Lecture 10 - Rankine, Brayton, CC, and CHP PDF

Summary

This lecture presents an overview of Rankine, Brayton, combined cycle, and combined heat and power (CHP) systems. It discusses their applications in various sectors. The lecture also analyzes components like boilers and heat recovery mechanisms within these systems.

Full Transcript

Rankine, Brayton, Combine
Cycles, and CHP
ME 4180 – Energy Systems and Sustainability

Prof. Mario Medina
Department of Mechanical Engineering
Sept. 30, 2020
Agenda
Objective
Review the basics of heat and power cycles for stationary and
transportation sectors

Agenda
Steam power plants: Rankine cycle
Gas turbine power plants: Brayton cycle
Combine cycle power plants
Combine heat and power: cogeneration
Steam power plants
The Rankine cycle: the working fluid is steam or water
Analyze boiler or steam heater
Critical step: heat from energy carrier to working fluid
Gas turbine power plants
The basic Brayton cycle: the working fluid is air

Cycle efficiency increases with increasing burner operating pressure.
Compressor work is a much higher fraction of the turbine work compared to pump work in a Rankine
cycle (back work ratio)
Gas turbine power plants
Improving the basic Brayton cycle Wcycle Wturb ,1 + Wturb ,2 + Wcomp ,1 + Wcomp ,1
ηcycle =  =
Q in Q + Q
cc ,1 cc ,2

Multi-stage compression with intercooling
Multi-stage expansion with reheat
Regenerator (counterflow heat exchanger)
In the limit of infinite intercooling/reheat, the Brayton cycle
approaches isothermal heat addition and isothermal heat
removal.
Combined cycle power plants
Our first effort at waste heat recovery
 Waste heat recovered through combined cycles
More than 20% of the U.S. total energy use in 1997 was wasted in thermal losses from
power plants. That is enough energy to power almost all of the transportation sector.*
60% Waste heat

Fuel Coal-fired
40% Electricity out ηRankine = 40%
100% Steam Power Plant

Combined Cycle

Fuel Natural Gas Turbine
30% Electricity out
100% (Brayton)

70% Waste heat ηCC = 55-60%

Steam Power Plant
70×40=28% Electricity out
(Rankine)

*Shepard and Shepard, 2003 70×60=42% Waste heat
Combined cycle power plants

Video tour of a combine cycle power plant

https://www.youtube.com/watch?v=KVjtFX
We9Eo
Combined heat and power (CHP)
Generating power always creates heat
Combined heat and power plants are also called co-generation plants
In CHP s the heat transfer is a desired product of the cycle
CHP can be used at any scale – industrial power plants to I.C. engines and fuel cells
But the heat transfer application needs to be co-located with the power source. Heat cannot be
transferred large distances without incurring high losses

Basic coal fired Combined cycle Combined heat
power plant power plant and power plant
Combined heat and power (CHP)
Comparing generating heat and power independently to combined heat and power
(CHP)

144 kWH vs. 100 kWh to generate the same useful energy and heat:
31% energy savings!
CHP implemented with NG or steam turbines
CHP = Cogeneration – Why not use waste Gas Turbine with Heat Recovery

heat for heating?
Heat exchangers have high efficiencies (80-
90%)
On-site generation of electricity
Waste-heat recovery for heating, cooling, air-
conditioning, process applications
Steam Power Plant with Heat Recovery
Advantage: Power and heat are generated
from one fuel source.
Limitation: This is a distributed power
generation model with co-located demand
for power and heat (heat cannot go too far)

Image source: http://www.epa.gov/chp/basic/index.html
CHP/Cogeneration Examples

Image source: http://www.utilities.cornell.edu/utl_cchp_how_graphic.html