you cut out the honeycomb BEFORE you layup the sandwich panel, insert the phenolic plate into the honeycomb layer as part of the layup? This would eliminate a lot of steps in the build process wouldn't it? Just need to drill out the hole and the hardpoint is already there!
Hi Richard! We would like to integrate the hard points into the honeycomb panels but the manufacturing process we use right now prevents that. Luckily the installation of the hard points isn’t too challenging, even though it does add another step. This is something we are still sorting out but a good compromise might be installing the hard points in the bulkheads when they are still laying flat at the factory rather than when they are installed in the fuselage and positioned more upright.
How do you avoid galvanic corrosion between the carbon and aluminum?
Thanks for the video.
I wanna add a few things, carbon fiber and fastener interaction (mostly made of aluminum) can cause corrosion. So you need to seal the fastener. Then, carbon is sensitive to machining, you may damage to part and weaken to composite. Lastly, carbon has high cost :D.
I have 2 question as well. How about their fatigue life performance? What precautions you take for the lightning protection of carbon?
Best Regards :)
Titanium is not a suitable metal for exhaust pipes, it suffers from thermal fatigue and oxidization at high temperatures, 321 is aircraft grade exhaust material, or if you want lighter, inconel is what is used. Another benefit of an aluminium frame is it does not burn as easily as carbon fibre. The resin is flammable.
What is your opinion about using carbon fiber I-beam for a spar? If used what is the best way to join a right and left spar?
*GREAT VIDEO* . Are there some new general videos in the plan, or are new video clips being pushed behind the pay wall? Thanks!
Several new videos coming this week. 🙂
@@DarkAeroInc AWESOME... thank you!
Here from JerrRigEverything
Hey Darkaero. Any chance to see More Videos on this plane?
Thanks for watching and reaching out! We’ve had our heads down busy with the aircraft lately. We will have a few good videos coming soon!
I'm really curious how much torque approximately the bolt can be tightened before breaking or crumbling the carbon fiber? That's a very crucial point when comparing to steel righr?
I have a question. Carbon fibre is not good for lightning strikes (in essence, lightning will travel through and not around like metal... bad news for passengers!), large aircraft manufacturers are investing heavily in research into copper mesh to cover carbon fibre used on aircraft exterior. Has this been considered in the Dark Aero, or is it just an acceptable risk?
I'd imagine a one man cockpit would be relatively easy to insulate sufficiently.
Enjoying the videos guys! 👍🏻
Carbon ceramic for the exhaust? J/k it will burn, Ti is the one you go for inlet/exhaust piping :)
If you could sandwich a piece of thin steel inside the carbon fiber would that work?
I think you'd prefer Inconel 625 to titanium for your exhaust. Unfortunately I both can't afford nor build it for you. Bummer!
The reasoning for going to titanium would be to reduce weight since titanium is roughly 60% the density of the 304 stainless steel that is currently used for our exhaust pipes. This would shave a couple pounds off the firewall forward weight.
I want to build a racecar body, will carbon fiber be a better option or steel? what should I use
Ceramic coat those exhaust pipes :)
If you randomly get more subscribers, Jerryrigeverithing shouted you out in his latest vid
I think the failure mode is also a very important criteria. Something like glass may be hard and stiff, but when it breaks it breaks catastrophically. Metal will bend while CF composites will splinter and fail suddenly and more or less completely. Glass fiber is a little bit better in this regard because it will bend and stretch a little more before failure.
Also RF properties are a think, as you see when you hide the antennas behind it.
Also corrosion and aging.
How does carbon fiber skin compare to aluminum skin with regard to radiation? Specifically, how will it hold up to UV radiation if it was to live out on the ramp instead of in a hanger? Will it last as long as conventional aluminum skin aircraft?