Presentation is loading. Please wait.

Presentation is loading. Please wait.

STEAM TURBINE POWER CYCLES. The vast majority of electrical generating plants are variations of vapour power plants in which water is the working fluid.

Published byMatthew Wells Modified over 9 years ago

Similar presentations

Presentation on theme: "STEAM TURBINE POWER CYCLES. The vast majority of electrical generating plants are variations of vapour power plants in which water is the working fluid."— Presentation transcript:

1 STEAM TURBINE POWER CYCLES

2 The vast majority of electrical generating plants are variations of vapour power plants in which water is the working fluid. The basic components of a simplified fossil-fuel vapour power plant are shown schematically in the next slide.

3 Components of a simple vapour power plant

4 Rankine Cycle

5 Principal work and heat transfers of subsystem A

6 The thermal efficiency of a Rankine Cycle is expressed as The back work ratio for the Rankine power cycle is

7 Ideal Rankine Cycle

8 Temperature-entropy diagram of the ideal Rankine cycle

9 Work of the pump is given by or

10 Example 1 Steam is the working fluid in an ideal Rankine cycle. Saturated vapour enters the turbine at 8.0 MPa and saturated liquid exits the condenser at a pressure of 0.008 MPa. The net power output of the cycle is 100 MW. Determine for the cycle (a) the thermal efficiency, (b) the back work ratio, (c) the mass flow rate of the steam, in kg/h, (d) the rate of heat transfer, into the working fluid as it passes through the boiler, in MW, (e) the rate of heat transfer, from the condensing steam as it passes through the condenser, in MW, (f) the mass flow rate of the condenser cooling water, in kg/h, if cooling water enters the condenser at 15 o C and exits at 35 o C.

11 Example 1

12 Effects of Boiler and Condenser Pressures on the Rankine Cycle

13 Effects of varying operating pressures on the ideal Rankine cycle. (a) Effect of boiler press. (b) Effect of condenser press.

14 Illustration used to compare the ideal Rankine cycle with the Carnot cycle

15 Principal Irreversibilities and Losses

16 Temperature-entropy diagrams showing the effects of turbine and pump irreversibilities

17

18 Example 2 Reconsider the vapour power cycle of Example 1, but include in the analysis that the turbine and the pump each have an isentropic efficiency of 85%. Determine for the modified cycle (a) the thermal efficiency, (b) the mass flow rate of steam, in kg/h, for a net power output of 100 MW, (c) the rate of heat transfer into the working fluid as it passes through the boiler, in MW, (d) the rate of heat transfer from the condensing steam as it passes through the condenser, in MW, (e) the mass flow rate of the condenser cooling water, in kg/h, if cooling water enters the condenser at 15 o C and exits at 35 o C.

19 Example 2

Download ppt "STEAM TURBINE POWER CYCLES. The vast majority of electrical generating plants are variations of vapour power plants in which water is the working fluid."

Similar presentations

Rankine Cycle Figures from Cengel and Boles, Thermodynamics, An Engineering Approach, 6th ed., McGraw Hill, 2008.

Rankine Cycle Figures from Cengel and Boles, Thermodynamics, An Engineering Approach, 6th ed., McGraw Hill, 2008.
EGR 334 Thermodynamics Chapter 4: Section 10-12

EGR 334 Thermodynamics Chapter 4: Section 10-12
Refrigeration Cycles Chapter 11.

Refrigeration Cycles Chapter 11.
A simplified Flow Chart for Thermal Science

A simplified Flow Chart for Thermal Science
Reading: Cengel & Boles, Chapter 9

Reading: Cengel & Boles, Chapter 9
ENERGY CONVERSION ES 832a Eric Savory www.eng.uwo.ca/people/esavory/es832.htm Lecture 12 – Large-scale plants Department of Mechanical and Material Engineering.

ENERGY CONVERSION ES 832a Eric Savory Lecture 12 – Large-scale plants Department of Mechanical and Material Engineering.
Example 1 - Superheat Rankine Cycle

Example 1 - Superheat Rankine Cycle
1 Lec 24: Rankine cycle reheat, deviations, efficiency increases, viscosity, introduction to fluid flow.

1 Lec 24: Rankine cycle reheat, deviations, efficiency increases, viscosity, introduction to fluid flow.
Vapor and Combined Power Cycles

Vapor and Combined Power Cycles
9 CHAPTER Vapor and Combined Power Cycles.

9 CHAPTER Vapor and Combined Power Cycles.
Power Generation OBJECTIVE To examine vapor power plants in which the working fluid is vaporized and condensed.

Power Generation OBJECTIVE To examine vapor power plants in which the working fluid is vaporized and condensed.
Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 25 Comparison to Carnot’s Heat Engine Effects of Boiling and.

Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 25 Comparison to Carnot’s Heat Engine Effects of Boiling and.
Chapter 1 VAPOR AND COMBINED POWER CYCLES

Chapter 1 VAPOR AND COMBINED POWER CYCLES
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)
Vapor Power Cycles Thermodynamics Professor Lee Carkner Lecture 19.

Vapor Power Cycles Thermodynamics Professor Lee Carkner Lecture 19.
GAS TURBINE POWER PLANTS

GAS TURBINE POWER PLANTS
Lec 23: Brayton cycle regeneration, Rankine cycle

Lec 23: Brayton cycle regeneration, Rankine cycle
A Vapor Power Cycle Boiler T Turbine Compressor (pump) Heat exchanger

A Vapor Power Cycle Boiler T Turbine Compressor (pump) Heat exchanger
Thermal_Power_Plant_2 Prepared by: NMG

Thermal_Power_Plant_2 Prepared by: NMG
Cogeneration.

Cogeneration.

Similar presentations

Ads by Google