(a) Interpretation: The length and the diameter of the given bar should be determined A 500-lb load is applied on the bar, after this length and the diameter of the bar are to be determined where the Poisson's ratio is 0.30. Concept Introduction: Following formulas will be used for the calculation of new length and the diameter of titanium bar- δ l = P L A E Stress formula- σ = P A Poisson's ratio- γ = − e l a t e r a l e l o n g i t u d n a l P= applied force L= initial length A= area E= modulus of elasticity δl= Change in length P= applied force A = area

Question

2. Consider a polymeric membrane within a 6 cm diameter stirred ultrafiltration cell. The membrane is 30 μm thick. The membrane has pores equivalent in size to a spherical molecule with a molecular weight of 100,000, a porosity of 80%, and a tortuosity of 2.5. On the feed side of the membrane, we have a solution containing a protein at a concentration of 8 g L-1 with these properties: a = 3 nm and DAB = 6.0 × 10-7 cm² s¹. The solution viscosity is 1 cP. The hydrodynamic pressure on the protein side of the membrane is 20 pounds per square inch (psi) higher than on the filtrate side of the membrane. Assume that the hydrodynamic pressure difference is much larger than the osmotic pressure difference (advection >> diffusion). Determine the convective flow rate of the solution across the membrane.

Answer 1

Question

Chapter 6, Problem 6.34P

Interpretation Introduction

(a)

Interpretation:

The length and the diameter of the given bar should be determined

A 500-lb load is applied on the bar, after this length and the diameter of the bar are to be determined where the Poisson's ratio is 0.30.

Concept Introduction:

Following formulas will be used for the calculation of new length and the diameter of titanium bar-

δl=PLAE

Stress formula-

σ=PA

Poisson's ratio-

γ=−elateralelongitudnal

P= applied force

L= initial length

A= area

E= modulus of elasticity

δl= Change in length

P= applied force

A = area

Interpretation Introduction

(b)

Interpretation:

The applied load should be determined for the given copper bar.

Concept Introduction:

Applied load is calculated by using the following formulas-

Relation between rigidity modulus, modulus of elasticity and Poisson's ratio is-

G=E2(1+v)

Where,

G = modulus of rigidity

E = modulus of elasticity

v = Poisson's ratio

Hooke's law for shear stress (t) and strain (τ) is −

τ=Gγ

Shear stress is −

τ=FA

Shear strain is-

γ=ΔAA

Where,

τ = shear stress

γ = shear strain

G = proportional constant, modulus of rigidity

τ = shear stress

F= applied force

A= area

τ = shear strain

ΔA= deformed area or change in area

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