Part 3 is up! kzbin.info/www/bejne/hmXIp6ZqftCZhbc

Been a machinist for 30 years never seen anyone use the mill like that. Unreal! Way to think outside the box!

This is amazing. Really looking forward to your future projects if this is your standard!

Wow, the quality of content on this channel is just so amazing. Love the spirit. When KZbin started we had DIYers tuning their cars and a few building kitcars. Today, people building the entire thing from scratch. What a journey!

I have a couple of suggestions for you. 1.) use a double spiral lock piston pin retainer (wire lock isn’t sufficient for that rpm) 2.) if you’re utilizing a dry sump system you can eliminate the oil control rings all together and use a Napier 2nd ring 3.) an accumulation groove between the top and 2nd ring wouldn’t be a bad idea 4.) a solid oil return design would be well worth the time in the design process 5.) checking the surface finish would be ideal and can be compensated with a coating 6.) if the design allows for a wider “rail” (for a lack of a better term) on the top of the pistons where it is at its thinnest that would be awesome. While the piston may sustain the pressure, it may not sustain the heat and can melt that edge

I can't believe it, this man is making his own pistons even

I started watching your channel in 2018 because of your educational engineering videos. I'm glad you're getting back into it! Thanks for adding to the underserved MotorSport Mechanical Engineering market on KZbin. If you can, please keep posting more nerdy engineering videos.

So excited for this amazing project

Great. Thumbs up. Ever thought of making a sleeve valve engine with your knowledge about thermal expansion? I could provide the CAD. One thing though, if u have a piston which can bear 250 bar, the open deck cylinder block will certainly be the limiting factor here, not the pistons.

It's so cool to see the design process of this car. Can't wait to see the rest!

Amazing! I'm in a project for a class in my university in which we choose a piston to design the forging manufacture process and it is very similar to what you guys are doing!

What material is the billet. I would suggest for a production run, get the shape you need, slightly under size the wrist pin holes, solution heat treat and age to the final temper, then final machine and ream the wrist pin hole. Then look into surface coatings such as sulfuric acid anodize or chem film.

Love the progress of the build!

Can’t wait to follow more of this build!!!

One the projects I'm most impressed with. Great work as always!

This is an awesome video, thank you for making and posting it!

Awesome! Thanks for sharing.

i cant wait to hear that engine start when its finished.

Design has several areas with sharp corners which will result in stress concentrations where fatigue cracks will form. For something like this fatigue is critical, need to analyze it subject to the acceleration loading it will see at TDC, BDC at max rpm and see what happens. Ball end mill can get you the required fillets in the pockets. Otherwise, exciting project. Maybe you can make me some custom pistons!

I so enjoy everything about this video great job thank you for the info

Loving the videos, really interesting and well explained. Keep it up :)

Great work, you guys put a lot of thought into it. I wish I could like this more than once, thank you.

This is an awesome project kudos to you guys!

can you please make video on Finite element analyais

Epic!!!! Well done mate they look awesome

Wow! Like the design decisions behind this.

I'm very impressed! Just a quick note, I'd make the sharp edges of the piston rounded. Round shapes will reduce stress concentrations, especially if the part is CNC'd instead of forged.

Good work 👍

Are you going to have the pistons coated with Teflon or Ceramic? I really enjoy watching your progress, from building a Race car from scratch, to making pistons In your new shop. Thanks for taking us along. 😊👍

This is amazing you have come so far buddy it's awesome, I wish I had half the knowledge you do. Throwing this out there would you ever consider making pistons for any other mercedes engines like the M111.975? We are having so much trouble to find affordable solutions to the brittle mercedes pistons well Nural pistons. We have found like the M104 the engine is tough but the pistons let it down and have limited options in the UK for machining. I know it's a bit off the wall especially considering you specialise in the V8s

Cool project!

Some amazing stuff happening here. Nice!

Love your content. Thank you very much!

I'm impressed with your piston lathe. Holding the tool in the vice :D That's creativity. Cheers!

There's a lot of sharp concave corners in that design unlike the f1 or any other piston. Concave edges are stress concentrations and sources of fatigue cracks and should always be filleted for load bearing features

fascinating work!

Forged w/finished machining will be stronger (f1 piston) and less prone to stress cracks due to proper grain flow in the metal lattice Billet machined wont have proper grain flow and will be more prone to fatigue and stress cracking across grain boundaries. This isn’t simulated in the FEA you’ve run. Good nugget of info to tell your viewers.

Mahle pistons are not only tapered, also egg-shaped. They're not round. it's compensation for the exhaust side getting hotter.

Kudos to you - you are definitely pushing way through the boundaries of small company tuning development and I admire this very much. I am very curious, you have not mentioned the metallurgy of your pistons - can you tell us which alloy you are using, what, if any, final treatment process you intend to apply and whether you are going to utilise any of the many coating treatments available?

Pistons are slightly oval to allow expansion in the direction of piston pin. From what I saw of the final turning of your piston it is not.

Hi, nice video. How do you estimate the thermal expansion of the cylinder in order to choose the correct clearence between piston and cylinder?

Make oil feed through piston, so it will be extremely cooled by oil.

Taking "building it better" to another level!

Crazy cool, nice work,

Next level engineering 👏👏👏👏

12:27 i think the clearance was perfect, considering that aluminum expands alot more than steel and the piston will be alot hotter than the wrist pin.

Hi XF and Marhew. Thank you for your vid. Your design requires substantial skirt ovality because the boss webs expand lengthwise with combustion heat. If you run these at a similar clearance to original pistons, they will sieize in 4 places. In contrast, a very basic design such as a 2 stroke, can get away with almost no ovality. With your equipment and expertise, a precision oval turning attachment that you could make yourselves is absolutely do-able. Reply to this comment if you want some pictures of my version for a cnc mill. Piston Pete UK.

Im so stoked to see this

Man it brings me joy to see how you have grown from a garage project to basically teaching engineering students in your own workshop

thanks for sharing. i really enjoy seeing your family and friends help.

Mercedes Benz's engineers: makes a piston XF Motorsport engeneers : Not good enough 🤣

Your work inspires me bro. Mercedes doesn’t have much aftermarket support and it’s sad but you got a great thing going keep the motion

Looks like you need to try out trochoidal high speed milling to speed up your roughing process. But very impressed in how you used your mill as a lathe to finish the OD of the pistons.

Interesting study congratulations for achieving it. I'm going to do the same. Pro: One axis turning for machining the piston profile and the ring grooves (+1) Cons : Missing the elliptical shape of the piston. Your alusil liners will rapidly wear without the needed coatings... How did you set up the loadings on the software? Thermal and mechanical. Thanks.

You are amazing man , i'm following from libya

wild machining skills

Amazing, this is good content

i'm wondering about heat treating those pistons. is that part of the plan? i was also wondering about the density of your aluminum vs. what you used for your simulations. are you planning on refining the FEA with updated material properties?

It looks like there was some technology sharing when Daimler-Benz owned Chrysler. the combustion chamber on those heads is basically a 3-valve version of gen 3 Hemi right down to the dual spark plugs. granted the Benz head is a OHC and the Hemi is a push rod engine. but it is amazing how similar the intake and exhaust runners are to a gen 3 hemi as well. amazing video.

This channel is so much underrated

The material you're using will determine expansion taper, and the top of the piston is called the crown...💯 But congratulations on pushing the boundaries, you've got a new subscriber

Is this a forged billet or what grade of aluminum exactly? Nice Job!

This project just keeps getting better.

Can't wait for the next vid. Definitely want to dry sump my m113 one day as well

Just curious, are you going to adjust the weights of the crankshaft balancing weights to adjust for the now lighter pistons?

Going fast is definitely cool but the journey to achieve fast is the real joy. Enjoy the journey !

As for wrist pin clearance, final coearance needs to be done on line hone for final surface polishing/cross hatch on the wrist pin area... Not to mention u need oil port hole for the pin, for the oil scraper ring as well as gas port for top of the piston ring for total cylinder seal during engine operation

ماشاء الله تكتيك هندسي رائع بلاغ ممتاز جميع حيتيات فنية برمجية ذرية مذهلة

Ace, great work. Have you given up on the e55 manual?

After the dry sump you need to start to design to go camless for the high rpm

Yes! Please analyze the F1 race used piston you have also!

Awesome work man! What kind of alloy did you use? You proved them on the race track?

A fantastic journey into automotive engineering.

Amazing content, will you be reducing the counterweights on the factory crankshaft to compensate the lighter pistons or is the weight decrease of the pistons not significant enough to cause imbalance?

Is this aluminium forged or a special strength?

Would love to visit this guy for once. Best youtube channel for geeky stuffs.

Excellent job

hi , saw your videous of suspension geometry , wanted to know which soft you were using?

Are there any books you would recommend on internal combustion engines? I would really like to learn more about clearances, engine designs etc. And I'm a bit puzzled on where to start.

What grade/alloy of aluminum are you using for the final product? Is it forged stock or cast stock? Congratulations on prototyping a design. There’s weeks of work that goes into getting something that works at all.

Very cool: I'm definitely looking forward to see the dyno results!

Good job 👍

Amazed by your work truly motivational to build something from scratch. All the best for your future. I am not sure though but since you reduced the weight of the pistons by a significant amount don't you need to decrease the weight of the balancing masses/counter weights on the crankshaft otherwise unbalanced rotational mass might lead to increased vibrations. I hope this is not the case since I am not quite sure. Anyways Jazak Allah Khaer for these amazing content.

What material did you use to make the piston and what is your clearance between the piston and bore. Just curious about thermal expansion and how you calculated for it.

First of all, I take my hat off to you for taking on such an ambitious project! And after watching this video I can see that you put a lot of thought into the design. The problem is, you don't know, what you don't know... :-) Here are a few things that I believe you should think about. 1. Piston Design. Pistons are not simply round and tapered... They are oval through the pin bore axis to account for the greater mass of the pin bore towers, which WILL expand more than the thrust and anti-thrust faces of the piston. Therefore, simply turning the piston round (and the ring grooves too) isn't wise. The "Cold" design of the piston will determine the "Hot" shape of the piston. The goal being that at full operating temperature the piston is round and straight. Therefore, by turning the piston with a round profile when cold, will mean that the piston will be oval at operating temperature. Pistons made by piston manufacturers for OEM Street (in the case of your sample piston is made by KS or Kolbenschmidt) are turned by a "cam lathe" which gives the oval horizontal profile, at the same time it gives the vertical profile a "Barrel Shape". The shape is highly complex and varies by the mass and thickness of the material at any given point. The Ferrari F1 piston you showed (manufactured by MAHLE I believe in 2001) is machined from a forged blank with the finished machining removing as little of the surface as possible. And it's only designed to run a few hours, maybe 250 hours, not 250,000 miles... So a comparison is unwise, unless you plan on rebuilding the engine after a very few hours. And that 2001 F1 piston is what I would consider "Old School" these days, as design has moved on in 20 years :-))) You may want to consider oil return holes in the back of the oil ring groove. Because the pumping pressures in that ring groove will be considerably higher than in a stock street engine. Another consideration is a gas relief or accumulator groove between the top and second ring, allowing for combustion gas which escapes the top ring, an area to expand into, rather than trying to force the second ring back into the second ring groove. It would be wise to chamfer all the sharp edges you have on the piston skirt tail and other areas. Especially as "piston slap" will be a feature of the piston you have made, simply due to the cold or ambient temperature tolerances you will have to run due to the alloy and lack of piston ovality. And as a precautionary feature, you might consider a skirt coating, such as Zylan or one of the other skirt coating materials. This could assist at cooler temperatures during startup. Given that you didn't create a barrel/ovality profile, I don't imagine you considered pin bore ovality or pin bore profile either. Under high load a wrist pin distorts and tries to ovalize, thus putting extreme pressure on the oil film between the pin and pin bore. This can be alleviated by giving the pin bore some ovality, or removing some material at these stress point to allow the pin to ovalize. This can be especially important in the "sheer plane" between the piston pin boss and the connecting rod bore. I would usually design in a slight taper to give the pin bore boss a "flair" or shape similar to a velocity stack. This reduces the stress on the pin in this crucial area. What are you making the wrist pins out of? Tool Steel? Or are you buying pins? If you are making them, you can consider tapering the inside wall from the outside ends of the pins, getting larger as they approach the highest load area in the center. This will remove a lot of weight from the pin, and thus the piston assembly. 2. Material Choice. While 2618 is a good choice sometimes 4032 is chosen. 2618 (Originally developed by Rolls Royce for the Merlin engines during World War 2) has a higher coefficient of expansion than 4032, but due to its ductility is often chosen as it can "take more abuse" (in many way, abuse is what we try to avoid when designing a piston :-) However, it requires much more cold clearance than the KS CAST Hypereutectic piston you are using as a base, therefore you will have to take this into consideration when you calculate your cold clearances. 4032 is formulated with a much higher silicon content (silicon is added to reduce the expansion of the alloy) and can be as high as 12.2% (or a little higher) which is right on the border of Hypereutectic alloys. This affords the piston a greatly reduced Coefficient of Expansion, and increases the wear characteristics making the piston more durable, but makes the piston less tolerant of detonation. In general, I recommend 2618 for race use, and 4032 for street, even high performance street. However, depending on the actual use of the vehicle that can change too. 2618 is "Stronger" having a higher tensile, yield, and fatigue strength than 4032, and it melts at a slightly higher temperature. All of which is why it was chosen for the Spitfire and Mustang fighter aircraft. But, it does mean that the engines must be warmed up carefully, and piston profiles must be carefully calculated as 2618 will expand up to 15% more than 4032, and even more than a Hypereutectic alloy. So, basing your tolerances on the KS piston is very unwise. 3. Manufacturing Method. It's also important to note that 2618 and 4032 are really designed as alloys for forging, and don't reach their full potential unless they are forged "near net" (in other words, forging the pistons shapes (mostly under the crown) into the alloy at, or very near, their finished shapes. In fact, the reason 4032's silicon content is limited to around 12% is that once an alloy reaches much higher than this it becomes VERY difficult to forge by conventional (heat and beat) methods; and Isothermal Forging is required, a complex method. This "compaction" of the crystalline alloy structure imparts additional strength and toughness. Imagine if you will, a plank of wood (the billet material) and plywood (the forged material) and you will understand what I mean. So, while 2618 is a good choice, you will have to really be careful with your tolerances when the engine is cold. Also, machining directly into billet without subsequent heat treatment will cause other issues. 4. Protective Finishes and Coatings. In an engine which reaches higher RPM and thermal loads it is wise to consider Hard Anodizing of the first ring groove and the pin bores. This harder surface prevents galling and localized micro welding. You might also consider a Diamond Like Coating (DLC) of the wrist pin. 5. Other considerations... Will you be rebalancing the crankshaft? I would have thought this is necessary due to the large change in the reciprocating mass. And reducing the crank weight will also aid you in your goal of 11,000 rpm. What ring pack will you use, and what will be the thickness of the rings? In this application I wouldn't go any thinner than 1 mm. Will you profile the underside of the piston crown to remove excess weight? Matching the under crown to the crown will help get the weight down. And likewise will you remove material from the pin boss between the under crown and pin bore? Just a thought for the future... 3D Printed Pistons... You can really remove some weight when you can easily leave voids where it would be really tough to machine it away... It's possible to utilize Diesel piston tech, such as oil cooling galleries in a gas engine, which can really help thermal dissipation. This is the future of piston manufacturing, for limited production anyway. Hope some of this helps. I really hope your design survives, but from what I can see it certainly isn't optimized, and could fail if tolerances aren't opened up. Best of luck!

Amazing stuff, so that ferrari piston came with the specifics of the alloy used in it? It also came with the thermal/chemical treatment guide, didn't it ?

Amazing content

did you leave the oil return holes out of the oil ring bore because this is a prototype?

U guys are geniuses

I like those robots carving the pistons....HUMANS ARE AMAZING able to create those robots.

Amazing. How the mterial of this piston is choosed can you give me an clear idea

How much do you change the ovality and taper on the piston to compensate for differing materials and higher designed operating temperatures?. Curious about how you simulate the change in the shape of the piston at operating temperature based on the temperature gradient and the thermal mass in differing areas - ie it does not expand evenly in all directions. how is this then fed into the design for machining at room temperature. be interesting to see the F1 piston - how much ovality and taper in the design

Amazing

perfect, perfect

I am working on a de-stroking of an engine, and using Fusion 360 may you show me the way you design the piston, and did analyzes? Thanks Arin

hey! nice job done there!! what is the piston aluminum material exactly? Thanks!

What about having to get the piston skirts coated for less friction?

My engine builder hones the bores on out of the box forged pistons from the aftermarket. Some times it's best to hand finish certain things. He often saw differences in fit from side to side. Are you going to balance the pistons for weight?

Really nice! No oil drain holes in the oil ring groove?

Wondering if the sharp corners where the side wall bits meet the flat head are optimal ? Quite a peak stress point ? The f1 piston also has a radius there.