MARITIME – HULL & NAVAL ARCHITECTURE CALCULATOR
Sloshing Frequency
A precise tool.
What is the Sloshing Frequency & How does it work?
Sloshing is the freeβsurface motion that occurs when a partiallyβfilled tank is subjected to ship motions or external accelerations. The phenomenon can generate large dynamic pressures on the tank walls and affect vessel stability, especially in roll and pitch maneuvers.
For a rectangular tank the natural angular frequency of the fundamental sloshing mode can be expressed analytically. Using the waveβnumber (k = frac{npi}{L}) (where (L) is the tank length and (n) the mode number) the frequency is
The corresponding cyclic frequency in hertz is (f = frac{\omega}{2pi}).
Knowing the sloshing natural frequency enables naval architects to avoid resonance with the vesselβs motion spectra, to size baffles appropriately, and to assess the impact on structural loads. The simple analytical model provides a quick firstβorder estimate before resorting to more detailed CFD or experimental studies.
\omega = \sqrt{g \, k \tanh(k h)}
\omega = natural angular frequency (rad/s)
g = gravitational acceleration (m/sΒ²)
k = waveβnumber (1/m)
h = liquid depth (m)
g = gravitational acceleration (m/sΒ²)
k = waveβnumber (1/m)
h = liquid depth (m)
Parameters
Result
β
Frequently Asked Questions
What is sloshing in a ship's tank?
Sloshing refers to the free-surface motion of liquid inside a partially-filled tank when subjected to ship motions or external forces, which can affect vessel stability.
How do you calculate the natural angular frequency for sloshing in a rectangular tank?
The natural angular frequency is calculated using the formula: omega = sqrt(g * k^2), where g is gravitational acceleration and k is the wave number given by k = n*pi/L, with L being the tank length and n the mode number.
What factors affect the sloshing frequency in a ship's tank?
The sloshing frequency is affected by the tank dimensions (length, width, height), the liquid properties (density), and the gravitational acceleration. The mode number also plays a significant role.
Why is it important to consider sloshing in maritime navigation?
Sloshing can generate large dynamic pressures on tank walls, potentially affecting vessel stability during roll and pitch maneuvers, which is crucial for safe maritime operations.
Can you explain the concept of mode number in sloshing frequency calculations?
The mode number (n) represents different vibration patterns within the tank. Higher mode numbers indicate more complex waveforms and higher frequencies.
Results are for informational purposes only and do not constitute professional advice.