A liquid of density ρ and viscosity μ is pumped at volume flow rate V ˙ through a pump of diameter D. The blades of the pump rotate at angular velocity ω . The pump supplies a pressure rise Δ P to the liquid Using dimensional analysis, generate a dimensionless relationship for Δ P as a function of the other parameters in the problem. Identify any established nondimensional parameters that appear in you: result Hint: For consistency (and whenever possible), it is wise to choose a length, a density, and a velocity (or angular velocity) as repeating variables.

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Textbook Question

Chapter 7, Problem 67P

A liquid of density ρ and viscosity μ is pumped at volume flow rate V ˙ through a pump of diameter D. The blades of the pump rotate at angular velocity ω . The pump supplies a pressure rise Δ P to the liquid Using dimensional analysis, generate a dimensionless relationship for Δ P as a function of the other parameters in the problem. Identify any established nondimensional parameters that appear in you: result Hint: For consistency (and whenever possible), it is wise to choose a length, a density, and a velocity (or angular velocity) as repeating variables.

Expert Solution & Answer

To determine

The dimensionless relationship for Δp.

Answer to Problem 67P

The dimensionless relationship for Δp is D2ρω2f(μD2ρω,V˙D3ω).

Explanation of Solution

Given information:

The number of variable parameters is 6.

Expression for number of pi terms,
k=n−j...... (I)
Here, number of variable parameters is n, number of primary dimensions is j.

Substitute 6 for n and 3 for j in Equation (I).

k=6−3=3

Expression for first pi terms,
∏1=ΔPDa1ρb1ωc1...... (II)
Here, pressure difference is ΔP, diameter is x, density is ρ, angular velocity is ω.

Expression for second pi terms,
∏2=μDa2ρb2ωc2...... (III)
Here, dynamic viscosity is μ.

Expression for third pi terms,
∏3=V˙Da2ρb2ωc2...... (IV)
Here, volume flow rate is V˙.

Expression for pressure,
ΔP=FA...... (V)
Here, force is F and area is A

Substitute [MLT−2] for dimension of F and [L2] for dimension of A in Equation (V).

ΔP=[ML T −2][ L 2]=[ML−1T−2]...... (VI)
Expression for dimension diameter,
D=[L]...... (VII)

Expression for density,
ρ=mv....... (VIII)
Here, mass is m, volume is v.

Substitute [M] for dimension of m, [L3] for dimension of v in Equation (V).

ρ=[M][ L 3]=[ML−3]...... (IX)
Expression for angular velocity,
ω=θt...... (X)
Substitute [M0L0T0] for dimension of θ and [T] for dimension of t.

ω=[ M 0 L 0 T 0]T=[T−1]...... (XI)
Expression for dynamic viscosity,
μ=FAVy...... (XII)
Substitute [MLT−2] for dimension of F, [L2] for dimension of A, [LT−1] for dimension of V and [L] for dimension of y in Equation (IX).

μ=[ML T −2][ L 2] [ L T −1 ] [L]=[ML−1T−1]...... (XIII)
Expression for dimension of volume flow rate,
V˙=vt...... (XIV)
Substitute [L3] for dimension of v and [T] for dimension of t in Equation (XIV).

V˙=[ L 3][T]=[L3T−1]...... (XV)
Expression for relation of ∏1, ∏2 and ∏3,
∏1=f(∏2,∏3)...... (XVI)
Calculation:

Substitute [M0L0T0] for dimension of ∏1, [ML−1T−2] for dimension of ΔP, [L] for dimension of D, [ML−3] for dimension of ρ and [T−1] for dimension of ω in Equation (II).

[M0L0T0]=[ML−1T−2][L]a1[ML −3]b1[T −1]c1[M0L0T0]=[M1+ b 1L−1+ a 1−3 b 1T−2− c 1]

Compare the exponent of [M] to obtain value of b1.

1+b1=0b1=−1

Compare the exponent of [T] to obtain value of c1.

−2−c1=0c1=−2

Compare the exponent of [L] to obtain dimension of a1.

−1+a1−3b1=0−1+a1+3=0a1=−2

Substitute the −2 for a1, −1 for b1, −2 for c1 in Equation (II).

∏1=ΔPD−2ρ−1ω−2=ΔPD2ρω2...... (XVII)
Substitute [M0L0T0] for dimension of ∏2, [ML−1T−1] for dimension of μ, [L] for dimension of D, [ML−3] for dimension of ρ and [T−1] for dimension of ω in Equation (III).

[M0L0T0]=[ML−1T−1][L]a2[ML −3]b2[T −1]c2[M0L0T0]=[M1+ b 2L−1+ a 2−3 b 2T−1− c 2]

Compare the exponent of [M] to obtain value of b2.

1+b2=0b2=−1

Compare the exponent of [T] to obtain value of c2.

−1−c2=0c2=−1

Compare the exponent of [L] to obtain dimension of a1.

−1+a2−3b2=0−1+a2+3=0a2=−2

Substitute the −2 for a2, −1 for b2, −1 for c2 in Equation (II).

∏2=μD−2ρ−1ω−1=μD2ρω...... (XVIII)
Substitute [M0L0T0] for dimension of ∏3, [L3T−1] for dimension of μ, [L] for dimension of D, [ML−3] for dimension of ρ and [T−1] for dimension of ω in Equation (IV).

[M0L0T0]=[L3T−1][L]a3[ML −3]b3[T −1]c3[M0L0T0]=[M b 3L3+ a 3−3 b 3T−1− c 3]

Compare the exponent of [M] to obtain value of b2.

b3=0

Compare the exponent of [T] to obtain value of c2.

−1−c3=0c3=−1

Compare the exponent of [L] to obtain dimension of a1.

3+a3−3b3=03+a3=0a3=−3

Substitute the −3 for a3, 0 for b3, −1 for c3 in Equation (IV).

∏3=V˙D−3ρ0ω−1=V˙D3ω...... (XVIII)
Substitute ΔPD2ρω2 for ∏1, μD2ρω for ∏2 and V˙D3ω for ∏3 in Equation (XVI).

ΔPD2ρω2=f(μ D 2 ρω, V ˙ D 3 ω)ΔP=D2ρω2f(μ D 2 ρω, V ˙ D 3 ω)

Conclusion:

The dimensionless relationship for Δp is D2ρω2f(μD2ρω,V˙D3ω).

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