A Building Energy Efficiency Optimization Method by Evaluating the Effective Thermal Zones Occupancy

Pisello, Anna Laura; Bobker, Michael; Cotana, Franco

doi:10.3390/en5125257

Cited by 56 publications

(18 citation statements)

References 32 publications

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“…Based on high order RC networks, several new dynamic simulation models have been developed for analyzing, as an example, the impact on the building energy demand of glazed/opaque surfaces and internal solar radiation [50], the thermal behavior of multi glazing façades [51], the thermo-physical behavior of a Phase Change Material (PCM) layer in combination with transparent and opaque materials [52], the performance of Building Integrated Solar Thermal and Photovoltaic systems (BIST-BIPVT) [53]. New BEPS computer-based models are also required to be flexible and suitable for the calculation of household actions and to effectively account model occupants' behavior [54]. Nevertheless, the available literature remarks a lack of knowledge regarding the availability of studies focused on the energy performance obtained through the building integration and combination of such innovative technologies [55,56].…”

Section: Innovative Capabilities Of Detectmentioning

confidence: 99%

Code-to-Code Validation and Application of a Dynamic Simulation Tool for the Building Energy Performance Analysis

Buonomano

2016

Energies

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Abstract:In this paper details about the results of a code-to-code validation procedure of an in-house developed building simulation model, called DETECt, are reported. The tool was developed for research purposes in order to carry out dynamic building energy performance and parametric analyses by taking into account new building envelope integrated technologies, novel construction materials and innovative energy saving strategies. The reliability and accuracy of DETECt was appropriately tested by means of the standard BESTEST validation procedure. In the paper, details of this validation process are accurately described. A good agreement between the obtained results and all the reference data of the BESTEST qualification cases is achieved. In particular, the obtained results vs. standard BESTEST output are always within the provided ranges of confidence. In addition, several test cases output obtained by DETECt (e.g., dynamic profiles of indoor air and building surfaces temperature and heat fluxes and spatial trends of temperature across walls) are provided.

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Section: Innovative Capabilities Of Detectmentioning

confidence: 99%

Code-to-Code Validation and Application of a Dynamic Simulation Tool for the Building Energy Performance Analysis

Buonomano

2016

Energies

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“…A dynamic simulation was performed for building No.1 using the Energy Plus software package [23,24] in order to obtain hourly profiles ( Figure 2) and to estimate the maximum daily energy requirement. A maximum of 100 kW h for heating and 70 kW h for cooling is found.…”

Section: Heating and Cooling Needs Calculationmentioning

confidence: 99%

Development of Innovative Heating and Cooling Systems Using Renewable Energy Sources for Non-Residential Buildings

et al. 2013

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Industrial and commercial areas are synonymous with high energy consumption, both for heating/cooling and electric power requirements, which are in general associated to a massive use of fossil fuels producing consequent greenhouse gas emissions. Two pilot systems, co-funded by the Italian Ministry for the Environment, have been created to upgrade the heating/cooling systems of two existing buildings on the largest industrial estate in Umbria, Italy. The upgrade was specifically designed to improve the system efficiency and to cover the overall energy which needs with renewable energy resources. In both cases a solar photovoltaic plant provides the required electric power. The first system features a geothermal heat pump with an innovative layout: a heat-storage water tank, buried just below ground level, allows a significant reduction of the geothermal unit size, hence requiring fewer and/or shorter boreholes (up to 60%-70%). In the other system a biomass boiler is coupled with an absorption chiller machine, controlling the indoor air temperature in both summer and winter. In this case, lower electricity consumption, if compared to an electric compression chiller, is obtained. The first results of the monitoring of summer cooling are presented and an evaluation of the performance of the two pilot systems is given.

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“…During the past years, building design to minimize consumption during the use phase has been intensified [4], for that reason special attention to impacts in other phases as a result of the reduction of such consumption must be shown, especially during the production phase [5,6].…”

Section: Introductionmentioning

confidence: 99%

Use of LCA as a Tool for Building Ecodesign. A Case Study of a Low Energy Building in Spain

et al. 2013

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This paper demonstrates how to achieve energy savings in the construction and operation of buildings by promoting the use of life cycle assessment techniques in the design for new buildings and for refurbishment. The paper aims to draw on the application of a specific methodology for low energy consumption, integrated planning, environmental performance evaluation of buildings, and design for sustainability and LCA techniques applied to buildings. The ENergy Saving through promotion of LIfe Cycle assessment in buildings (ENSLIC) methodology based on LCA for use in an integral planning process has been promoted to stakeholders who require a means to optimize the environmental performance of buildings. Feedback from the stakeholders has facilitated the creation of simplified LCA guidelines, a systematic approach guiding the user through the alternative options regarding software choices, their strengths and weaknesses, the databases available, the usefulness of different indicators, aggregation, definition of limits and options for simplifying the process. As a result, this paper presents the applied results of a case study where this methodology is implemented serving as an energy savings evaluation tool for decision makers, end-users, professionals involved in the different stages of construction, etc. Finally, it is demonstrated how LCA can facilitate comparisons between different buildings, showing the influence of all variables on a building's life cycle environmental impact and showing the potential for energy savings. Removing market barriers to sustainable construction is actually stricter and this is good news for promoting higher energy efficiency in buildings.

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A Building Energy Efficiency Optimization Method by Evaluating the Effective Thermal Zones Occupancy

Cited by 56 publications

References 32 publications

Code-to-Code Validation and Application of a Dynamic Simulation Tool for the Building Energy Performance Analysis

Code-to-Code Validation and Application of a Dynamic Simulation Tool for the Building Energy Performance Analysis

Development of Innovative Heating and Cooling Systems Using Renewable Energy Sources for Non-Residential Buildings

Use of LCA as a Tool for Building Ecodesign. A Case Study of a Low Energy Building in Spain

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