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(Fluid Flow). Two types of fluid flow:. Laminar. Turbulent.
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Flow direction.
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DSC_0059. Occlude: to block or reduce the cross-sectional area of an opening..
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Laminar flow. Non-viscous, incompressible fluids.
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Position 1. Position 2. Equation of Continuity.
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DSC_00012762.
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How much greater will the speed of the fluid be in the narrow part of the pipe?.
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Try this example before continuing with the presentation. Hit the down arrow when ready to continue..
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Lecture Example 1. Blood flows through the aorta with a velocity of 0.4 m.s -1 where the diameter is 16 mm. Given that the aorta braches into capillaries whose total cross-sectional area is 0.1π m 2 , calculate the average speed of the blood in the capillaries?.
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Lecture Example 1. Blood flows through the aorta with a velocity of 0.4 m.s -1 where the diameter is 16 mm. Given that the aorta braches into capillaries whose total cross-sectional area is 0.1π m 2 , calculate the average speed of the blood in the capillaries?.
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Conservation of Energy. Bernoulli’s Principle.
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Bernoulli’s Principle. Conservation of Energy.
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Bernoulli’s Principle. Conservation of Energy.
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Bernoulli’s Principle.
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Bernoulli’s Principle.
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Bernoulli’s Principle.
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2. ‘Torricelli’s Theorem’.
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Fluid is to be injected into a blood vessel at a rate of 10 -5 m 3 .min -1 through a tube of 0.5 mm in internal diameter. The fluid is in a container of large cross-sectional area, open to the atmosphere. How high above the end of the tube must the free surface of the fluid be? The gauge pressure in the blood is 100 mm Hg. Ignore the viscosity of the fluid, which has a density of 10 3 kg.m -3 ..
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Image result for intravenous drip. Fluid is to be injected into a blood vessel at a rate of 10 -5 m 3 .min -1 through a tube of 0.5 mm in internal diameter. The fluid is in a container of large cross-sectional area, open to the atmosphere. How high above the end of the tube must the free surface of the fluid be? The gauge pressure in the blood is 100 mm Hg. Ignore the viscosity of the fluid, which has a density of 10 3 kg.m -3 ..