Holooly Plus Logo
Holooly Plus Logo

Question 9.19: Turbulent Flow of Blood BIO GOAL Use the Reynolds number to ...

Turbulent Flow of Blood BIO

GOAL Use the Reynolds number to determine a speed associated with the onset of turbulence.

PROBLEM Determine the speed at which blood flowing through an artery of diameter 0.20 cm will become turbulent.

STRATEGY The solution requires only the substitution of values into Equation 9.26 giving the Reynolds number and then solving it for the speed υ.

R N={\frac{\rho v d}{\eta}}              [9.26]

The blue check mark means that this solution has been answered and checked by an expert. This guarantees that the final answer is accurate.
Learn more on how we answer questions.

Solve Equation 9.26 for v, and substitute the viscosity and density of blood from Example 9.18, the diameter d of the artery, and a Reynolds number of 3.00 × 10³:

v=\frac{\eta(R N)}{\rho d}=\frac{\left(2.7  \times  10^{-3}  N \cdot s / m ^2\right)\left(3.00  \times  10^3\right)}{\left(1.05  \times  10^3  kg / m ^3\right)\left(0.20  \times  10^{-2}  m \right)}

υ = 3.9 m/s

REMARKS The exercise shows that rapid ingestion of soda through a straw may create a turbulent state

Related Answered Questions

Question: 9.9

Floating Down the River GOAL Apply Archimedes’ principle to a partially submerged object. PROBLEM A raft is constructed of wood having a density of 6.00 × 10² kg/m³. Its surface area is 5.70 m², and its volume is 0.60 m³. When the raft is placed in fresh water as in Figure 9.25, to what depth h is ...

Verified Answer:

Apply Newton’s second law to the raft, which is in...
Question: 9.14

Fluid Flow in a Pipe GOAL Solve a problem combining Bernoulli’s equation and the equation of continuity. PROBLEM A large pipe with a cross-sectional area of 1.00 m² descends 5.00 m and narrows to 0.500 m², where it terminates in a valve at point  ① (Fig. 9.33). If the pressure at point ② is ...

Verified Answer:

Write Bernoulli’s equation: (1)\quad P_{1}+...
Question: 9.13

Shoot-Out at the Old Water Tank GOAL Apply Bernoulli’s equation to find the speed of a fluid. PROBLEM A nearsighted sheriff fires at a cattle rustler with his trusty six-shooter. Fortunately for the rustler, the bullet misses him and penetrates the town water tank, causing a leak (Fig. 9.32 on page ...

Verified Answer:

(a) Find the speed of the water leaving the hole. ...
Question: 9.11

Niagara Falls GOAL Apply the equation of continuity. PROBLEM Each second, 5 525 m³ of water flows over the 670-m-wide cliff of the Horseshoe Falls portion of Niagara Falls. The water is approximately 2 m deep as it reaches the cliff. Estimate its speed at that instant. STRATEGY This is an estimate ...

Verified Answer:

Calculate the cross-sectional area of the water as...
Question: 9.10

Floating in Two Fluids GOAL Apply Archimedes’ principle to an object floating in a fluid having two layers with different densities. PROBLEM A 1.00 × 10³-kg cube of aluminum is placed in a tank. Water is then added to the tank until half the cube is immersed. (a) What is the normal force on the ...

Verified Answer:

(a) Find the normal force on the cube when half-im...
Question: 9.2

Built to Last GOAL Calculate a compression due to tensile stress, and maximum load. PROBLEM A vertical steel beam in a building supports a load of 6.0 × 10^4 N. (a) If the length of the beam is 4.0 m and its cross-sectional area is 8.0 × 10^-3 m², find the distance the beam is compressed along its ...

Verified Answer:

(a) Find the amount of compression in the beam. So...
Question: 9.1

Pressure and Weight of Water GOAL Relate density, pressure, and weight. PROBLEM (a) Calculate the weight of a cylindrical column of water with height h = 40.0 m and radius r = 1.00 m. (See Fig. 9.6.) (b) Calculate the force exerted by air on a disk of radius 1.00 m at the water’s surface. (c) What ...

Verified Answer:

(a) Calculate the weight of a cylindrical column o...
Question: 9.17

Rising Water GOAL Apply surface tension to capillary action. PROBLEM Find the height to which water would rise in a capillary tube with a radius equal to 5.0 × 10^-5 m. Assume the contact angle between the water and the material of the tube is small enough to be considered zero. STRATEGY This ...

Verified Answer:

Substitute the known values into Equation 9.22: [l...
Question: 9.6

A Pain in the Ear BIO GOAL Calculate a pressure difference at a given depth and estimate a force. PROBLEM Estimate the net force exerted on your eardrum due to the water above when you are swimming at the bottom of a pool that is 5.0 m deep. STRATEGY Use Equation 9.11 to find the pressure ...

Verified Answer:

Use Equation 9.11 to calculate the difference betw...
Question: 9.5

Oil and Water GOAL Calculate pressures created by layers of different fluids. PROBLEM In a huge oil tanker, salt water has flooded an oil tank to a depth of h2 = 5.00 m. On top of the water is a layer of oil h1 = 8.00 m deep, as in the cross-sectional view of the tank in Figure 9.14. The oil has a ...

Verified Answer:

Use Equation 9.11 to calculate the pressure at the...