WoS İndeksli Yayınlar Koleksiyonu

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Citation - WoS: 38
Citation - Scopus: 40
A comparative study on conventional and advanced exergetic analyses of geothermal district heating systems based on actual operational data
(Elsevier Science SA, 2013) A. Hepbasli; Ali Keçebaş; Hepbasli, Arif; Kecebas, Ali
This paper comparatively evaluates exergy destructions of a geothermal district heating system (GDHS) using both conventional and advanced exergetic analysis methods to identify the potential for improvement and the interactions among the components. As a real case study the Afyon GDHS in Afyonkarahisar Turkey is considered based on actual operational data. For the first time advanced exergetic analysis is applied to the GDHSs in which the exergy destruction rate within each component is split into unavoidable/avoidable and endogenous/exogenous parts. The results indicate that the interconnections among all the components are not very strong. Thus one should focus on how to reduce the internal inefficiency (destruction) rates of the components. The highest priority for improvement in the advanced exergetic analysis is in the re-injection pump (PM-IX) while it is the heat exchanger (HEX-III) in the conventional analysis. In addition there is a substantial influence on the overall system as the total avoidable exergy destruction rate of the heat exchanger (HEX-V) has the highest value. On the overall system basis the value for the conventional exergetic efficiency is determined to be 29.29% while that for the modified exergetic efficiency is calculated to be 34.46% through improving the overall components. © 2013 Elsevier B.V. © 2013 Elsevier B.V. All rights reserved.
Citation - WoS: 12
Citation - Scopus: 13
A comparative study on estimating the landfill gas potential: Modeling and analysis
(Taylor and Francis Inc. 325 Chestnut St Suite 800 Philadelphia PA 19106, 2016) Ali Kemal Çakir; Huseyin Gunerhan; A. Hepbasli; Hepbasli, A.; Gunerhan, H.; Cakir, A. K.
The main objective of this study is to investigate the use of the landfill gas as potential energy and electricity obtained from the municipal solid waste (domestic industrial medical waste and sewage sludge) stored regularly in the Harmandali solid waste landfill area within the boundaries of the contiguous area of Izmir. The most important factor in making a decision about energy potential in the landfill is the amount of methane in the landfill gas. There are several approaches that have been used to determine the amount of the landfill gas. In this study three different methods and one approach in the literature were used for this purpose. The methods used are the Multi-Phase the LandGEM and the IPCC 2006. The results of the landfill gas obtained using the three methods namely the Multi-Phase the LandGEM (k = 0.35 k = 0.1 and k = 0.05) and the IPCC 2006 were as follows respectively: 291897215 792073359 769734749 681685027 and 491752247 m3. It may be concluded that the Harmandali Landfill has high landfill gas potential based on the measurements and mathematical methods used in the Harmandali landfill. © 2017 Elsevier B.V. All rights reserved.
A comparative study on estimating the landfill gas potential: Modeling and analysis
(TAYLOR & FRANCIS INC, 2016) A. K. Cakir; H. Gunerhan; A. Hepbasli
The main objective of this study is to investigate the use of the landfill gas as potential energy and electricity obtained from the municipal solid waste (domestic industrial medical waste and sewage sludge) stored regularly in the Harmandali solid waste landfill area within the boundaries of the contiguous area of Izmir. The most important factor in making a decision about energy potential in the landfill is the amount of methane in the landfill gas. There are several approaches that have been used to determine the amount of the landfill gas. In this study three different methods and one approach in the literature were used for this purpose. The methods used are the Multi-Phase the LandGEM and the IPCC 2006. The results of the landfill gas obtained using the three methods namely the Multi-Phase the LandGEM (k = 0.35 k = 0.1 and k = 0.05) and the IPCC 2006 were as follows respectively: 291897215 792073359 769734749 681685027 and 491752247 m(3). It may be concluded that the Harmandali Landfill has high landfill gas potential based on the measurements and mathematical methods used in the Harmandali landfill.
Citation - WoS: 347
Citation - Scopus: 419
A key review of building integrated photovoltaic (BIPV) systems
(Elsevier B.V., 2017) Emrah Biyik; Mustafa Araz; A. Hepbasli; Mehdi Shahrestani; Runming Yao; Li Shao; Emmanuel A. Essah; Armando Coelho Oliveira; Teodosio del Caño; Elena Rico; Shahrestani, Mehdi; Hepbasli, Arif; Biyik, Emrah; Yao, Runming; Shao, Li; Araz, Mustafa; Atli, Yusuf Baver
Renewable and sustainable energy generation technologies have been in the forefront due to concerns related to environment energy independence and high fossil fuel costs. As part of the EU's 2020 targets it is aimed to reach a 20% share of renewable energy sources in final energy consumption by 2020 according to EU's renewable energy directive. Within this context national renewable energy targets were set for each EU country ranging between 10% (for Malta) and 49% (for Sweden). A large share of renewable energy research has been devoted to photovoltaic systems which harness the solar energy to generate electrical power. As an application of the PV technology building integrated photovoltaic (BIPV) systems have attracted an increasing interest in the past decade and have been shown as a feasible renewable power generation technology to help buildings partially meet their load. In addition to BIPV building integrated photovoltaic/thermal systems (BIPV/T) provide a very good potential for integration into the building to supply both electrical and thermal loads. In this study we comprehensively reviewed the BIPV and BIPVT applications in terms of energy generation amount nominal power efficiency type and performance assessment approaches. The two fundamental research areas in the BIPV and BIPVT systems are observed to be i) improvements on system efficiency by ventilation hence obtaining a higher yield with lowering the panel temperature ii) new thin film technologies that are well suited for building integration. Several approaches to achieve these objectives are reported in the literature as presented in this paper. It is expected that this comprehensive review will be beneficial to researchers and practitioners involved or interested in the design analysis simulation and performance evaluation financial development and incentives new methods and trends of BIPV systems. © 2018 Elsevier B.V. All rights reserved.
Citation - WoS: 168
Citation - Scopus: 211
A key review of wastewater source heat pump (WWSHP) systems
(Elsevier Ltd, 2014) A. Hepbasli; Emrah Biyik; Orhan Ekren; Huseyin Gunerhan; Mustafa Araz; Ekren, Orhan; Araz, Mustafa; Hepbasli, Arif; Gunerhan, Huseyin; Biyik, Emrah
Heat pumps (HPs) are part of the environmentally friendly technologies using renewable energy and have been utilized in the developed countries for years. Wastewater is seen as a renewable heat source for HPs. At the beginning of the 1980s waste (sewage) water source heat pumps (WWSHPs) were widely applied in North European countries like Sweden and Norway and partially applied in China. In the past two decades the WWSHP has become increasingly popular due to its advantages of relatively higher energy utilization efficiency and environmental protection. The present study comprehensively reviews WWSHP systems in terms of applications and performance assessments including energetic exergetic environmental and economic aspects for the first time to the best of the authors' knowledge. In this context a historical development of WWSHPs was briefly given first. Next wastewater potential and its characteristics were presented while a WWSHP system was introduced. The previously conducted studies on WWSHPs were then reviewed and classified in a tabulated form. Finally some concluding remarks were listed. The COP values of the reviewed studies ranged from 1.77 to 10.63 for heating and 2.23 to 5.35 for cooling based on the experimental and simulated values. The performance assessments are mostly made using energy analysis methods while the number of exergetic evaluations is very low and has not been comprehensively performed. It is expected that the comprehensive review here will be very beneficial to those dealing with the design analysis simulation and performance assessment of WWSHP systems. © 2017 Elsevier B.V. All rights reserved.
Citation - WoS: 58
Citation - Scopus: 63
A method of strategic evaluation of energy performance of Building Integrated Photovoltaic in the urban context
(ELSEVIER SCI LTD, 2018) V. Costanzo; R. Yao; E. Essah; L. Shao; M. Shahrestani; A. C. Oliveira; M. Araz; A. Hepbasli; E. Biyik; Essah, E.; Shahrestani, M.; Yao, R.; Biyik, E.; Shao, L.; Costanzo, V.; Oliveira, A. C.
This paper presents an integrated bottom-up approach aimed at helping those dealing with strategical analysis of installation of Building Integrated Photo Voltaic (BIPV) to estimate the electricity production potential along with the energy needs of urban buildings at the district scale. On the demand side hourly energy profiles are generated using dynamic building simulation taking into account actual urban morphologies. On the supply side electricity generated from the system is predicted considering both the direct and indirect components of solar radiation as well as local climate variables. Python-based Algorithm editor Grasshopper is used to interlink four types of modelling and simulation tools as 1) generation of 3-D model 2) solar radiation analysis 3) formatting weather files (TMY data set) and 4) dynamic energy demand. The method has been demonstrated for a cluster of 20 buildings located in the Yasar University in Izmir (Turkey) for which it is found the BIPV system could achieve an annual renewable share of 23% in line with the Renewable Energy Directive target of 20%. Quantitatively compared demand and supply information at hourly time step shows that only some energy needs can be met by BIPV so there is a need for an appropriate matching strategy to better exploit the renewable energy potential. (C) 2018 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license.
Citation - WoS: 27
Citation - Scopus: 27
A new approach to determine the outdoor temperature distributions for building energy calculations
(Pergamon-Elsevier Science Ltd, 2014) Can Coskun; Mustafa Ali E. Ertürk; Zuhal Oktay; A. Hepbasli; Oktay, Zuhal; Ertürk, Mustafa; Coskun, Can; Hepbasli, Arif
This study formulated annual monthly and hourly ambient temperature distributions for simplifying the calculation of cooling and heating degree-hours. In this regard Turkey was selected as an application country of which 79 cities were considered for modeling purposes. The temperature data over a period of 42 years were also utilized in the analysis. Similar outdoor distributions were categorized in the same group. The analysis results showed eight main annual distribution trends for the cities in Turkey. Such a detailed analysis and categorization for the outdoor temperature has been done for the first time in the literature. The outdoor temperature distributions are very useful tools for determination of heating and cooling loads while they enable the calculation of the annual- monthly- and hourly-based degree-hours values. In this regard a population-based outdoor temperature distribution concept was also introduced to the literature and tested for Turkey. One temperature distribution was achieved for Turkey with reference to population. © 2013 Elsevier Ltd. All rights reserved. © 2013 Elsevier B.V. All rights reserved.
Citation - WoS: 86
Citation - Scopus: 90
A new correlation for predicting the thermal conductivity of nanofluids, using dimensional analysis
(Elsevier Ltd, 2015) S. Hassani; Rahman Saidur; Saad Mekhilef; A. Hepbasli; Mekhilef, Saad; Hassani, Samir; Saidur, R.; Hepbasli, Arif
Abstract Thermal conductivity of nanofluids is a key thermophysical property which depends on concentration and size of nanoparticles temperature and thermophysical properties of the base fluid. Over last decades several works have been done on the thermal conductivity of nanofluids while a number of numerical and theoretical models have been proposed. However most of these models were not able to predict appropriately the thermal conductivity for a variety of nanofluids. In the present paper using the Vaschy-Buckingham theorem new correlations for predicting the thermal conductivity of nanofluids were developed based on the existing experimental data. The new correlation proposed took into account the Brownian motion the variation of volume fraction the temperature and the size distribution of nanoparticles. The expression developed successfully predicts the thermal conductivity of a variety of nanofluids TiO2 Al2O3 Al Cu Fe MWCNTs/EG Al2O3 SiO2/methanol TiO2 Al2O3 CuO MWCNTs/water Al2O3/radiator coolant Al2O3/R141b Al CNTs/Engine Oil and Cu/Therminol 66 and suits the data with a mean and standard deviation of 2.74% 3.63% respectively. The correlation was derived from 196 values of nanofluids thermal conductivity 86% of them are correlated within a mean deviation of ±5% while 98% of them belong to an interval of ±10%. Moreover the proposed correlation has been tested on 284 values of thermal conductivity of different nanofluids and the predicted values have been found in excellent agreement with the experimental ones with a mean deviation of 3%. The mean deviation between the correlated and the tested point found to be 2.94%. The present correlation will be a good tool for engineers in preparing the nanofluid for different applications in heat exchangers and thermal solar collectors. © 2015 Elsevier B.V. All rights reserved.
Citation - WoS: 12
Citation - Scopus: 12
A parametric study on energy exergy and exergoeconomic assessments of a modified auto-cascade refrigeration cycle supported by a dual evaporator refrigerator
(Elsevier Ltd, 2024) Ibrahim Karacayli; Lutfiye Altay; A. Hepbasli; Karacayli, Ibrahim; Hepbasli, Arif; Altay, Lutfiye
This paper presents an evaluation of the energetic exergetic and exergoeconomic performances of a modified auto-cascade refrigeration (MACR) cycle integrated with a dual evaporator refrigerator (DER) to determine optimum operating conditions. DER facilitates a reduction in the compression ratio allowing the low-boiling-point component to release more heat before entering the evaporator. In this study the R170/R290 refrigerant mixture which has a low global warming potential but an explosion risk was used. The main purpose of this study is to eliminate the risk of explosion by reducing the compressor discharge temperature and at the same time to enhance the overall cycle performance. To achieve this DER is used instead of air-cooled coils which have limited cooling performance. Despite an ambient temperature of 35°C the MACR cycle achieved a remarkable 51.29 % reduction in compressor discharge temperature when the separator inlet temperature was reduced to 10°C by the DER. It also results in a 72.73% reduction in compression work rate and a significant 137.02% increase in cooling effect compared to the conventional auto-cascade refrigeration cycle. Furthermore the MACR cycle exhibits notable improvements in total exergy destruction rate and exergy destruction cost rate with a 75.23% and a 76.07% reduction respectively. Simultaneously the exergy efficiency and the exergoeconomic factor increased by 266.67% and 179.15% respectively. The MACR cycle achieves optimum energy and exergy performance with a 60% R170 mass fraction and 0.50 vapor quality resulting in 1.429kW compression work rate a COP of 0.70 and an exergy efficiency of 26.66 %. The optimum exergoeconomic performance is achieved with a 40% R170 mass fraction and 0.50 vapor quality. © 2024 Elsevier B.V. All rights reserved.
Citation - WoS: 3
Citation - Scopus: 3
A REVIEW ON COMPUTATIONAL FLUID DYNAMICS SIMULATION METHODS FOR DIFFERENT CONVECTIVE DRYING APPLICATIONS
(Serbian Society of Heat Transfer Engineers, 2023) Seda Özcan Çoban; Fatih Selimefendigil; Hakan Fehmi Oztop; A. Hepbasli; Coban, Seda Ozcan; Hepbasli, Arif; Oztop, Hakan Fehmi; Selimefendigil, Fatih
This paper focuses on the CFD studies on one of the commonly used drying processes for different applications. First a brief information about drying is given with determining important properties that effect drying characteristics. Next basic principles of CFD modelling are explained while capabilities of computational processing are presented. A detailed literature survey about CFD studies in convective drying process is then conducted. Finally some sound concluding remarks are listed. It may be concluded that the CFD is a powerful and flexible tool that can be adopted to many different physical situations including complex scenarios results of CFD simulations represent good predictions for fluid-flow heat and mass transfer of various drying methods and those numerical studies can be used for validation and controlling of applicability of new drying systems. © 2023 Elsevier B.V. All rights reserved.
Citation - WoS: 28
Citation - Scopus: 29
A sub-system design comparison of renewable energy based multi-generation systems: A key review along with illustrative energetic and exergetic analyses of a geothermal energy based system
(ELSEVIER, 2022) A. Bozgeyik; L. Altay; A. Hepbasli; Hepbasli, A.; Bozgeyik, A.; Altay, L.
In recent years it has gained a significance importance to decrease ecological footprint so to have a positive contribution to environmental quality. Renewable energy plays a significant role in future trends for efficiency and environmental issues. Efficiency of systems is to be increased to meet future demands in terms of sustainability with increased consumption. There is a need for new and innovative research studies on promising technologies processes and strategies to have sustainable water and energy management in cities. This review paper investigates the use of energy sources in single or multiple forms with different system designs from simple to complex structures. The examined studies were presented in a tabulated form including energy and exergy efficiency values as well as the methods and tools used. The results indicated that the systems with the highest energy and exergy efficiency values had several useful outputs such as hydrogen fresh water drying heating and cooling etc. The maximum exergetic efficiency was determined to be 94% for a multiple energy sourced multi-generation system while the maximum energetic efficiency was calculated to be 111.3% for a solar assisted and heat pump integrated multi-generation system amongst the reviewed studies. To illustrate the obtained results from review a geothermal energy based multi-generation system was considered. Some parametric studies were also undertaken to see the effects of geothermal water temperature and flow rates on efficiency values. For a single production case they were determined to be 13.7% and 50% respectively while they were obtained to be 98.6% and 67.7% for a multi-generation system in which electricity low grade hot water production high temperature hot water production and hydrogen were useful outputs. However it should be noted that there was a threshold about the number of products to have an optimum increase in the efficiency values.
Citation - WoS: 7
Citation - Scopus: 6
Achieving ultra-high coefficient of performance in a novel solar-assisted trigeneration system integrating absorption and Rankine cycles
(Elsevier Ltd, 2025) Aslı Tiktaş; A. Hepbasli; Huseyin Gunerhan; Hepbasli, Arif; Gunerhan, Huseyin; Tiktas, Asli
A novel solar-driven trigeneration system was developed and thermodynamically assessed integrating an absorption heat transformer (AHT) a Rankine cycle (RC) and an absorption cooling cycle (ACC) into a unified configuration. The innovation lay not only in the use of an AHT to power the RC—an uncommon integration in itself—but more significantly in the full thermodynamic loop architecture that employed a single working fluid pair (LiBr–H2O) shared by both absorption subsystemswhile also driving a steam-based Rankine subsystem. This tightly coupled single-loop design enabled internal thermal cascading and eliminated the need for separate working fluids auxiliary heating or intermediate heat exchangers— unlike conventional hybrid or cascade systems which (i) rely on multiple working fluid loops for power and cooling (ii) require fossil-fueled auxiliary heaters to drive RCs or (iii) incur high irreversibility losses due to fluid-to-fluid heat exchange between subsystems. Based on the simulation results a net electrical power output of 457.90 kW an overall exergetic efficiency of 74.40 % and a RC energy efficiency of 56.30 % were obtained. The cooling coefficient of performance (COP) reached 7.03 significantly outperforming conventional single-effect absorption systems. The system was fully powered by flat-plate solar collectors (FPSCs) without requiring any fossil-based auxiliary energy. A comprehensive validation was performed using component-level comparisons with experimental studies covering pressure drops internal irreversibility and the influence of working fluid properties on performance metrics. Additionally detailed thermo-economic assessments were carried out. The total investment cost was approximately US$8.54 million with a remarkably short payback period (PP) of 2.56 years and an internal rate of return (IRR) of 24.43 %. Levelized costs of electricity cooling and heating were calculated as US$0.20/kWh US$0.024/kWh and US$0.024/kWh respectively. Comparative analysis against literature benchmarks proven that the proposed system offered superior thermodynamic and economic performance especially in cooling and heating outputs. This study showed a new design paradigm for low-grade renewable energy utilization providing both a scalable solution for high efficiency multigeneration and a practical framework for future sustainable energy systems. © 2025 Elsevier B.V. All rights reserved.
Citation - WoS: 62
Citation - Scopus: 66
Advanced exergoeconomic analysis of an electricity-generating facility that operates with natural gas
(Pergamon-Elsevier Science Ltd, 2014) Emin Açıkkalp; Haydar Aras; A. Hepbasli; Aras, Haydar; Hepbasli, Arif; Açikkalp, Emin
This paper presents an advanced exergy analysis of an electricity generation facility in the Eskisehir Industry Estate Zone in Turkey. The total electricity generation rate is approximately 55 MW. The exergy efficiency of the system is 0.402 and the total exergy destruction rate of the system is 78.242 MW. The unit exergy cost of electrical power that is generated by the system is 25.660 $/GJ and the total exergoeconomic factor of the system is 0.247. Advanced exergetic and exergoeconomic analyses were applied to the considered system. The advanced exergoeconomic analysis shows that the combustion chamber the high-pressure steam turbine and the condenser have great economic improvement potential because of their high exergy destruction cost rates. Similarly the heat recovery steam generator and the condenser have significant potential because of their investment costs. In addition suggestions to improve the system economical parameters are provided. Finally it can be concluded that relations between the components are strong. © 2013 Elsevier Ltd. All rights reserved. © 2013 Elsevier B.V. All rights reserved.
Citation - WoS: 53
Citation - Scopus: 56
Advanced Exergy Analysis of a Heat Pump Drying System Used in Food Drying
(Taylor & Francis Inc, 2013) Zafer Erbay; A. Hepbasli; Hepbasli, Arif; Erbay, Zafer
Exergy analysis has been used as a powerful tool to study and optimize various types of energy systems. However the methodology of splitting the exergy destructions (the so-called advanced exergy analysis) allows for a further understanding of the exergy destruction values to improve the system efficiency. In this study advanced exergy analysis was applied to a pilot-scale heat pump drying system used in food drying for the first time to evaluate its performance at different drying temperatures. The results showed that inefficiencies within the compressor and condenser were mainly due to the internal operating conditions and the efficiencies in the evaporator and heat recovery system could be improved by structural improvements of the whole system and remaining system components. © 2013 Copyright Taylor and Francis Group LLC. © 2013 Elsevier B.V. All rights reserved.
Citation - WoS: 38
Citation - Scopus: 41
Advanced exergy analysis of a trigeneration system with a diesel-gas engine operating in a refrigerator plant building
(Elsevier Ltd, 2014) Emin Açıkkalp; Haydar Aras; A. Hepbasli; Aras, Haydar; Hepbasli, Arif; Açikkalp, Emin
In this paper a trigeneration system is analyzed using an advanced exergy analysis. The trigeneration system is located in the Eskisehir Industry Estate Zone in Turkey. The exergy efficiency of the system was found to be 0.354 while the total exergy destruction rate of the system was 16.695 MW. The purpose of this study is to determine the improvement potential of the system. The exergy destruction within the components of the facility is divided into four parts: endogenous exogenous avoidable and unavoidable exergy destruction. The components of the trigeneration system have strong relationships with each other since the endogenous exergy destruction of the components is smaller than the exogenous exergy destruction. The avoidable exergy destruction rates are generally greater than the unavoidable ones. Thus the trigeneration system possesses a high potential for improvement. This analysis indicates that from a thermodynamic perspective the turbo air compressor is the most important component in the system. Through the advanced exergy analysis information about the relationships among the system components as well as the potential for further improvements may be provided in more detail. © 2014 Elsevier B.V. © 2014 Elsevier B.V. All rights reserved.
Citation - WoS: 85
Citation - Scopus: 100
Advanced exergy analysis of an aircraft gas turbine engine: Splitting exergy destructions into parts
(Elsevier Ltd, 2015) Yasin Şöhret; Emin Açıkkalp; A. Hepbasli; Hikmet Tahir Karakoc; Acikkalp, Emin; Sohret, Yasin; Karakoc, T. Hikmet; Hepbasli, Arif
Advanced exergy analysis of an aircraft gas turbine engine is presented in this paper. In this framework the main exergy parameters of the engine components are introduced while the exergy destruction rates within the engine components are split into endogenous/exogenous and avoidable/unavoidable parts. Also the mutual interdependencies among the components of the engine and realistic improvement potentials depending on operating conditions are acquired through the analysis. As a result of the study the exergy efficiency values of the engine components are determined to be 89% 86% 60.6% and 98.6% of the low pressure compressor the high pressure compressor the combustion chamber and the gas turbine respectively. The system has low improvement potential because the unavoidable exergy destruction rate is 93.55%. The relationships between the components are weak since 81.83% of the exergy destruction is endogenous. Finally it may be concluded that the combustion chamber component of the engine should be focused on according to the results obtained. © 2017 Elsevier B.V. All rights reserved.
Citation - WoS: 15
Citation - Scopus: 18
Advanced life cycle integrated exergoeconomic analysis of building heating systems: An application and proposing new indices
(Elsevier Ltd, 2018) Emin Açıkkalp; A. Hepbasli; Cem Tahsin Yucer; Hikmet Tahir Karakoc; Açıkkalp, Emin; Yucer, Cem Tahsin; Karakoc, T. Hikmet; Hepbasli, Arif
Advanced exergy-based analysis and assessment tools have been considered very useful tools for detecting the interactions among components of energy-conversion systems and the real potential for improving each component in any system. In this study a building heating system is analyzed using advanced life cycle integrated (LCI)exergoeconomic analysis method which combines cost and environmental impacts. Some new indices (metrics) such as advanced exergy destruction ratio advanced LCIexergoeconomic ratio advanced LCIexergoeconomic sustainability index and advanced indices are presented. These metrics are also applied to the main components of the system. The boiler has the maximum LCI endogenous exergy destruction cost ratio while the maximum LCI exogenous destruction ratio is due to the water heater. The advanced LCIexergoeconomic depletion ratios are 0.187 0.599 0.414 and 0.371 for the endogenous exogenous unavoidable and avoidable parts respectively. © 2018 Elsevier B.V. All rights reserved.
An experimental investigation of heat transfer enhancement of a minichannel heat sink using Al2O3-H2O nanofluid
(PERGAMON-ELSEVIER SCIENCE LTD, 2014) M. R. Sohel; S. S. Khaleduzzaman; R. Saidur; A. Hepbasli; M. F. M. Sabri; I. M. Mahbubul
The thermal performances of a minichannel heat sink are experimentally investigated for cooling of electronics using nanofluid coolant instead of pure water. The Al2O3-H2O nanofluid including the volume fraction ranging from 0.10 to 0.25 vol.% was used as a coolant. The effects of different flow rates of the coolant on the overall thermal performances are also investigated. The flow rate was ranged from 0.50 to 1.25 L/min as well as the Reynolds number from 395 to 989. The coolant was passed through a custom made copper minichannel heat sink consisting of the channel height of 0.8 mm and the channel width of 0.5 mm. The experimental results showed the higher improvement of the thermal performances using nanofluid instead of pure distilled water. The heat transfer coefficient was found to be enhanced up to 18% successfully. The nanofluid significantly lowered the heat sink base temperature (about 2.7 degrees C) while it also showed 15.72% less thermal resistance at 0.25 vol.% and higher Reynolds number compared to the distilled water. (C) 2014 Elsevier Ltd. All rights reserved.
Citation - WoS: 173
Citation - Scopus: 206
An experimental investigation of heat transfer enhancement of a minichannel heat sink using Al2O3-H2O nanofluid
(Elsevier Ltd, 2014) M. R. Sohel; S. S. Khaleduzzaman; Rahman Saidur; A. Hepbasli; Mohd Faizul Mohd Sabri; Islam Mohammed Mahbubul; Sabri, M.F.M.; Sohel, M.R.; Khaleduzzaman, S.S.; Mahbubul, I.M.; Hepbasli, A.; Saidur, R.
The thermal performances of a minichannel heat sink are experimentally investigated for cooling of electronics using nanofluid coolant instead of pure water. The Al2O3-H2O nanofluid including the volume fraction ranging from 0.10 to 0.25 vol.% was used as a coolant. The effects of different flow rates of the coolant on the overall thermal performances are also investigated. The flow rate was ranged from 0.50 to 1.25 L/min as well as the Reynolds number from 395 to 989. The coolant was passed through a custom made copper minichannel heat sink consisting of the channel height of 0.8 mm and the channel width of 0.5 mm. The experimental results showed the higher improvement of the thermal performances using nanofluid instead of pure distilled water. The heat transfer coefficient was found to be enhanced up to 18% successfully. The nanofluid significantly lowered the heat sink base temperature (about 2.7 °C) while it also showed 15.72% less thermal resistance at 0.25 vol.% and higher Reynolds number compared to the distilled water. © 2014 Elsevier Ltd. All rights reserved. © 2014 Elsevier B.V. All rights reserved.
An experimental study of solar thermal system with storage for domestic applications
(UNIV MALAYSIA PAHANG, 2018) M. Abid; B. A. A. Yousef; M. E. Assad; A. Hepbasli; K. Saeed
Building sector consumes a greater portion of energy for heating and cooling applications. The utilization of fossil fuels for space and water heating in buildings cause a negative effect on the environment by producing larger CO2. In this study solar thermal water heating system for building application have been analyzed from the first and second law perspectives of thermodynamics considering various scenarios and water consumption pattern. The solar flat collector is very commonly used to extract energy from sunlight. Therefor energy and exergy efficiency curves for the solar flat collector were presented. The energetic and exergetic values for the system were calculated based on the experimental values for the overall system the heat exchanger and the pumps using the approach of exergetic product/fuel basis. The greatest and lowest relative irreversibility's occurred at the solar collector and the heat exchanger with values of 85.73% and 2.45% respectively and the system overall exergy efficiency was determined to be 20.28%. The energy and exergy efficiencies of the solar collector were analyzed at three different cases depending on the mass flow rates in the solar collector and the secondary circuit of the system. Three different mass flow rates were applied to the inlet of the secondary circuit to observe the efficiency effect on the solar collector circuit. This study can assist in selecting a proper solar collector and storage size for buildings of various capacity and possible improvement in the design of the system components.

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