Explanation Given information: There are 18 stator blades. The axial flow speed is 31.4 m / s and impeller rotation is 1800 rpm . The radius is 0.50 m and the trailing edge angle is 26.6 ° . Write the expression for the angular velocity of the centrifugal pump. ω = 2 π n ˙ 60 .......(I) Here, the angular velocity of the centrifugal pump is ω and the number of rotation is n ˙ . The following figure represents the arrangement of the stator blade row. Figure-(1) Write the expression for tangential velocity of the rotor blades. u θ = ω r ....... (II) Here, the tangential velocity of the rotor blade is u θ and the radius is r . Write the expression for the magnitude of the velocity leaving the trailing edge. V → st = V in cos ( β st ) .......(III) Here, the velocity leaving at the trailing edge is V → st , the axial flow speed is V in and the trailing edge angle is β st . The following figure represents the reference frame of the rotor. Figure-(2) Write the expression for the trailing edge angle. β st = tan − 1 ( u θ + V in tan ( β st ) V in ) .......(IV) The following figure represents the exit of the trailing edge of the rotor. Figure-(3) Write the expression for the trailing edge angle of rotor. tan ( β rt ) = u θ V in ....... (V) Calculation: Substitute 1800 rpm for n ˙ in Equation (I). ω = 2 π ( 1800 rpm ) 60 = 11309.73355 rpm ( 1 rad / s 1 rpm ) 60 = 188.4955 rad / s Substitute 188.4955 rad / s for ω and 0.50 m for r in Equation (II). u θ = 188.4955 rad / s × ( 0.5 m ) = 94.2477 m / s Substitute 31.4 m / s for V in and 26

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ISBN: 8220103676205

Author: CENGEL

Publisher: YUZU

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Chapter 14, Problem 69P

To determine

The leading edge angle of the rotor blade.

The trailing edge angle of the rotor.

The number of blades in the rotor.

Sketch the shape of the shape of the rotor blade.

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Chapter 14, Problem 68P

Chapter 14, Problem 70P

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Chapter 14 Solutions

EBK FLUID MECHANICS: FUNDAMENTALS AND A

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The leading edge angle of the rotor blade. The trailing edge angle of the rotor. The number of blades in the rotor. Sketch the shape of the shape of the rotor blade.

Solution Summary: The author illustrates the leading edge angle of the rotor blade, the trailing edge angles, and the number of blades.

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The leading edge angle of the rotor blade. The trailing edge angle of the rotor. The number of blades in the rotor. Sketch the shape of the shape of the rotor blade.

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Chapter 14 Solutions

The leading edge angle of the rotor blade.

The trailing edge angle of the rotor.

The number of blades in the rotor.

Sketch the shape of the shape of the rotor blade.