A methodology for performance robustness assessment of low-energy buildings using scenario analysis

Kotireddy, Rajesh; Hoes, P Pieter-Jan; Hensen, Jlm Jan

doi:10.1016/j.apenergy.2017.12.066

Cited by 57 publications

(29 citation statements)

References 46 publications

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“…This could be achieved by the adoption of future scenarios considering projected weather files (Drury B. Crawley, 2008;Taylor et al, 2014) and robust designs buildings alternatives (Kotireddy et al, 2018). These considerations may contribute to avoid the adoption of obsolete energy efficiency policies, which is a common challenge in many countries nowadays (Jenkins et al, 2013;Visscher et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

Validation of the climatic zoning defined by ASHRAE standard 169-2013

2019

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Climatic zoning has a direct impact on building energy efficiency policies. Currently, most countries adopt simplified weather parameters to define their climatic zoning, with the degree-days method being the most widely used. This widespread use of degree-days has been substantially influenced by the adoption of this indicator by ASHRAE on its climatic zoning, which is a core element for the prescription of requirements for buildings based on their location. However, there is no scientific evidence regarding the agreement between building energy performance and the ASHRAE climatic zones. The objective here was to quantify the mismatch between buildings' energy performance in each given location and the expected energy performance in the climatic zone they are placed. The study uses a performance-based assessment method relying on building energy simulation and GIS. Climatic zoning performance indicators were calculated based on the energy demand of 52 archetype buildings of the U.S. building stock complying with the ASHRAE Standard 90.1-2013. EnergyPlusV8.3 and ArcGIS were used in the process. Results suggest that the stipulated climatic zone misclassifies 10% of the area evaluated, potentially misclassifying highly populated urban areas. These misclassifications have direct impact on the building energy efficiency policies of a given location, which may not be the most adequate for its climate.

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Section: Discussionmentioning

confidence: 99%

Validation of the climatic zoning defined by ASHRAE standard 169-2013

2019

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“…In this case, the original building design configuration was considered as a baseline. Then parametric simulations were run using the Design of Experiments (DOE) methodology [58], similarly to other research studies on the variability in building performance simulation [15,16,59]. Variations and multiple runs are meant to reproduce the actual variability of the performance of envelope components, air-change rates and of occupants' behaviour and comfort preferences.…”

Section: Methodsmentioning

confidence: 99%

“…), as specified in detail in Section 3.1. The parametric approach aims at detecting critical assumptions in the preliminary design stage, to guarantee a more robust evaluation of performance [15,23]. In simpler terms, the objective of the parametric simulation is to include from the very beginning more realistic, and possibly less optimistic, assumptions, and use the simulation outcomes as boundaries for comparative performance analysis during the operation phase.…”

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confidence: 99%

Parametric Performance Analysis and Energy Model Calibration Workflow Integration—A Scalable Approach for Buildings

Manfren

Nastasi

2020

Energies

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High efficiency paradigms and rigorous normative standards for new and existing buildings are fundamental components of sustainability and energy transitions strategies today. However, optimistic assumptions and simplifications are often considered in the design phase and, even when detailed simulation tools are used, the validation of simulation results remains an issue. Further, empirical evidences indicate that the gap between predicted and measured performance can be quite large owing to different types of errors made in the building life cycle phases. Consequently, the discrepancy between a priori performance assessment and a posteriori measured performance can hinder the development and diffusion of energy efficiency practices, especially considering the investment risk. The approach proposed in the research is rooted on the integration of parametric simulation techniques, adopted in the design phase, and inverse modelling techniques applied in Measurement and Verification (M&V) practice, i.e., model calibration, in the operation phase. The research focuses on the analysis of these technical aspects for a Passive House case study, showing an efficient and transparent way to link design and operation performance analysis, reducing effort in modelling and monitoring. The approach can be used to detect and highlight the impact of critical assumptions in the design phase as well as to guarantee the robustness of energy performance management in the operational phase, providing parametric performance boundaries to ease monitoring process and identification of insights in a simple, robust and scalable way.Energies 2020, 13, 621 2 of 14 by assessing transparently the impact of human and technical factors [11]. With respect to human factors in particular, the effects of occupants' behaviour [12] and of their comfort preferences [13] on building performance are generally overlooked in the design phase. This paper aims to present a way to integrate modelling methodologies used across building life cycle phases, from design to operation, in a simple and scalable way. A residential building has been chosen as a case study. The building is a detached single family certified Passive House built in Italy, in the Province of Forlì-Cesena, in the Emilia Romagna region. It has been monitored for three years, learning incrementally insights by comparing the original design phase simulation data with actual measured data. Background and MotivationThe research work answers to the necessity of linking parametric performance analysis and model calibration from a conceptual and practical point of view. Building performance parametric and probabilistic analysis is an essential tool today to ensure robustness of performance and the importance of the Design of Experiments (DOE) is becoming clear [14-17], both for new and retrofitted buildings [18,19]. For example, accounting for the robustness of performance estimates with respect to economic indicators (e.g., in cost-optimal analysis [20-22]) is important because uncertainty can aff...

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“…The probability of occurrence of many influential factors (like occupant behaviour) is largely unknown over a building's life-span, and as such it is difficult for designers to quantify their impact. For those influential factors it is possible to use scenario analysis in order to understand the impact of their uncertainty (Kotireddy, Hoes, and Hensen 2018). In scenario analysis, alternative futures for the influential factors are formulated, which can be used to identify designs that perform well (robust performing) in these formulated futures (Moss et al 2010).…”

Section: Introductionmentioning

confidence: 99%

“…As such, integration of scenario analysis into performance robustness assessment allows for a thorough investigation of uncertainties (Kim 2013;Struck and Hensen 2013). Accordingly, a non-probabilistic robustness assessment based on scenario analysis is used to identify robust designs (Hoes et al 2011;Rysanek and Choudhary 2013;Kotireddy, Hoes, and Hensen 2018). The max-min method and the minimax regret method are widely used for robustness assessment using scenario analysis (Averbakh 2000;Aissi, Bazgan, and Vanderpooten 2009).…”

Section: Introductionmentioning

confidence: 99%

Integrating robustness indicators into multi-objective optimization to find robust optimal low-energy building designs

Kotireddy

Hoes

Hensen

2018

Journal of Building Performance Simulation

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Uncertainties can have a large influence on building performance and cause deviations between predicted performance and performance during operation. It is therefore important to quantify this influence and identify robust designs that have potential to deliver the desired performance under uncertainties. Generally, robust building designs are identified by assessing the performance of multiple design configurations under various uncertainties. When exploring a large design space, this approach becomes computationally expensive and infeasible in practice. Therefore, we propose a simulation framework based on multi-objective optimization and sampling strategies to find robust optimal designs at low computational costs. The genetic algorithm parameters of optimization are fine tuned to further enhance the computational efficiency. Furthermore, a modified fitness function is implemented to use minimax regret robustness method in the optimization loop. The implemented simulation framework can save up to 94-99% of computational time compared to full factorial approach, while identifying the same robust designs.

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A methodology for performance robustness assessment of low-energy buildings using scenario analysis

Cited by 57 publications

References 46 publications

Validation of the climatic zoning defined by ASHRAE standard 169-2013

Validation of the climatic zoning defined by ASHRAE standard 169-2013

Parametric Performance Analysis and Energy Model Calibration Workflow Integration—A Scalable Approach for Buildings

Integrating robustness indicators into multi-objective optimization to find robust optimal low-energy building designs

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