Difference between revisions of "Long Wavelength Approximations"
Line 112: | Line 112: | ||
=== Horizontal force on multiple vertical cylinders in any arrangement === | === Horizontal force on multiple vertical cylinders in any arrangement === | ||
− | The proof is essentially based on a phasing argument. Relative to the reference frame | + | The proof is essentially based on a phasing argument. Relative to the reference frame, |
<center><math> \Phi_I = \mathrm{Re} \left\{ \frac{i g A}{\omega} e^{Kz-iKx + i\omega t} \right\} \,</math></center> | <center><math> \Phi_I = \mathrm{Re} \left\{ \frac{i g A}{\omega} e^{Kz-iKx + i\omega t} \right\} \,</math></center> | ||
− | + | Expressing the incident wave relative to the local frames by introducing the phase factors, | |
− | introducing the phase factors | ||
<center><math> \mathbf{P}_i = e^{-iKx_i} </math></center> | <center><math> \mathbf{P}_i = e^{-iKx_i} </math></center> | ||
− | + | and letting | |
<center><math> X+X_i + \xi_i \,</math></center> | <center><math> X+X_i + \xi_i \,</math></center> | ||
− | Then relative to the i-th leg | + | Then relative to the i-th leg, |
<center><math> \Phi_I^{(i)} = \mathrm{Re} \left\{ \frac{ i g A}{\omega} e^{Kz - iK\xi_i + i\omega t} \mathbf{P}_i \right\} \quad i=1,\cdots,N </math></center> | <center><math> \Phi_I^{(i)} = \mathrm{Re} \left\{ \frac{ i g A}{\omega} e^{Kz - iK\xi_i + i\omega t} \mathbf{P}_i \right\} \quad i=1,\cdots,N </math></center> | ||
− | Ignoring interactions between legs, which is a good approximation in long waves, the total exciting force on an n-cylinder platform is | + | Ignoring interactions between legs, which is a good approximation in long waves, the total exciting force on an n-cylinder platform is |
<center><math> \mathbf{X}_1^N = \sum_{i=1}^N \mathbf{P}_i \mathbf{X}_1 \,</math></center> | <center><math> \mathbf{X}_1^N = \sum_{i=1}^N \mathbf{P}_i \mathbf{X}_1 \,</math></center> | ||
Line 135: | Line 134: | ||
The above expression gives the complex amplitude of the force with <math>\mathbf{X}_1\,</math> given in the single cylinder case. | The above expression gives the complex amplitude of the force with <math>\mathbf{X}_1\,</math> given in the single cylinder case. | ||
− | + | The above technique may be easily extended to estimate the Sway force and Yaw moment on n-cylinders with little extra effort. | |
=== Surge exciting force on a 2D section === | === Surge exciting force on a 2D section === |
Revision as of 11:56, 10 April 2009
Wave and Wave Body Interactions | |
---|---|
Current Chapter | Long Wavelength Approximations |
Next Chapter | Wave Scattering By A Vertical Circular Cylinder |
Previous Chapter | Added-Mass, Damping Coefficients And Exciting Forces |
Introduction
Very frequently the length of ambient waves [math]\displaystyle{ \lambda \, }[/math] is large compared to the dimension of floating bodies. For example the length of a wave with period [math]\displaystyle{ T=10 \mbox{s}\, }[/math] is [math]\displaystyle{ \lambda \simeq T^2 + \frac{T^2}{2} \simeq 150\mbox{m} \, }[/math]. The beam of a ship with length [math]\displaystyle{ L=100\mbox{m}\, }[/math] can be [math]\displaystyle{ 20\mbox{m}\, }[/math] as is the case for the diameter of the leg of an offshore platform.
GI Taylor's formula
Consider a flow field given by
[math]\displaystyle{ U(x,t):\ \mbox{Velocity of ambient unidirectional flow} \, }[/math]
[math]\displaystyle{ P(x,t):\ \mbox{Pressure corresponding to} \ U(x,t) \, }[/math]
In the absence of viscous effects and to leading order for [math]\displaystyle{ \lambda \gg B \, }[/math]:
where
Derivation using Euler's equations
An alternative form of GI Taylor's formula for a fixed body follows from Euler's equations:
Thus:
If the body is also translating in the x-direction with displacement [math]\displaystyle{ x_1(t)\, }[/math] then the total force becomes
Often, when the ambient velocity [math]\displaystyle{ U\, }[/math] is arising from plane progressive waves, [math]\displaystyle{ \left| U \frac{\partial U}{\partial x} \right| = 0(A^2) \, }[/math] and is omitted. Note that [math]\displaystyle{ U\, }[/math] does not include disturbance effects due to the body.
Applications of GI Taylor's formula in wave-body interactions
Archimedean hydrostatics
So Archimedes' formula is a special case of GI Taylor when there is no flow. This offers an intuitive meaning to the term that includes the body displacement.
Regular waves over a circle fixed under the free surface
So the horizontal force on the circle is:
Thus:
We can derive the vertical force along very similar lines. It is simply [math]\displaystyle{ 90^\circ\, }[/math] out of phase relative to [math]\displaystyle{ F_x\, }[/math] with the same modulus.
Horizontal force on a fixed circular cylinder of draft [math]\displaystyle{ T\, }[/math]
This case arises frequently in wave interactions with floating offshore platforms.
Here we will evaluate [math]\displaystyle{ \frac{\partial u}{\partial t} \, }[/math] on the axis of the platform and use a strip wise integration to evaluate the total hydrodynamic force.
The differential horizontal force over a strip [math]\displaystyle{ \mathrm{d} z \, }[/math] at a depth [math]\displaystyle{ z \, }[/math] becomes:
The total horizontal force over a truncated cylinder of draft [math]\displaystyle{ T\, }[/math] becomes:
This is a very useful and practical result. It provides an estimate of the surge exciting force on one leg of a possibly multi-leg platform as [math]\displaystyle{ T \to \infty; \quad \frac{1-e^{-KT}}{K} \to \frac{1}{K}\, }[/math]
Horizontal force on multiple vertical cylinders in any arrangement
The proof is essentially based on a phasing argument. Relative to the reference frame,
Expressing the incident wave relative to the local frames by introducing the phase factors,
and letting
Then relative to the i-th leg,
Ignoring interactions between legs, which is a good approximation in long waves, the total exciting force on an n-cylinder platform is
The above expression gives the complex amplitude of the force with [math]\displaystyle{ \mathbf{X}_1\, }[/math] given in the single cylinder case.
The above technique may be easily extended to estimate the Sway force and Yaw moment on n-cylinders with little extra effort.
Surge exciting force on a 2D section
- If the body section is a circle with radius [math]\displaystyle{ a\, }[/math]:
So in long waves, the surge exciting force is equally divided between the Froude-Krylov and the diffraction components. This is not the case for Heave!
Heave exciting force on a surface piercing section
In long waves, the leading order effect in the exciting force is the hydrostatic contribution:
where [math]\displaystyle{ A_w\, }[/math] is the body water plane area in 2D or 3D. [math]\displaystyle{ A\, }[/math] is the wave amplitude. This can be shown to be the leading order contribution from the Froude-Krylov force
Using the Taylor series expansion:
It is easy to verify that: [math]\displaystyle{ \mathbf{X}_3 \to \rho g A A_w \, }[/math].
The scattering contribution is of order [math]\displaystyle{ KB\, }[/math]. For submerged bodies: [math]\displaystyle{ \mathbf{X}_3^{FK}=O(KB)\, }[/math].
This article is based on the MIT open course notes and the original article can be found here
Ocean Wave Interaction with Ships and Offshore Energy Systems