Lakesailor
Well-Known Member
That's quite right. Teachers have been telling children for quite a few years now that leaving lights on and driving 4x4s will damage the planet.
The Physics Of Sailing
- Thread starter Yantlet
- Start date
BobPrell
Well-Known Member
I do not accept the conventional explanation of how a sail works. I have developed an explanation which is good enough for me at this point. I will discard my explanation if a critical flaw in it is explained to me.
That is a stupid assumption. I have not chosen to lie. You cannot possibly know what I think unless I tell you.
I did not intentionally make a false statement, nor did I intend to deceive.
You are in a duel because you persist in accusing me of lying.
My reply is to accuse you of being stupid for making a dumb assumption about my motive, and making the stupid statement that lying is not a slur on my character.
BobPrell
Well-Known Member
Thank you Nigel, I think your post supports my idea. Likewise, most fans just have blades with curve, and they work well enough for most purposes. If a really powerful efficient fan is needed, it is usually given blades with different profiles top and bottom.
AngusMcDoon
Well-Known Member
Aerofoils that use both Bernouilli and deflection (like standard aeroplane wings) are more eficient than those that don't (like helicopter blades). Similarly you could make a sail from a flat sheet of plywood, but it wouldn't be very efficient. Nor would it look quite right on Valsheda.
SimonP85
Well-Known Member
A foresail has fairly significant curvature cut into it to produce the different curves. The spoon example works well here too, the same curved surface has very different flows on either side. The sail shape and draft position is adjusted by changing the lead in angle
A flatter sail will produce less power and this technique can be used to de-power the sail in increasing winds. The sheet is also used to control the draft position and twist in the sail.
A flatter sail will produce less power and this technique can be used to de-power the sail in increasing winds. The sheet is also used to control the draft position and twist in the sail.
blackknight
Well-Known Member
My very first post, I know. But I could not let this slide. The understanding of how a wing/sail works is very well known. It is only personal ignorance that makes people believe anything other. (Incidentally just like Biological Evolution but that is way off topic.)
Do people forget the pioneers of flight with their "sail wings" so quickly?
DJE
Well-Known Member
All aerofoils deflect the flow passing over them in order to generate lift. If the flow exerts a force on the foil then the foil exerts an equal and oposite force on the flow. This force changes the momentum of the flow by changing its direction.
The Bernoulli effect produces differing pressures on the two sides of the foil and the sum of these pressures is the force on the foil or the flow.
Skysail
Well-Known Member
Symmetrical airfoils do work, but only when given an angle of attack; in which case they become unsymmetrical relative to the airflow.
Try looking at wikipedia http://en.wikipedia.org/wiki/Lift_(force)
which basically says you are all correct depending on what level of complexity you want to go for - Newton, Coanda, Bernoulli, Kutta-Joukowski.
The pressure on the leeward side of a sail has been measured as lower than the windward side - 'Sails' by Jeremy Howard-Williams, and 'Sailing Theory and Practice' by A. C. Marchaj.
The 'Newton' approach is OK if you are happy with a very basic approach, but this does not explain the full effect, and in my experience most students are very happy with the aircraft wing analogy.
Try looking at wikipedia http://en.wikipedia.org/wiki/Lift_(force)
which basically says you are all correct depending on what level of complexity you want to go for - Newton, Coanda, Bernoulli, Kutta-Joukowski.
The pressure on the leeward side of a sail has been measured as lower than the windward side - 'Sails' by Jeremy Howard-Williams, and 'Sailing Theory and Practice' by A. C. Marchaj.
The 'Newton' approach is OK if you are happy with a very basic approach, but this does not explain the full effect, and in my experience most students are very happy with the aircraft wing analogy.
deuc02
Well-Known Member
Some interesting thoughts and theories here so I thought i might as well stick my 2p in the pot.
Sails basically work exactly the same way as an aeroplane wing. They induce lift by creating a pressure differential between (for simplicity) the top and bottom of the sails. For a sail to work efficiently you need to create laminar flow overthe 2 surfaces as remember the lift is created across the whole top surface. This laminar flow is what makes tell tales on sails work. All they are doing is letting you know if you are creating a boundry layer ie smooth airflow over the 2 sides of the sail. And just like aircraft wings on slow planes and faster planes the chord angle will dictate how efficient the sail will be at differing wind speeds. Hence why when the draft is to excessive the boundry layer will start pulling away from the sail surface inducing turbulent airflow ie drag (noticeable on a main for example when areas of the leech start fluttering). So part of the sail (the forward part) will provide a bit of forward motion to the boat and the lift that creates sideways lift is partly transferred to forward motion by the hull shape and keel. And allthe excess sideways lift is what makes you heel
Thats how i understand it anyway. And 1 final point. I was always under the assumption that draft position was altered using halyard tension but maybe someone can correct me if ive got that 1 wrong
Sails basically work exactly the same way as an aeroplane wing. They induce lift by creating a pressure differential between (for simplicity) the top and bottom of the sails. For a sail to work efficiently you need to create laminar flow overthe 2 surfaces as remember the lift is created across the whole top surface. This laminar flow is what makes tell tales on sails work. All they are doing is letting you know if you are creating a boundry layer ie smooth airflow over the 2 sides of the sail. And just like aircraft wings on slow planes and faster planes the chord angle will dictate how efficient the sail will be at differing wind speeds. Hence why when the draft is to excessive the boundry layer will start pulling away from the sail surface inducing turbulent airflow ie drag (noticeable on a main for example when areas of the leech start fluttering). So part of the sail (the forward part) will provide a bit of forward motion to the boat and the lift that creates sideways lift is partly transferred to forward motion by the hull shape and keel. And allthe excess sideways lift is what makes you heel
Thats how i understand it anyway. And 1 final point. I was always under the assumption that draft position was altered using halyard tension but maybe someone can correct me if ive got that 1 wrong
AngusMcDoon
Well-Known Member
You can quite effectively alter the maximum draft position of your sail my using it long after its useful life as well.
Frankie-H
Well-Known Member
B0ll0X
And you are an instructor
From memory, the theory of lift was discovered at the begining of the last century. The shape of aerowings should give you some help.
Oh. I get it - sorry. You are a Troll and the whole thing was a wind up.
The alternative is too sad to contemplate.
jimbaerselman
Well-Known Member
Some of you do like to complicate things by looking at the detail.
Put any shape into an airflow, and it will change the momentum of the airflow; so a force will be created.
If it's a cylinder, it'll slow the airflow down (drag); the pressure at the front of the cylinder will be greater than that at the back (bless Bernoulli if you wish; whether it's turbulent or laminar, friction slows the air down . . .)
If it's longer than it is wide, it may be a plank, a symmmetrical aerofoil, an asymmetrical airofoil, a thin curved sheet, a sail, I don't care. But any of these shapes could be rotated relative to the airflow, and (unlike the cylinder) this will create changes of direction of the arflow as well speed.
Sure, with a bit of twizzling, you can find an angle at which they're just a bit of a drag.
But, at any other angle, they will not only slow things down a bit, they'll also change airflow direction. That's a change in momentum - which will be matched by a force. Change in momentum=force.
Do vectors to find how much and in exactly what direction the resultant force acts. But crudely, it's at right angles to the mean flow - half way between input and output (ignoring the additional element of drag). The force manifests itself as a difference in pressure each side of the aerofoil, explained by Bernoulli, flow being faster on the "outside" than on the "inside"
You don't have to have think "inside" vs "outside" either. Water and spoons have been mentioned. Flow direction will change whether the flow is just around the convex, or just inside the concave, and the force developed will be the same if the change in flow angle is the same. Take a pause and consider how many water sprinklers work - changing water direction through a right angle.
That's how any shape creates forces in an airflow. Changing momentum of the airflow. Over simplifying, direction change=lift, speed change=drag (or thrust if it's had energy added by going thru a device!)
For doubters, aircraft with asymmetric aerofoils can still be made to fly level upside down - if they're strong enough and the engine doesn't stop.
So all arguments about "what shape" are not very relevant. These shapes are just variations of machines which change air momentum. Parachutes are great at drag, but poor at lift. Gliders are brilliant at lift, and create very little drag indeed. Sailboats have two airfoils pushing against each other, one under water, and one above which flips to match the airflow direction. This incidentally creates a heel angle, but the net result is a bit like sqeezing a damp lemon pip - there's only one way left to go.
Not exactly the rocket out of the back; more like the only remaining option!
Put any shape into an airflow, and it will change the momentum of the airflow; so a force will be created.
If it's a cylinder, it'll slow the airflow down (drag); the pressure at the front of the cylinder will be greater than that at the back (bless Bernoulli if you wish; whether it's turbulent or laminar, friction slows the air down . . .)
If it's longer than it is wide, it may be a plank, a symmmetrical aerofoil, an asymmetrical airofoil, a thin curved sheet, a sail, I don't care. But any of these shapes could be rotated relative to the airflow, and (unlike the cylinder) this will create changes of direction of the arflow as well speed.
Sure, with a bit of twizzling, you can find an angle at which they're just a bit of a drag.
But, at any other angle, they will not only slow things down a bit, they'll also change airflow direction. That's a change in momentum - which will be matched by a force. Change in momentum=force.
Do vectors to find how much and in exactly what direction the resultant force acts. But crudely, it's at right angles to the mean flow - half way between input and output (ignoring the additional element of drag). The force manifests itself as a difference in pressure each side of the aerofoil, explained by Bernoulli, flow being faster on the "outside" than on the "inside"
You don't have to have think "inside" vs "outside" either. Water and spoons have been mentioned. Flow direction will change whether the flow is just around the convex, or just inside the concave, and the force developed will be the same if the change in flow angle is the same. Take a pause and consider how many water sprinklers work - changing water direction through a right angle.
That's how any shape creates forces in an airflow. Changing momentum of the airflow. Over simplifying, direction change=lift, speed change=drag (or thrust if it's had energy added by going thru a device!)
For doubters, aircraft with asymmetric aerofoils can still be made to fly level upside down - if they're strong enough and the engine doesn't stop.
So all arguments about "what shape" are not very relevant. These shapes are just variations of machines which change air momentum. Parachutes are great at drag, but poor at lift. Gliders are brilliant at lift, and create very little drag indeed. Sailboats have two airfoils pushing against each other, one under water, and one above which flips to match the airflow direction. This incidentally creates a heel angle, but the net result is a bit like sqeezing a damp lemon pip - there's only one way left to go.
Not exactly the rocket out of the back; more like the only remaining option!
Yantlet
Well-Known Member
Now now gentlemen, and here I am thinking I was doing something useful in posting the link - never expected WW3 to break out, isn't science wonderful?
chewi
Well-Known Member
I suggest a few folk here read Arvel Gentrys articles, published in Sail magazine and found on google. He was a research Aerodynamicist at Boeing who learnt to sail but found the books make explanations of airflow that made no sense, especially the slot.
He explains how sails really work, including the fabric, unfixed nature of a sail, how the main affects the jib, the jib affects the main. stalling, and circulation. All based on bernoulli, Reynolds and other giants of aerodynamics. He became aero/hydronamic consultant to the Americas cup team.
his "gentry tufts" are now known as telltales.
It may take a few reads to take them all in, but its worth the effort.
He explains how sails really work, including the fabric, unfixed nature of a sail, how the main affects the jib, the jib affects the main. stalling, and circulation. All based on bernoulli, Reynolds and other giants of aerodynamics. He became aero/hydronamic consultant to the Americas cup team.
his "gentry tufts" are now known as telltales.
It may take a few reads to take them all in, but its worth the effort.
BobPrell
Well-Known Member
B0ll0X
And you are an instructor
From memory, the theory of lift was discovered at the begining of the last century. The shape of aerowings should give you some help.
Oh. I get it - sorry. You are a Troll and the whole thing was a wind up.
The alternative is too sad to contemplate.
This is an example of a response I have had to my explanation a number of times. It amounts to "No you are wrong " (put more or less rudely), "It's a wing. Everybody knows that."
This goes a little further. Nobody could possibly be that ignorant when it's in all the sailing books, so I must be saying it out of malice. Troll!!!!
BobPrell
Well-Known Member
Yes, thank you for the link. My post #4 was critical of the style of the film rather than the content. I looked at my post after I published it and thought now if I have been critical of something for being overcomplicated I should offer an alternative. So I did, thinking I would look less grumpy that way.
I did not anticipate the level of flak it would attract.
I'm glad you mentioned science. To uncritically accept conventional wisdom is not scientific.
mjcoon
Well-Known Member
Just to stir things up a bit more, that reminds me that I think there was a proposal to use vertical rotating cylinders to get sailing propulsion. Anyone remember what happened to that (or what it was called)?
Mike.
Lakesailor
Well-Known Member
Was it a bit too much weight, too high up?
Just a guess.
Just a guess.
D
Deleted member 36384
Guest
There was a few articles about it a couple of years ago, maybe a bit more, a trimaran was rigged up with rotating drums. It worked, but not that well. If I remember correctly the original ship was not that efficient either. You would need to check the various articles for the facts, but that is what I remember, not efficient.
Here you go a link: http://www.grc.nasa.gov/WWW/k-12/airplane/cyl.html
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BobPrell
Well-Known Member
Jim you explained at greater length than I did, I am a bit lazy at composition.
I have quoted the parts which are critical to my explanation.
High school physics students are taught very early that velocity consists of speed and direction. Acceleration is to change velocity, and requires a force. If something has velocity and you change its direction only, that is still acceleration and requires a force.
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