Physics For Scientists And Engineers: Foundations And Connections, Extended Version With Modern Physics
Physics For Scientists And Engineers: Foundations And Connections, Extended Version With Modern Physics
1st Edition
ISBN: 9781305259836
Author: Debora M. Katz
Publisher: Cengage Learning
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Chapter 15, Problem 67PQ

(a)

To determine

Volume flow rate between the two sections of the hose having a pressure difference 5.00kPa.

(a)

Expert Solution
Check Mark

Answer to Problem 67PQ

The volume flow rate between the two sections of the hose having a pressure difference 5.00kPa is 2.67×104m3/s_.

Explanation of Solution

Bernoulli’s theorem states that the energy stored in the olive oil flowing through both narrow and wide part of hose is constant.

Apply Bernoulli’s theorem in the given situation.

  P1+12ρv12+ρgy1=P2+12ρv22+ρgy2                                                                     (I)

Here, P1 is the pressure of olive oil flowing through the wide part of hose, ρ is the density of olive oil, g is the acceleration due to gravity, y1 is the height of oil in the wide part of hose, v1 is the velocity of oil, P2 is the pressure of oil flowing through the narrow part of hose, v2 is the velocity of oil in narrow part of hose, and y2 is the height of the oil in the narrow part of pipe.

Apply the continuity equation to find the relation between the velocities of oil in both parts of the hose.

  A1v1=A2v2                                                                                                          (II)

Here, A1 is the area of wide part of hose and A2 is the area of the narrow part of the hose.

Both wide and narrow parts of the hose are same height. Therefore, y1 is equal to y2.

Rewrite equation (I) to find P1P2.

  P1P2=12ρv2212ρv12ΔP=12ρv2212ρv12                                                                                            (III)

Here, ΔP is the pressure difference between the wide and narrow part of hose.

Write the equation to find the volume flow rate of the wide part of hose.

  R1=A1v1                                                                                                            (IVa)

Here, R1 is the volume flow rate of the wide part of hose.

Write the equation to find the volume flow rate of the narrow part of hose.

  R2=A2v2                                                                                                           (IVb)

Here, R2 is the volume flow rate of the wide part of hose.

Write the equation to find the area of the wide part of hose.

  A1=πr12                                                                                                           (V)

Here, r1 is the radius of the wide part of hose.

Write the equation to find the area of the narrow part of hose.

  A2=πr22                                                                                                           (VI)

Here, r2 is the radius of the narrow part of hose.

Write the equation to find the radius of wide part of hose.

  r1=d12                                                                                                                 (VII)

Here, d1 is the diameter of the wide part of hose.

Write the equation to find the radius of narrow part of hose.

  r2=d22                                                                                                                  (VIII)

Here, d2 is the diameter of the narrow part of hose.

Conclusion:

Substitute 3.00cm for d1 in equation (VII) to get r1.

  r1=3.00cm2=1.50cm

Substitute 1.50cm for r1 in equation (V) to get A1.

  A1=π(1.50cm)2

Substitute 1.00cm for d2 in equation (VIII) to get r2.

  r2=1.00cm2=0.500cm

Substitute 0.500cm for r2 in (VI) to get A2.

  A2=π(0.500cm)2

Substitute π(1.50cm)2 for A1 and π(0.500cm)2 for A2 in equation (II) and solve for v2.

  π(1.50cm)2v1=π(0.500cm)2v2v2=9v1

Substitute 9v1 for v2 and 875kg/m3 for ρ in equation (III).

  ΔP=12ρ(9v1)212ρv12=12(875kg/m3)(80v12)=35000v12

Rearrange for v1.

  v1=ΔP35000

Substitute 5kPa for ΔP in above equation to get v1.

  v1=5kPa(1000Pa1kPa)35000=0.378m/s

Substitute 0.378m/s for v1 and π(1.50cm)2 for A1 in equation (IV a) and solve for R1.

  R1=(0.378m/s)π(1.50cm(1m100cm))2=2.67×104m3/s

Therefore, the volume flow rate between the two sections of the hose having a pressure difference 5.00kPa is 2.67×104m3/s_.

(b)

To determine

Volume flow rate between the two sections of the hose having a pressure difference 12.5kPa.

(b)

Expert Solution
Check Mark

Answer to Problem 67PQ

The volume flow rate between the two sections of the hose having a pressure difference 5.00kPa is 4.22×104m3/s_.

Explanation of Solution

Refer sub part (b).

Substitute π(1.50cm)2 for A1 and π(0.500cm)2 for A2 in equation (II) and solve for v1.

  π(1.50cm)2v1=π(0.500cm)2v2v1=19v2

Substitute 19v2 for v1 and 875kg/m3 for ρ in equation (III).

  ΔP=12ρ(v2)212ρ(19v22)2=(875kg/m3)(0.494v22)=432.25v22

Rearrange for v1.

  v2=ΔP432.25

Substitute 12.5kPa for ΔP in above equation to get v2.

  v2=12.5kPa(1Pa103kPa)432.25=5.377m/s

Substitute 5.377m/s for v2 and for π(0.500cm)2 A2 in equation (IV b) and solve for R2.

  R2=(5.377m/s)π(0.500cm(1m100cm))2=4.22×104m3/s

Conclusion:

Therefore, the volume flow rate between the two sections of the hose having a pressure difference 12.5kPa is 4.22×104m3/s_.

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Chapter 15 Solutions

Physics For Scientists And Engineers: Foundations And Connections, Extended Version With Modern Physics

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