Harvey wrote:DewCatTea-Bob wrote: the intake-charge was already waiting (behind the intake-valve) in an overly-positive state of pressure,
The inlet tract is not in a “overly-positive state of pressure” when the valve is to open, it is at the end of the cycle when the valve is closing that there is a positive pressure at the valve.
____ You are most-certainly not incorrect Harvey, (DEPENDING-on exactly WHICH 'air-pressure' we are actually in reference to !). ...
__ In order for my chosen-wording to have made completely CORRECT-sense, I should've made ALL such details better established.
In defense of my (rather incomplete) post-wording, I now point-out that there are actually more than one 'pressure' which could've been the 'point-of-reference pressure' being referenced-to, in my statement - (those others being 'cylinder-pressure' & 'exhaust-pressure', in addition to 'atmospheric-pressure'). _ However, the particular pressure-difference which I was actually in reference-to, is 'intake-PORT pressure' relative-to 'atmospheric-pressure',, (which you apparently correctly assumed).
HOWEVER, it seems that you need to be brought up to speed on the matters of in.port-pressures... While it is very quite true that in.port-pressure is at it's MAXimum just-AFTER the in.valve has closed (due to ram-effect), that pressure then only BEGINS to become relieved as a created pressure-wave moves backward through the intake-tract (at about the speed of sound, from the closed valve-head). _ And while that pressure-wave is on it's way out (to become fully released, once it's wave-front reaches the open-end of the intake-tract, [to THEN become exposed to the atmosphere's pressure]), it's pressure is STILL-remaining greater than that of the atmosphere !
__ Now IF I had been in reference to an engine running at low-RPMs,, THEN, the point which you've made would then very-likely be completely-valid indeed, (as in such case as THAT, the in.port pressure-wave would've then had TIME to become exposed to the atmosphere). _ BUT at higher-RPMs, (which I had quite definitely referenced to), that pressure-wave doesn't get enough time to reach-through back-out all the way to the atmosphere BEFORE the intake-valve is once-again opened ! _ (Thus my questioned-claim is actually indeed certainly VALID !)
__ And that's the added-pressure effect which wilder cams like DESMO-cams depend-on, so as to help better fill the cylinder ! _ And that's a substantial contribution of why engine-torque builds-up as revs increase, cuz that pressure-wave gets less & less time to allow the intake-port's rammed-up air-pressure to re-diminish (all the way back-down the in.port & out the inlet) before the in.valve opens again.
And that's why wilder cams produce the power-effect which is often referred-to as "coming-ON-the-cam", (as those cams open the in.valve earlier, so as to take greater advantage of the intake-charge's rammed-pressure,, NOT ONLY before it gets completely released, but MORE-so before it even becomes very diminished !).
So-thus as the revs build-up higher & higher, the in.valve then repeatedly opens to even-better catch that rammed-up air-pressure sooner & sooner before the retreating wave-front gets much time to further bleed-off the intake-port's built-up max.pressure (which had occurred just-after the in.valve closed on the previous 4s.cycle). _ Thus-therefore leading to that 'rush' of building power that ya feel as the engine "comes-on-the-cam" !
That effect could never occur IF the pressure within the intake-port were to INSTANTLY-diminished (back to mere atmospheric-pressure), much faster than the speed of sound !
Harvey wrote:DewCatTea-Bob wrote:creates a vacuum which strongly tends to suck the ex.valve closed
When the inlet valve opens the exhaust valve still has about 60* till it closes. By that time the negative pressure that was in the exhaust pipe has dissipated in starting the inlet gas to move. So no sucking of the valve to keep it closed.
____ Sorry Harvey, but I can-NOT agree with you any at all, on that statement of yours !
While that which you've stated would certainly be true IF the exhaust-port was opened directly to the atmosphere, it actually takes a relatively much greater time for ALL the mass of the expelled ex.gases to be thrown-out (from the cylinder) all the way to the tip-end of the ex.system, (which is part of why the ex.cam has to continue holding-open the ex.valve, [so that the moving-gas doesn't pull the valve shut along-with or behind it] ) !
AND-also, on-top of that effect,, once most-all of the fresh-ex.gas has just been expelled from the ex.system,, a vacuum (relative to atmospheric-pressure), pressure-wave then travels back up the ex.pipe (near the speed of sound) towards the ex.valve, which of-course creates a relatively-great NEGATIVE-pressure which not only MORE greatly attempts to suck the ex.valve shut, but also greatly assists at pulling-in the intake-charge (inward past the in.valve) ! _ THAT effect is often referred-to as "coming-on-the-pipe".
(However that desirable effect also comes-along with a following (undesirable)- positive pressure-wave, which occurs after the exhaust-system once-again becomes fully re-pressurized [as the atmospheric-pressure becomes re-established within]. _ So by then, ya desire the valves to be closed [or-else there'll then become a loss, which is part of why mild-cams & wild-cams perform their best nearer to opposite-ends of the RPM-range].)
All this tech.stuff is referred-to as valve-timing & ex.system 'tuning' (to best suit one-another).
__ So now back to my original claim,, the ex.valve has no (overwhelming) reason to get pulled-open by the piston's downward-action, even when there's no valve-springs or closing-lobe to prevent that undesired action,, as the mass of the expelled ex.gas creates all that's necessary to keep the ex.valve closed (long enough) without the added-help.
____ Incidentally,, concerning DESMO-cams, your statement:
"When the inlet valve opens the exhaust valve still has about 60* till it closes.", is rather OFF,, as when the in.valve is about to open, the ex.valve still has another 135-degrees before it closes !
__ And also,, IF your statement:
"By that time the negative pressure that was in the exhaust pipe has dissipated in starting the inlet gas to move.", was actually true, THEN there would be no sense in purposely keeping the ex.valve remaining open (for continuing to perform that particular function) for so long, (as is ACTUALLY practiced).
Or are you really meaning to declare that the designer (of the DESMO-cam.model) was wrong to have purposely set the ex.valve to stay open for so long as it does ? _ Cuz if not, then certainly leaving the ex.valve open that late (during the intended high-revs), must STILL even then be purposely-intended to help perform the function of helping to draw-in the intake-charge !
Harvey wrote:DewCatTea-Bob wrote:(And of-course we're aware that when the valve-head is raised further out of the way, increased air-flow is then the result.)
Not So. In the case of a 40mm inlet valve. Port throat area-valve stem=968mm2. The valves open area at 8.1mm lift= this open throat area. So it does not matter know much more lift you have, the valve throat won’t flow any more. It is the amount of time that the valve throat flows at its maximum flow that counts.
____ Okay Harvey, you seem to have caught me with my chosen-wording not having been detailed extensively enough,, (which is most-often purposely-left to be less-detailed whenever my wording is thusly bracketed with-in the next-following notation-marks: ( )
).
__ Anyhow, it seems that you're claiming that if tested on a flow-bench,, regardless of whether the valve-head is held-open at-least 8.1mm, or completely removed from it's stem,, the flow-bench testing would remain indicative of the very-same flow-rate in either case, (since ANOTHER limiting-factor -[the "Port throat"] has already set the flow-limit) ! _ Is that correct ??
__ To put your statement in other-words... I believe you're claiming that once the created-area between the valve-head & it's seat has been lifted-upward & increased enough to become EQUAL to the same amount of area as that of the valve-seat ID's area, (minus the area-space taken-up by the valve-stem, of-course),, that THEN no further increase of the valve-lift area will allow for any further increase in air-flow. _ Is that not pretty-much the same as you meant to state ? - (Just so I'll know for-sure that I've properly understood exactly what you're claiming.)
I've checked-out your math, and in order for it to be correct, your expected 'port-throat' restriction-diameter MUST be '36.0mm' (in order to equal-out & exactly-match the same area-figuring for "8.1mm" of valve-lift. _ (So it seems you have a good handle on your math-skills.)
__ Now I must admit that that logical/mathematical reasoning SEEMS to set-the-stage as being firmly-sound & undeniably factual. _ However, if such was ACTUALLY & completely true, THEN it would make no sense for cams to have lift-heights which actually provide even greater lift-areas.
While it certainly must be true that up to that point of equality, there are of-course SUBSTANTIAL-gains derived from increased valve-head lift,, anyMORE beyond that balanced-point, will merely provide 'diminishing-returns' (up to the point where as if the valve-head has been completely taken out of the picture).
The reason that the valve-head still remains as an impediment to airflow even beyond that point of area-equality, is because the v.head forces the air to change it's flow-direction ! _ (You wouldn't expect an unrestrained intake-valve to be content with remaining set in-place [lifted-out merely to that point of area-equality], with air being forced-through the in.port & towards the valve-head,, now would you ?) _ The fact that the valve-head has to force the air-flow to change direction, is the proof that it must be continuing-on with impeding airflow, even when beyond that point of area-equality -(that you've indicated of) ! _ It's just not as great of an impediment as it is BEFORE that equality-point is reached, (as it's merely-just a turning-point between substantial & diminishing-return gains).
After-all, airflow is what it is... 'air-flow',, disrupt it's 'flow' in any way, and it becomes decreased ! _ (And ANY decreased amount, is of-course undesired [in the case of intake-valving], which is why even higher valve-lift is always sought-after.)
IF that point (which I think you meant to make note of), were actually all there is to it,, then in like-kind, it seems that airflow would not be assisted at all by a carb with a bore-size that's any wider than the diameter of the intake-port (as opposed to a carb with the SAME bore as the port). _ After-all, 'funnels' do help 'flow', and so then why shouldn't a funnel-shape in reverse with an increased outlet-area, (which is pretty-much what we're equating-to - with a valve-head opened even further), not also help-out with max.airflow ?
__ Obviously I've gotten too carried-away at this-point, as I think my viewpoint has already been made fairly well enough.
Any further arguments ?
____ I actually appreciate others who so attempt to help keep me (& my claims) on-my-toes, (like with these posts) ! _ As it helps to keep the O'noggin off junk-TV, and hopefully also helps others to contemplate something which they may-not have otherwise.
Dukaddy-DUKEs,
D.Bob
