4.6.1.2: Metacentric Height, \(\overline{GM}\), Measurement
- Page ID
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The metacentric height can be measured by finding the change in the angle when a weight is moved on the floating body. Moving the weight, \(T\) a distance, \(d\) then the moment created is \[M_{weight} = Td\] This moment is balanced by \[M_{righting} = W_{total}\overline{GM_{new}}\theta\] Where, \(W_{total}\), is the total weight of the floating body including measuring weight. The angle, \(\theta\), is measured as the difference in the orientation of the floating body. The metacentric height is \[\overline{GM_{new}} = \frac{Td}{W_{total}\theta}\] If the change int he \(\overline{GM}\) can be neglected, equation 58 provides the solution. The calculation of \(overline{GM}\) can be improved by taking into account the effect of the measuring weight. The change in height of \(G\) is \[\not{g} m_{total} G_{new} = \not{g} m_{ship} G_{actual} + \not{g} T h \] Combinging equation 59 with equation 58 results in \[\overline{GM_{actual}} = \overline{GM_{new}} \frac{m_{total}}{m_{ship}} - h\frac{T}{m_{ship}}\] The weight of the ship is obtained from looking at the ship depth.
Contributors and Attributions
Dr. Genick Bar-Meir. Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or later or Potto license.