Which of the following statement is TRUE?(A) Friction factor f in laminar flow depends on the Reynolds number and the surface roughness of the pipe(BBoth Circular and non-circular pipes can withstand large pressure differences between the inside and the outsidewithout undergoing any significant distortion.The pressure drop in a pipeline changes by a factor of 2 when the velocity of the flowing fluid is doubled(D)In a steady flow/ streamline flow, the rate of mass entering the flow system equals that leaving, as mass can neitheraccumulated nor depleted within a flow system under steady conditions(E)Reynolds experiment concluded that at streamline flow, thevelocity moved from a minimum at the tube center to amaximum atthe wall whereas the fluid itself moved in shells or lamina.

WE KNOW THAT, Pressure drop = △P = 32 μVLD2 WHERE, V = velocity if we doubled the velociy V2 = 2…

Answered: Which of the following statement is…

Introduction to Chemical Engineering Thermodynamics

8th Edition

ISBN:9781259696527

Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart

Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart

Chapter1: Introduction

Section: Chapter Questions

Problem 1.1P

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1. Water (p= 1000 kg m-³ and μ = 0.0011 kg m-¹ s-1) flows at 5 m s-1 over a 0.3 m long flat plat. Determine if the flow in the boundary layer is laminar over the entire length of the plat or it becomes turbulent at a downstream location. If latter is the case, determine the location of transition from laminar to turbulent. [Ans. BL flow is Laminar & turbulent, x = 0.11 m]
Please show your solution and write clearly.
The laminar flow of water in a small pipe is given by where R = 0.5 cm is the pipe radius, and Umax = 20 cm/s. Assume the temperature is 15°C. (a) Find the wall shear stress. (b) Find the pressure drop in a 10 cm length of the pipe. (c) Verify that the flow is indeed laminar.
Match each description with the most relevent (and appropriate) fluid property in the list. Intermolecular forces in the fluid that act parallel to the surface of the fluid Internal fluid resistance to motion or an applied stress A. Drag force B. Coefficient of compressibility, K resistance to deformation A force a flowing fluid exerts on a body moving through the fluid C. Surface tension, o the change in pressure corresponding to a fractional change in volume or density of a fluid while the temperature remains constant. D. Coefficient of volume expansion, B E. Viscosity, p The variation of the density of a fluid with temperature at constant pressure
5. Consider the problem of laminar, unidirectional flow in a pipe of radius a. Using the Navier- Stokes Equations: Solve for the velocity profile, u(r), in the pipe Calculate the maximum and bulk velocity (umax, ub) for this flow
Consider the following system where the fluid is moving upward in an annulus of height L using cylindrical coordinates
a) (i) What are a Newtonian fluid and a -Newtonian fluid? Classify pendent non-Newtonian fluids and illustrate - flow time- behaviours in a diagram g. shear stress vs. shear (ii) across a flat plate and the s with the aid of a schematic diagram. Explain boundary concept for a flow
7.11. The U-bend shown in Fig. 7.23 is connected to the rest of the piping system by flexible hoses. The inside diameter of the pipe is 3 in. The fluid flowing is water, and its average velocity in the pipe is 50 ft/s. The gauge pressure at point 1 is 30 psig and at point 2 is 20 psig. What is the horizontal component of the force in the support? Flow Flexible hoses →→ Flow Support FIGURE 7.23
1. An incompressible fluid of kinematic viscosity v = μ/p= 10-4 m²/s flows steadily through a circular pipe of diameter d = 10 cm. The pipe flow is fully developed. Friction Factor If the average velocity V is 2 m/s, is the flow laminar or turbulent? What is the value of the friction factor, f? If the pipe is perfectly smooth on its internal surface and V is 20 m/s, the pipe flow is turbulent (double check yourself). Evaluate its friction factor using the Moody chart below. Repeat (c) by numerically solving the Colebrook formula (using, for example, Matlab). Attach the source code you used. Suppose that the pipe internal surface is rough. Also suppose that increasing V up to 200 m/s yields no change in the value of f found in (a). Determine the relative roughness, e/d, using the Colebrook formula. 0.1 0.09 0.08 0.07 0.06 0.05 0.04 0.03 0.02 0.015 0.01 Laminar Flow 64 Material Concrete, coarse Concrete, new smooth Drawn tubing Glass, Plastic Perspex Iron, cast Sewers, old Steel, mortar…
Choose the correct option: According to Darcy's Law, the flow is considered to be: a) Laminate b) Tortuous c) Turbulent d) Systematic
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