It truly appears that you have not read a single thing I have written. Seriously.
Please read this entire post and save your knee jerk reactions until the end.
I am perfectly happy to “shoot down” things which make no sense. I don't know how you arrived at "ALL."
I've read the entire thread and all you have is theory, just like the rest of us. Pardon me if I am mistaken but it seems like you have agreed with no one and you firmly believe it is false.
You may not be aware, analysis can be conducted by taking a hypothesis and applying known physical laws to see if it results in some inconsistency. If there is, the hypothesis needs to be adjusted, if only to identify factors which may have been overlooked or omitted. I have been searching for any such unidentified factors to explain the perceived successs “left foot braking.” The “common knowledge” hypothesis tends to gloss over that a stalled wheel is receiving no more driving torque than braking torque. I.e. no net drive
I also cannot overlook that you are heavy on assumptions and light on “real world data,” as discussed further below.
That is fine. Feel free to analyze all you want but understand that beginning a statement with NO implies that the other person is wrong. There is nothing wrong with informing someone they are wrong, when they are wrong. In this case however, we are all discussing theory. You aren't wrong, we aren't wrong. No one has solid evidence for why this occurs or doesn't. I will add here that I am not glossing over anything. The stalled wheel receives more driving torque than brake torque, that is why it moves.
I am not going to ignore anything that facilitates understanding of the whole system. Let's at least understand WHY a torque biasing differential can be easily understood to work for the technique - even under the "common knowledge" hypothesis. Whereas (simplified version) an open differential would only provide drive torque equal to the braking torque (no net drive), the drive torque via TB differential can be, for example, 3:1 that of the braking torque. And that clearly accounts for substantial drive.
Again you missed that I have been trying to identify factors which would explain why people perceive success in left footed braking. Understanding how all these systems work is useful.
One aspect of traction control (or “inverse traction control” via ABS) is unequal application of braking force as resistance to cause drive torque to be increased to the stalled wheel. That works. But without some other explanation, braking the wheels on opposite ends of an axle in left footed braking fails as a hypothesis since braking torque and drive torque cancel out. I explained how ABS could achieve unequal braking which would facilitate a perception of success via left footed braking.
Again, we aren't talking about anything with either, ABS, TB diff or traction control. So if you please, leave it out of the discussion. It opens up many possibilities in this situation.
Yes indeed. And we are still seeking a good explanation, not repetition of the same erroneous hypotheses.
Let me just say here that calling a hypotheses erroneous, is just like saying NO you're wrong. When again, we are all discussing theory. Until you have actual evidence to disprove something, you can't say it's wrong or erroneous.
OK. Are we or aren't we trying to take advantage of available traction? Now you are talking about increasing traction, not managing/utilizing that which is available.
This was a further explanation of the previous sentence. I thought that was pretty obvious but I guess not
“Saying it” is to assume facts and reach a conclusion. It is not providing any data nor even describinghow this is taking place, using physical laws. Momentary is about as weasly a word as you could use.
Sorry, Bzzzzzt!
Read by itself I could see how this sentence has nothing to offer, however there is an entire post to go along with it that describes how I think it works.
There you go assuming again. In this case, assuming the fact that you wish to prove. That's poor form.
The “extra heat” nonsense is addressed below.
Assuming something that I know to be pretty common. I could see with your self professed lack of experience behind the wheel how you might not get it but this is often the case. You get stuck, tires are spinning like mad and maybe you start trying to use the brake to help you out of a jam. So you've got a spinning tire to stop and you may even be applying throttle still. It takes very little time to heat up a brake pad like that. When you're off roading, the brakes can often times never get touched for long periods of time, leaving them dead cold until now.
So we now have a limited slip differential? Great assumption!
But, seriously, how much binding is possible? Perhaps this should be fleshed out as it has not previously been raised. I am not intimately familiar with how the side gears normally interface with the housing. Can you fill us in on that?
But recognize that you are starting to get into the area of seeing that the “common knowledge” hypothesis for WHY left footed braking may work is probably myth, which was all I was addressing.
But in support of your theory (THIS detail - wedging side gears - not your scattered shotgun approach), it IS consistent with the anecdotal evidence suggesting there is some very slight benefit to the technique (enough to get unstuck, not enough to climb hills or over rocks). And by your theory, its effectiveness would improve with increasing application of brakes and throttle. And it would work even with operation of only the parking/emergency brake.
Yeah man, this kind of understanding comes along with knowing the inner working of vehicles on an intimate level. It is my profession after all. The inner workings of an open differential is automotive 101. I am not going in to that. There are plenty of youtube vids you can watch. Or spend 30 years learning about cars and working on them and building them from scratch in every form.
Let's start with brake temperature. Yes I am absolutely discounting it. Just out of curiosity, how much braking energy has to be dissipated to stopping a spinning tire? And how many hundred degrees
of temperature change does that create? I think we can agree that heat will result from stopping, for example, a 6000 lb vehicle from 60 mph. How does that compare with merely topping one of its freely spinning wheels @60 lbs from, say, 20 mph (and that's probably high for the speed of a spinning wheel). In terms of energy dissipation, it's a factor of 900. (Energy = 1/2 mv^2)
Bottom line, we're likely talking a VERY small difference in brake temperature and a VERY small difference in coefficient of friction from merely stopping a spinning wheel.
But, also,
IF a difference in brake temperature (and friction) between sides is what enables the effect, the technique would unequivocally NOT work if the brakes are at the same temperature due to the vehicle sitting. Your hypothesis makes a spinning wheel mandatory, and probably requires that it be spun under heavy load (braking plus throttle) for a period of time to generate substantial heat. That does not fit with descriptions of applying heavy brake and throttle and slowly releasing the brake until the vehicle starts to creep.
I will allow all of this stand as it is a fair evaluation. Except the last part, you still do that, only it comes after the spinning wheel stops.
