Analysis of a Residential Photovoltaic-Thermal (PVT) System in Two Similar Climate Conditions

Barbu, Madalina; Darie, George; Siroux, Monica

doi:10.3390/en12193595

Cited by 33 publications

(18 citation statements)

References 16 publications

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“…This is relevant in the context of European Member States, which are obliged to meet 2030 energy efficiency targets-expressed in terms of national primary energy use. Moreover, it is also relevant in future academic research, given the fact that the "alternative" PEF calculation methodology (with respect to hydro, wind and solar) is typically left unconsidered in previous studies (e.g., [20,38,45,52])-even though this methodological choice could have a significant impact on the results of primary energy calculations.…”

Section: Impact Of Pef Calculation Methodology With Respect To Hydro Wind and Solarmentioning

confidence: 99%

“…In terms of temporal resolutions, many recent studies still use yearly conversion factors [8,[20][21][22][23], even though it has been widely recognized elsewhere that it is often better to use monthly or even hourly conversion factors [24][25][26][27][28][29]. By using higher resolutions, temporal changes in the electricity mix are better taken into account.…”

Section: Introductionmentioning

confidence: 99%

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CO2 Intensities and Primary Energy Factors in the Future European Electricity System

Hamels

2021

Energies

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The European Union strives for sharp reductions in both CO2 emissions as well as primary energy use. Electricity consuming technologies are becoming increasingly important in this context, due to the ongoing electrification of transport and heating services. To correctly evaluate these technologies, conversion factors are needed—namely CO2 intensities and primary energy factors (PEFs). However, this evaluation is hindered by the unavailability of a high-quality database of conversion factor values. Ideally, such a database has a broad geographical scope, a high temporal resolution and considers cross-country exchanges of electricity as well as future evolutions in the electricity mix. In this paper, a state-of-the-art unit commitment economic dispatch model of the European electricity system is developed and a flow-tracing technique is innovatively applied to future scenarios (2025–2040)—to generate such a database and make it publicly available. Important dynamics are revealed, including an overall decrease in conversion factor values as well as considerable temporal variability at both the seasonal and hourly level. Furthermore, the importance of taking into account imports and carefully considering the calculation methodology for PEFs are both confirmed. Future estimates of the CO2 emissions and primary energy use associated with individual electrical loads can be meaningfully improved by taking into account these dynamics.

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Section: Impact Of Pef Calculation Methodology With Respect To Hydro Wind and Solarmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

CO2 Intensities and Primary Energy Factors in the Future European Electricity System

Hamels

2021

Energies

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“…The software package TRNSYS is often used for analysing the PVT systems in residential settings since the readily available components can be used to design a model that can generate results consistent with the experimental data as shown in [70]. Barbu et al [71] looked at the potential of a simple PVT system using TRNSYS for a small residential setup at two different locations with similar climates in France and Romania, respectively. The proposed system was able to meet the household demands of 58% in Romania and 48% in France with the help of a battery.…”

Section: Water-based Pvt Systemsmentioning

confidence: 99%

A Review of Photovoltaic Thermal (PVT) Technology for Residential Applications: Performance Indicators, Progress, and Opportunities

et al. 2021

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Solar energy has been one of the accessible and affordable renewable energy technologies for the last few decades. Photovoltaics and solar thermal collectors are mature technologies to harness solar energy. However, the efficiency of photovoltaics decays at increased operating temperatures, and solar thermal collectors suffer from low exergy. Furthermore, along with several financial, structural, technical and socio-cultural barriers, the limited shadow-free space on building rooftops has significantly affected the adoption of solar energy. Thus, Photovoltaic Thermal (PVT) collectors that combine the advantages of photovoltaic cells and solar thermal collector into a single system have been developed. This study gives an extensive review of different PVT systems for residential applications, their performance indicators, progress, limitations and research opportunities. The literature review indicated that PVT systems used air, water, bi-fluids, nanofluids, refrigerants and phase-change material as the cooling medium and are sometimes integrated with heat pumps and seasonal energy storage. The overall efficiency of a PVT system reached up to 81% depending upon the system design and environmental conditions, and there is generally a trade-off between thermal and electrical efficiency. The review also highlights future research prospects in areas such as materials for PVT collector design, long-term reliability experiments, multi-objective design optimisation, techno-exergo-economics and photovoltaic recycling.

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“…In order to estimate the DHW demand, a realistic daily time dependent simulation was performed using the DHWcalc software [32] developed for the IEA-SHC Task 26, which can generate realistic DHW profiles for European countries in several time steps. This software has been successfully used and validated in previous literature [33].…”

Section: Domestic Hot Water Demandmentioning

confidence: 99%

Residential Sector Energy Demand Estimation for a Single-family Dwelling: Dynamic Simulation and Energy Analysis

Gesteira¹,

Uche²,

Rodrigues³

2021

J. sustain. dev. energy water environ. syst.

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Detailed demand profiles for the residential sector are an important prerequisite for the improvement of building energy efficiency and the development of polygeneration systems. Therefore, the aim of this paper is to provide a generic pattern for each energy demand required for a single-family dwelling. The data of electricity, domestic hot water and freshwater were obtained through literature reported methods of demand profile estimation, whereas heating and cooling have been estimated by TRNSYS software simulation. All methods provide energy consumption profiles with 1-hour time step along 1-year period. Daily, weekly and yearly results are presented. The total dwelling consumption amounts to 3,866 kWh/y of electricity, 941 kWh/y of heating, 1,450 kWh/y of cooling, 41 m 3 /y or 2,090 kWh/y of domestic hot water and 110 m 3 /y of freshwater. Primary energy saving can achieve up to 13,917 kWh/y in case of renewable energy use and a higher comfort level is felt by the users during summer.

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Analysis of a Residential Photovoltaic-Thermal (PVT) System in Two Similar Climate Conditions

Cited by 33 publications

References 16 publications

CO2 Intensities and Primary Energy Factors in the Future European Electricity System

CO2 Intensities and Primary Energy Factors in the Future European Electricity System

A Review of Photovoltaic Thermal (PVT) Technology for Residential Applications: Performance Indicators, Progress, and Opportunities

Residential Sector Energy Demand Estimation for a Single-family Dwelling: Dynamic Simulation and Energy Analysis

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