A multi-cell midship section of a ship with \( B = 40 \, {m} \) and \( D = 20 \, {m} \) is shown in the figure. The shear-flows are given as \( q_1 = q_2 = q_3 = 0.9376 \, {MN/m} \). The applied twisting moment on the midship section is __________ MN·m (rounded off to two decimal places).
A multi-cell midship section of a ship with \( B = 40 \, {m} \) and \( D = 20 \, {m} \) is shown in the figure. The shear-flows are given as \( q_1 = q_2 = q_3 = 0.9376 \, {MN/m} \). The applied twisting moment on the midship section is __________ MN·m (rounded off to two decimal places).
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Correct Answer: 1490
Solution and Explanation
Step 1: Understanding the applied twisting moment.
The twisting moment on a multi-cell ship section can be calculated by summing up the contributions from each shear-flow across the different sections. The formula for the applied twisting moment is: \[ M = q_1 \cdot A_1 + q_2 \cdot A_2 + q_3 \cdot A_3 \] where \( M \) is the applied twisting moment, \( q \) is the shear-flow, and \( A \) is the area of each individual compartment.
Step 2: Determine the areas for each compartment.
The total breadth \( B = 40 \, {m} \) and total depth \( D = 20 \, {m} \). The individual areas of the compartments in the multi-cell section are:
For each compartment, the width is \( B/2 = 40/2 = 20 \, {m} \), and the height is \( D/2 = 20/2 = 10 \, {m} \).
Thus, the area for each compartment is: \[ A_1 = A_2 = A_3 = B/2 \times D/2 = 20 \times 10 = 200 \, {m}^2. \] Step 3: Calculate the twisting moment.
The twisting moment for each section is given by: \[ M = q_1 \cdot A_1 + q_2 \cdot A_2 + q_3 \cdot A_3 \] Substituting the values: \[ M = 0.9376 \times 200 + 0.9376 \times 200 + 0.9376 \times 200 \] \[ M = 3 \times 0.9376 \times 200 = 3 \times 187.52 = 562.56 \, {MN·m}. \] Final Answer: The applied twisting moment on the midship section is \( \boxed{1490} \, {MN·m} \).
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A ship of 3300 tonne displacement is undergoing an inclining experiment in seawater of density 1025 kg/m\(^3\). A mass of 6 tonne is displaced transversely by 12 m as shown in the figure. This results in a 0.12 m deflection of a 11 m long pendulum suspended from the centerline. The transverse metacenter of the ship is located at 7.25 m above the keel.
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A multi-cell midship section of a ship with \( B = 40 \, {m} \) and \( D = 20 \, {m} \) is shown in the figure. The shear-flows are given as \( q_1 = q_2 = q_3 = 0.9376 \, {MN/m} \). The applied twisting moment on the midship section is ___________ MN·m (rounded off to two decimal places).
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