merlot566jka
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A careful and relentless search of this forum and other documents on the LDT-465 have resulted in one thing, do not go faster than 2650 rpm or you'll throw a rod.
I, being the engineer type, ask why? What causes this, and how can we fix it?
To figure it out, I applied some numbers to the question and did some research.
First we start with the research. It is said by race engine builder and author Tom Monroe, that
“Unless your engine will have pneumatic- or solenoid-operated valves, the valvetrain will limit maximum engine rpm, but piston velocity must not be ignored. High rpm operation causes reduced ring sealing , excessive wear and low durability or catastrophic failure from dynamic loads on the piston as it moves up and down. As a crankshaft rotates, each piston travels up and down the bore at an average velocity, or mean velocity, between TDC and BDC. Directly proportional to stroke and engine speed usually expressed in feet per minute, average piston velocity is found by multiplying engine rpm by stroke in inches, then dividing by six. For example, an engine turning at 7500 rpm, with a four inch stroke has an average piston velocity of 7500rpm x 4.000in. ÷ 6 = 5000fpm. For a stroke of 3.50in, average velocity drops to 4375 fpm. The accepted average velocity was 4600fpm, but it is common for race engines to operate at sustained average piston speeds of up to 5700fpm. I am also familiar with instances where average piston velocities have exceeded 7000fpm, although with 200-gram pistons. Advancements in piston design and development of materials used for them, piston rings and connecting rods have made this possible. Although the envelope has been expanded, basics still apply.
You may have wondered how a formula 1 engine stays together at 17000rpm. Notwithstanding pneumatic-operated valves, short stroke is the simple answer. A V-10 wit a 1.7 in stroke has an average piston velocity of 4817 fpm compared to a stock car engine with over 5500 fpm at 9500 rpm! More importantly, when a piston decelerates to a stop at the top or bottom of a stroke, it is accelerated in the reverse direction to maximum velocity. A matter of dynamics, maximum piston velocity far exceeds average velocity.”
Accompanying this was the supportive formula to find the average and instant piston velocity.
“Maximum velocity of a piston occurs when the connecting rod is at 90 degrees to the crank pin. Therefore, the angle of crank rotation from either side of TDC must first be found. To do this you'll need to know connecting-rod length () and crankshaft throw (), or half of the stroke. A calculator or trig tables will be needed for doing these calculations.”
I removed the example, but if you need it, you can pm me or buy the book.
So what does this mean to us? It means that at 2650 rpm, we have an max piston velocity of 3580.7943 feet per minute. Well with in the “accepted average velocity of 4600 FPM”. We shouldn’t be throwing rods like crazy when someone pushes past the 2650rpm limit.
Now this guy is talking race engines, with balanced and blue printed rotating assemblies, and light weight components...right? Nope, this is a basic rule of thumb for any engine building.
But the questions that need to be asked are:
Is the rotating assembly balanced? I sure hope so.
Is the flywheel neutral balanced or specific to the crankshaft? (if someone swapped your flywheel with
a different one that wasn't balanced exactly like yours, something is bound to fail)
Is the crankshaft balancer/harmonic balancer/damper balanced to each engine or are they neutral?
Do the crankshaft balancer/harmonic balancer/damper suffer the same wear and failure that the CUCV 6.2L did?
What is the quality of the LDT con-rods and bolts? The LDS shares the same P/N for the con-rod and bolts as the LDT, so that shouldn't be the limit.
Does the offset rod cap have anything to do with the failures? I don’t know, but I don’t think so.
OK, now why do we still have a limited rpm range? Is it our valvetrain? According to this illustration, we have 216 deg of open intake valve, and 218 degrees of open exhaust valve. Somewhere else I found the number for the lift, and it was based on the valve spring seat pressure tests at closed and open, it was .450in of lift. So we have plenty of cam timing and, as I remember, valve spring to keep this engine alive at higher rpms than 2650. Provided the valves are sufficient in size, I don’t see the valvetrain limiting the LDT to 2650. Especially with a turbo added to the mix, there is enough air coming in and going out to see 2800rpm.
(To add, the LDS has a different intake rocker, the only difference is a hole for oiling, the ratio is the same. )
What about other support systems?
Is the Injection Pump limited by this engine speed? Looking through TM 9-2910-226-34, I see nothing saying there is a limit to the speed of the IP. As a mater of fact the TM has several test procedures for above 2900 rpm.
The alternator? Would an extra 400 rpm kill the factory alternator? Probably not.
Water pump? No way.
The fan? Nope.
Oil pump? Maybe, it could over pressurize, maybe over flow. But looking at the LDS, the use the same oil pump, so I don’t think that’s an issue.
Turbo? Yup. That could definitely limit the rpm range. Spinning the turbo too fast causes the intake temps to soar, pushing the compressor out of its efficiency island. That would be a huge reason to limit the extended rpm range. Not to mention raising back pressure on the exhaust valves. Adding a waste gate and matching a better sized turbo would alleviate that problem. But with out exact specs on the turbo we don’t know the range or limits on it. We do know that over running it at high loads results in soaring EGTs. Consistent high EGTs is recipe for disaster.
Coolant system? I could see it, if the heat cant be removed from the coolant efficiently to sustain higher engine temps caused at higher rpm and load, it could cause a failure. But its not rods flying out of the block.
It is worth while to note the difference in the LDT and LDS that may permit higher rpm. The pistons are fairly different. The LDS ones are lighter, lower compression, and are oil cooled. Does this make the 150rpm difference for the two engines? ****, it sure doesn’t hurt, but I don’t see it as the sole factor.
The injectors are different, make a difference in rpm range? Its possible, if the old injectors cant keep up with the flow at 2800 rpm... but if that’s true, then at 2650 the injectors would be really pushing their limits in the first place. Not to mention the IP being the main factor in driving those injectors.
Speaking of the IP, yeah, that’s different too. Whats the difference? Well there are quite a few, too many to outline here, but do those differences really limit the rpm range? I don’t see it.
What to take from this...
Mechanically the engine (LDT) should be well suited to see 2900 rpm.
The turbo is the largest limiting factor on engine speed.
The quality of hard parts and internal/external balancing are equally important.
Anyone have anything else to add?
