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This is the kind of video that makes KZbin worthwhile.

Gear driven camshafts. The ultimate in reliability and peformance. No timing belts/chains to break.

Why did the Germans make inverted inline engines?: Because they were required to do so by the visionary head of engine design at the RLM (German Air Ministry) Dr Helmuth Sachse in the early 1930s. He required all new engine designs to have fuel injection single stage superchargers, and inline engines were to be inverted and to be able to accommodate a cannon firing through the propeller hub. It was no coincidence that the Daimler-Benz 601, 603, 605 and Junkers Jumo 211 and 213 engines and Argus were all structured this way. Strangely enough Sachse was good mates with his opposite number in England, Major George Bulman, . At their last meeting (in a Munich beer hall in 1938) Sachse complained to Bulman about how difficult it was working under politically driven Nazis who failed to understand what he was doing. He was convinced his unimpressed attitude toward them was going to get him fired and he was right. He was quickly snatched up by BMW who made him the head of piston engine development, where he oversaw the development of the legendary BMW-801 14 cylinder radial which powered many Luftwaffe aircraft, including the venerable Focke-Wulf FW-190A series. This engine may have been the first to include a mechanical computer, the 'Kommandogerat' which automatically managed propeller pitch, mixture (and spark advance?) which freed a hard-pressed fighter pilot from having to deal with engine settings while trying to score victories and stay alive. Power, weight and Fuel: During the Battle of Britain... The DB-601A displaced 33.9L (2,069 cu in), developed 1,007 kW (1350hp) and weighed 660 kg (1,455 lb) with 6.9:1 compression ratio, for a power to weight ratio of 0.928 hp/lb, using B4 fuel of roughly 87 octane equivalent fuel. The Rolls Royce Merlin III displaced 27.04L (2,069 cu iin), developed 775 kW (1030hp) and weighed 624 kg (1,375 lb) with 6.1:1 compression ratio, for a power to weight ratio of 0.749 hp/lb, using 87 octane fuel. It didn't take long for the RAF to upgrade to 100 octane rated fuel, improving the Merlin's output to 860 kW (1150 hp), but the development of high octane equivalent fuel in Germany was accomplished by a complex combination of additives derived from coal hydrogenation with lower octane equivalent B4 type fuel, which arrived after the Battle of Britain. So although the DB-601A displaced more than 25% than the Merlin III, it weighed only 6% more and when both used ~87 octane fuel it delivered a 31% higher maximum power. At the National Air ans Space Museum Smithsonian campus there is a Merlin on display behind a description claiming (as I recall) it delivered the highest hp output per cu in displacement of any WW2 V12 inline engine. However we can see above that there is more than one specification one needs to know when comparing engines. Coolant temperature: The Rolls Royce Merlin did operate at a higher coolant temperature than the DB-601. The higher 120C coolant temperature of the Merlin compared with the 90C equivalent of the DB-601 meant that the frontal area of the Merlin's radiators could be less, causing less parasite drag and permitting higher aircraft speed. To make this work, Rolls Royce had to develop lightweight plumbing and radiators that could withstand both the high pressure and temperature of the coolant.Willi Messerschmitt complained about this to Daimler-Benz but to no avail. Part of the reason may have been Germany's lack of strategic metals like nickel, chromium, copper, vanadium and others that were needed to make ideal high temperature alloys. Their metallurgists knew how, but the materials were not available in quantity while Allied engine builders could draw and ore from the natural resources of the entire British Empire and the United States. This also compromised Germany's gas turbines, which suffered serious engine life, reliability and logistical support issues. To me it speaks volumes about the quality of that Germany's overworked engineers that they were able to produce such competitive engines in spite of this. Direct Fuel Injection: Oddly the otherwise astute British examined the concept of direct fuel injection in the 1930s but discarded it as offering no advantage over carburetor induction. Germany's engine designers would cause them to regret that decision. The Bosch direct injection systems in the Daimler-Benz engines offered a number of advantages, some of which were not obvious... Unlike carburetors which regulated fuel flow with float chambers, direct fuel injection systems were not affected by G-forces. A Bf-109 pilot with a Spitfire on his tail could shove the sick forward and try diving full throttle to safety knowing his DB-601 will give full power. A Spitfire pilot with a Bf-109 on his tail could not do that - the negative G forces would close the float valve in his Merlin's carburetor perhaps stalling the engine at a very bad time. He had to roll upside down first. The Bf-109 was designed from the outset as a short range interceptor to be used as part of Blitzkreig warfare. It then found itself having to escort bombers across the Channel during the BoB, for which it lacked range. Limited to 87-90 octane equivalent fuel, it had a larger displacement than the Merlin and although it offered a comparable or better power to weight ratio, it had to burn fuel at a faster rate than did the Merlin to output comparable power. Direct fuel injection ensured the maximum possible efficiency of fuel usage. For each cylinder, the precise amount of fuel required was injected at exactly the right instant for the right duration, limiting waste. The range of the Bf-109 would have been even shorter had it not been for direct fuel injection. Direct injection meant that the inlet manifolds carried only air, not an air-fuel mix. The closing of the inlet and exhaust valves overlapped, leaving a brief period where both were open at the end of the exhaust stroke. This meant that air from the inlet manifold briefly passed through the cylinder and out the exhaust, helping to cool the block, head and exhaust valves reducing the chance of knocking due to a hot engine. Because of the aforementioned shortage of strategic metals, preventing excessive engine temperature was always an issue with the Daimler-Benz engines. Excellent video Francis - fabulous graphics that make normally obscure details much easier to understand. It would be a great companion to Douglas' book. I was investigating whether I should try modeling and animating a DB-601 myself, but you've done it! I wonder if it's possible to export solid geo files from Solidworks to Houdini? Thanks again! (Continued in the Reply....)

Actually, the original steam engines had the cylinders at the bottom and crank or beam above so this V12 is "right-side-up". When engineers decided to put the cylinders on top and crank at the bottom, they were called "inverted" engines, which became the norm.

I remember a video where a guy sent a DB601 crankshaft into RR to have it measured and checked. The engineer at RR said the specs were spot on to its very high tolerances He said don't drop it because they couldn't make another like it the tolerances were so exact with their modern equipment. Imagine they were doing this in the thousands under constant bombing of their factories.😮

I'm impressed. This engine epitomizes elegant design.

I just completed a restoration of a 57 Mercedes 300sl with the direct injection adapted from these engines. Absolutely amazing technology for the era.

Well done. The cooling issues were covered well, didn't know about them until this.

Technical yet very clear. Thanks, I've always wondered why the German V-12 was inverted when no Allied engine maker tried this. Lots of stuff in there I didn't even know I didn't know!

Waking up to this was an unexpected surprise. I never heard of a hydraulic supercharger and it's counterintuitive to me that higher compression ratios are better for fuel economy. Very interesting and informative. This is my first comprehensive look at the Messerschmitt BF 109 engine after learning about it decades ago.

Thanks for the video. According to a 109 pilot there was a valve to isolate the left or right radiator in case it was hit.

First time I watch one of your videos. Been an engine nut since childhood, and this answered many questions I had. Very good work sir.

Thank you I have wondered about this configuration & now I know

Really nice animations, makes everything quick to understand. What a marvel of engineering!

I can imagine these engines consumed huge amounts of oil. I had a BMW motorcycle where the engine was flat on it's side and when you parked it on the kickstand the "top" side was angled slightly downward. Every single time you parked the engine there was oil seeping past the rings into the combustion chamber and there was ALWAYS white smoke on startup - LOTS of white smoke on cold starts in the morning.

Answer is easy and no mystery: a V engine upside down puts the small end of the engine up, allowing for a narrower canopy, hereby increasing visibility for pilots by a big margin. Recall the "hun out of the sun"? German pilots were able to spot their enemies much earlier

Great video bro, really informative and well put together keep up the good work

11:36 Fiat?! That's a Rába Bf-109G-2 Built by Rába in Győr, Hungary under license. That is NOT an Italian Bf-109. Fiat and Alfa-Romeo built the engines under license to domestic Italian Fighters, like the Macchi C.201, Reggiane Re.2001. Kawasaki and Aichi both recieved the license, because Japan had a severe interservice rivalry, and the Navy and Army would not want to share an engine, or aircraft. Aichi produced for the Navy, and Kawasaki produced it for the Army. The other thing you missed is that Germany didn't have a fuel shortage when the engine was developed, the Injection was specifically developed for manuvering advantage, and the MW-50 injection was used for energy traps as well, since with the extra power, they could actually have both the horsepower, and airframe advantage over the P-51D. The inverted design was sought after specifically for leaving more space over the engine, enabling the installation of machine guns, and giving better visibility for the pilot.

I've watched another video on this engine, but this, by far, was much more informative, You've gained another subscriber.

Always wondered how they managed oil in those. Now I know!!!! Thank you!

You should look into the Napier Saber engines. They are a wonderful and slightly weird engine that uses sleeves instead of valves to exhaust and intake air.

The db 610 sounds like an absolute nightmare to service

Everything is very clearly and neatly laid out, I just noticed that either the propeller is rotating in the wrong direction in the entire video material, or the angle of the blades in the direction of the aircraft's movement is incorrect

Funny that porsche used a similar con rod while developing v rod for harley davudson.

Nothing in America or England Japan or Russia could compare. An elegant design concept made complete with great engineering & problem solving...

@1:57 "if the engine was stopped for a long time, the cylinders could become flooded with oil and the spark plugs had to be removed and cleaned." No, that isn't the main reason, and that is why this video was definitively not written by any airplane mechanic. If oil gets into the cylinder and the engine is rotated by a starter without draining the oil first, the rods will bend (fluids don't compress) and the motor will have to be rebuilt. This is called hydraulicing by most mechanics. That is probably the main reason that the Allies didn't want to use an inverted V-12, because it was so easy to hydraulic the motor. It may have required that the spark plugs be cleaned, but the main reason was the hydraulicing that would damage the motor. This is why you don't just start an engine that has ingested water - it will destroy the engine. You have to pull all the spark plugs and spin the motor over to force all the water out of the cylinders. If you've ever wondered why you have to pull the prop through two revolutions on a radial - this is why. You have to get the oil out of the bottom cylinders before spinning the engine over.

I love the centrifugal compressor swirl.

This design brought with it a lot of positives as the video explains. I learned some facts about this engine today. Thank you for posting this!!

Stunning and well presented animation and explanation! Subbed.

Very well done !! An upside down engine for airplanes they used was brilliant, and I wonder why more countries did not use it. The mechanical injection had issues, but it worked! It was stupid the way England slaved themselves to carb's even with the choke point regulator hack. A few minor points to mention: Germany never seem to master the high pressure coolant problem, compared to the British and Americans. They always had issues with it, and many engines only lasted 14-20 hours. Germany's main fuel and lubricant sources was coal converted to low grade fuel. They never got over 80-90 octane, where England and America eventually got up to 130 octane. The NITROUS OXIDE was Germany's secredt weapon! And it took YEARS for England and America to figure it out. Although water injection to cool the cylinders was an old racing hack. The Turbo's - and Nitrous - LOVED low compression ratio's and that worked out very well. The dual engine concept never really worked out. Dual sparkplugs another brilliant idea, you are right, they needed to be opposite or further apart. Kawasaki cruiser motorcycle still use this concept today!

Because of the fuel injection it was possible to keep both intake and exhaust valves open for a certain time. This increased the gas exchange in the cylinders.

Finally a comprehensive breakdown.

I can just about change the oil on an engine i am not a motor head, however the engineering and technology involved in this 1940's engine is facinating, infact incredible

Tower Shafts and bevel gears were standard for inline aircraft engines. Gears also drove the magnetos, oil pumps, foolant pumps and mechanical superchargers. Botton end bearings could be plain or roller type. Radials it was common to use ball bearings on the crank. The cam rings were driven by external and internal spur gears. The cam ring in an 18 cylinder radial often turned wt 25% of crank speed. Props in all engines except low powered direct drive engines used speed reduction drives to keep prop tip blade speeds below the speed of sound.

Fantastic video, descriptive and informative. Nicely put together!

Well done! Most sources just say, "Well, uh, moves the engine out of the pilot's line of sight and allows through-the-prop and top gun placement. You dove MUCH deeper!

Adding 2 engines for the DB610 reminds me of the video talking about the differential. In order to increase the engine output, we will put in ... MORE engines.

Did anyone else notice that the propeller blades were pitched backwards. In the animation of them rotating, they would be pushing the air in the wrong direction.

The lower C of G is a myth, if the cannon tube is on the planes centre line, then the heavy crank and rods are now above the planes centre line.(In cars there are no inverted V engines to keep the C of G low) The higher C of G of this engine helps the plane to initiate a roll from straight and level.

Excellent graphics! Another video comparing the Merlin with the DB601 would be good. At the beginning of the war the 2 opposing engines had near identical output and the respective aircraft Bf 109E and Spitfire Mk 1 had near identical performance. As the war progressed the DB 601 started to fall behind as did later models of the Bf109.

@TheEulerID Thanks so much for your reply, it was informative and fascinating. I knew of diesel being more power dense because of it being less refined. My reasoning was that, the first thing manufacturers did during the first U.S oil crisis in 1973-74 to improve fuel economy was to lower compression. I learned so much from your reply.

always wondered how the oiling system worked on this, thanks for the explanation.

You did an awesome animation job..

The inverted aircraft engine wasn't an idea of Daimler-Benz, it was a requirement of the Air Ministry for Air Force Engines. For this reason, the majority of German V-Engines for aircraft during WWII were inverted, Argus AS 10/410/411, Junkers Jumo 210/211/213, DB 603/605. It appears that one of the main reasons for this requirement was easier maintenance. Because, the mechanics could perform most of the work from below the engines.

Alison (US Aircraft) Coupled two of their V-1710's together also. This is the very rare V-3420 (although technically it was a "W" engine just like the DB. It was never quite perfected, and with the advent of British Jet Engines, Alison stopped the program entirely,. However, the "V-3420" drove a fancy gearbox that turned Counterrotating Propellers, which was a fad for awhile. In my opinion only the British got this right... In all but a very few cases, instead of a Huge Engine driving a complex gearbox (which was the source of most of the failure that almost always resulted in a crash*), they went with (most of the time) with two standard engines per Counter-rotating propeller set! Each driving it's own propeller to achieve the same counter rotating affect! *like the Hughes XF-11 crash after a gearbox failure cause the right hand propeller set change the pitch with one propeller going into full reverse thrust and the other went to fine pitch (which produce very little forward thrust. Just before Howard Hughes got to a golf course, the forward propeller went to zero thrust and this, along with other factors caused the crash that nearly killed H.H.!

Excellent video, well done! Thank you!! German Engineering at it's finest....I learned a little more about this engine. So cool!!!

These are excellent !!!! I volunteer for an aviation museum and would love to see one to help explain the WWI Rotary engines like the LeRhone.

There's an excellent by Calum Douglas, 'The secret horsepower race' that provides tons of detail on WW2 engine development including the DB engines.

great work - best explanation I have seen of this unusual engine geometry

this is flat out amazing. great work on the video. can you do one about rotary engines such as which was used in the nieuport 17? always wanted to know how they work. especially the fuel systems.

Thank you for this educational video! I admire your work! I'm sure it takes a lot of time for 3D modeling and gathering informatio!

You read my mind what I have always wanted to see in DB600..

I have to admit, I do like the looks of the German Stuka but the P51 mustang is my ultimate favorite fighter of old. Today it’s the A10 followed by a close second is the F22 then F15.

In minute 9.19 it was mentioned that Germany had to use low octane fuel in 1935! Till 1939 all nations used 87oz aviation fuel. In 1940 the USA provided the first high octane aviation fuel to the UK.

Nice work with all the CAD modelling and animations!

A great video idea would be about AG and AX engines from the 1900s to 1930 or 1920s and how they work.

Very instructional video. Thanks for creating it.

this is an excellent video. truly one of my favourites

*DUDE THAT WAS FANTASTIC* You got a sub...!!!

Most WW2 (and earlier engines) used Reduction Gear! (This is why most Radial engines have that big hunk of metal in front of the cylinder bank(s)... it is where they have a planetary reduction gear system).

I just wanted to tell you that I subscribed to your channel and I like your channel because I like it very much because it is shown it with a video and all I like features in the morning and the evening and in the morning to then I was watching videos so it's a nice show and always see individual played at the KZbin channel here I can subscribe where it is awesome to see how it is done from the engine to see it when it's rotating and the opposite side with the cylinders with two spark plugs I didn't know that and that's awesome to see when there is a spark plug on the other side but the next to each other then again I would like to say this is an awesome video

Excellent video very well done and I definitely learned something.

I’m already amazed by the timing systems to be able to fire through the propeller arc. Whoever decided to yeet a 30 mm through the engine was definitely thinking outside the box.

Sorry water boils at 212 at sea level is absolutely correct, but somehow i don't think that you mentioned how a airplane is rarely at sea level and the lack of air pressure caused lower boiling point , and air density has a great effect on heat transfer, i did enjoy video, just thought minor important details slipped by, i did learn things, and thanks for sharing sir

Don’t ask a German company what they did in 30s and 40s

The Merlin and Allison engines used a water/ethylene glycol mix to allow higher temperature coolants, and thus smaller radiators, without requiring a highly pressurised system. It ran at about 120C. I wonder why the Germans didn't try that approach. Maybe they just didn't have the capacity (the British got their ethylene glycol from the USA). Incidentally, there were bf109s with V12 engines the "right way up" in the form of the Spanish licence-built Hispano Aviación HA-1112. However, the Germans could not provide the DB605A engines as they needed all they could build once WW II started. Consequently, the Spanish installed the Hispano-Suiza 12Z V12, which was similar capacity (36.5 litres) and had the same provision for a hollow propeller shaft to accommodate a cannon barrel. After WW II, when surplus Merlin engines became available, then those were retro-fitted to the Hispano Aviación HA-1112 fighters. They can be seen in the film Battle of Britain, as the producers leased a number of those Hispano Aviación HA-1112 fighters and painted them up as Battle of Britain era bf109s. However, you can clearly see the give-away that they were Merlin engined from the higher line of the exhaust stubs. They would also, of course, not have sounded like a DB605A engine either, but the producers just dubbed the "correct" sound in. So to what extent the adoption of a conventionally orientated V12 affected the performance and flight dynamics of the bf109, I really don't know. But clearly the inverted engine format wasn't absolutely essential.

I didn't really get that crucial advantage of up side down cylinders. But troubles with spark plugs and hydro locking - obvious down side. It seems like no one else used that layout at the time

Somewhere in the collection of random facts in my head, I've got some little voice saying that the entire reason Germany developed an inverted 'V' engine was because during peace time, at some gathering or other, the British thought it would be awfully funny to turn their engines upside down and claim that's actually how they worked. Maybe I dreamt this. I dunno.

The W24 engines on the HE-177 (the A-5 varient from war thunder) is a maintenance nightmare, the placement meant cooling problem are a plenty

verrry interesting , never hear about the close to perfect ger. engeniering me engine ....perfect animatiton too

They should put it in a Mercedes Benz

Finnish Air Force had some problems with crankshaft lubrication on DB605's. Late engines had only bare iron cylinders, they wore fast.

My first thought, having paused the video at the start, is that this is an aircraft engine. A reason to have it "upside down" would be to allow maintenance access standing on the ground under the engine. I may be completely wrong but that is my initial guess.

thanks for a good video, another inverted engine was of course the gipsy major for one and many others also

So why the engine is inverted? :D I know. It is because it is the only way how to increase visibility out of cockpit. Which in the case of ME-109 was already quite bad.

great video on a fantastic engine , just subscribed

Great vid, thanks. Btw the Heinkel 177 with its twinned engines was a disaster, suffering engine fires.

I'm liking your videos. New subscriber! :)

The W 24 engines use on some of the bombers is certainly a brilliant idea with the life of me I don't know why they didn't just go for large or two-stroke diesels. The engines would have weighed a lot less, be more economical to run in terms of fuel, would have required less maintenance, and by all accounts probably would have generated a lot more torque.

I'm a first timer here. Great video!

That airplane was a well designed well thought out piece of engineering.

Great illustrations and well written text!

That was excellent. The best I have seen.

Never ceases to amaze me how smart people were even in those days.

Different compression ratios are amazing. I think the same, and even more strong, problem should be at Subaru engines. Amount of oil going to left and right sides must be very different. I think that is a reason of the 4th cylinder knocking, just lack of lubrication and piston cooling.

There’s a point at which complex engineering undermines reliability and serviceability. No doubt the engine development phase was ongoing.

Excellent commentary, Thank you !!

Incredibly well done thanks!!!!

The power and rpm figures are manifestly wrong. The engine produced 1000 PS at 2300 RPM and 1.3 Ata and 1100 PS at 2400 RPM and 1.4 Ata (according to the engine tech-manual for the DB-601 A). The N-Model (DB 601 N) allowed up to 2800 RPM at 1.4 ATA and produced 1280 PS. The inverted configuration and the way the piston sprayed the oil in the crankcase produced problems with foaming at high RPM, thus the later DB engines were all fitted with defoaming devices to allow higher RPM in the DB601, 605 and 603. Also the DB601 didn't have a pressurized cooling system (the DB605 had).

07:29 If the engine will be operating at higher temp, then the radiators have to be BIGGER, NOT SMALLER. That sounds backwards.

Nice video bro

What a great video! Well scripted and informative.

3D stuff moving around without perspective is trippy.

cool vid man! really well done

nice way to get rid of the timing chain. should do that now

Excellent Explanation 👍🙏

Perfect video and technical information 👌 Respect to You 👍

Great Job! Thanks

Excellent video!