(a) Interpretation: To calculate the velocity at point 2 by neglecting friction. Concept introduction: Following assumptions are made in the derivation of Bernoulli’s equation: The liquid is ideal and incompressible. The flow is at steady state and continuous. The flow is along the streamline The velocity is uniform over the section and is equal to the mean velocity. The only force acting on the fluid are gravity forces and the pressure forces. Now apply Bernoulli equation at point 1 and 2 P 1 ρ g + V 2 1 2 g + z 1 = P 2 ρ g + V 2 2 2 g + z 2 + h f ………………(1) Where P 1 & P 2 are pressure at section I and 2. V 1 & V 2 are velocity at section 1 and 2. z 1 & z 2 are the elevation from the horizontal at section 1 and 2. h f is the frictional losses

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Answer 1

Question

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

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In the production of ethyl acetate via reactive distillation, the column operates at 5 bar with an equimolar feed (ethanol + acetic acid) at 80°C. The reaction follows: \[CH_3COOH + C_2H_5OH \rightleftharpoons CH_3COOC_2H_5 + H_2O \quad (K_{eq} = 4.2 \text{ at } 80°C)\] Given: - NRTL parameters for all binary pairs - Tray efficiency = 65% - Vapor-liquid equilibrium exhibits positive azeotrope formation Calculate the exact minimum reflux ratio required to achieve 98% ethyl acetate purity in the distillate, assuming: 1) The reaction reaches equilibrium on each tray 2) The heavy key component is water

In a multi-stage distillation column designed to separate a binary mixture of ethanol and water, the mass flow rate of the feed entering the column is \( F \), and the distillate product flow rate is \( D \). The reflux ratio \( R \) is defined as the ratio of the liquid returned to the column to the distillate flow rate. For the ideal case, where the column operates at maximum efficiency, determine the **minimum reflux ratio** \( R_{\text{min}} \) when the relative volatility \( \alpha = 1.5 \).

Q2: Draw the layout of a basic asynchronous 32k * 8 SRAM.

Answer 2

Question

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

Expert Solution & Answer

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Check out a sample textbook solution

See solution

Answer 3

Question

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 4

Question

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 5

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

Answer 6

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Answer 7

Chapter 7, Problem 7.56P

Interpretation Introduction

(a)

Interpretation:

To calculate the velocity at point 2 by neglecting friction.

Concept introduction:

Following assumptions are made in the derivation of Bernoulli’s equation:

The liquid is ideal and incompressible.
The flow is at steady state and continuous.

The flow is along the streamline

The velocity is uniform over the section and is equal to the mean velocity.

The only force acting on the fluid are gravity forces and the pressure forces.

Now apply Bernoulli equation at point 1 and 2
P1ρg+V212g+z1=P2ρg+V222g+z2+hf ………………(1)
Where
P₁ & P₂ are pressure at section I and 2.

V₁ & V₂ are velocity at section 1 and 2.

z₁ & z₂ are the elevation from the horizontal at section 1 and 2.

h_f is the frictional losses

Answer 8

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

Answer 9

Interpretation Introduction

(b)

Interpretation:

To determine the diameter at point 1 if the pipe diameter at point 2 is 6.00 cm.

Concept introduction:

Mass balance for study flow processes:

The total amount of mass within the control volume does not change with time.

So that, the total amount of mass entering a control volume equal to the total amount of mass leaving it.

If the mass flow is m. kg/s and volumetric flow rate is v. m³/s
Then from conservation of mass for steady flow process will be as follows
∑min.=∑mout. (Kg/s)
Where min. = (? ×A ×V) _in mout.
= (? A× V)_out
Conservation of mass at section 1 and section 2.

ρ1A1V1=ρ2A2V2

If density is constant then above equation reduce to
A1V1=A2V2

A is the area at respective section of the flowing processes

V is the velocity at respective section

? is the density of flowing fluid in control volume

Answer 10

Expert Solution & Answer

Answer 11

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Answer 12

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Answer 13

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