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Chapter 4 Control Volume Analysis Using Energy (continued)

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Presentation on theme: "Chapter 4 Control Volume Analysis Using Energy (continued)"— Presentation transcript:

1 Chapter 4 Control Volume Analysis Using Energy (continued)

2 Learning Outcomes ►Distinguish between steady-state and transient analysis, ►Distinguishing between mass flow rate and volumetric flow rate. ►Apply mass and energy balances to control volumes. ►Develop appropriate engineering models to analyze nozzles, turbines, compressors, heat exchangers, throttling devices. ►Use property data in control volume analysis appropriately.

3 Energy Rate Balance time rate of change of the energy contained within the control volume at time t net rate at which energy is being transferred in by heat transfer at time t net rate at which energy is being transferred out by work at time t net rate of energy transfer into the control volume accompanying mass flow

4 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 2 properties

5

6

7 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 2 properties

8 Turbines ► Turbine: a device in which power is developed as a result of a gas or liquid passing through a set of blades attached to a shaft free to rotate.

9 Eq. 4.20a Turbine Modeling ► If the change in kinetic energy of flowing matter is negligible, ½(V 1 2 – V 2 2 ) drops out. ► If the change in potential energy of flowing matter is negligible, g(z 1 – z 2 ) drops out. ► If the heat transfer with surroundings is negligible, drops out.

10 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 2 properties Look up state 3 properties in order to determine W of Turbine

11

12 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 2 properties Look up state 3 properties in order to determine W of Turbine

13 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 4 properties

14 Heat Exchangers ► Direct contact: A mixing chamber in which hot and cold streams are mixed directly. ► Tube-within-a-tube counterflow: A gas or liquid stream is separated from another gas or liquid by a wall through which energy is conducted. Heat transfer occurs from the hot stream to the cold stream as the streams flow in opposite directions.

15 3 4

16 3 4 Q rejected

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18 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 4 properties Now one can solve for Q rejected

19 Compressors and Pumps ► Compressors and Pumps: devices in which work is done on the substance flowing through them to change the state of the substance, typically to increase the pressure and/or elevation. ► Compressor : substance is gas ► Pump: substance is liquid

20 Eq. 4.20a Compressor and Pump Modeling ► If the change in kinetic energy of flowing matter is negligible, ½(V 1 2 – V 2 2 ) drops out. ► If the change in potential energy of flowing matter is negligible, g(z 1 – z 2 ) drops out. ► If the heat transfer with surroundings is negligible, drops out.

21 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 1 properties

22

23 12 4 3 Consider a system similar to what the components that we’ve just analyzed in class. Assume ideal conditions initially Look up state 1 properties Now one can solve for W pump

24 Heat Exchangers – Boilers too Pump State 1To turbine, state 2

25 Power Cycle ►Applying the closed system energy balance to each cycle of operation, (Eq. 2.39)  E cycle = Q cycle – W cycle ►Since the system returns to its initial state after each cycle, there is no net change in its energy:  E cycle = 0, and the energy balance reduces to give (Eq. 2.41) W cycle = Q in – Q out ►In words, the net energy transfer by work from the system equals the net energy transfer by heat to the system, each per cycle of operation.

26 Power Cycle ►The performance of a system undergoing a power cycle is evaluated on an energy basis in terms of the extent to which the energy added by heat, Q in, is converted to a net work output, W cycle. This is represented by the ratio called the thermal efficiency.

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