TY - GEN
T1 - Comparative Energy And Exergy Analysis Of Large Capacity Ammoniawater And Water-Lithium Bromide Vapor Absorption Refrigeration (Var) Cycles
AU - Khan, Muhammad Saad
AU - Kadam, Sambhaji T.
AU - Kyriakides, Alexios Spyridon
AU - Hassan, Ibrahim
AU - Papadopoulos, Athanasios I.
AU - Rahman, Mohammad Azizur
AU - Seferlis, Panos
N1 - Publisher Copyright:
© 2021 by ASME.
PY - 2021
Y1 - 2021
N2 - District Cooling Plants (DCP) is the sustainable way of energy consumption, refrigeration, and supply of chilled water to end-users via chillers and distribution networks. Thermodynamic assessment of the vapor absorption refrigeration (VAR) in the open literature has been performed for cooling capacity well below the actual requirement (less than 300 kW) of DCP. Therefore, this work aims to investigate energy and exergy analysis of large-scale single effect VAR cycles operated on NH3-water and water-LiBr systems for a cooling capacity of 4000 kW and assess several operating parameters' influence on cycle performance. Different parameters such as evaporator operating pressure (water-LiBR = 0.010-0.020 atm, NH3-water = 5.39-6.20 atm), chilled water outlet temperature (288-297 K), absorber temperature (300-305 K), condenser temperature (310-315 K), cooling output (2900-4000 kW) and heat input (4300-5500 kW) to the generator are varied during the parametric analysis. The exergy destruction analysis of the cycle's components is also included in the study. Overall, the COP (0.89) and Exergy efficiency (89%) of water-LiBr were found to be higher than that of an equivalent NH3-water system which is 0.697 and 81%, respectively. The maximum exergy destruction was found at the absorber unit (24%), followed by the generator (23%). Furthermore, the NH3-water and water-LiBr simulations were optimized for different parametric conditions, and optimal operating conditions were identified for large-capacity district cooling systems. Therefore, the findings will provide the roadmap for designing and optimizing largescale DCP operated on VAR cycles.
AB - District Cooling Plants (DCP) is the sustainable way of energy consumption, refrigeration, and supply of chilled water to end-users via chillers and distribution networks. Thermodynamic assessment of the vapor absorption refrigeration (VAR) in the open literature has been performed for cooling capacity well below the actual requirement (less than 300 kW) of DCP. Therefore, this work aims to investigate energy and exergy analysis of large-scale single effect VAR cycles operated on NH3-water and water-LiBr systems for a cooling capacity of 4000 kW and assess several operating parameters' influence on cycle performance. Different parameters such as evaporator operating pressure (water-LiBR = 0.010-0.020 atm, NH3-water = 5.39-6.20 atm), chilled water outlet temperature (288-297 K), absorber temperature (300-305 K), condenser temperature (310-315 K), cooling output (2900-4000 kW) and heat input (4300-5500 kW) to the generator are varied during the parametric analysis. The exergy destruction analysis of the cycle's components is also included in the study. Overall, the COP (0.89) and Exergy efficiency (89%) of water-LiBr were found to be higher than that of an equivalent NH3-water system which is 0.697 and 81%, respectively. The maximum exergy destruction was found at the absorber unit (24%), followed by the generator (23%). Furthermore, the NH3-water and water-LiBr simulations were optimized for different parametric conditions, and optimal operating conditions were identified for large-capacity district cooling systems. Therefore, the findings will provide the roadmap for designing and optimizing largescale DCP operated on VAR cycles.
KW - COP
KW - H2O/LiBr
KW - NH3/H2O
KW - Parametric analysis
KW - Single effect VAR cycle
KW - Working fluid mixture
UR - http://www.scopus.com/inward/record.url?scp=85124391574&partnerID=8YFLogxK
U2 - 10.1115/IMECE2021-71084
DO - 10.1115/IMECE2021-71084
M3 - Conference contribution
AN - SCOPUS:85124391574
T3 - ASME International Mechanical Engineering Congress and Exposition, Proceedings (IMECE)
BT - Heat Transfer and Thermal Engineering
PB - American Society of Mechanical Engineers (ASME)
T2 - ASME 2021 International Mechanical Engineering Congress and Exposition, IMECE 2021
Y2 - 1 November 2021 through 5 November 2021
ER -