Thermodynamic analysis of hybrid cycles based on a regenerative steam Rankine cycle for cogeneration and trigeneration

•Different hybrid configurations are proposed for Co and Trigeneration purposes.•A steam regenerative Rankine cycle, driven by a solar tower, is investigated.•The Rankine cycle is coupled with absorption cooling and multi effect distillation.•Configurations that use a lower temperature and pressure...

Full description

Saved in:
Bibliographic Details
Published in:Energy conversion and management 2018-02, Vol.158, p.460-475
Main Authors: Mohammadi, Kasra, McGowan, Jon G.
Format: Article
Language:English
Subjects:
Absorption
Absorption cooling
Cogeneration
Cogeneration and trigeneration
Compression
Condensates
Condensation
Configurations
Cooling
Cooling effects
Cooling towers
Desalination
Distillation
Distilled water
Economic factors
Electric power generation
Electric power plants
Electricity
Extraction points
Feasibility studies
Fresh water
Freshwater environments
Integration
Multi effect absorption cooling
Natural gas
Power penalty
Power plants
Rankine cycle
Reverse osmosis
Steam electric power generation
Steam Rankine cycle
Studies
Thermodynamics
Vapors
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Different hybrid configurations are proposed for Co and Trigeneration purposes.•A steam regenerative Rankine cycle, driven by a solar tower, is investigated.•The Rankine cycle is coupled with absorption cooling and multi effect distillation.•Configurations that use a lower temperature and pressure steam are more efficient.•Findings of this study are helpful to design efficient Co and Trigeneration plants. In this study, different feasible integrated configurations were proposed and thermodynamically evaluated for cogeneration of power and fresh water/cooling, and trigeneration of power, cooling and fresh water. A steam regenerative Rankine cycle with condensation and steam extractions, driven by a concentrated solar tower, was designed to supply the thermal heat requirements of absorption cooling and multi effect distillation, or thermal vapor compression-multi effect distillation. The results showed the configurations that utilize steam extraction with a lower temperature and pressure were more efficient. For power and fresh water cogeneration, utilizing the condensation steam to integrate multi effect distillation with a power cycle was thermodynamically more efficient than the integration of thermal vapor compression-multi effect distillation using extraction steams. Integrated Rankine cycle-multi effect distillation configuration was found to be very competitive with the direct supply of electricity to reverse osmosis systems, particularly at higher fresh water productions. However, further examinations are required considering geographical, environmental and economic factors. For power and cooling cogeneration, all proposed absorption cooling configurations were more efficient than supplying electricity directly to vapor compression cooling. Moreover, despite significantly lower steam requirements of double and triple effects absorption cooling, integration of a single effect absorption cooling to the power cycle was more efficient. The most efficient trigeneration configuration was identified when multi effect distillation and single effect absorption cooling were integrated to a Rankine cycle. The results and conclusions of this study can be generalized to other coal and natural gas power plants that employ similar Rankine cycle configurations.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2017.12.080