Presentation is loading. Please wait.

Presentation is loading. Please wait.

ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma.

Published byIliana Scull Modified over 9 years ago

Similar presentations

Presentation on theme: "ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma."— Presentation transcript:

1 ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma

2 Energy Analysis for a Control Volume Conservation of Mass Net Change in Mass within CV Total Mass Entering CV Total Mass Leaving CV = - Steady State

3 Example 1 Feedwater Heater: Inlet 1 T 1 = 200 ºC, p 1 = 700 kPa, Inlet 2 T 2 = 40 ºC, p 2 = 700 kPa, A 2 = 25 cm 2 Exit sat. liquid, p 3 = 700 kPa, Find Inlet 1 Inlet 2 Exit

4 Example 1 (continued) Steady State Inlet 2: compressed liquid Table A-4,v 2 = 0.001008 m 3 /kg Exit: saturated liquid Table A-5,v 3 = 0.001108 m 3 /kg

5 Example 1 (continued) = 54.15 – 40 = 14.15 kg/s

6 Energy Analysis for a Control Volume Flow work Energy that is necessary for maintaining a continuous flow through a control volume. A cross-sectional area p fluid pressure L width of fluid element F = pA W = FL = pAL= pV

7 Energy Analysis for a Control Volume Energy carried by a fluid element in a closed system Energy carried by a fluid element in a control volume

8 Energy Analysis for a Control Volume Conservation of Energy Net Change in Energy of CV Total Energy Carried by Mass Entering CV Total Energy Carried by Mass Leaving CV = - Total Energy Crossing Boundary as Heat and Work +

9 Steady-Flow Process A process during which a fluid flows through a control volume steadily. ● No properties within the control volume change with time. ● No properties change at the boundaries of the control volume with time. ● The heat and work interactions between a steady- flow system and its surroundings do not change with time.

10 Steady-Flow Process Conservation of mass Conservation of energy

11 Steady-Flow Process Conservation of mass Conservation of energy For single-stream steady-flow process

12 Steady-Flow Devices ● Nozzles and Diffusers A nozzle is used to accelerate the velocity of a fluid in the direction of flow while a diffuser is used to decelerate the flow. The cross-sectional area of a nozzle decreases in the direction of flow while it increases for a diffuser. For nozzles and diffusers,

13 Example 2 Steam enters an insulated nozzle at a flow rate of 2 kg/s with T i = 400 ºC, p i = 4 MPa, and Find the cross-sectional area at the exit. Inlet T i = 400 ºC p i = 4 MPa Exit p e = 1.5 MPa It exits at p e = 1.5 MPa with a velocity of

14 Example 2 (continued) Inlet, superheated vapor Table A-6, h i = 3213.6 kJ/kg = 2992.5 kJ/kg

15 Example 2 (continued) Table A-6, h e = 2992.5 kJ/kg 1.4 MPa 1.5 MPa 1.6 MPa 250 2927.2 2923.2 2919.2 300 3040.4 3037.6 3034.8 T = 280 ºC v = 0.1627 m 3 /kg = 0.000489 m 2

16 Steady-Flow Devices ● Turbines A turbine is a device from which work is produced as a result of the expansion of a gas or superheated steam through a set of blades attached to a shaft free to rotate. For turbines,

17 Example 3 Steam enters a turbine at a flow rate of 4600 kg/h. At the inlet, T i = 400 ºC, p i = 6 MPa, and If the turbine produces a power of 1 MW, find the heat loss from the turbine. Inlet T i = 400 ºC p i = 6 MPa Exit x e = 0.9 p e = 10 kPa At the exit, x e = 0.9, p e = 10 kPa and

18 Example 3 (continued) Inlet: superheated vapor at 6 MPa and 400 ºC Table A-6, h i = 3177.2 kJ/kg Exit: x = 0.9, saturated mixture at 10 kPa Table A-5, h f = 191.83 kJ/kg, h fg = 2392.8 kJ/kg h e = h f + x e h fg = 191.83 + 0.9 (2392.8) = 2345.4 kJ/kg

19 Example 3 (continued) h e - h i = 2345.4 – 3177.2= - 831.8 kJ/kg = - 63.1 kW

20 Steady-Flow Devices ● Compressors and Pumps Compressors and pumps are devices to which work is provided to raise the pressure of a fluid. For compressors, Compressors → gases Pumps → liquids For pumps,

21 Example 4 Air enters a compressor. At the inlet, T i = 290 K, p i = 100 kPa, and If given that A i = 0.1 m 2 and heat loss at a rate of 3 kW, find the work required for the compressor. Inlet T i = 290 K p i = 100 kPa Exit T e = 450 K p e = 700 kPa At the exit, T e = 450 K, p e = 700 kPa and

22 Example 4 (continued) Table A-17, at 290 K, h i = 290.16 kJ/kg, at 450 K, h e = 451.8 kJ/kg. = 0.72 kg/s

23 Example 4 (continued) = - 119.4 kW

24 Example 5 A pump steadily draws water at a flow rate of 10 kg/s. At the inlet, T i = 25 ºC, p i = 100 kPa, and If the exit is located 50 m above the inlet, find the work required for the pump. Inlet T i = 25 ºC p i = 100 kPa Exit T e = 25 ºC p e = 200 kPa At the exit, T e = 25 ºC, p e = 200 kPa and

25 Example 5 (continued) Table A-4, at 25 ºC v f = 0.001003 m 3 /kg h e – h i ~ [h f + v f (p – p sat )] e - [h f + v f (p – p sat )] i = v f (p e – p i ) = 0.001003 (200 – 100) = 0.1 kJ/kg g(z e – z i ) = 9.8(50)/10 3 = 0.49 kJ/kg

26 Example 5 (continued) = 20 (0.1 + 0.75 + 0.49) = 13.4 kW

Download ppt "ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma."

Similar presentations

ME 200 L19: ME 200 L19:Conservation Laws: Cycles HW 7 Due Wednesday before 4 pm HW 8 Posted Start early Kim See’s Office ME Gatewood Wing Room 2172 https://engineering.purdue.edu/ME200/

ME 200 L19: ME 200 L19:Conservation Laws: Cycles HW 7 Due Wednesday before 4 pm HW 8 Posted Start early Kim See’s Office ME Gatewood Wing Room
EGR 334 Thermodynamics Chapter 4: Section 6-8

EGR 334 Thermodynamics Chapter 4: Section 6-8
Entropy balance for Open Systems

Entropy balance for Open Systems
The First Law of Thermodynamics

The First Law of Thermodynamics
Chapter 5 MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES

Chapter 5 MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES
First Law of Thermodynamics - Open Systems

First Law of Thermodynamics - Open Systems
Chapter 4 Mass and Energy Analysis of Control Volumes (Open Systems)

Chapter 4 Mass and Energy Analysis of Control Volumes (Open Systems)
Chapter 4 The First Law of Thermodynamics: Control Volumes.

Chapter 4 The First Law of Thermodynamics: Control Volumes.
Chapter 5 MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES

Chapter 5 MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES
Lecture# 9 MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES

Lecture# 9 MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES
CHAPTER 5: Mass and Energy Analysis of Control Volumes

CHAPTER 5: Mass and Energy Analysis of Control Volumes
Chapter 7 Entropy (Continue).

Chapter 7 Entropy (Continue).
Energy Conservation(cont.) Example: Superheated water vapor is entering the steam turbine with a mass flow rate of 1 kg/s and exhausting as saturated steamas.

Energy Conservation(cont.) Example: Superheated water vapor is entering the steam turbine with a mass flow rate of 1 kg/s and exhausting as saturated steamas.
ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical

ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical
ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma.

ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma.
Mass and Energy Analysis of Control Volumes. 2 Conservation of Energy for Control volumes The conservation of mass and the conservation of energy principles.

Mass and Energy Analysis of Control Volumes. 2 Conservation of Energy for Control volumes The conservation of mass and the conservation of energy principles.
Lec 12: Closed system, open system

Lec 12: Closed system, open system
Chapter 7 Continued Entropy: A Measure of Disorder Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 5th edition.

Chapter 7 Continued Entropy: A Measure of Disorder Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 5th edition.
Chapter 5 Mass and Energy Analysis of Control Volumes Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 5th edition.

Chapter 5 Mass and Energy Analysis of Control Volumes Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 5th edition.
Eng. Samra Essalaimeh Philadelphia University 2nd Semester

Eng. Samra Essalaimeh Philadelphia University 2nd Semester

Similar presentations

Ads by Google