Combined cooling for CSP plants: Modeling, experimental validation and optimization analysis

The global development of Concentrated Solar Thermal Power (CSP) projects demands new technologies that enhance the thermal efficiency of power cycles without increasing costs or environmental impact. Among the subsystems of the power cycle, the cooling circuit plays a critical role, as it must mini...

Full description

Bibliographic Details
Authors: Serrano, Juan Miguel, Palenzuela, Patricia, Ruiz, Javier, Navarro, Pedro, Muñoz-Cámara, José, Ortega-Delgado, Bartolomé, Roca, Lidia
Format: article
Publication Date:2026
Country:España
Institution:Universidad Miguel Hernández de Elche
Repository:REDIUMH. Depósito Digital de la UMH
OAI Identifier:oai:dnet:rediumh_____::463dab287059e304a3c8ae5f097da3a3
Online Access:https://hdl.handle.net/11000/39788
Access Level:Open access
Keyword:concentrated solar power
water consumption
wet cooling tower
air cooled heat exchanger
hybrid cooling
CDU::6 - Ciencias aplicadas::62 - Ingeniería. Tecnología::621 - Ingeniería mecánica en general. Tecnología nuclear. Electrotecnia. Maquinaria
Description
Summary:The global development of Concentrated Solar Thermal Power (CSP) projects demands new technologies that enhance the thermal efficiency of power cycles without increasing costs or environmental impact. Among the subsystems of the power cycle, the cooling circuit plays a critical role, as it must minimize water consumption while maintaining high efficiency; a challenge that is particularly relevant in arid regions where many CSP plants are installed. This paper presents a model for a cooling system that combines Dry Cooling (DC) and Wet Cooling Tower (WCT) technologies, enabling multiple operating configurations (parallel, series, parallel–series, only-WCT, and only-DC). The model was validated using experimental data from a 200 kWth pilot plant, achieving a Mean Absolute Error (MAE) below 0.97 ◦C for system temperatures and 19.4 l/h for water consumption. An optimization analysis was also performed, demonstrating the potential of the proposed technology to provide adaptive cooling for CSP plants under varying seasonal and operating conditions. For the pilot plant during summer, optimally combining DC and WCT in a parallel series configuration enabled a nearly continuous variation in specific electricity consumption, ranging from 0.06 kWe∕kWth in only-DC operation to values up to 90 % lower in only-WCT mode, at a water usage cost of 1.48 l/kWhth.