Question 2.9: In a major human artery with an internal diameter of 5 mm, t...
In a major human artery with an internal diameter of 5 mm, the flow of blood, averaged over the cardiac cycle, is 5 cm^{3}·s^{−1}. The artery bifurcates (splits) into two identical blood vessels that are each 3 mm in diameter. What are the average velocity and the mass flow rate upstream and downstream of the bifurcation? The density of blood is 1.06 g·cm^{−3}.
The average velocity is given by the volumetric flow rate divided by the area for flow. Thus, upstream of the bifurcation, where the vessel diameter is 0.5 cm,
u_{up} = \frac{q}{A} = \frac{5 cm^{3} . s^{-1} }{(\pi /4)(0.5^{2} cm^{2})} =25.5 cm.s^{-1}
Downstream of the bifurcation, the volumetric flow rate in each vessel is 2.5 cm^{3}·s^{−1}, and the vessel diameter is 0.3 cm. Thus,
u_{down} = \frac{2.5 m^{3} . s^{-1} }{(\pi /4)(0.3^{2} cm^{2})} =35.4 cm.s^{-1}
The mass flow rate in the upstream vessel is given by the volumetric flow rate times the density:
\dot{m} _{UP} = 5 cm^{3}.s^{-1}\times 1.06 g⋅ cm^{-3} = 5.30 g.s^{-1}
Similarly, for each downstream vessel:
\dot{m} _{down} = 2.5 cm^{3}.s^{-3}\times 1.06 g⋅ cm^{-3} =2.65 g.s^{-1}
which is of course half the upstream value.