Overview and future challenges of nearly zero energy buildings (nZEB) design in Southern Europe

Attia, Shady; Eleftheriou, Polyvios; Xeni, Flouris; Morlot, Rodolphe; Ménézo, Christophe; Kostopoulos, V.; Betsi, M; Kalaitzoglou, Iakovos; Pagliano, Lorenzo; Cellura, Maurizio; Almeida, Manuela; Ferreira, Marco António Pedrosa Santos; Baracu, Tudor; Badescu, Viorel; Crutescu, Ruxandra; Betanzos, Juan María Hidalgo

doi:10.1016/j.enbuild.2017.09.043

Cited by 259 publications

(150 citation statements)

References 40 publications

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“…Indoor air quality and energy saving of existing buildings are often considered as incompatible goals [1,2]. Nonetheless, the introduction of the new regulation on the performance of buildings [3], i.e., the introduction of nearly zero energy buildings (NZEBs) as the new building target [4,5], will force the building sector to handle simultaneously the heat losses and the air quality issues, since ventilation approaches not properly designed will likely not fulfill the limitation on energy need for space heating typical of the NZEBs [6][7][8]. Apart from new constructions, the strategic challenge in view of the reduction of the energy consumption of the building sector is the energy retrofit of the existing buildings [9][10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

The Effect of Ventilation Strategies on Indoor Air Quality and Energy Consumptions in Classrooms

et al. 2019

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Most of the school buildings in Italy are high energy-demanding buildings with no ad-hoc ventilation systems (i.e., naturally-ventilated buildings). Therefore, reducing the heat losses of schools represent the main aspect to be dealt with. Nonetheless, the indoor air quality of the building should be simultaneously considered. Indeed, to date, energy consumptions and air quality are considered as incompatible aspects especially in naturally-ventilated buildings. The aim of the present paper is to evaluate the effect of different ventilation and airing strategies on both indoor air quality and energy consumptions in high energy-demanding naturally-ventilated classrooms. To this purpose, an Italian test-classroom, characterized in terms of air permeability and thermophysical parameters of the envelope, was investigated by means of experimental analyses and simulations through CO2 mass balance equation during the heating season. The air quality was assessed in terms of indoor CO2 concentrations whereas the energy consumptions were evaluated through the asset rating approach. Results clearly report that not adequate indoor CO2 concentrations are measured in the classroom for free-running ventilation scenarios even in low densely populated conditions (2.2 m2 person−1), whereas scheduled airing procedures can reduce the indoor CO2 levels at the cost of higher energy need for ventilation. In particular, when airing periods leading to the air exchange rate required by standards are adopted, the CO2 concentration can decrease to values lower than 1000 ppm, but the ventilation losses increase up to 36% of the overall energy need for space heating of the classroom. On the contrary, when the same air exchange rate is applied through mechanical ventilation systems equipped with heat recovery units, the ventilation energy loss contribution decreases to 5% and the overall energy saving results higher than 30%. Such energy-saving was found even higher for occupancy scenarios characterized by more densely populated conditions of the classroom typically occurring in Italian classrooms.

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Section: Introductionmentioning

confidence: 99%

The Effect of Ventilation Strategies on Indoor Air Quality and Energy Consumptions in Classrooms

et al. 2019

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“…A few years later, a revised text was approved, Directive 2010/31/EU, known as the EPDB Recast [2]. Thus, the regulations on Nearly Zero Energy Buildings, known as NZEBs, were introduced for all new buildings from year 2020 onwards [3]. This text was revised in 2012 and has now become Directive 2012/27/EU [4].…”

Section: Introductionmentioning

confidence: 99%

The Passivhaus Standard in the Spanish Mediterranean: Evaluation of a House’s Thermal Behaviour of Enclosures and Airtightness

et al. 2019

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Few houses have been built in the Spanish Mediterranean in accordance with the Passivhaus (PH) standard. This standard is adapted to the continental climates of Central Europe and thorough studies are necessary to apply this standard in Spain, especially in the summer. High relative air humidity levels in coastal areas and solar radiation levels of west-facing façades require adapted architectural designs, as well as greater control of air renewal and dehumidification. A priori, energy consumptions undergo big variations. In this study, the construction of a single-family house in the Spanish Levante was analysed. All enclosure layers were monitored using sensors of surface temperature, solar radiation, indoor and outdoor air temperature, relative humidity, and air speed. The thermal behaviour of the façade enclosure and air infiltration through the enclosure were examined using the blower door test and impacts on annual energy demand were quantified. Using simulation tools, improvements are proposed, and the results are compared with examples of PH housing in other geographical areas. The annual energy demand of PH housing was 69.19% below the usual value for buildings in the Mediterranean region. Very thick thermal insulation and low values of airtightness could be applied to the envelope, which would work very well in the winter. These technique solutions could provide optimal comfort conditions with a well-designed air conditioning system in summer and low energy consumption.

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“…To achieve these goals of very low or nearly zero energy consumption in the building section, an innovative concept of nearly zero energy buildings (nZEBs) representing high-performance buildings was proposed [9,10]. The nZEB refers to the low energy consumption of buildings by adopting energy-saving technologies or renewable energy measures [11,12]. A great number of studies have been conducted on energy-saving technologies.…”

Section: Introductionmentioning

confidence: 99%

“…The results showed that the building with only high-efficiency PV modules comes closest to reaching a zero energy balance. Wu et al [37] found that ground source heat pump (GSHP) used less energy than the air source heat pump (ASHP) Energies 2019, 12,4734 3 of 31 in 11 out of 15 zones across the United States, particularly in cold climate zones like Chicago through Duluth, where savings ranged from 24.3% to 39.2%.…”

Section: Introductionmentioning

confidence: 99%

A Study on Energy-Saving Technologies Optimization towards Nearly Zero Energy Educational Buildings in Four Major Climatic Regions of China

Zhao

2019

Energies

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An educational building is a kind of public building with a high density of occupants and high energy consumption. Energy-saving technology utilization is an effective measure to achieve high-performance buildings. However, numerous studies are greatly limited to practical application due to their strong regional pertinence and technical simplicity. This paper aims to further optimize various commonly used technologies on the basis of the current national standards, and to individually establish four recommended technology selection systems corresponding to four major climatic regions for realizing nearly zero energy educational buildings (nZEEBs) in China. An educational building was selected as the case study. An evaluation index of energy-saving contribution rate (ECR) was proposed for measuring the energy efficiency of each technology. Thereafter, high energy efficiency technologies were selected and implemented together in the four basic cases representing different climatic regions. The results showed that the total energy-saving rate in severe cold regions increased by 70.74% compared with current national standards, and about 60% of the total energy-saving rate can be improved in cold regions. However, to realize nZEEBs in hot summer and cold winter regions as well as in hot summer and warm winter regions, photovoltaic (PV) technology needs to be further supplemented.

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Overview and future challenges of nearly zero energy buildings (nZEB) design in Southern Europe

Cited by 259 publications

References 40 publications

The Effect of Ventilation Strategies on Indoor Air Quality and Energy Consumptions in Classrooms

The Effect of Ventilation Strategies on Indoor Air Quality and Energy Consumptions in Classrooms

The Passivhaus Standard in the Spanish Mediterranean: Evaluation of a House’s Thermal Behaviour of Enclosures and Airtightness

A Study on Energy-Saving Technologies Optimization towards Nearly Zero Energy Educational Buildings in Four Major Climatic Regions of China

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