Motion Stability - Seakeeping and Manoeuvring - Solved Assignment, Exercises of Applied Chemistry

The major points discuss in these assignment notes are: Motion Stability, Equations of Motion, Maneuverability, Hydrodynamic Derivatives, Types of Motion Stability, Straight Line Stability, Directional Stability, Positional Stability, Momentary Disturbance

Typology: Exercises

2012/2013
On special offer
30 Points
Discount

Limited-time offer


Uploaded on 04/20/2013

gaaddin
gaaddin 🇮🇳

4.3

(36)

245 documents

1 / 6

Toggle sidebar

This page cannot be seen from the preview

Don't miss anything!

bg1
1
MODULE II : MANEUVERABILITY
Topic: Motion Stability, Equations of Motion and Hydrodynamic Derivatives
Question 1
Describe by suitable sketches different types of motion stability for a surface ship
Answer:
Motion stability refers to the ship’s behavior after a momentary disturbance is applied
to the vehicle in steady forward motion.
There are 3 types of motions stability:
i. Straight line stability : this is the ships ability to resume a straight-line path
without application of control surface forces. This means, if the ship takes
a straight-line path after the disturbance is removed, then it is said to
possess straight-line stability.
ii. Directional stability: this is the ship’s ability to resume a straight line path
having the same direction as it had before the disturbance. There can be
two possible paths during the disturbance phase: either it can be
oscillatory or non-oscillatory.
iii. Positional stability: this is the ship’s ability to resume a straight line path
having the same direction and position it had before the disturbance. Here
by position we mean that it follows essentially the same straight line path it
had before the disturbance.
These are illustrated in the diagram below.
Docsity.com
pf3
pf4
pf5
Discount

On special offer

Partial preview of the text

Download Motion Stability - Seakeeping and Manoeuvring - Solved Assignment and more Exercises Applied Chemistry in PDF only on Docsity!

MODULE II : MANEUVERABILITY

Topic: Motion Stability, Equations of Motion and Hydrodynamic Derivatives

Question 1

Describe by suitable sketches different types of motion stability for a surface ship

Answer:

Motion stability refers to the ship’s behavior after a momentary disturbance is applied to the vehicle in steady forward motion.

There are 3 types of motions stability:

i. Straight line stability : this is the ships ability to resume a straight-line path without application of control surface forces. This means, if the ship takes a straight-line path after the disturbance is removed, then it is said to possess straight-line stability.

ii. Directional stability: this is the ship’s ability to resume a straight line path having the same direction as it had before the disturbance. There can be two possible paths during the disturbance phase: either it can be oscillatory or non-oscillatory.

iii. Positional stability: this is the ship’s ability to resume a straight line path having the same direction and position it had before the disturbance. Here by position we mean that it follows essentially the same straight line path it had before the disturbance.

These are illustrated in the diagram below.

Question 3

Briefly describe what is meant by hydrodynamic derivatives. Identify the important linear hydrodynamic derivatives that arise in the study of maneuverability and discuss their relative magnitudes.

Answer:

Hydrodynamic derivatives are essentially derivatives of hydrodynamic forces and moments against the motion parameters. Thus if A represents hydrodynamic forces/moments and α represents a velocity parameter, then the derivatives 2 , 2

A A

etc. are called the hydrodynamic derivatives. Forces/moments and

velocities/accelerations are related through Newton’s equation of motion and one influences the other. The importance of the hydrodynamic derivatives terms arise from the fact that the nature of the various hydrodynamic forces/moments and the motions parameters are related through these terms.

For a ship in horizontal plane motions, the important forces and moments are sway force Y and yaw moment N. The important motion parameters are sway and yaw

velocities and accelerations v v , ,&^ ψ ψ & &&,^. Thus the important linear derivatives are:

Yv , Nv , Yv (^) & , Nv (^) & , Y ψ (^) & , N ψ (^) & , Y (^) ψ (^) && , N ψ&&. Their relative magnitudes are as shown below:

Y v & : large negative Y v : large negative N v & : small, positive or negative N v : small, positive or negative Y ψ (^) && ≡ Y r & : small, positive or negative Y ψ (^) & ≡ Y r : small, positive or negative N ψ (^) && ≡ N r &: large negative N ψ (^) & ≡ N r : large negative

Question 4

Two designs possess the following values of derivatives:

Design (^) Y v ' N v ' Y r ' N ' r m ' A -0.36 -0.07 0.06 -0.07 0. B -0.26 -0.10 0.01 -0.03 0.

Comment on the straight-line motion stability of the two designs. Assuming both designs are 100m long, how far are the neutral points ahead of CG?

Answer:

For the ship to possess straight-line motion stability, the following criterion must be met:

' ' ' '

r v r v

N N

Y m Y

or equivalently the stability index must be positive:

' ' ' (^) ( ' ') 0 cN Yr vNv Yrm >

For design A, c = (-0.07)(-0.36) - (-0.07)(0.06-0.12)=0.0252 - 0.0042=+0.

For design B, c =(-0.03)((-0.26) – (-0.10)(0.01-0.10)=0.0078 – 0.009 = -0.

Thus we see that design B does not possess straight-line stability while design A has straight-line stability.

The distance of neutral point ahead of CG is given by ( Nv '^ / Yv ') L.

Thus for L =100m., the distance of neutral point for design A and B are respectively (100)(-0.07/-0.36)=19.44m and (100)(-0.10/-0.26)=38.46m.

Question 5

The hydrodynamic derivatives for a 180m. long ship without a skeg are:

' ' ' ' '

v v r r

Y N

Y N

m

When a skeg is added, Y v ' and N v ' become -0.0050 and 0.0 respectively, Show that

the ship without the skeg is unstable but addition of the skeg makes it stable. Determine the distance of the neutral point for the two cases, and find the relative distance the neutral point has shifted aft due to addition of the skeg.

Answer:

The stability index is :

' ' ' (^) ( ' ') cN Yr vNv Yrm