Your assertion seemed to be that the cause was due to "abuse" or where someone was a fault for doing something wrong. It could have been simply the "environment", normal usage, age as contributing factors.Trying to pull a fat girl up slalom one time doesn't break an outboard crank. It was either a manufacturing defect, or the last straw in a long history of abuse(s), i.e. overpropping, underpropping, etc.
Well, it certainly wasn't a new engine so perhaps the parts were already worn, cracked, etc., but there is no doubt that the specific waterski incident was what caused the crank to break..as I observed it with my own eyes and ears.Moe wrote:Trying to pull a fat girl up slalom one time doesn't break an outboard crank. It was either a manufacturing defect, or the last straw in a long history of abuse(s), i.e. overpropping, underpropping, etc.
Well said, Moe. I've adopted it as my mantra, but for the dozens of times I've posted it, many seem not to get it, or simply don't subscribe.Moe wrote:. . . However, in the latter case, there's usually a weight penalty to be paid. Frank C chose the "big motor with longer life at the same lower output" . . . Where performance and/or initial cost matter, longevity is often, if not usually, sacrificed for for lighter weight.
(and me thinks Moe does too!) Lets just stick with the word "load".I don't fully agree with this because when the engine is under a greater load, the RPM (and piston speed) is definitely lower. On my boat, it can be as much as 600 RPM's lower under load. Although I do agree that wear goes up...and expect that it is due to higher torque on the crank (caused by higher load on pistons and rods).There is, however, an increase in piston, rod, bearing, and crank load due to the higher piston speed (compared to that at the torque peak rpm), as the piston is accelerated and decelerated. And wear goes up as well.
My previous posts were in response to Chip and Moe stating that the higher loads of more weight did not stress a motor out additionally. But to get back to BK's original question, I can plane my boat with full ballast (and 6-7 people) with a 50HP bigfoot. Sure, it is just barely planing at about 14 mph but it is still planing. So therefore, I don't believe you need a bigger motor just to "plane" with full ballast.BK wrote:I have been reading the posts on larger engines on the Mac and one of the reasons stated for buying a bigger engine was to plane the boat with full ballast. It is stated in the manual that each 100LBs of weight in the boat reduces speed by one MPH. At 1400LBs of water in the ballast, a lot of power will be needed to move the boat at high speed. Also, I think the boat was never designed to carry a full ballast at high speed and could be a safety issue. I would check with Macgregor on this point as that is a lot of stress on the F/G. As far as I know we have never discussed this before and did not want it to get lost in 60 replies. Alot of money for something the boat was not designed to do.
IMHO, Frank's statement also proves the point that you don't need a bigger engine to run with full ballast. I'm pretty much like him, although I don't run at full ballast in heavy conditions much more than 11 mph. Moe will probably know the exact number, but I expect my engine is turning what, 2-300 more RPM at that speed? Not a big deal IMO.Frank wrote:And to fully connect w/ the thread topic, I have NEVER driven my fully ballasted boat at WOT except on the smoothest water, and only for the briefest of minutes. Don't see any reason to do it, and many reasons not to. When ballasted in heavy conditions, I willingly drive the boat at prudent speeds, probably 4000 rpms & ~11 knots. If wave conditions punish the hull at that speed, I slow down. With my usual crew of 2 or 3, my boat (as loaded & equipped) absolutely does not need ballast to run safely in heavy conditions, and I'd prefer empty ballast. Speed is potentially higher, maneuverability is quicker, economy is better, ride is drier, and IMO, the hull suffers less.
So, would you say that you never run unballasted at WOT then? If so, I can understand your "mantra"...but if you do occasionally open her up and get that extra few mph over a 50, then what are you trying to get people to subscribe to? Also, I believe you bought a brand new boat and were already pushing Roger's design envelope in your mind at the time. You probably didn't have the benefit of Billy, Mark, Rolf, and other's BIG engine switches at the time. Begs the question of if your motor blew up tomorrow and you had to repower, would you go bigger than your current motor? And would you ever "open her up"? Or would you just enjoy that lower RPM cruise.Frank wrote:I've adopted it as my mantra, but for the dozens of times I've posted it, many seem not to get it, or simply don't subscribe.
Yes, rpm at WOT heavily loaded is lower than WOT lightly loaded, but reread what you quote from me. I was referring to speed relative to the speed at the torque peak, which is much lower than either WOT speed.Dimitri wrote:Moe wrote:
There is, however, an increase in piston, rod, bearing, and crank load due to the higher piston speed (compared to that at the torque peak rpm), as the piston is accelerated and decelerated. And wear goes up as well.
I don't fully agree with this because when the engine is under a greater load, the RPM (and piston speed) is definitely lower. On my boat, it can be as much as 600 RPM's lower under load.
Under load, the engine applies torque to the drivetrain. The load is irrelevant. The most torque on the drivetrain is that which the engine is supplying. If it is greater than that required to pull the given load at the current speed, acceleration occurs, and vice versa. If the load goes up, deceleration occurs until the load (drag) decreases to match the torque, and vice versa. Under deceleration with engine braking, the load applies torque to the crank.Dimitri wrote: Although I do agree that wear goes up...and expect that it is due to higher torque on the crank (caused by higher load on pistons and rods).
What I wanted you to see is that it is possible (with the right prop), to narrow the rpm range between loaded and unloaded.Dimitri wrote: And about slippage, I didn't say there was no slippage (nice figures though). My point was that the slippage would not be enough to significantly reduce the load (unless you are running the outboard in a barrel or something)
I hate to break the quote here, but need to say that none of us, except the guys who run the motors on the dyno, know what the horsepower curve looks like in the last 1,000 rpm. Mercury's service manual says the EFI version gets peak HP at 5750, which is conveniently halfway between 5,500 and 6,000 rpm. For all we know, the horsepower may be within +/- one to two HP from 5,000 to 6,000 rpm, not just 5,500 to 6,000 rpm. My point is, you MAY have as much horsepower at 5,300 rpm as you do at 5,900 rpm.Dimitri wrote: You may call it "overpropped" ... but in a practical sense, when I have full ballast and 7 people aboard and can only turn 5300 RPM, I'm not putting out max HP because I need to be between 5500-6000 for that.
Whoa! I never said that. In fact the opposite. My point was that in the last 1,000 rpm with two-valve engines of this size, the HP at the loaded and unloaded rpms is the same or very close. It was on that I based the high/low miles per hour. The 35HP had nothing to do with this.Dimitri wrote: Next day, I go out by myself with no ballast and I can get up to 5900. I'm not about to switch props in the middle of those two days....as much as my uncle was going to switch props between 80# and 200# skiers. The lower RPM at load argument pretty much disproves the argument that you are putting out 50HP at load and 35HP when not at load, don't you think?
That's correct. At rpms above the torque peak, torque is decreasing as speed increases. If the torque is decreasing slower than rpm is rising, horsepower increases as speed goes up. If torque is falling the same speed as rpm is rising, horsepower remains level as speed increases. If torque is falling faster than rpm is rising, horsepower is falling.Dimitri wrote: Now, if you change that to higher torque at load (with lower RPM), I could buy that.
Then you are wrong. Power is proportional to both engine speed and TORQUE, which is supplied by the engine, not the LOAD. Increasing the load does not increase the engine's power output.Dimitri wrote: Both yours and Chip's arguments indicate that the power is only proportional to the speed (RPM) but I am stating that power is proportional to both engine speed AND load. Load will increase as weight (and/or pitch) increases.
Actually your extremes there sound equally unlikely. The motor might not've broken on the next pull, but it wasn't long for this world, certainly not another 10 years.Dimitri wrote: The main point here is that if my uncle hadn't tried to pull the fat slalom girl out that day, that motor could have lasted another 10 years. Can you agree with that??? Yes, I know you can make the point that maybe the motor would have broke on the next ski despite who was being pulled out...but that does this sound as likely?
Sorry... but it's an ancedotal childhood memory that doesn't prove anything.Dimitri wrote: Afterall, we don't typically do high tech imaging on our crankshafts before and after an incident like this...so of course, it is hard to prove beyond all doubt. But if you (or other readers) do agree with me, then it proves the point that there is significant additional stress and wear on the motor when it is under high load.
There's no doubt in my mindDimitri wrote: I believe that both of these last two paragraphs prove that a fully ballasted boat being pushed around at WOT is more stressful to the "machine" than a light boat going at WOT...so, there is where I stand on this topic.
If we say your horsepower at WOT 5,300 rpm is equal to the horsepower at WOT 5,900 rpm, the force required to push your boat to its top speed when heavily loaded is EXACTLY equal to that required to push it to its top speed when lightly loaded.Dimitri wrote: I will agree with you that if you go with a lower pitch meant for full ballast, the wear will be less...but the force required to push the boat is still proportional to the weight so the difference is not zero.
And in their short life, they've done as much or more work as "smaller motors" on lighter boats.Dimitri wrote: Talk to commercial barge folks who use outboards...they don't go fast, but they burn thru smaller motors pretty quick.
This is where you are wrong and should pay attention. I may have been out of school for the better part of 2 decades but I do remember some Newtonian physics and can still do research and equations. Will you buy Newton's theories?Moe wrote:This is where it really gets good now. PAY ATTENTION! If we say your horsepower at WOT 5,300 rpm is LESS THAN the horsepower at WOT 5,900 rpm, then the force required to push your boat to its top speed when heavily loaded is LESS THAN that required to push it to its top speed when lightly loaded.
You seem to have acknowledged the fact that a small engine under greater load (a barge) works much harder than the same engine pushing a lighter load...isn't that my position in this debate???Moe wrote:And in their short life, they've done as much or more work as "smaller motors" on lighter boats.
Old School (work done in one hour):New Physics book wrote:Newton's idea that work=force*distance is not logical. The definition of force as being any influence producing a linear change in the momentum of a body is wrong too. You can apply force to a stone and still not perform any work because of inertia. However, you did exert force. Exertion of force on an object does not depend on reaction of the object. Thats WORK! Work is the result of the force that you applied, not the force applied! Therefore you cannot use force in such equation. The equation for work is W=mass*distance. W=md. The inertia of the object can be calculated by subtracting force from work. The amount of work depends on mass and distance of displacement. It does not depend on friction or even inertia because it does not mater how much force or energy you lost. It matters how much work you have done. For the same reason it doesn't matter how much inertia have you defeated. Newton's equation for work contains "v," for velocity at which the mass is displaced. The velocity has no influence on the amount of performed work, therefore there is no place for it in such equation.
To illustrate my point, imagine two workers who are going to move your furniture. One of them may do it in 2 hours, the other in 4 hours, but they still will perform the same work The speed with which they will do work has nothing to do with the amount of work. It has to do with "power." It's easy to confuse "force" with "work" or "power" because not all their definitions in books are correct.
Everything I Need to Know I Learned in Kindergarten!Moe wrote:Sorry... but it's an ancedotal childhood memory that doesn't prove anything.
a Lot more fun my way BTW
In a single phrase, prove it then!Huh? In a single phrase, no you can't.
