Your search keyword '"Rafaela A. Agathokleous"' showing total 12 results

1. A design tool for a parabolic trough collector system for industrial process heat based on dynamic simulation

Author

Rafaela A. Agathokleous, Panayiotis Ktistis, and Soteris A. Kalogirou

Subjects

Environmental Engineering, Payback period, Industrial process heat, Renewable Energy, Sustainability and the Environment, business.industry, Boiler (power generation), TRNSYS, Thermal energy storage, Dynamic simulation, Parabolic trough collector, Parabolic trough, Fuel efficiency, Concrete storage, Engineering and Technology, Environmental science, Steam production, business, Process engineering, Concentrated solar power, Thermal energy

Abstract

The industrial sector is one of the biggest oil consumers in Cyprus, corresponding to 20% of the fuel consumption. A parabolic trough collector (PTC) system seems the best option to produce clean thermal energy at higher temperatures than those that can be achieved from the already widely used flat plate collectors on the island. This paper presents a simulation model built to investigate the performance of the first industrial PTC system in Cyprus, installed at the Cyprus biggest soft drinks factory. The simulation model is built in TRNSYS and is validated using data from the real PTC system installed at the factory. The results show a very good fitting between the operating parameters and the power output of the Solar Field (SF), Concrete Thermal Storage System (CTES), and the Steam Generator (SG). The average percentage relative error of the system's contribution to the process is less than 6.32% for the daily steam production and during a week did not exceed 6.45%. The novelty of this study is the development of a design tool that can be used by potential interested industries to identify the suitable system that fits their needs. All data are provided in the form of graphs and allow anyone to use as input data the thermal energy demand and required steam temperature of the industry to retrieve information about the size of a suitable system which satisfies these requirements depending on each case. The payback period for all cases examined varies from 2 to 6 years, depending on the size of the system.

Published

2022

2. PV roofs as the first step towards 100% RES electricity production for Mediterranean islands: The case of Cyprus

Author

Soteris A. Kalogirou and Rafaela A. Agathokleous

Subjects

Consumption (economics), business.industry, Mechanical Engineering, Photovoltaic system, Fossil fuel, 100% RES, Energy transition, Environmental economics, Energy storage, Renewable energy, Renewable energy systems, Households, Smart grid, Electricity generation, Engineering and Technology, Cyprus Electricity production, business, Domestic

Abstract

The challenge of integration of large scale RES to islands seems infeasible when the islands have isolated energy systems without primary fuel sources, with limited sources of RES and without energy storage systems. Cyprus island is one of these cases, which covers 93% of the energy demand using imported fossil fuels. Building sector is the second biggest energy consumer accounting for 19% of the final energy consumption. A net-metering scheme is introduced recently to promote the installation of small PV systems in buildings. This paper therefore takes the approach of analyzing various scenarios for installation of PV roof systems in existing and future households of Cyprus island until 2050. The goal is to achieve 100% renewable energy production to cover the needs of the households sector. Results show that the electricity demand of the domestic sector can be 100% covered when over 70% of the existing residential stock install 3 kW roof PV system. Even if 50% of the existing residential stock install a 3 kW PV system the required capacity from other applications (eg. PV parks) to make domestic sector 100% renewable is 191 MW, which is feasible. To ensure a smooth transition to 100% renewable energy in all sectors, significant actions should be taken for the development of renewable energy systems, sector coupling, smart grid system planning and storage technologies. The present study examines only the potential of the further use of net-metering scheme in the domestic sector and discusses the barriers to full energy transition as well.

Published

2021

3. Households with Fibre Reinforced Composite BIPV modules in Southern Europe under Net Metering Scheme

Author

E. Mathas, Anastasios Kyritsis, S. Tselepis, Rafaela A. Agathokleous, E. Roman, J. Nikoletatos, and Soteris A. Kalogirou

Subjects

Engineering, Architectural engineering, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Photovoltaic system, Context (language use), 02 engineering and technology, Civil engineering, Net metering, Renewable energy, Photovoltaics, 0202 electrical engineering, electronic engineering, information engineering, Inverter, Building-integrated photovoltaics, business, Building envelope

Abstract

In recent years many Renewable Energy Sources (RES) power plants have been connected to power networks throughout Europe, in order to meet the EU's objectives for sustainable energy supply. As far as RES residential applications are concerned, the grid-connected photovoltaic (PV) systems constitute the most important representative of RES, because PVs can be easily installed even in densely built-up areas. In this context, small residential PV systems utilising Building Integrated PV (BIPV) modules are going to gain ground mainly at newly built or rebuilt building structures. That is because a BIPV module operates as a multi-functional building construction material; it generates energy and serves as part of the building envelope. This paper highlights the energy benefits of residential buildings in Southern Europe with Fibre Reinforced Composite BIPV modules under Net Metering Scheme and proposes suitable grid-connected PV inverter structures in case of BIPV systems with multiple orientation and inclination profiles.

Published

2019

4. Operational experience and behaviour of a parabolic trough collector system with concrete thermal energy storage for process steam generation in Cyprus

Author

Nicolas Ürlings, Ricardo Alexander Chico Caminos, Siddharth Dutta, Spiros Alexopoulos, Christian Jung, J. Sattler, Soteris A. Kalogirou, Cristiano Teixeira Boura, Ulf Herrmann, Vikrama Atti, Victor Ruiz, Rafaela A. Agathokleous, and Panayiotis Ktistis

Subjects

Solar plant, Environmental Engineering, business.industry, HELISOL® XA, silicone oil, Boiler (power generation), Process (computing), Thermal energy storage, Steam generation, Τhermal energy storage, parabolic trough collector system, On demand, Parabolic trough, concrete thermal energy storage, Environmental science, Engineering and Technology, Factory, Process engineering, business

Abstract

As part of the transnational research project EDITOR, a parabolic trough collector system (PTC) with concrete thermal energy storage (C-TES) was installed and commissioned in Limassol, Cyprus. The system is located on the premises of the beverage manufacturer KEAN Soft Drinks Ltd. and its function is to supply process steam for the factory's pasteurisation process [1]. Depending on the factory's seasonally varying capacity for beverage production, the solar system delivers between 5 and 25 % of the total steam demand. In combination with the C-TES, the solar plant can supply process steam on demand before sunrise or after sunset. Furthermore, the C-TES compensates the PTC during the day in fluctuating weather conditions. The parabolic trough collector as well as the control and oil handling unit is designed and manufactured by Protarget AG, Germany. The C-TES is designed and produced by CADE Soluciones de Ingenieria, S.L., Spain. In the focus of this paper is the description of the operational experience with the PTC, C-TES and boiler during the commissioning and operation phase. Additionally, innovative optimisation measures are presented.

Published

2020

5. Exergy analysis of a naturally ventilated Building Integrated Photovoltaic/Thermal (BIPV/T) system

Author

Rafaela A. Agathokleous, Soteris A. Kalogirou, and Sotirios Karellas

Subjects

Exergy, Engineering, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Photovoltaic system, Thermodynamics, Natural ventilation, 02 engineering and technology, Photovoltaics, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Exergy efficiency, Building-integrated photovoltaics, business, Process engineering, Efficient energy use

Abstract

The efficiency of Building Integrated Photovoltaic/Thermal (BIPV/T) systems depends on various parameters such as the location, amount of incident radiation, orientation of the collector surface, slope of the system and the type of ventilation of the air gap between the Photovoltaic (PV) panels and the secondary skin of the building. However, in order to examine the performance of the system, apart from the energy efficiency, the exergy efficiency needs to be estimated as well. There are numerous studies about energy and exergy efficiency of PV systems, however, most of them are based on PV/T systems, water systems and mechanically ventilated air systems. This paper examines theoretically and experimentally the energy and exergy analysis of a naturally ventilated BIPV/T system. Experimental procedure is carried out to record the temperature distribution of a naturally ventilated BIPV/T system. The results from the experimental procedure are used to estimate the energy efficiency and exergy efficiency of the system. It is proved that the energy efficiency of the system varies from a minimum of 26.5% to a maximum of 33.5%, and the exergy efficiency varies from a minimum 13% to a maximum of 16%. It is also observed that the exergy input to the system is much higher than the exergy output of the system.

Published

2018

6. Preliminary assessment of waste heat potential in major European industries

Author

Paul Christodoulides, Giorgos Georgiou, Rafaela A. Agathokleous, Konstantinos M. Tsamos, Lazaros Aresti, Georgios A. Florides, Soteris A. Kalogirou, Savvas A. Tassou, Maria C. Argyrou, Giuseppe Bianchi, and Gregoris Panayiotou

Subjects

Finance, Carnots potential, Engineering, Energy demand, Operations research, business.industry, energy statistics, 020209 energy, 02 engineering and technology, 7. Clean energy, 12. Responsible consumption, Sustainable energy, waste heat potential, Work (electrical), 13. Climate action, Waste heat, 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, media_common.cataloged_instance, Energy statistics, European union, business, media_common

Abstract

Industrial processes are currently responsible for almost 26% of European primary energy consumptions (275 Mtoe/yr). Furthermore, most of the energy sources that drive the industrial sector are fossil fuel based. Every industrial process is characterised by a multitude of waste heat streams at different temperature levels whose recovery would undoubtedly contribute to the enhancement of the sustainability of the industrial sites and their products. Waste heat recovery systems can offer significant energy savings and substantial greenhouse gas emission reductions. For the latter to materialise technological improvements and innovations aimed at improving the energy efficiency of heat recovery equipment and reducing installation costs should take place. This paper outlines the opportunities and the potential for industrial heat recovery in the European Union by identifying and quantifying primary energy consumption in the major industrial sectors and their related waste streams and temperature levels. Through a systematic analysis considering waste heat and Carnot’s potential estimation, detailed results are given for all industrial sectors, temperature ranges and EU countries. The ‘big picture’ is rather promising with regards to the estimated total waste heat potential. The research presented in this paper has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 680599. Aspects of the work are also funded by the Centre for Sustainable Energy Use in Food Chains (CSEF). CSEF is an End Use Energy Demand Centre funded by the Research Councils UK, Grant No: EP/K011820/1.

Published

2017

7. Target for 100% Renewable Energy Systems Use in Cyprus for Electricity Production

Author

Rafaela A. Agathokleous and Soteris A. Kalogirou

Subjects

100% renewable energy, Government, Mains electricity, Natural resource economics, business.industry, Fossil fuel, 100% RES, Cyprus electricity production, Renewable energy systems, Energy efficiency, Electricity generation, Engineering and Technology, Electricity, business, Drawback, Efficient energy use

Abstract

Cyprus covers 93% of the energy demand using fossil fuels which are fully covered from imports. This does not only stand as a barrier to the various European Directives and measures which apply for all EU members, but it is also a drawback for the economy of Cyprus. Around 1000 tons of heavy fuel oil is required every year by the Electricity Authority of Cyprus to cover the energy demand. The household electricity prices including taxes paid in Cyprus are the 7th highest in Europe. From 2009, renewable energy systems have started to be used, but due to the price of the systems they were limited. However, price was not the main problem of the systems to explain why they didn’t expand more. Many other parameters are still affecting the use of RES in Cyprus; the public acceptance, the education of people, the environmental consciousness, but the most important is the motivation and ease of the applications and licensing from the government parties. Here in this study, an overview of the current energy situation is discussed and suggestions to increase the use of RES are mentioned as well. These include the use of electricity production RES for the domestic needs and measures for the improvement of energy efficiency of the building sector in general, which is the second biggest energy consumer in Cyprus after the commercial sector.

Published

2020

8. Double skin facades (DSF) and building integrated photovoltaics (BIPV): A review of configurations and heat transfer characteristics

Author

Soteris A. Kalogirou and Rafaela A. Agathokleous

Subjects

Solar façades, Engineering, Convective heat transfer, Renewable Energy, Sustainability and the Environment, business.industry, Mechanical Engineering, 020209 energy, Airflow, Photovoltaic system, BIPV, Mechanical engineering, Natural ventilation, PV, 02 engineering and technology, Renewable energy system, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Engineering and Technology, DSSF, BIPV/T, DSVF, Building-integrated photovoltaics, business

Abstract

This article presents the state of the knowledge on the thermal analysis of double skin facades with integrated photovoltaic (PV) panels called the Building Integrated Photovoltaics (BIPV) in terms of the published studies carried out on these systems. The idea of integration of the PV panels by replacing building elements, increase the prospects of the renewable energy systems. Taking also into account the need to use more renewable energy systems in buildings, the investigation of the BIPV systems to improve their performance is of a great importance. The literature studies are separated into experimental and theoretical for naturally ventilated systems and mechanically ventilated with external means e.g. fan use. It is concluded that most researchers studied the systems with mechanical ventilation rather than the systems with natural ventilation because the latter are more complex in terms of the air flow behaviour in the air duct. Additionally, various researchers proposed Nu number correlations and convective heat transfer correlation under several assumptions and conditions every time, for different range or Ra number which are presented and compared in this paper.

Published

2016

9. Experimental performance of a parabolic trough collector system for an industrial process heat application

Author

Soteris A. Kalogirou, Panayiotis Ktistis, and Rafaela A. Agathokleous

Subjects

Environmental Engineering, 020209 energy, 02 engineering and technology, Thermal energy storage, Industrial and Manufacturing Engineering, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Parabolic trough, Concrete storage, Steam production, 0204 chemical engineering, Electrical and Electronic Engineering, Dispatchable generation, Process engineering, Civil and Structural Engineering, business.industry, Mechanical Engineering, Boiler (power generation), Building and Construction, Pollution, PTC, General Energy, Fuel efficiency, Engineering and Technology, Environmental science, Solar collector, business

Abstract

The authors regret to realise a typing mistake on page 3, line 9. The number of 280 kWth should be 280 kWhth. Additionally, there is a problem in Fig. 5. The correct figure and the correct legend of the figure are as shown below: [Figure presented] Fig. 5. (a) Steam generator (b) feed water tanks (c) variable speed pump (d) control valves. The authors would like to apologise for any inconvenience caused. Manufacturing is responsible for 60% of the fuel consumption in Cyprus and the industrial sector is the second biggest fuel consumer, mainly for steam production. Thus, the use of parabolic trough collector (PTC) systems for the production of steam or hot water can be a promising solution for the industrial sector. This study presents the first industrial PTC system in Cyprus, installed at the biggest soft drinks factory. The system consists of 288 m2 of PTC, a steam generator and concrete thermal energy storage (CTES) in order to keep the system dispatchable. To achieve that, two operation strategies are developed which are controlled automatically by the main processor of the system. The first strategy is enabled when there is a steam demand and the second when the energy can be stored directly to the CTES. Both strategies are tested, and it is shown that under Strategy 1 the PTC system can produce 940 litters of steam per day, and under Strategy 2 it can store 107.3 kWhth. In two months period tests, it is proved that it can supply the required amount of steam to the factory even when solar radiation is low, with the support from the CTES.

Published

2021

10. Waste Heat Recovery in the EU industry and proposed new technologies

Author

Paul Christodoulides, Soteris A. Kalogirou, Giorgos Georgiou, Lazaros Arestia, Giuseppe Bianchi, Gregoris Panayiotou, Georgios A. Florides, Savvas A. Tassou, Rafaela A. Agathokleous, Hussam Jouhara, and Maria C. Argyrou

Subjects

waste heat recovery, Energy recovery, Horizon (archaeology), Emerging technologies, Energy management, 020209 energy, heat pipe, Trilateral Flash Cycle, 02 engineering and technology, Environmental economics, 7. Clean energy, Engineering and Physical Sciences, supercritical CO2, 12. Responsible consumption, Sustainable energy, Waste heat recovery unit, 020401 chemical engineering, 13. Climate action, 0202 electrical engineering, electronic engineering, information engineering, media_common.cataloged_instance, Business, 0204 chemical engineering, European union, media_common

Abstract

In the European Union (EU), industrial sectors use 26% of the primary energy consumption and are characterized by large amounts of energy losses in the form of waste heat at different temperature levels. Their recovery is a challenge but also an opportunity for science and business. In this study, after a brief description of the conventional Waste Heat Recovery (WHR) approaches, the novel technologies under development within the I-ThERM Horizon 2020 project are presented and assessed from an energy and market perspectives. These technologies are: heat to power conversion systems based on bottoming thermodynamic cycles (Trilateral Flash Cycle for low grade waste heat and Joule-Brayton cycle working with supercritical carbon dioxide for high temperature waste heat sources); heat recovery devices based on heat pipes (flat heat pipe for high grade radiative heat sources and condensing economizer for acidic effluents). European Union’s Horizon 2020 research and innovation programme, the Centre for Sustainable Energy Use in Food Chains (CSEF) and the Engineering and Physical Sciences Research Council (EPSRC) funded project ‘Optimising Energy Management in Industry-OPTEMIN’

Published

2019

11. Development and validation of a new TRNSYS Type for thermosiphon flat-plate solar thermal collectors: energy and economic optimization for hot water production in different climates

Author

Adolfo Palombo, Cesare Forzano, Soteris A. Kalogirou, Giovanni Barone, Rafaela A. Agathokleous, Annamaria Buonomano, Kalogirou, S. A., Agathokleous, R., Barone, G., Buonomano, A., Forzano, C., and Palombo, A.

Subjects

Experimental validation, 060102 archaeology, Primary energy, Renewable Energy, Sustainability and the Environment, business.industry, Dynamic energy performance analysi, 020209 energy, Design of experiments, DoE analysi, 06 humanities and the arts, 02 engineering and technology, TRNSYS, Volume (thermodynamics), Economic assessment, Thermal insulation, Building solar thermal system, Storage tank, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0601 history and archaeology, Thermosiphon, business, Marine engineering

Abstract

This paper presents a new TRNSYS Type (called Type 99) which can be used for the energy assessment of thermosiphon Flat-Plate solar thermal Collectors (FPCs) for water heating. The accuracy of this new type is higher than the standard type (Type 45a) available in TRNSYS library, since the density and specific heat of water are estimated according to the operating fluid temperature. The results of a suitable experimental campaign are also presented for different commercial FPCs system layouts. The developed Type 99 is successfully validated, proven by the very good agreement achieved between the simulation and experimental results. By the new Type 99 a suitable Design of Experiment (DoE) analysis is carried out with the aim to assess the design and operating parameters mostly affecting the energy and economic performance of two types of FPCs. Specifically, collector pipe diameters, slope, storage tank volume, and thermal insulation thickness are investigated. The analysis is carried out for three case studies which refer to residential Domestic Hot Water (DHW) production applications and to three different European weather zones (Freiburg, Naples and Larnaca). For these case studies an optimization procedure is also carried out by varying the same design and operating parameters for two different objective functions: best energy behaviour [maximum Primary Energy Saving (PES)] and best economic performance [minimum Simple Pay Back (SPB)]. Interesting novel design criteria and encouraging economic results are obtained.

Published

2019

12. Status, barriers and perspectives of building integrated photovoltaic systems

Author

Soteris A. Kalogirou and Rafaela A. Agathokleous

Subjects

Architectural engineering, Environmental Engineering, Building integration, Computer science, 020209 energy, PV, 02 engineering and technology, Industrial and Manufacturing Engineering, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Electrical and Electronic Engineering, Feed-in tariff, Civil and Structural Engineering, business.industry, Mechanical Engineering, Photovoltaic system, BIPV, Subsidy, Building and Construction, Energy consumption, Pollution, Renewable energy, General Energy, Electricity generation, Engineering and Technology, BIPV/T, Building-integrated photovoltaics, business, Electrical efficiency, Barriers, Perspectives

Abstract

Many countries apply measures for the limitation of the conventional energy technologies and try to expand the use of renewables. As the building sector accounts for almost 40% of the energy consumption in Europe, building integrated photovoltaic (BIPV) systems gain peoples’ interest lately concerning the replacement of the conventional construction materials of the buildings envelope with photovoltaic (PV) panels which can serve at the same time as construction material and energy producer. The aim of this study is to present an overview of the available published research on the BIPV systems and identify the barriers and risks associated with the application of BIPV and discuss the future perspectives and solutions through recommendations for future research and development. The most important barriers of the BIPV systems are the feed in tariff implementation, the public acceptance, the governmental economic support in terms of subsidies and technical aspects like the power losses and the architectural considerations. The future perspectives of the BIPV systems proposed are based on the barriers discussed. It is stated that new solutions in the PV industry are many and various and there is room for improvement regarding design, configuration, ventilation, positioning, guidelines, monitoring and performance prediction. In total, more than 100 articles have been identified and analysed since 2000. Many of these articles have a predominant focus on the investigation of the performance of the system, and the ventilation of the PV panels in BIPV applications for electricity production, due to the negative role of the temperature on PVs electrical efficiency, and the heat transfer behavior of the system. This paper shows that although research in the adoption of BIPV systems in terms of their performance and optimization is fairly new, it has gained attention in the last decades. However, their practical applications have been slow in comparison with the conventional rack-mounted PV panels.

Published

2020