Your search keyword '"K. Vasilakopoulou"' showing total 4 results

1. Minimizing the energy consumption of low income multiple housing using a holistic approach

Author

G.-E. Kyriakodis, V. Lontorfos, R. F. De Masi, Theoni Karlessi, K. Vasilakopoulou, Mattheos Santamouris, Afroditi Synnefa, and Elena Mastrapostoli

Subjects

Low income, Engineering, business.industry, Public housing, 020209 energy, Mechanical Engineering, 0211 other engineering and technologies, Environmental engineering, 02 engineering and technology, Building and Construction, Energy consumption, Environmental economics, Building simulation, Renewable energy, 021105 building & construction, 0202 electrical engineering, electronic engineering, information engineering, Carbon footprint, Electrical and Electronic Engineering, business, Environmental quality, Civil and Structural Engineering, Efficient energy use

Abstract

The present paper describes a holistic energy efficient retrofit of low income multiple social housing located in Athens, Greece. A holistic analysis was conducted in order to determine the optimum retrofit plan that includes innovative and state of the art commercially available technologies, passive techniques as well as renewable energy sources, aiming to reduce its energy consumption and carbon footprint, improve indoor environmental conditions and be cost effective at the same time. An extensive experimental campaign including air leakage measurements, thermal imaging, energy consumption and indoor environmental quality measurements was conducted before and after the implementation of the retrofit. In addition, advanced building simulation, occupant surveys and socioeconomic analyses were performed in order to evaluate the impact of the retrofit and estimate specific performance indicators.

Published

2017

2. The Impact of Several Construction Elements on the Thermal Performance of Solar Chimneys

Author

K. Vasilakopoulou, K. Pavlou, and M. Santamouris

Subjects

Engineering, Solar chimney, business.industry, Thermal resistance, Natural ventilation, Building and Construction, Structural engineering, Sizing, Glazing, Control and Systems Engineering, Thermal mass, Chimney, Passive solar building design, Electrical and Electronic Engineering, business, Civil and Structural Engineering

Abstract

Solar chimneys may provide enough ventilation to buildings when properly designed. Although many design tools, theoretical models and experimental studies have been reported, the impact of many design parameters such as the construction thickness, the thermal resistance of the walls, the absorptivity of the internal surfaces of the chimney, the thermal mass of the chimney and the type of glazing, is not well known. This paper aims to provide information on the optimum sizing of the above parameters. Dynamic simulations and sensitivity analysis have been carried out and specific information on the impact of each parameter is given.

Published

2009

3. Design, construction and monitoring of a near-zero energy laboratory building in Cyprus

Author

M. Fintikaki, N. Fintikakis, Nestor Fylaktos, K. Vasilakopoulou, G. Kalouris, M. A. Lange, C. Pavlou, Mattheos Santamouris, Dionysia Kolokotsa, Costas N. Papanicolas, K. Tsirbas, and Alaric Montenon

Subjects

Engineering, Zero-energy building, Passive cooling, business.industry, Building and Construction, Energy consumption, 7. Clean energy, Civil engineering, Low-energy house, Energy conservation, Solar air conditioning, 13. Climate action, Passive solar building design, business, Efficient energy use

Abstract

The paper presents the architectural, engineering and energy design of a laboratory building located in Cyprus. The building is designed to meet near-zero energy consumption criteria using advanced energy conservation measures, smart energy management and solar thermal and photovoltaic systems to cover the remaining energy load. The energy conservation techniques used result in reduced energy consumption of the building by almost 70% compared with a conventional building, while almost 27% of the remaining heating-, cooling- and lighting load is covered by photovoltaics. A concentrating solar thermal system for cooling and heating is being installed to cover the remainder of the load.

4. Development of a web based energy management system for University Campuses: the CAMP-IT platform

Author

Kostas Gobakis, Sotiris Papantoniou, K. Vasilakopoulou, C. Georgatou, Mat Santamouris, Nikolaos Kampelis, Dionysia Kolokotsa, and Kostas Kalaitzakis

Subjects

Engineering, 020209 energy, 02 engineering and technology, computer.software_genre, Prediction of energy loads, Civil engineering, law.invention, law, Internet Protocol, 0202 electrical engineering, electronic engineering, information engineering, Web application, Electrical and Electronic Engineering, Indoor outdoor modelling, Civil and Structural Engineering, business.industry, Mechanical Engineering, Information technology, Building and Construction, Energy management system, IT infrastructure, Energy efficiency, Information technology management, Scalability, Web service, business, Telecommunications, computer, Efficient energy use, University campus

Abstract

Summarization: University campuses can be considered as small towns due to their size, number of users and mixed and complex activities, including numerous actions usually met in urban environments. The energy and environmental impact of universities could be considerably reduced by applying organizational, technological and energy optimization measures. The aim of the present paper is to present an efficient web based energy management system for Campuses which manages in an energy efficient way the Campus buildings and spaces of public use, monitors the energy load and performs energy analysis per building and for the Campus as a whole, as well as it interacts with each building's BEMS and each user through questionnaires, e-mails and forms. The existing Campus IP infrastructure is exploited by using sensor networks, where nodes communicate their information using Web services, allowing direct integration in modern IT systems. To guarantee the system scalability and respect consolidated and diffused standards, the logical/architectural level of the whole Campus Energy Management System is linked with the existing infrastructure based on Internet Protocol (IP). The overall installation is tested via on line questionnaires to the building users showing a significant increase of the occupants' satisfaction. Finally, the energy efficiency achieved by the proposed system is almost 20%. Presented on: Energy and Buildings