(a) Interpretation: Derive the relation between the velocity u 1 and u 2 at point 1 and point 2. 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 . m 3 /s Then from conservation of mass for steady flow process will be as follows ∑ m i n . = ∑ m o u t . (Kg/s) Where m i n . = (? ×A ×u) in m o u t . = (?× A× u) out A is the area at respective section of the flowing processes u is the velocity at respective section ? is the density of flowing fluid in control volume

Question

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Answer 1

Question

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Expert Solution & Answer

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Answer 2

Question

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Expert Solution & Answer

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See solution

Answer 3

Question

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Expert Solution & Answer

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Check out a sample textbook solution

See solution

Answer 4

Question

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Expert Solution & Answer

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Check out a sample textbook solution

See solution

Answer 5

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Answer 6

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Answer 7

Chapter 7, Problem 7.58P

Interpretation Introduction

(a)

Interpretation:

Derive the relation between the velocity u₁ and u₂ at point 1 and point 2.

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 ×u) _in mout. = (?× A× u)_out

A is the area at respective section of the flowing processes

u is the velocity at respective section

? is the density of flowing fluid in control volume

Answer 8

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Answer 9

Interpretation Introduction

(b)

Interpretation:

The Bernoulli equation for the system between point 1 and 2 should be used to prove the following equation:

P1−P2=15ρV2.2A12

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)

Given

A1=4A2

And from assumption density is constant and process is at steady state

Now from conservation of mass ρ1A1V1=ρ2A2V2

It gives 4V1=V2

Now from equation (1) P1ρg−P2ρg=V122g−V222g+z2−z1+hf

Answer 10

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Answer 11

Interpretation Introduction

(c)

Interpretation:

The volumetric flow rate of the acetone should be calculated.

Concept introduction:

If manometer reading is given, then to calculate the volumetric flow rate we can use the following formula, which is a function of area at both the section, and manometer reading.

V.=A1A22ghA12−A22

V.=A1V1

Answer 12

Expert Solution & Answer

Answer 13

Expert Solution & Answer

Answer 14

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Answer 15

Ch. 7 - A certain gasoline engine has an efficiency of...Ch. 7 - Prob. 7.2P Ch. 7 - Prob. 7.3P Ch. 7 - Prob. 7.4P Ch. 7 - Liquid ethanol is pumped from a large storage tank...Ch. 7 - Air at 300°C and 130 kPa flows through a...Ch. 7 - Prob. 7.7P Ch. 7 - Prob. 7.8P Ch. 7 - Prob. 7.9P Ch. 7 - Prob. 7.10P

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