Chapter 4 ENERGY ANALYSIS OF CLOSED SYSTEMS

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Chapter 4 ENERGY ANALYSIS OF CLOSED SYSTEMS Thermodynamics: An Engineering Approach Yunus A. Cengel, Michael A. Boles McGraw-Hill© Chapter 4 ENERGY ANALYSIS OF CLOSED SYSTEMS Dr. Kagan ERYURUK Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

MOVING BOUNDARY WORK Moving boundary work (P dV work): The expansion and compression work in a piston-cylinder device. The work associated with a moving boundary is called boundary work. Quasi-equilibrium process: A process during which the system remains nearly in equilibrium at all times. Wb is positive  for expansion (boundary work output) Wb is negative  for compression (boundary work input) A gas does a differential amount of work Wb as it forces the piston to move by a differential amount ds.

The boundary work done during a process depends on the path followed as well as the end states. The area under the process curve on a P-V diagram represents the boundary work. The net work done during a cycle is the difference between the work done by the system (A) and the work done on the system (B).

A rigid tank contains air at 500 kPa and 150°C A rigid tank contains air at 500 kPa and 150°C. As a result of heat transfer to the surroundings, the temperature and pressure inside the tank drop to 65°C and 400 kPa, respectively. Determine the boundary work done during this process.

A piston–cylinder device initially contains 0 A piston–cylinder device initially contains 0.4 m3 of air at 100 kPa and 80°C. The air is now compressed to 0.1 m3 in such a way that the temperature inside the cylinder remains constant. Determine the work done during this process. where C is a constant. Schematic and P-V diagram for example.

Polytropic, Isothermal, and Isobaric processes Polytropic process: C, n (polytropic exponent) constants Polytropic process Polytropic and for ideal gas When n = 1 (isothermal process)

A piston–cylinder device contains 0 A piston–cylinder device contains 0.05 m3 of a gas initially at 200 kPa. At this state, a linear spring that has a spring constant of 150 kN/m is touching the piston but exerting no force on it. Now heat is transferred to the gas, causing the piston to rise and to compress the spring until the volume inside the cylinder doubles. If the cross-sectional area of the piston is 0.25 m2, determine (a) the final pressure inside the cylinder, (b) the total work done by the gas, and (c) the fraction of this work done against the spring to compress it. 1 The expansion process is quasi-equilibrium. 2 The spring is linear in the range of interest. Schematic and P-V diagram for example

ENERGY BALANCE FOR CLOSED SYSTEMS Energy balance for any system undergoing any process Energy balance in the rate form The total quantities are related to the quantities per unit time is Energy balance per unit mass basis Energy balance for a cycle

Energy balance when sign convention is used (i. e Energy balance when sign convention is used (i.e., heat input and work output are positive; heat output and work input are negative). For a cycle E = 0, thus Q = W.

A rigid tank is divided into two equal parts by a partition A rigid tank is divided into two equal parts by a partition. Initially, one side of the tank contains 5 kg of water at 200 kPa and 25°C, and the other side is evacuated. The partition is then removed, and the water expands into the entire tank. The water is allowed to exchange heat with its surroundings until the temperature in the tank returns to the initial value of 25°C. Determine (a) the volume of the tank, (b) the final pressure, and (c) the heat transfer for this process. 1 The system is stationary and thus the kinetic and potential energy changes are zero, ∆KE = ∆PE = 0 and ∆E = ∆U. 2 The direction of heat transfer is to the system (heat gain, Qin). A negative result for Qin indicates the assumed direction is wrong and thus it is a heat loss. 3 The volume of the rigid tank is constant, and thus there is no energy transfer as boundary work. 4 The water temperature remains constant during the process. 5 There is no electrical, shaft, or any other kind of work involved. Schematic and P-v diagram for example

SPECIFIC HEATS Specific heat at constant volume, cv: The energy required to raise the temperature of the unit mass of a substance by one degree as the volume is maintained constant. Specific heat at constant pressure, cp: The energy required to raise the temperature of the unit mass of a substance by one degree as the pressure is maintained constant. It takes different amounts of energy to raise the temperature of different substances by the same amount. Constant-volume and constant-pressure specific heats cv and cp (values are for helium gas). Specific heat is the energy required to raise the temperature of a unit mass of a substance by one degree in a specified way.

cp is always greater than cv. Formal definitions of cv and cp. The equations in the figure are valid for any substance undergoing any process. cv and cp are properties. cv is related to the changes in internal energy and cp to the changes in enthalpy. A common unit for specific heats is kJ/kg · °C or kJ/kg · K. Are these units identical? The specific heat of a substance changes with temperature. True or False? cp is always greater than cv. Formal definitions of cv and cp.

INTERNAL ENERGY, ENTHALPY, AND SPECIFIC HEATS OF IDEAL GASES Internal energy and enthalpy change of an ideal gas For ideal gases, u, h, cv, and cp vary with temperature only.

At low pressures, all real gases approach ideal-gas behavior, and therefore their specific heats depend on temperature only. The specific heats of real gases at low pressures are called ideal-gas specific heats, or zero-pressure specific heats, and are often denoted cp0 and cv0. u and h data for a number of gases have been tabulated. These tables are obtained by choosing an arbitrary reference point and performing the integrations by treating state 1 as the reference state. Ideal-gas constant-pressure specific heats for some gases (see Table A–2c for cp equations). In the preparation of ideal-gas tables, 0 K is chosen as the reference temperature.

Three ways of calculating u and h By using the tabulated u and h data. This is the easiest and most accurate way when tables are readily available. By using the cv or cp relations (Table A-2c) as a function of temperature and performing the integrations. This is very inconvenient for hand calculations but quite desirable for computerized calculations. The results obtained are very accurate. By using average specific heats. This is very simple and certainly very convenient when property tables are not available. The results obtained are reasonably accurate if the temperature interval is not very large. Three ways of calculating u.

Specific Heat Relations of Ideal Gases The relationship between cp, cv and R dh = cpdT and du = cvdT On a molar basis Specific heat ratio The specific ratio varies with temperature, but this variation is very mild. For monatomic gases (helium, argon, etc.), its value is essentially constant at 1.667. Many diatomic gases, including air, have a specific heat ratio of about 1.4 at room temperature. The cp of an ideal gas can be determined from a knowledge of cv and R.

Air at 300 K and 200 kPa is heated at constant pressure to 600 K Air at 300 K and 200 kPa is heated at constant pressure to 600 K. Determine the change in internal energy of air per unit mass, using (a) data from the air table (Table A–17), and (b) the average specific heat value (Table A–2b).

A piston–cylinder device initially contains air at 150 kPa and 27°C A piston–cylinder device initially contains air at 150 kPa and 27°C. At this state, the piston is resting on a pair of stops, as shown in figure, and the enclosed volume is 400 L. The mass of the piston is such that a 350-kPa pressure is required to move it. The air is now heated until its volume has doubled. Determine (a) the final temperature, (b) the work done by the air, and (c) the total heat transferred to the air. 1 Air is an ideal gas since it is at a high temperature and low pressure relative to its critical-point values. 2 The system is stationary and thus the kinetic and potential energy changes are zero, ∆KE = ∆PE = 0 and ∆E = ∆U. 3 The volume remains constant until the piston starts moving, and the pressure remains constant afterwards. 4 There are no electrical, shaft, or other forms of work involved. Schematic and P-V diagram for example

INTERNAL ENERGY, ENTHALPY, AND SPECIFIC HEATS OF SOLIDS AND LIQUIDS Incompressible substance: A substance whose specific volume (or density) is constant. Solids and liquids are incompressible substances. The specific volumes of incompressible substances remain constant during a process. The cv and cp values of incompressible substances are identical and are denoted by c.

Internal Energy Changes Enthalpy Changes The enthalpy of a compressed liquid

Determine the enthalpy of liquid water at 100°C and 15 MPa (a) by using compressed liquid tables, (b) by approximating it as a saturated liquid.

A 50-kg iron block at 80°C is dropped into an insulated tank that contains 0.5 m3 of liquid water at 25°C. Determine the temperature when thermal equilibrium is reached. 1 Both water and the iron block are incompressible substances. 2 Constant specific heats at room temperature can be used for water and the iron. 3 The system is stationary and thus the kinetic and potential energy changes are zero, ∆KE =∆PE = 0 and ∆E =∆U. 4 There are no electrical, shaft, or other forms of work involved. 5 The system is well-insulated and thus there is no heat transfer. Schematic for example