Thermodynamic analysis of a new design of temperature controlled parabolic trough collector

Thermodynamic analysis of a new design of temperature controlled parabolic trough collector

•This new design parabolic trough collector has been made as temperature control.•The TCPTC system is very appropriate for the industrial systems which require high temperatures.•With TCPTC can provide hot water with low solar radiation.•TCPTC system costs are cheaper than other systems (thermo siph...

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Veröffentlicht in:Energy conversion and management 2013-10, Vol.74, p.505-510
Hauptverfasser: Ceylan, İlhan, Ergun, Alper
Format: Artikel
Sprache:eng
Schlagworte:
Accumulators
Applied sciences
Collectors
Computational efficiency
Computing time
Energy
Energy management
Equipments, installations and applications
Exact sciences and technology
Exergy
Mathematical analysis
Natural energy
PTC
Solar energy
Solar thermal conversion
Solar water heater
Temperature control
Water temperature
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container_title Energy conversion and management
container_volume 74
creator Ceylan, İlhan
Ergun, Alper
description •This new design parabolic trough collector has been made as temperature control.•The TCPTC system is very appropriate for the industrial systems which require high temperatures.•With TCPTC can provide hot water with low solar radiation.•TCPTC system costs are cheaper than other systems (thermo siphon systems, pomp systems, etc.). Numerous types of solar water heater are used throughout the world. These heaters can be classified into two groups as pumped systems and thermo siphon systems. However, water temperature cannot be controlled by these systems. In this study, a new temperature-controlled parabolic trough collector (TCPTC) was designed and analyzed experimentally. The analysis was made at a temperature range of 40–100°C, with at intervals of 10°C. A detailed analysis was performed by calculating energy efficiencies, exergy efficiencies, water temperatures and water amounts. The highest energy efficiency of TCPTC was calculated as 61.2 for 100°C. As the set temperature increased, the energy efficiency increased as well. The highest exergy efficiency was calculated as 63 for 70°C. However, as the set temperature increased, the exergy efficiency did not increase. Optimum exergy efficiency was obtained for 70°C.
doi_str_mv 10.1016/j.enconman.2013.07.020
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Numerous types of solar water heater are used throughout the world. These heaters can be classified into two groups as pumped systems and thermo siphon systems. However, water temperature cannot be controlled by these systems. In this study, a new temperature-controlled parabolic trough collector (TCPTC) was designed and analyzed experimentally. The analysis was made at a temperature range of 40–100°C, with at intervals of 10°C. A detailed analysis was performed by calculating energy efficiencies, exergy efficiencies, water temperatures and water amounts. The highest energy efficiency of TCPTC was calculated as 61.2 for 100°C. As the set temperature increased, the energy efficiency increased as well. The highest exergy efficiency was calculated as 63 for 70°C. However, as the set temperature increased, the exergy efficiency did not increase. 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source Elsevier ScienceDirect Journals
subjects Accumulators
Applied sciences
Collectors
Computational efficiency
Computing time
Energy
Energy management
Equipments, installations and applications
Exact sciences and technology
Exergy
Mathematical analysis
Natural energy
PTC
Solar energy
Solar thermal conversion
Solar water heater
Temperature control
Water temperature
title Thermodynamic analysis of a new design of temperature controlled parabolic trough collector
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