Jason Mauldin wrote:
Richard Casto wrote:
. I can't speak as to why the Ford OHC engine is so tall. Other manufactures seem to be able to make quite compact OHC V8 engines.
Who?
Ok, I will admit to overstepping here as I can't give good specific example (not that I don't believe they exist). So let me back down and rephrase...
"I can't imagine that the Ford example above is the most compact OHV design that can be done."
There is no one perfect design. So if you want the things that an OHC engine gives you (general the ability to rev higher) then you have to give up some height of the long block.
You can build a short OHC design. I think the Honda SOHC non VTEC heads are an example of this. The cam is low and uses rocker arms to actuate the valves. But if you want to do tricky things such as optimal profiles for each valve, variable valve timing, etc. (all of which bring additional performance advantages) you typically have to move the cams ups over the valve stems which increases the height of the long block.
I also think everyone gives too much weight or importance to the "long block" height and compactness. It would be interesting to see what the total difference is between a pushrod engine and OHC engine once you factor in things like intake, throttle body and other plumbing. Is it worth everything you give up by not using an OHC?
For example here is the Corvette LT5 DOHC engine which shows that it's not the extra valvetrain parts that eats up the space...
Basically where I am going with this is that the majority of the production auto and race engines seem to have gravitated to OHC engines for a reason. The benefits of OHC (more power via revs, ability to do more tricks with the valve timing, more flexibility on head design, and maybe even more fuel efficiency via the above items) seem to outweigh the benefits of pushrod OHV (more compact long block, simpler valvetrain, lower overall height of long block, lower center of gravity, lower cost via fewer parts).
IMHO, the only reasons you see pushrod engines in racing environments are for the following reasons...
1. The rules require it (ala NASCAR)
2. Equivalence rules for pushrod engines result in a performance advantage (ala 1994 Mercedes Indy engine)
3. Stock block requirements for production based engines
4. Marketing
IMHO, GM races the Corvette with a pushrod engine because of #3, #4 and #2 (maybe even in that order). When given a straight up displacement rule for a NA purpose built race engine, nobody is going to use a pushrod valvetrain.
Chevy and Corvette fans may give all kinds of reasons as to why the Corvette street car still has a pushrod engine. My opinion is that it all boils down to ...
1. Historic continuity of identifying feature.
2. Cost
The Porsche 911 is a perfect example of #1. I can't imagine Porsche EVER moving the location of the engine in the 911 for marketing reasons. The 911 faithful want to keep it as is. Just like the Corvette faithful like the pushrod engine (does it also still have the transverse rear spring as well?) I am a Porsche fan, but I consider the engine location in the 911 to be just as archaic (if not more so) than the pushrod engine in the Corvette. Sure, both GM and Porsche make both work VERY well, but both features do not exist for engineering reasons.
One day I do expect the Corvette to loose the pushrod engine. It has been done once already with the LT5 DOHC engine. It will happen again. It is just a matter of time. I suspect that at some point it will just be cost that causes the change.
_________________
Richard Casto
1972 Porsche 914
2013 Honda Fit Sport
2015 Honda Fit EX
http://motorsport.zyyz.comMoney can't buy happiness, but somehow it's more comfortable to cry in a Porsche than a Kia.
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