I Force required to pull a cruise liner or cargo ship

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The discussion centers on calculating the force required to pull a cargo ship using a kite as the sole propulsion method, without engine assistance. Key factors influencing this force include the ship's size, speed, and resistance from water and air, with a focus on achieving a cruising speed of around 10 m/s. The participants explore the drag force calculations, emphasizing the importance of the wetted surface area and drag coefficient, which significantly impact the total drag force. Estimates suggest that maintaining a speed of 10 m/s would require a continuous force of approximately 7.5 MN, although the actual force needed may vary based on conditions. Ultimately, the conversation highlights the complexities of using kite propulsion for large vessels and the need for precise calculations to determine effective force requirements.
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Force required to pull a cargo ship using a rope, connected to Kite.
I was wondering how much force is required to pull the Cargo ship using a Kite as shown in below image and specifications given in table? This picture is taken from a seawing aka airseas website. I do not know the water / air / skin resistance values or coefficients for the cargo.

All I know is F = ma
Tonnage235,579 GT [Gross Ton]
Length400 m (1,312 ft 4 in)
Beam61.5 m (202 ft)
Draught17 m (55 ft 9 in)
1668475346161.png
 
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The vessel will be turned by the kite, unless you attach the kite to the centre-of-drag of the vessel.

The force required will depend on the speed required through the water, and on the wind direction and strength.
 
Baluncore said:
The force required will depend on the speed required through the water, and on the wind direction and strength.
Plus the current direction and strength.

@KuriousKid ,
I believe that this idea has been explored before, but not as the sole means of propulsion, but rather as a way to use less fuel. In other words, both kite and engine at the same time.

But the kite arrangement must compete with conventional masts and sails. Remember that if the kite falls into the water, the ship will run it over. Conventional masts and sails don't have that specific problem.
 
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@Baluncore @anorlunda Thank you for your insights.
I Understand the issue of just using Kite. But I'm trying to understand (only) how we can calculate the force required for complete Cargo to be pulled only by Kite and no Engine force (ignoring the issues comes with it).

For the sake of calculation we can consider normal speed of Cargo around 25 knots and maybe we can ignore air resistance too as it will be almost around 800 times less than water resistance, considering the density difference [but again it depends on how tall is ship and so on].
 
KuriousKid said:
For the sake of calculation we can consider normal speed of Cargo around 25 knots ...
What is the normal operating power of the engines in a similar ship, at that speed?
 
KuriousKid said:
@Baluncore @anorlunda Thank you for your insights.
I Understand the issue of just using Kite. But I'm trying to understand (only) how we can calculate the force required for complete Cargo to be pulled only by Kite and no Engine force (ignoring the issues comes with it).

For the sake of calculation we can consider normal speed of Cargo around 25 knots and maybe we can ignore air resistance too as it will be almost around 800 times less than water resistance, considering the density difference [but again it depends on how tall is ship and so on].
To be clear, we have a tethered air foil? With a really good lift to drag ratio so that even with 25 knots of relative headwind, we can still eke out positive thrust from, let us say, 15 knots of absolute crosswind?

Which means that not only must the sail have a good lift to drag ratio, the keel must also have a good lift to drag ratio.

I am not saying that it is impossible. Sailboats manage the trick with conventional sails. But the pictures on the web site depict a ship being pulled by the kite. That mode will not work unless you have a tailwind that is faster than the ship speed.

The ship class we seem to be talking about is the Emma Maersk. 108,920 horsepower (about 81 megawatts).

At 25 knots (about 13 meters per second), that translates to a force of ##\frac{81}{13}## or about 6.2 megaNewtons. A metric ton is about 10,000 Newtons. So that comes to about 620 metric tons. The claim I see is that this tethered airfoil generates about 100 tons of "traction" by flying in a back and forth pattern to sweep out an area greater than its nominal size.

This idealized performance would result in a fuel savings of about 16 percent -- as long as one has a sufficiently speedy tail wind. The web site seems to be short on detailed specifications. [Better than 16 percent if we figure in the propellor. The propellor will not be 100% efficient. The tether will be]

Note that ##F=ma## deals with acceleration. We are talking about constant speed cruising here. It is all about thrust and drag. Mainly hull form drag, I expect, but I am not a naval architect.

Edit: One more thing I gleaned from the web site...

The wing zips around at "over 100 km/h". Which would be about 50 knots. If we assume a lift to drag ratio of about 10 to 1, this means that the wing needs at least five knots of relative wind to function at peak efficiency. So we need 30 knots of tailwind to get peak performance on our 25 knot container ship.

On the Beaufort scale, that is:

7
28-33Near GaleSea heaps up, waves 13-19 ft, white foam streaks off breakersWhole trees moving, resistance felt walking against wind
 
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@jbriggs444
I believe if you go higher than 300 m, you get considerable higher wind speeds than what is it at sea level. So we cannot relate sea level wind speed with speed at 300m above sea level. But you are right at Cruise speed... so we may get 5-6 m wind speed difference. So it might be impossible to get speed of 25 knots by only wind speed. So that way our calculation would be for around 5-6 m/s cruise speed.

The ship engine capacity of 81 Mega Watt might not be used in total just for propulsion. Maybe part of it is used for other purposes. Not sure. But this pulling force will give us right answer to the question. How much engine power is used to push the cargo.

I also believe the pulling is much more efficient than pushing by propeller from under the water, because LOT of power is lost in friction and not all power is translated into moving the Cargo ship. Whereas in pulling condition, all power is used in moving the Cargo ship minus drag forces.
 
KuriousKid said:
I believe if you go higher than 300 m, you get considerable higher wind speeds than what is it at sea level.
Even at moderate heights an increase can be expected [1]. Since the kite uses lift to extract power from the wind I guess it is fair to consider the available off-shore wind power density as a function of height and wind speed at a reference height [2]. According to [3] it seems one can expect around 10 times more wind power at 100m compared to 10m.

[1] https://en.wikipedia.org/wiki/Log_wind_profile
[2] https://en.wikipedia.org/wiki/Wind_profile_power_law#Wind_power_density
[3] http://www.inference.org.uk/withouthotair/cB/page_266.shtml
 
Once the vessel has accelerated, later that day, all the available main engine power may not be needed while cruising. Let's assume 50%, so 40 MW goes to keep it moving. Assume the propeller is 50% efficient, that gives an estimate of vessel drag, from water and air, of 20 MW.

Work done is force * distance; so we can estimate the total drag forces from the 40 MW power and the speed of 25 knots.
First, convert to SI units. Velocity, 25 knots = 12.86 m/s.
Then compute the force, 40 MW / 12.86 m/s = 3.11 MN.

The force required to pull a cruise liner or cargo ship will be the same as the force needed to push it. My initial estimate is 3 million Newtons.

Big diesel propulsion engines are directly coupled to the propeller shaft.
Electrical power usually comes from two or more separate diesel generator sets.
 
  • #10
@Baluncore
I think we are going in reverse direction (doing reverse engineering) in calculating how much force is required based on our knowledge/assumptions of losses and total power available.

My intention was to calculate the minimum power required to pull the Cargo ship using the tethered rope at X m/s. I'm not even interested to know how much thrust or pull force that Kite can exert on ship [They say it can save 20-30% fuel, that's based on small vessel size, which doesn't apply to this big sized vessel we are talking].

What I'm trying it to understand how to calculate the pulling force required to move Ship from Point A to Point B with speed of 10 m/s or so. We have Mass, We have Speed. But I'm not sure about the drag force from the water / skin effect and how we can take that into account to calculate the pulling force.

Drag force = 1/2 m V^2 Area Cd = 0.5 * 235579000 * 10 * 10 * 61 * 17 * 0.04 = 488590846000 N [I hope I'm wrong somewhere]

F = m a = 235579000 * ? [We want to pull it with 10 m/s speed constantly], so not sure how to solve this.

F + Drag Force = Total force required.
 
  • #11
KuriousKid said:
I was wondering how much force is required to pull the Cargo ship using a Kite as shown in below image and specifications given in table?
I have not reverse engineered a kite powered ship being "pulled". I have estimated the total of all drag forces from the power it normally takes to drive a real ship, to keep the ship moving, once it is moving.

KuriousKid said:
What I'm trying it to understand how to calculate the pulling force required to move Ship from Point A to Point B with speed of 10 m/s or so. We have Mass, We have Speed.
Point A to point B is irrelevant to the force, you must apply force for the whole voyage. You only need to study the force and the energy needed to keep the ship going for one second. Power in watts is the rate of flow of energy in joules per second.
As far as acceleration of the ship's mass is concerned, that is irrelevant. But the mass of the ship will displace the same mass of water, a volume of water. The dimensions and shape of that volume of hull will determine the wetted area and surface drag. The length of the hull will decide maximum hull speed due to wave generation, but like a real vessel, you will have to reduce that speed to get improved fuel efficiency.

If you think you can work out the optimum hull dimensions and calculate the drag from your hydrodynamic model, then go ahead. You could then compare your result with my quicker estimate.
 
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  • #12
The size of kite seems impracticably large. For instance, the wind jammer Herzogin Cecilie of 3242 tons required 3530 m2 of sail area. Scale that up to a modern cargo ship and the requirements for the kite are formidable.
 
  • #13
I was able to find Drag Coefficient for Cargo ship is about 0.004 and the formula is wrong above as we don't have to include the mass of ship for calculation of drag force. So it is like this

Drag Force = 0.5 * Cd * A * V^2 * Water density = 0.5 * 0.004 * 61 * 17 10 * 10 * 1.2 = 248.88 N

Am I still missing something?
 
  • #14
KuriousKid said:
Am I still missing something?
Yes, three orders of magnitude.
A density of 1.2 = 1200 kg/m3
 
  • #15
KuriousKid said:
I was able to find Drag Coefficient for Cargo ship is about 0.004 and the formula is wrong above as we don't have to include the mass of ship for calculation of drag force. So it is like this

Drag Force = 0.5 * Cd * A * V^2 * Water density = 0.5 * 0.004 * 61 * 17 10 * 10 * 1.2 = 248.88 N

Am I still missing something?
250 Newtons to pull a cargo ship! Really?
 
  • #16
A drag coefficient of 0.004 applies to the wetted area of a ship's hull, not to the cross-section.
Length 400 m, Beam 61.5 m, Draught 17 m.
Wetted area = 400 * ( 17 + 61.5 + 17 ) = 38200 m2

Drag = 0.5 * 0.004 * 38200 * 100 * 1200 = 9.168 MN.
 
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  • #17

@Baluncore You nailed it. Thank you.

Wetted Surface Area Formula

The following formula is used to calculate the Wetted Surface Area.

WSA = WLL * (B+D)

Variables:

  • WSA is the Wetted Surface Area (ft^2)
  • WLL is the water line length (ft)
  • B is the beam (ft)
  • D is the draft (ft)
To calculate the wetted surface area, multiply the water line length by the sum of the beam and draft.This makes Wetted area = 400 * ( 17 + 61.5 ) = 31400 m2

So

Drag = 0.5 * 0.004 * 31400 * 100 * 1200 = 7536000 N = 7.5 MN

This means I can use about 750 N force to move Cargo liner at 0.01 m/s speed considering there is no other drag force acting on ship.

Now I have another question in this case, in case above calculations are correct.

Let's say our ship is cruising at speed of 10 m/s in sea. To maintain this speed, do we have to continuously provide same force or only part of it?

e.g. If at 10 m/s ship's engine is turned off, that means it will keep going far before stopping completely. May be 1000 meter. Which means Every 100 meter it looses 1 m/s speed. If this is the case, then can we supply only 75360 N force [this force can pull ship with 1 m/s speed], to keep it running at 10 m/s speed?
 
  • #18
KuriousKid said:
Let's say our ship is cruising at speed of 10 m/s in sea. To maintain this speed, do we have to continuously provide same force or only part of it?
The drag force is operating while ever the ship is moving. You must maintain the force to maintain the velocity. If you turn off the energy supply to the propeller, the ship will begin to decelerate. Remember that the drag is proportional to the square of the velocity, so in theory, the ship will never quite stop.
 
  • #19
I didn't understand this sentence "Remember that the drag is proportional to the square of the velocity, so in theory, the ship will never quite stop." [Never stop?]
 
  • #20
KuriousKid said:
I didn't understand this sentence "Remember that the drag is proportional to the square of the velocity, so in theory, the ship will never quite stop." [Never stop?]
The mathematically correct description of this is with a differential equation. Let us use something simpler. An approximation which will lead to the same conclusion. We will get there...

Start with the fact that drag is proportional to the square of velocity. So ##F=kv^2## for some contstant k.

The ships mass is fixed. Call it m. If drag is the only force operating then the ships acceleration ##a=\frac{kv^2}{m}##.

Suppose that the ship is going at ##v=1## meters per second. How long that it will take to slow down to ##v=0.1## meters per second?

During the time interval from when ##v = v_0=1## to when ##v = v_1=0.1##, the deceleration force will be at most ##F=k{v_0}^2##.

So the deceleration will be at most ##\frac{F}{m} = \frac{k}{m}{v_0}^2##.

This means that the elapsed time between ##v=v_0## and ##v=v_1## must be at least ##\frac{v_0-v_1}{k{v_0}^2/m}##. Since ##v_1 = v_0/10##, this simplifies to ##\frac{0.9m}{kv_0}##.

Now repeat the analysis for the interval between ##v=v_1=0.1## and ##v=v_2 = 0.01##. If you follow through the algebraic steps, you should end up with ##\frac{0.9m}{kv_1}##.

Each of these guaranteed minimum time intervals is getting ten times larger than the one before. There are infinitely many of them. The series sum does not converge. The conclusion is that there is no time at which the ship stops moving.

Even if drag were linear, the ship would still never stop moving. In that case, each element in the series sum would be constant and the series sum would diverge.

One might ask if there is a goal line beyond which the ship will never progress. In the case of linear drag, the answer is yes, there is a goal line that the ship will never coast across. It would keep approaching the goal, perhaps getting asymptotically close, but will never make it there, not even when given infinite time. [If you work through it, the series sum for distance traversed is geometric and can have a finite sum despite having infinitely many non-zero terms]

In the case of quadratic drag, I believe that the answer is no, there is no goal line that the ship will never coast across, though it may take a very long time. I think that the series for this one is the harmonic series. That one goes infinite. But the sum is logarithmic in the number of terms and the time elapsed for each term increases exponentially, so it takes a long time to get to a big total. [Try throwing a ping pong ball a light year]
 
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  • #21
I'm trying to compare this with coasting with Car or Bicycle on road now.
When I ride my bicycle, I apply 40 lb equivalent force to begin with. Once I get to a speed of 20 miles / hr and if the road is plane, to maintain the 20 miles/hr speed, I only have to apply a force of 2 lb now. Although the peddling RPM is higher at this time.

Here the energy supplied is almost same as I supplied it at the beginning but it is lot more easier to supply 2 lb force than 40 lb force.

So isn't it valid for Cargo ship too? When it is travelling at higher speed, to maintain that speed, we may have to supply 10 times less thrust force than to get it started. Energy supplied is same but thrust force is much lower than at start period. Am I correct in understanding or analyzing this now?
 
  • #22
KuriousKid said:
I'm trying to compare this with coasting with Car or Bicycle on road now.
When I ride my bicycle, I apply 40 lb equivalent force to begin with. Once I get to a speed of 20 miles / hr and if the road is plane, to maintain the 20 miles/hr speed, I only have to apply a force of 2 lb now. Although the peddling RPM is higher at this time.

Here the energy supplied is almost same as I supplied it at the beginning but it is lot more easier to supply 2 lb force than 40 lb force.

So isn't it valid for Cargo ship too? When it is travelling at higher speed, to maintain that speed, we may have to supply 10 times less thrust force than to get it started. Energy supplied is same but thrust force is much lower than at start period. Am I correct in understanding or analyzing this now?
A cargo ship doesn't run on wheels. And water gives a lot more resistance to motion than air.
 
  • #24
KuriousKid said:
I'm trying to compare this with coasting with Car or Bicycle on road now.
When I ride my bicycle, I apply 40 lb equivalent force to begin with. Once I get to a speed of 20 miles / hr and if the road is plane, to maintain the 20 miles/hr speed, I only have to apply a force of 2 lb now. Although the peddling RPM is higher at this time.

Here the energy supplied is almost same as I supplied it at the beginning but it is lot more easier to supply 2 lb force than 40 lb force.

So isn't it valid for Cargo ship too? When it is travelling at higher speed, to maintain that speed, we may have to supply 10 times less thrust force than to get it started. Energy supplied is same but thrust force is much lower than at start period. Am I correct in understanding or analyzing this now?
That´s the difference between solid friction and fluid friction.
Solids keep their shape and require a nonzero force to alter it and start moving. Fluids will move under arbitrarily small force.
The cargo ship will need a starting force when and if it has a solid attachment to overcome. Like a mudbank in contact with bottom, solid ice sheet on waterline, rope/s attached to bollards or anchor...

When none of these apply, the ship can undergo a slow drift under an arbitrarily small force, or inertia. When you leave your bicycle in a parking lot, it will have little trouble staying put where you left it - it will not slowly wander to the opposite edge of the parking lot, or drop off that edge. When you leave your boat in a port basin without solid attachments like the ones I listed (beached, frozen in, moored, anchored), you may well find it drifted away to the middle of port basin, or opposite edge, or off the port...
 
  • #25
snorkack said:
When none of these apply, the ship can undergo a slow drift under an arbitrarily small force, or inertia.
It's probably not a good business model for a shipping company to put its vessels into the water and let them drift with the tides.
 
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  • #26
PeroK said:
It's probably not a good business model for a shipping company to put its vessels into the water and let them drift with the tides.
Sounds to me just like a leisure sailing cruiser. Not only that but coastal barges (commercial and pretty big by those standards) did exactly that. 120 tons with 400m2 of sail, up and down the Thames. Very reliable motive power! But that wasn't out in the open ocean.

I have to say, the kite idea would have to prove itself very superior to conventional sails. The possible lack of control would really worry me. It's only loopy young men who actually use kites at sea and they'd have a real problem convincing shareholders that it's a good idea (with or without pages of figures and calculations.)
 
  • #27
When you are exploring a sailing ship, it may be useful to keep track of the forces and momenta involved.
Some sails are fixed to a rigid beam among two edges (yard and mast). Some only along one edge (yard) and the opposite corners held by lines. Some sails are not attached at any edge, only to lines at corners - e. g. spinnakers - and therefore have degrees of freedom to swing around the mast. In all these cases, it is important to keep track of the stability of the sail, and consider how you avoid the sail flapping itself into unfavourable position, or recover from such position. As well as the rigid beams undertaking unwanted motions, like booms jibing.
Considering the large force desired for sail propulsion, lifting the sail atop a tall mast means giving the force a large moment, which must be resisted by the heeling stability of the underwater hull.
So instead the idea of a kite sail, whose drag force is exerted low on the ship, to keep the heeling moment low, and the sail is kept high by the lift on the sail. But how do you make sure to recover from maneuvers where the kite sail falls into sea?
 
  • #28
KuriousKid said:
So isn't it valid for Cargo ship too? When it is travelling at higher speed, to maintain that speed, we may have to supply 10 times less thrust force than to get it started. Energy supplied is same but thrust force is much lower than at start period. Am I correct in understanding or analyzing this now?

No, that's not how it works. Just for reference, this is the measured (measured on model scale and extrapolated to full scale) resistance for 'a' ship which is a little bit smaller than the ship that is referred to in the first post (Length 390m, beam 60m, draught 16m, displacement 245Mt) which I happen to have laying around:
ship.png
This ship needs about 35MW at 20 knots in ideal conditions (no wind, no waves, clean hull). This number also depends on the propeller efficiency of course.

So the resistance increases continually with speed. Note that:
  • The total resistance is higher than frictional resistance because of wave resistance. The frictional resistance here also includes a form factor resistance due to the ship hull not being a flat plate.
  • The difference between frictional resistance and total resistance also increases since wave resistance increases with speed.
  • This is the minimal force that you need to apply to keep the ship at that velocity. The actual force may be larger due to interaction effects (the thrust of a propeller needs to be larger due to something called 'thrust deduction', which is the part of the thrust that is lost because the resistance of the ship is increased due to the propeller doing its work and generating a low pressure area on the aft part of the ship) or due to weather effects (wind, waves) etc.
 
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  • #29
A kite has lift and drag when flown from a vessel.
The vessel is driven horizontally by the drag.
The vessel displacement is reduced by the lift.
Should the kite be designed for high lift, or for high drag?
 
  • #30
Baluncore said:
A kite has lift and drag when flown from a vessel.
The vessel is driven horizontally by the drag.
The vessel displacement is reduced by the lift.
Should the kite be designed for high lift, or for high drag?
Since the aerodynamic forces on the ship should be a small fraction of its displacement, the lift should mostly be used to keep the kite up.
Also, note that the reason a sailing ship can sail close-hauled is that it has both an efficient airfoil AND an efficient waterfoil. The underwater part of the ship must be efficient in producing lift!
 
  • #31
Baluncore said:
The vessel displacement is reduced by the lift.

The ship in my post has a displacement of 245,000,000 kg. I don't think the lift of a kite is going to have any significant influence on that... Furthermore, it is not at all said that lifting the bow will reduce the drag since wave resistance can become worse and frictional resistance is hardly affected.
 
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  • #32
Baluncore said:
The vessel is driven horizontally by the drag.

If you use the drag of the kite for propulsion you're doing it wrong ;). The lift is much higher than the drag and the lift vector of the kite should have a significant component in the horizontal direction (and of course as much as possible in the forward direction). So you should optimize the lift over drag ratio and get a high as possible/practical amount of lift.
 
  • #33
So something like this:
kite.png
 
  • #34
Arjan82 said:
If you use the drag of the kite for propulsion you're doing it wrong ;). The lift is much higher than the drag and the lift vector of the kite should have a significant component in the horizontal direction (and of course as much as possible in the forward direction). So you should optimize the lift over drag ratio and get a high as possible/practical amount of lift.
The advertising information for the kite in question indicates that they do just this. The kite is flown back and forth in a figure eight pattern at high speed (100 kph) so that it is primarily lift that tensions the cable rather than drag.

The claim is that this increases the "effective area" of the kite by a significant factor. Much like three bladed wind turbines effectively harvest wind energy from a region larger than just the area of the blades.
 
  • #35
snorkack said:
The underwater part of the ship must be efficient in producing lift!
If you generate lift from the hull, you generate bigger waves.
We are discussing heavily loaded displacement hulls here, not surface skimming hydroplanes or hydrofoils.
 
  • #36
Arjan82 said:
The ship in my post has a displacement of 245,000,000 kg. I don't think the lift of a kite is going to have any significant influence on that...
Kite thrust is some significant fraction of the approximately 3.5 million N of engine thrust versus about 2.5 billion N of gravitational down-force. Yes, we are down about three orders of magnitude from the kite's upward force on the ship being significantly helpful.
 
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  • #37
Arjan82 said:
So something like this:
View attachment 318232
As in all pictures I've seen, the ship has a tailwind, the kite is flying dead ahead. There is no tacking going on. The hull is not being called upon to act as a water foil. There is no yaw torque to interfere with steering.
 
  • #38
jbriggs444 said:
As in all pictures I've seen, the ship has a tailwind, the kite is flying dead ahead. There is no tacking going on. The hull is not being called upon to act as a water foil. Nor is there any yaw torque to interfere with steering.

Actually, the kite in the picture does not have tailwind but the wind is somewhat from the side. This means the angle of attack of the wind on the kite is from the side such that it can generate a forward lift. Otherwise it would have to rely solely on its drag resistance, which generates a much lower force (and you can never sail faster than the wind for it to generate a forward force)

That however doesn't dismiss your other conclusions. There is definitely no tacking going on, much too difficult for such a ship (and prohibitively increases time and costs due to the longer path taken).
 
  • #39
Arjan82 said:
Actually, the kite in the picture does not have tailwind but the wind is somewhat from the side.
Based on the waves, the absolute wind appears to be about twenty, maybe thirty degrees port of directly astern. Call it a quartering tailwind if you like.

If the absolute wind was from directly to port, a kite flying directly ahead of the ship would have zero lift and would be falling into the sea.

But yes, certainly a kite can fly directly ahead in a relative wind that is coming from a direction somewhat aft of directly abeam.
 
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  • #40
Baluncore said:
If you generate lift from the hull, you generate bigger waves.
We are discussing heavily loaded displacement hulls here, not surface skimming hydroplanes or hydrofoils.
For the ship underwater part, remember that the lift is horizontal! It is the force that prevents the ship from making leeway - travelling sideways through the water.
 
  • #41
snorkack said:
For the ship underwater part, remember that the lift is horizontal! It is the force that prevents the ship from making leeway - travelling sideways through the water.
Leeway... An etymology lesson learned. Obvious in retrospect.
 
  • #42
jbriggs444 said:
Call it a quartering tailwind if you like.

Ok, that's what I meant by 'somewhat from the side'... I didn't mean exactly 90 degrees. Sorry for being so wooly :).

But this picture is also fake (intended for commerce), I don't think the kite is effective for tailwind.
 
  • #43
snorkack said:
For the ship underwater part, remember that the lift is horizontal! It is the force that prevents the ship from making leeway - travelling sideways through the water.
You are kidding yourself. The length-way section is symmetrical, designed to minimise drag and wave generation, while the sideways section is very close to rectangular, all drag.
 
  • #44
Arjan82 said:
I don't think the kite is effective for tailwind.
If the relative wind is coming from abeam or anywhere forward of that then one must change strategy. Instead of flying the kite directly ahead, one must fly it somewhat leeward of that.

If the kite has a lift to drag ratio of 10 to 1 then one should be able to fly it anywhere in a 170 degree arc. 85 degrees right or left. So with a relative wind 10 degrees away from directly ahead, one should be able to fly the kite at five degrees forward of directly abeam.

If the ship's hull had a lift to drag ratio of 10 to 1 (unlikely) then one could then start getting forward propulsion from a kite flying as little as five degrees forward of directly abeam.

That is called "sailing close hauled" (you haul in on the sheets so that the sails are about as close to parallel to the ship as you can arrange). However, I doubt that a cargo ship could tack as close-hauled as 1 point from the wind. We generally did 4 points (45 degrees) when I was learning to sail.
 
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  • #46
jbriggs444 said:
If the relative wind is coming from abeam or anywhere forward of that then one must change strategy. Instead of flying the kite directly ahead, one must fly it somewhat leeward of that.

In normal sailing you have a change in strategy between tailwind and about quarterly tailwind. Because if the wind is coming (almost) directly from aft, a sail cannot get an angle of attack that is low enough to prevent full separation of the flow. So instead it must work like a 'bag' which is just 'catching' and slowing down the wind as much as possible, but it has nothing to do anymore with a wing. This is what spinnakers are especially good at. But between quarterly tailwind and close hauled I don't see a clear change in strategy, only a kite that is pulling gradually more sideways.

But the kite is really designed as a wing and thus should be used as a wing. I do now remember that they are proposing to do 'figure eights' which would still use the kite as a wing at tailwinds. But I would wonder how that would work in a practical sense with a kite like that, the thing is huge! Try to control that properly and safely...

jbriggs444 said:
If the kite has a lift to drag ratio of 10 to 1 then one should be able to fly it anywhere in a 170 degree arc. 85 degrees right or left. So with a relative wind 10 degrees away from directly ahead, one should be able to fly the kite at five degrees forward of directly abeam.

If the ship's hull had a lift to drag ratio of 10 to 1 (unlikely) then one could then start getting forward propulsion from a kite flying as little as five degrees forward of directly abeam.

Unlikely indeed :) [EDIT: sorry I thought you meant the ship with some leeway angle, not the kite... for a kite 1/10 seems much more likely]. I don't think such a configuration can even come close to 170 degrees... [EDIT: ok, I need to eat some dinner before I answer stuff... :( Here I meant the total angle around the into-the-wind direction (i.e. 85deg to either side) for which 170deg is already pretty bad :)] I would expect not any further than abeam winds. Also, in the picture I've shown the kite is attached near to the bow. If you put a significant side force at that point on the ship you introduce a significant steering force (i.e. moment, aside from the side force I mean) which you need to compensate with the rudder or your angle in the water (or both..). This introduces a serous amount of extra drag...

jbriggs444 said:
That is called "sailing close hauled" (you haul in on the sheets so that the sails are about as close to parallel to the ship as you can arrange). However, I doubt that a cargo ship could tack as close-hauled as 1 point from the wind. We generally did 4 points (45 degrees) when I was learning to sail.

45 degrees is actually really close to the wind and is only achievable for well designed yachts. With the sailing ships that I'm used to sail on it is more likely to be 50 to 60 degrees... And those are still somewhat meant to be able to do this, unlike the above cargo ship...:

sailingtrips-in-holland.jpg
 
  • #47
Baluncore said:
You are kidding yourself. The length-way section is symmetrical, designed to minimise drag and wave generation, while the sideways section is very close to rectangular, all drag.

You are misunderstanding @snorkack. You are thinking vertical lift (more lift = bigger waves, which only applies to hydroplanes not these displacement vessels) But @snorkack is thinking horizontal lift, the lift generated by your hull in horizontal and sideways direction that prevents a large velocity component in sideway direction. The idea here is indeed that the 'sideways' section as you call it has a much higher drag than in forward direction, this is exactly what prevents sideway velocity and this is why sailing yachts have keels (or daggerboards, or these micky mouse ears on the side of the ship on the picture of my previous post :) )
 
  • #48
Arjan82 said:
You are misunderstanding snorkack.
No, I am not.
With a symmetrical hull, to develop a sideways lift, requires a side-slip to generate a non-zero angle of attack. That involves a non-zero angle on the rudder, turning the boat slightly into the wind to compensate for drift by changing the heading. What a waste of energy that would be, when a change of heading could compensate for the drift.
The next thing you will be telling me is that an aeroplane, flying in a cross wind, gains lift from its fuselage by flying slightly sideways, to compensate for the cross wind.

Arjan82 said:
... these micky mouse ears on the side ...
Those are called leeboards. I sailed one of those back in the 1970s.
 
  • #49
Baluncore said:
No, I am not.

Ok... then I really don't know what you meant...

Baluncore said:
With a symmetrical hull, to develop a sideways lift, requires a side-slip to generate a non-zero angle of attack.

true

Baluncore said:
That involves a non-zero angle on the rudder,

Not necessarily true, at least not continuously (of course you need corrections for a varying force). It all depends on where the forces apply and if they generate a moment and in which direction that moment is. Some badly trimmed sailing ships need a constant rudder angle turning the ship away from the wind (I'm really hampered by the fact that I don't know the English sailing terms... only the Dutch ones...) This then adds to the already leeward direction due to drift due to the side force.

Baluncore said:
turning the boat slightly into the wind to compensate for drift by changing the heading. What a waste of energy that would be, when a change of heading could compensate for the drift.

I don't understand this part. "turning the boat slightly into the wind to compensate the drift" to me is equal to "when a change of heading could compensate the drift", yet one seems to be good and the other bad...

Baluncore said:
The next thing you will be telling me is that an aeroplane, flying in a cross wind, gains lift from its fuselage by flying slightly sideways, to compensate for the cross wind.

No... That is some ill founded logic I hope I would never say... A ship works on the interface of wind and water, unlike an airplane, that makes a big difference.

Baluncore said:
Those are called leeboards. I sailed one of those back in the 1970s.

Ah, didn't know the English term :)
 
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