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ES 202 Fluid and Thermal Systems Lecture 23: Power Cycles (2/4/2003)

ES 202 Fluid and Thermal Systems Lecture 23: Power Cycles (2/4/2003). Assignments. Homework: Reading assignment ES 201 notes (Section 7.9 and 8.4). Announcements. Lab #3 this week in DL-205 (Energy Lab) 4 lab groups over 3 periods (6 students per group)

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ES 202 Fluid and Thermal Systems Lecture 23: Power Cycles (2/4/2003)

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  1. ES 202Fluid and Thermal SystemsLecture 23:Power Cycles (2/4/2003)

  2. Assignments • Homework: • Reading assignment • ES 201 notes (Section 7.9 and 8.4) ES 202 Fluid & Thermal Systems

  3. Announcements • Lab #3 this week in DL-205 (Energy Lab) • 4 lab groups over 3 periods (6 students per group) • group formation (let me know by the end of today) • schedule sign-up • EES program for property lookup (download from course web) • I am available for discussion during evenings this week (in preparation for Exam 2 next Monday) • email me in advance to set up a meeting time ES 202 Fluid & Thermal Systems

  4. Road Map of Lecture 23 • Power cycle • use Rankine cycle as an example • the ideal Rankine cycle • representation on a T-s diagram • divergence of constant pressure lines • analysis of individual components (energy balance) • effects of irreversibility in turbine and compressor • Comments on Quiz 4 ES 202 Fluid & Thermal Systems

  5. Power Cycles • The integration of turbines, compressors, heat exchangers and combustors can generate power. • For example, the gas turbine engine: • identify the different components • The process path of any thermodynamic cycles form a closed loop on any phase/property diagram. • The direction of process path determines what kind of cycle it is (extracting power versus refrigeration, etc.) ES 202 Fluid & Thermal Systems

  6. heat exchanger (heat addition) 2 3 pump/compressor turbine 1 4 heat exchanger (heat removal) Rankine Cycle • Schematic of a typical Rankine cycle: • For an ideal Rankine cycle: • from State 1 to State 2: isentropic compression (pump) • from State 2 to State 3: isobaric heating (boiler) • from State 3 to State 4: isentropic expansion (turbine) • from State 4 to State 1: isobaric cooling (condenser) ES 202 Fluid & Thermal Systems

  7. Questions of Interests • Representation on a T-s diagram • How do we get a net work output from the cycle? • Effects of irreversibilities on cycle performance (graphical representation) • Analysis of individual components • definition of thermal efficiency • back work ratio ES 202 Fluid & Thermal Systems

  8. T 3 isentropic expansion through turbine 2 isentropic compression through pump 4 isobaric cooling through condenser s The T-s Diagram • Advice on problem solving: start with a process diagram on a T-s plane: P2 = P3 isobaric heating through boiler P4 = P1 1 ES 202 Fluid & Thermal Systems

  9. Energy Conversion • With reference to the T-s diagram on previous slide, a few observations are noteworthy: • the divergence of constant pressure lines at high temperatures implies that the mechanical power extracted from the turbine outweighs that required by the pump • in most situations, a fraction of the turbine work output is used to drive the pump and this fraction is called the back work ratio: • the Rankine cycle can be viewed as an energy conversion process from thermal energy to mechanical energy • the ratio between the net power output (turbine power – pump power) and the heat addition at the boiler is termed the thermal efficiency: ES 202 Fluid & Thermal Systems

  10. T 3 2a 2s 4a 4s 1 s Effects of Irreversibilities • Irreversibilities in the pump and turbine for non-ideal processes result in higher entropy at the exit of pump (2a) and turbine (4a). • highertemperature at pump exit implies morepump work • highertemperature at turbine exit implies lessturbine work ES 202 Fluid & Thermal Systems

  11. (due to mass conservation) steady state Energy Analysis • Adopt a “divide and conquer” approach to analyze the Rankine cycle. • Apply energy balance to the four individual components in the cycle. • Depending on the particular component, different terms in the energy balance are active while others are suppressed. • Typical assumptions common to all four components are: • steady state operation • negligible changes in kinetic and potential energy • Caution: changes in kinetic energy are not negligible for nozzle and diffusers • For these components, the energy balance can be reduced to a simple form: ES 202 Fluid & Thermal Systems

  12. Summary of Energy Analysis ES 202 Fluid & Thermal Systems

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