The system enables the average

flow and mass transfer rat

The system enables the average

flow and mass transfer rate between different rooms based on the mass conservation and energy balance equations to approximate find more how materials or energies are transmitted among the compartments of the multibody fluid delivery system by assuming each room homogenous (see Chang et al., 2003). In the context of the ventilation literature, researchers dealt with an algebraic set of equations detailing the flux between rooms/windows with empirical closures for the pressure drop coefficients characterising the flow between spaces. For example, Zhao et al. (2003), Engdahl (1999) and Chu et al., 2009 and Chu et al., 2010 have applied multizone models to simulate air velocity and temperature distributions in ventilated rooms. Available methodologies to study ballast MEK inhibitor water exchange include

field measurements, CFD, reduced models and small-scale experiments. Although field experiments are the most convincing method, they are expensive and restricted to specific types and therefore cannot provide general laws for all kinds of ships. For example, at three volumes flushing, the ballast water exchange efficiency is 99% for commercial oil tankers (Ruiz et al., 2005), 95% for bulk carriers (Rigby and Hallegraeff, 1994) and 87% for containerships (Ruiz and Reid, 2007). The dye samples were collected from the surface, 10 m deep and bottom of deck hatches. Due to limitations on tank access and sampling equipment, on-board experiments generally rely on measurements taken at the overflow outlet of the tank do not necessarily represent the volume mixture that remains in the ballast tank (Wilson et al., 2006). CFD can provide detailed results, but the major challenge is grid generation for such complex geometry and grid resolution. There is limited understanding of PIK-5 the vortex shedding flow due to the sharp edge of the

lightening holes between compartments. The reduced mathematical model is restricted to simple flows, but time saving and easy to extend. The dimensionless groups characterising small-scale tests may not match those of field problems, which may restrict their applicability, but they tend to be easier to operate. Therefore, in this study a reduced model is developed and validated by laboratory scale experiments. There is currently a significant gap in understanding how water that is initially in a ballast tank is removed by flushing. The purpose of this paper is to examine quantitatively how much of the initial water in idealised models of ballast tanks is removed using the current strategy of flushing. The focus in this paper is on scenarios where flushing occurs in waters with similar composition of the port water, where buoyancy effects are negligible.

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