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A.T.
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You can say 'no' to all physical models. The approximation I proposed doesn't require any additional info, and already makes clear how little the speed will increase.anorlunda said:
You can say 'no' to all physical models. The approximation I proposed doesn't require any additional info, and already makes clear how little the speed will increase.anorlunda said:Sorry no on both counts.
A.T. said:You can say 'no' to all physical models. The approximation I proposed doesn't require any additional info, and already makes clear how little the speed will increase.
A.T. said:The approximation I proposed doesn't require any additional info, and already makes clear how little the speed will increase.
DaveC426913 said:Is the approximation in post 69, and the summarized conclusion in post 72?
Yes, if you really want to get more specific then you cannot solve this analytically.Hercuflea said:This thread calls for some simulations.
Can this condition be true of a motor that is specifed to only be able to push the boat from 0 to 5 knots?ddjj77 said:If the motor or engine is able to operate at any RPM...
No real motor can operate at any RPM, but that is not required to provide positive thrust at 10 knots.DaveC426913 said:an this condition be true of a motor that is specifed to only be able to push the boat from 0 to 5 knots?
IWO, with that limit on the motor specified, can it still be stated that the motor can operate at any RPM?
What is relevant is the power output. If the motor is working extremely inefficiently at 5 kts (far below it's optimal RPM), so that it's power output at 15 kts is multiple times higher, then it might add those 5 kts or even more to the 10 kts by sail. But this is a rather contrived case.ddjj77 said:If the motor or engine is able to operate at any RPM, then it will be able to provide an increase in speed by 5 knots.
Not quite the same, because the rocket force doesn't depend on velocity like engine-power supplied force does. But you still won’t get an 5 kts increase, because drag is non-linear.Hercuflea said:I'm still trying to think about whether this question would be the same if, say for example the motor were replaced with a tiny rocket mounted above the water that is capable of pushing the boat along at 5 kts.
desertbike said:One of the things that all of these discourses have failed to take into consideration is maximum hull speed of a sailboat. The maximum that a boat can theoretically sail is the square root of the waterline x 1.34 for a displacement hull, x 1.43 for a non-displacement hull. So the square root of a 25 ft waterline, = 5 x 1.34 gives a hull speed of 6.7 knots. You can achieve a reduction on the rigging and sails by use of the motor and to even out the pulsations of the wind effect on the sails, but only by lengthening the waterline, usually by heeling the boat over 20-30 degrees, can you increase the hull speed of the sailboat. Once you go past hull speed the drag increases and the boat sits lower and deeper in the water and if speed is not reduced you can sail the boat under and lose it all.
Missed this before. How does that work?desertbike said:Once you go past hull speed the drag increases and the boat sits lower and deeper in the water and if speed is not reduced you can sail the boat under and lose it all.
Ah. I see.gleem said:As the boat speed increase a bow and stern wave are created and increase in height with a concomitant reduction in the water level between them. A sailboat has a greater percentage of buoyancy at mid ship where the beam is greatest with much less at the bow and stern. Thus relative to amount of the boat above the water level at the beam the bow and stern are more underwater. If the boat goes fast enough and has too little buoyancy at the bow you could submerge the bow. This usually doesn't happen under the boats own power but if it is being towed by a more powerful boat it has happened apparently.
You are only talking about specially designed racing sailboats. That can only be true on certain designs of sailboats, ULDB's (Ultra Light Displacement Boats) which are primarily off the wind sailboats with little in the way of keels and hulls designed specially to plane, they don't go to weather well at all, or multi-hulls, these days usually catamarans. Multi-hulls have come up with designs and systems which allow the boat to sail faster than "apparent wind" speed, and have incorporated foils to raise up out of water which is what you suggest. But the typical sailboat is a displacement hull and doesn't follow your premise. I've sailed well over hull speed in hurricanes unintentionally, and pushed a 60 ft boat deeper in the water in the process, increasing drag and load on the rest of the rigging and structure.cjl said:This isn't true at all, or boat racing would be a very boring sport. It's true that power required goes up pretty dramatically as you approach and exceed hull speed, but when you do, the boat definitely doesn't sit lower and deeper in the water. It starts to raise the nose instead, and depending on hull design, might even get up on full plane (at which point it can go almost arbitrarily fast if you have the power to do so).
As I stated in another post on the subject I've nearly sailed a boat under before in a hurricane down south, but we reduced sail to keep from plowing it under. I know of boats under tow being pulled too far past hull speed and being submerged, and have read historical accounts of it occurring during battles and hurricanes. It's not an issue with multi-hulls or special hull designs made to plane or surf. They have their own bad things which can happen when going too fast, but the engine (remember, this all started about the engine!) can help mitigate the pulsations of sail power and provide a better smoother sailing experience, but it's not going to let you get too far past hull speed.gleem said:As the boat speed increase a bow and stern wave are created and increase in height with a concomitant reduction in the water level between them. A sailboat has a greater percentage of buoyancy at mid ship where the beam is greatest with much less at the bow and stern. Thus relative to amount of the boat above the water level at the beam the bow and stern are more underwater. If the boat goes fast enough and has too little buoyancy at the bow you could submerge the bow. This usually doesn't happen under the boats own power but if it is being towed by a more powerful boat it has happened apparently.