This classroom is dope, I wish I had this in school back in the days...

D-Sport has been doin' the Lords' work!

Only 41k views? This video is so under rated and full of useful information. Thank you Dsport, for taking the time to nourish us car geeks with this information

This was absolutely fantastic!! And free!! Are you for real!! I feel like I waisted thousands of dollars in education after this. Thank you so much!!

The definition for engine displacement is flawed. Bore and stroke is not the total volume or displacement of a engine. To exclude the piston hight, the un-swept, or (combustion chamber), makes no sense. There is always a give and take. The lower compression piston has less piston hight, taking up less space in the cylinder, giving you a higher displacement. The higher compression piston, means increased piston hight taking up more space of the cylinder, and decreasing displacement. Using his example of a 2L 4 cylinder, with a 500cc cylinder. The piston that gives you a low 8:1 compression, has a un-swept of 55cc. Giving you a total of 555cc, that is a 11% increase to displacement, that is a big deal. Bringing the true or total displacement of the engine to 2220cc or 2.2L. Now if you swap the pistons for a 14:1, I think he said you would have a un-swept of 35cc. Bringing the cylinder to a 535cc, and a total displacement of 2140cc, or a 2.1L. He also claimed a increase of 14hp, and a better fuel millage. Now he claimed that increasing compression decreases volume efficiency. From the data he has provided, that statement is false. How can a engine that has less displacement, and uses less fuel be said to have a lower volume efficiency? This is only possible when you have a increase of volume efficiency. We have to remember that all parts have to work together. For example increasing the flow rate of the head, on paper should mean more power, but in reality that might not be the case. A evo8 with the stock turbo would not see a increase in performance, it might actually decrease it, do to a decrease of air velocity or VE. The stock turbo does not flow enough air to support this. Now if you put a gt35 on it, then increasing the head flow rate makes sense and more power. I just want to say thank you for making this video, and sharing your knowledge.

Higher compression in boosted applications definitely has its place more compression means you can make the same power with less boost and get faster spoil I think That's why things are really going that direction nowadays

Great presentation. Very well spoken. DSPORT deserves an award who agrees?

As the unswept volume decreases with increasing CR , swept volume increases as well .. total volume remains constant . At 9:13/9:42 you call 2nd column unswept , later 10:19 calling it swept !!!

Love the way you explain everything, goes straight to the brain. I wish, i could've got to attend your classes/workshop.

3 things determine displacement bore. stroke. # of cylinders. Higher ignition temps depends on octane/fuel. 94 octane gas burns cooler than 87, E85 is cooler yet. Also, there's no way a 8:1 engine will have a higher VE than a 12:1 engine with all things being equal. Another thing 8:1 engine @ 45 psi you certainly won't be running 45 psi on a 12:1. 15 psi on a 12.1 will be making equal to or greater horsepower than 45 psi @ 8:1, plus the VE & efficiency on the 8:1 when not on boost is going to be terrible. Now if you talking NA, compression ratio is KING DADDY, there's no compromise, and the VE on high compression will always be greater than lower CR's. Good thing some of the top racers don't subscribe to your theory haha. I could go on but I'm tired of typing.

I raised my fiesta's compression to 12 to 1 and over bored it .75 and I can feel the difference. It was part of the Rebuild

Compression ratio does not affect volumetric efficiency -- volumetric efficiency is just how much air mass a cylinder actually sucks in vs. how much air mass the cylinder can "maximally" hold (as if the piston did nothing and just sat with open valves at BDC all day). The slower the piston (giving more time for air to flow in) and the bigger the valves (for more air inflow "area"), the better the volumetric efficiency. Simple as that -- compression ratio plays no role.

Racing engines have a way greater VE than 100%. Cylinders at rpm are being filled with more volume than the math indicates. Due to valve events, and port velocity. Design of quench area is extremely important when building a engine that runs better than it should. A 8 to 1 engine will spark knock way more than a 10 to 1 engine. The efficiency of the combustion chamber is more important than CR within reason. 9:1 vs 12:1. All my experience comes from NA Racing. I know very little about boosted apps.

XR650L - 2009 version. 8.3 going to 10.2 on local pump gas 95 Octane - should be a sweet spot. Smoking hopium until things turn out right. Cool channel. Greetings from DBN.

I am more interested with compression ratio in relations to power in a NA engine..

Can you post the charts for compression ratio thermic efficiency and volumetric efficiency? Does this mean there is a point where the amount of boost would dictate your compression ratio?

Great video !!! You really didn’t addressed noc psi or NA engines or the math behind it, however this was awesome I think if you added a tiny bit of animated grafix and charts we would all understand allot better

I’m only 8 min in and I’ve already learned a ton. Cheers mate

I have a question. I have a supercharged 9.0:1 vvt 4.4 with 12 psi of boost with centrifugal blower and intercooler the size of the radiator. if I went with a 10. 5 4.8 with all things being equal from engine to engine minus comp ratio an displacement would I loose or win. I understand it a very general question.

How do I determine the proper timing for a engine that is being built as a high compression engine?

Which one is good for fuel economy?

I'm reading between the lines here but if volumetric efficiency is the ratio of fuel/air charge volume to swept cylinder volume then presumably the reason a higher compression ratio yields worse efficiency, is that you have to ease off the volume of gas introduced into the cylinder on each stroke, so as to avoid preignition, right? Because at high compression, knocking is going to occur if you cram too much gas in there.

All that and miss the real point. Compression ratio is really the EXPANSION RATIO.

So does this all mean for any given engine, if I had say 16 degrees at 47psi, 8000rpm with 9.0 comp and then raised the comp to say 9.7 with everything else remaining the same, there is a much higher chance of knock and detonation and cylinder pressure?

What would the cross over point be on a port injection motor as we run much lower cr as opposed to direct injection

Great class good nowlege can't off tricky or confused but I highet comp lest boost more power that's my understanding great 👍 video man but very derispect full people in there

I have a question, what about NA engines with no turbo/boost? Does high comp ratio equal more power in NA's? When would it be advisable to increase CR in a NA engine?

Thank You for sharing! I love all motor application, and this is definitely worth watching and learning! By the way, I was basing the 2L bore and stroke off from a factory K20 86x86. It’s easier for me to compared and reference. Love it! #allmotor

what about non turbocharged engines? like bike engines , what if it is changed from 9:1 to 12:1?

Honda engines.... I got a JDM F20B (11:0.1 Stock Compression). Thinking of fully building this engine & going 12:0.1 on 10psi max. How reliable so you think that will be? Honestly just making this build to daily the car & keep up with modern daily sports cars. I went from a D15B8 (70 HP) to F20B (200HP). Not building an all out racecar just want something fast & fun to abuse daily. Most likely going to keep it at 5 or 7psi since I don't want to blow the engine & lose all my $$. Reason why I say 12:1 Compression is because it's almost the same Compression as stock. I won't dare to go 13 or 14:1.

You must be new at this. The engine is a combination of parts that must work together, hence a given compression ratio must be combined with the right cam and heads to max it out.

You didn’t explain WHY you get less power with more boost and higher comp ratio. Is it to do with knock limitation??... or are you still able to reach MBT??

A lot of math,, but all is lost as you forget one thing. The higher unswept volume the more possibilites to have more diluted gasses left in cylinder when exhaustvalve closes. Especially in turboengines that reaches equal exhaustpressure as boost, or even worse, higher exhaustpressure than boostpressure. This combo won´t 'flush' the combustionchamber as good as an tuned N/A engine. One might think that pulsation would take care of that, and yes in an N/A engine it can do that, and reach high VE numbers. But a turboengine is something else. It can have some pulsation left, but as the pressurelevels over intake/exhaust during overlap is higher in boosted mode, the density is higher, tempratures is higher, so all pulsetuning in N/A mode alters quickly and might even become really bad. The experienced guy will recognize this that the N/A engine with a tuned header might have some 'chop' to the idle. And when slapping that turbo exhaust manifold on it the idle chop increases.

Very interesting and informative.

ok then can I ask something so what different compression 10:1 and 9:1 if they dynamic compression is same like 8:1 dynamic compreession?? what different in power and thermal efficiency between that 2 static compression ratio????

great work Michael! Very smooth delivery of technical stuff. Just a quick question: why does total volume increase with increasing compression ratios? I mean why not just decrease unswept volume like you showed in the Subaru heads example and increase swept volume to accordingly account for that decrease keeping total the same? or is is some kind of standard volume values manufacturers follow? Thanks!

What compression ratio can I use in my all motor h22a,5100139 want more power

Running a 13:1 big turbo on my built lsvt hoping to see how it runs

Have you posted the Math or charts to calculate this. I am at 11:1, VQ37VHR at 22psi of boost. HP was 780whp. Factory compression was 11:1. I am trying to figure out what compression ratio I need to run. I am building another engine. Max boost will be 24psi this time.

So if increase the compression at top dead center(high comp piston) whats the technical terms ?

Nice work Dsport. But if you extrapolate the maths to even lower compression ratios then the numbers show significant total gains by going even lower than 8. Have you done the maths for a compression of 5 or 6? This show 10-20 percent gains on some engines in theory.

farm tractors used to have low compression pistons to run on gasoline and high compression pistons to run on propane

For piston-ported 2-strokes (chainsaws), does this "volumetric efficiency" concept matter? I've watched your (awesome!!) presentation a couple times now and still struggling to understand this "losing volumetric efficiency" concept, when explained it basically sounds like "If you have a smaller combustion-chamber, you 'lose' volumetric efficiency" -- well, of course, that is inherent it's like using synonyms, to reduce the chamber and up compression is to inherently reduce chamber-size (though I'm still lost on the concept of 'volumetric efficiency' as, to my misunderstanding ears, it sounds like wishful thinking "Oh if only we had the larger combustion-volume *and* the higher compression" (ie have your cake & eat it, too) which of course doesn't happen....this "volumetric efficiency" concept sounds like it is automatically "inverse-correlate" to compression-level of the jug, so the idea of "efficiency" being part of the term confuses me (ie why not just say 'reduces area of combustion', yknow?) For chainsaws where boost is not on the table, and compression is kinda "the go-to" for higher-power modifications of saws, it has me wondering again if "more=better" for this application (IE, it's "more-better" at least until the point you're snapping rods / cracking pistons / etc) For context, I'm working on a pair of kit saws that are 92cc displacement, OEM spec is 13.1:1 compression ratio but I took the cylinder and squish band down so the entire jug sits lower on the crankcase *and*, with that higher squish band, my combustion-dome is now automatically smaller....problem is I'm having a helluva time telling what "ideal" compression would be here, I can really only aim at it as I've also ported the case (ie volume is now >92cc) but it keeps seeming like "I should go more & more compression until I'm worrying about the rod / internal failure of engine components", it doesn't seem like there's a practical wall to performance IE *if* I had titanium internals that could take 15:1, that *would* mean a stronger saw, period. Thanks again for the video & even more if you can help me out, have watched all the chainsaw-specific content that seemed worthy but so much misses so many critical concepts (it's a norm to take a 1/2" drill to the rear of the muffler "for flow & cooling" w/o a 2nd thought Re negating the back-pressure required of a muffler for a 2-stroke to function properly :P )

All these numbers are peak HP? What about area under the curve. I've built a 10:1 RB25, all angled to mid range. Peak boost will be 28-30PSI. So what affect do you have in the mid range...

@DSPORT so i have a built Fa20 at 10:1 compression but with wrx pistons running about 20psi... can you explain what is going on in my chambers?

Great video. it helped me a lot. I have one question if u don't mind. I have a car with a 4 cylinder 1.747 L engine that produces 130hp and a compression ratio of 12.1:1(multiport injection) and a weight of 1222 Kg or 2696 pounds. Let's say I want to achieve 200 250 hp, If put a turbo should I lower the compression? or can I get away with the same compression and not so much boost? what would you consider ideal and what would be ok to do? looking for a fun "reliable" build

Very nice vid ive been building engines for a long time lol I just stuck to what worked but have a better understanding now I can picture it in my head what is happening thanks loads

Would this be the same for the FA20DIT application? Also have you guys seen any actual fa20dit with built engine's last more then 20k miles? I'm starting to believe the 15+wrx should not be built

32:25 I have a fa20 brz. So if I reprofile my combustion chamber and shave some of the of the material to mimic the fa20f combustion chamber, I can effectively lower my 12:5 compression ratio for boosted application?

Thank you sir,big help to me👍

It's about cylinder pressure not compression ratio. The bigger the cam in duration the more compression ratio your need to maintain a given cylinder pressure.

What's the highest compression ratio you would want to run on A NA build, if knock was not A factor?

Screw the science just drive a turbo trans am from 1980 with 8 to 1 and them drive a small block with 10 and a half to 1 flattop and the non turbo will roast the turbo car like it's a 4 cylinder 80 horse engine lol

When the teacher is teaching whith he’s heart and you got kids in the class room

Do the math using the imperial system. I dear you. Lol Nice vid.

very good sir, ty ty

so you telling me at lower boost levels a 250 could be improved?

Before I view your video; I must emphasize an evident need of a multiple fuel types injecting systems of tweakings on an automatics management programing capabilities. And also; why isn't there a weighted type of piston or a ram system that cranks cocked a load that keeps a force or anything that makes more sense than top dead center being the combustion instead of the chamber being on a up down cycle as an also application where one's combustion is diverted as channeled within the last one before's chamber that it also had done the same(a need for 16 for 2 cycle and 32 pistons for a four cycle would be needed for this) ........... It takes such shallow concentrations in order to advance logistics of combustions engines; that I realised another while writing this. It's the chamber that needs to drive a crank driver; of or and an engine should be a drive motor.Cheers

I am hoping to build my k20 I want to turbo it at simi low boost What my goal is I want to increase my mileage and power my factory compression is 11.0 when i rebuild the engine I had planned to run 12.0 on 7-14 psi this is a normal street car and want reliability. I'm not chasing the drag strip mostly hoping to break end up with 300 ish hp and slightly better fuel mileage. would I be smarter to run 11.5:1, stock, or the 12.1 I had planned. the car will probably be out of boost most of the time and didn't want to give up the low end.

Bore x bore x stroke x .7854 x number of cylinders🚀

You left the labels on the small containers...

I appreciate the video.

This was an awesome video. Thank you so much for making this

i think you need to understand about level of combustion accure in different level of compression. i know when we increase compression ratio, it will degrease swept volume like you what you say. but its just make tiny different than increase compression. if compression increase, level of heat combustion will do. i am study in mechanical engineering. so i know about this.

is that like a actual university?

Is it true that higher compression ratio only helps more or less below 5k rpm?

How much compression ratio is the best

Beware of the Crickets😳 if the guy in the other lane has crickets coming out the pipes at idle be very aware

This is why we turbo Méxican nissans engines with mexican stock ratio of around 12@1's like is nothing... 😂😂😂😂

I can't see shit with the fish in the way

I want square pistons , square valves. Why wouldn’t this work and why hasn’t it been attempted?

why diesel engine run on lean mixture?

What a bunch of disrespectful people in the class....

❤️it!🇺🇸

Nice guys!

I see not all heros wear capes

"Quench Pads"

🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥🔥great teacher!

Fantastic thank you

This people don’t have no respect in that room

Yes untill detonation or preignition comes knocking on your door

Would have been better if you went threw the maths how you found the loss in power on high boost etc You could be chatting crap lol but good content thanks again