scholarly journals An Exploration of Building Energy Model (BEM) Calibration in New Zealand

2021 ◽  
Author(s):  
◽  
Ethan Duff
Keyword(s):  
Quality Assurance ◽  
New Zealand ◽  
Energy Use ◽  
Building Energy ◽  
Building Energy Efficiency ◽  
Existing Building ◽  
Individual Interviews ◽  
Industry Research ◽  
Energy Modelling ◽  
Calibration Techniques

<p>This study explored the use of Building Energy Modelling (BEM) and BEM calibration techniques for existing buildings as currently employed in New Zealand Industry.  Research on the use of BEM for existing building energy efficiency retrofits has increased dramatically over the past few decades. However, this use of BEM has been criticised for inaccurate and unbelievable results. These are often the result of not closely matching the building being modelled due to uncertainties around model inputs and modeller assumptions. As a result, researchers have responded by developing techniques to ‘calibrate’ models by comparing the simulated building with the actual building energy use thus providing quality assurance.  However, many of these techniques are difficult, esoteric, convoluted or impractical for industry professionals. This research explored if a simple calibration technique developed at Victoria University of Wellington by Dr. Shaan Cory would meet the needs of industry practitioners. The technique was turned into a usable tool and student trialled to prepare it for industry assessment. Four BEM experts were then interviewed in a series of individual interviews and workshops trialling the use of the technique.  The research concluded that the use of BEM is limited in New Zealand due to a perceived Industry value gap – building owners are not aware of the benefits of modelling whole-building retrofits. This leads to reduced uptake of calibration techniques from industry resulting in a credibility gap, where the modeller themselves may not be confident of their own BEMs. This is due, in part, to a lack of industry quality assurance guidelines, usable calibration tools, and certainty around model inputs. The adoption of the streamlined Cory method would be of significant benefit to practitioners. However, it was identified that it did not solve all issues relating to uncertainty estimation.</p>

scholarly journals An Exploration of Building Energy Model (BEM) Calibration in New Zealand

2021 ◽  
Author(s):  
◽  
Ethan Duff
Keyword(s):  
Quality Assurance ◽  
New Zealand ◽  
Energy Use ◽  
Building Energy ◽  
Building Energy Efficiency ◽  
Existing Building ◽  
Individual Interviews ◽  
Industry Research ◽  
Energy Modelling ◽  
Calibration Techniques

<p>This study explored the use of Building Energy Modelling (BEM) and BEM calibration techniques for existing buildings as currently employed in New Zealand Industry.  Research on the use of BEM for existing building energy efficiency retrofits has increased dramatically over the past few decades. However, this use of BEM has been criticised for inaccurate and unbelievable results. These are often the result of not closely matching the building being modelled due to uncertainties around model inputs and modeller assumptions. As a result, researchers have responded by developing techniques to ‘calibrate’ models by comparing the simulated building with the actual building energy use thus providing quality assurance.  However, many of these techniques are difficult, esoteric, convoluted or impractical for industry professionals. This research explored if a simple calibration technique developed at Victoria University of Wellington by Dr. Shaan Cory would meet the needs of industry practitioners. The technique was turned into a usable tool and student trialled to prepare it for industry assessment. Four BEM experts were then interviewed in a series of individual interviews and workshops trialling the use of the technique.  The research concluded that the use of BEM is limited in New Zealand due to a perceived Industry value gap – building owners are not aware of the benefits of modelling whole-building retrofits. This leads to reduced uptake of calibration techniques from industry resulting in a credibility gap, where the modeller themselves may not be confident of their own BEMs. This is due, in part, to a lack of industry quality assurance guidelines, usable calibration tools, and certainty around model inputs. The adoption of the streamlined Cory method would be of significant benefit to practitioners. However, it was identified that it did not solve all issues relating to uncertainty estimation.</p>

scholarly journals The Development of a Biomimetic Design Tool for Building Energy Efficiency

Biomimetics ◽  
2020 ◽  
Vol 5 (4) ◽  
pp. 50
Author(s):  
Negin Imani ◽  
Brenda Vale
Keyword(s):  
Focus Group ◽  
Qualitative Data ◽  
Energy Use ◽  
Thermal Adaptation ◽  
Building Energy ◽  
Design Tool ◽  
Building Energy Efficiency ◽  
Energy Efficient Buildings ◽  
Building Energy Use ◽  
Architectural Framework

The initial aim of the research was to develop a framework that would enable architects to look for thermoregulation methods in nature as inspiration for designing energy efficient buildings. The thermo-bio-architectural framework (ThBA) assumes designers will start with a thermal challenge in a building and then look in a systematic way for how this same issue is solved in nature. The tool is thus a contribution to architectural biomimicry in the field of building energy use. Since the ThBA was created by an architect, it was essential that the biology side of this cross-disciplinary tool was validated by experts in biology. This article describes the focus group that was conducted to assess the quality, inclusiveness, and applicability of the framework and why a focus group was selected over other possible methods such as surveys or interviews. The article first provides a brief explanation of the development of the ThBA. Given the focus here is on its validation, the qualitative data collection procedures and analysis results produced by NVivo 12 plus through thematic coding are described in detail. The results showed the ThBA was effective in bridging the two fields based on the existing thermal challenges in buildings, and was comprehensive in terms of generalising biological thermal adaptation strategies.

scholarly journals Spatial and Behavioral Thermal Adaptation in Net Zero Energy Buildings: An Exploratory Investigation

2020 ◽  
Vol 12 (19) ◽  
pp. 7961 ◽  
Author(s):  
Shady Attia
Keyword(s):  
Energy Efficiency ◽  
Thermal Comfort ◽  
Energy Use ◽  
Thermal Adaptation ◽  
Building Energy ◽  
Building Energy Efficiency ◽  
Zero Energy ◽  
Net Zero Energy ◽  
Net Zero ◽  
Energy Efficiency Standards

Climate responsive design can amplify the positive environmental effects necessary for human habitation and constructively engage and reduce the energy use of existing buildings. This paper aims to assess the role of the thermal adaptation design strategy on thermal comfort perception, occupant behavior, and building energy use in twelve high-performance Belgian households. Thermal adaptation involves thermal zoning and behavioral adaptation to achieve thermal comfort and reduce energy use in homes. Based on quantitative and qualitative fieldwork and in-depth interviews conducted in Brussels, the paper provides insights on the impact of using mechanical systems in twelve newly renovated nearly- and net-zero energy households. The article calls for embracing thermal adaptation as a crucial design principle in future energy efficiency standards and codes. Results confirm the rebound effect in nearly zero energy buildings and the limitation of the current building energy efficiency standards. The paper offers a fresh perspective to the field of building energy efficiency that will appeal to researchers and architects, as well as policymakers.

scholarly journals The New Market Transformation Needed for Commercial Building Energy Efficiency

2016 ◽  
Vol 9 (1) ◽  
pp. 229
Author(s):  
Valerie Patrick ◽  
Leslie A. Billhymer ◽  
William Shephard
Keyword(s):  
Energy Efficiency ◽  
Energy Use ◽  
Building Energy ◽  
Department Of Energy ◽  
Building Energy Efficiency ◽  
Commercial Building ◽  
Innovation Cluster ◽  
Stakeholder Perspectives ◽  
Regional Market ◽  
Market Transformation

The U.S. Department of Energy [DOE] established the Consortium for Building Energy Innovation [CBEI] to address commercial building energy efficiency as an innovation cluster, where the regional market context (Note 1) guides the research agenda for market transformation (Porter, 2001). CBEI develops content to support Advanced Energy Retrofits (AERs), a retrofit which results in 50% or greater reduction in building energy use, in small- and medium- sized commercial buildings (less than 250 000 ft<sup>2</sup>). The challenge is collecting input for a market with many stakeholders so that a strategy emerges to implement AERs. This research applies systems and complexity theories to develop a strategy to promote the emergence of AERs in this market incorporating multiple stakeholder perspectives (Note 2).

scholarly journals Increasing Building Energy Efficiency Through Advances in Materials

MRS Bulletin ◽  
2008 ◽  
Vol 33 (4) ◽  
pp. 449-454 ◽  
Author(s):  
Ron Judkoff
Keyword(s):  
Energy Use ◽  
Cost Benefit Analysis ◽  
Cost Benefit ◽  
Building Energy ◽  
Primary Energy ◽  
Building Envelope ◽  
Performance Criteria ◽  
System Component ◽  
Building Energy Efficiency ◽  
Innovative Materials

AbstractMaterials advances could help to reduce the energy and environmental impacts of buildings. Globally, buildings use about 20% of primary energy and account for 20% of atmospheric emissions. Building energy consumption emanates from a variety of sources, some of which are related to the building envelope or fabric, some to the equipment in the building, and some to both. Opportunities for reducing energy use in buildings through innovative materials are therefore numerous, but there is no one system, component, or material whose improvement alone can solve the building energy problem. Many of the loads in a building are interactive, and this complicates cost/benefit analysis for new materials, components, and systems. Moreover, components and materials for buildings must meet stringent durability and cost/performance criteria to last the long service lifetimes of buildings and compete successfully in the marketplace.

scholarly journals AN INVESTIGATION STUDY ON EXISTING BUILDING ENERGY EFFICIENCY RENOVATION WITH A WATER THERMAL STORAGE SYSTEM

2021 ◽  
Vol 27 (66) ◽  
pp. 779-784
Author(s):  
Tadao YAGI ◽  
Shigehiro ICHINOSE ◽  
Hiroyuki MIYAJI ◽  
Hironori KIMURA ◽  
Tomoya KAWAJI
Keyword(s):  
Energy Efficiency ◽  
Storage System ◽  
Thermal Storage ◽  
Building Energy ◽  
Building Energy Efficiency ◽  
Existing Building

Potentials Analysis of Carbon Mitigation and Energy Consumption Reduction of Shanghai Non-Residential Buildings

2012 ◽  
Vol 512-515 ◽  
pp. 2766-2774
Author(s):  
Wei Bai ◽  
Wei Ding Long
Keyword(s):  
Energy Consumption ◽  
Energy Use ◽  
Residential Buildings ◽  
Energy System ◽  
Building Energy ◽  
Economic Incentives ◽  
Building Energy Efficiency ◽  
Carbon Reduction ◽  
Energy Consumption Reduction ◽  
Business As Usual

The aim of this study is to analyze the potentials of energy consumption and the energy-related carbon reduction of Shanghai non-residential buildings, to discuss the contributions of positive policies. This study uses system dynamic tool to examine the behaviour of the complex social-economic-energy system over time. This study defines three types of scenarios, BAU (business-as-usual), reference and ambitious scenarios in which policies on sustainability and technology progress are different. In order to highlight the importance of policies, this study adds several sub-scenarios and compares the contributions of them. The results show that Shanghai can reduce by at most 22% of building energy use and 30.9% of the energy-related carbon emissions by 2020 on the 2005 baseline. The strong economic incentives, including both encouraging and punishment measures are quite helpful for Shanghai building energy efficiency and CO2 reduction.

scholarly journals Modelling the Impacts of Climate Change on Building Heating and Cooling Energy Use in Toronto

2021 ◽  
Author(s):  
Pouriya Jafarpur
Keyword(s):  
Climate Change ◽  
Energy Demand ◽  
Energy Use ◽  
Dynamical Downscaling ◽  
Ghg Emissions ◽  
Building Energy ◽  
Weather Data ◽  
Existing Building ◽  
Average Decrease ◽  
The Future

The study describes the results of climate change impact assessment on building energy use in Toronto, Canada. Accordingly, three future weather data sets are generated and applied to the energy simulation of 16 building prototypes. Both statistical and dynamical downscaling techniques are used to generate the future weather files. The results indicate an average decrease for the future in the range of 18-33% in heating EUI, and an average increase of 16-126% in cooling EUI, depending on the baseline climate and building type. In addition, the GHG emissions for each building model are presented. It is concluded that the application of future weather files for building performance simulation leads to a better quantification of building energy demand in the future than a historical weather file. Furthermore, the results demonstrate the need to modify and adapt existing building modelling regulations and to plan future building according to the future climate.

scholarly journals The Effectiveness of Roofing Cool Coatings On The Building Energy Demand In A Cold Climate

2021 ◽  
Author(s):  
Tahmina Begum
Keyword(s):  
Energy Saving ◽  
Energy Demand ◽  
Building Energy ◽  
Cold Climate ◽  
Second Phase ◽  
Building Energy Efficiency ◽  
Cool Roof ◽  
Average Temperature ◽  
Energy Modelling ◽  
Cool Roofs

An average temperature increase of 2oC over the last 140 years in Toronto may not seem significant, but in reality heating demand for buildings will go down by impacting natural gas usage while cooling demand will go up by impacting electricity-usage. For preparedness against hot summer in cold climate, passive cooling needs to be adopted for building energy efficiency. In warm climate, cool roof technology proves effectiveness in reducing cooling energy demand of buildings but its use in cold climate is not much seen. Thus it is interesting to investigate the effectiveness of cool roofs in cold climate. This study investigates the properties of cool coatings available in North America, their performance on aging and energy saving benefits. The first phase of research includes selection of building, collection of information, field measurement of surface temperatures of the studied building and also lab testing of collected samples. The second phase includes energy modelling of the studied building with validation to understand their energy saving benefits. Finally the most effective cool coating for the studied building is recommended.

scholarly journals The Effectiveness of Roofing Cool Coatings On The Building Energy Demand In A Cold Climate

2021 ◽  
Author(s):  
Tahmina Begum
Keyword(s):  
Energy Saving ◽  
Energy Demand ◽  
Building Energy ◽  
Cold Climate ◽  
Second Phase ◽  
Building Energy Efficiency ◽  
Cool Roof ◽  
Average Temperature ◽  
Energy Modelling ◽  
Cool Roofs

An average temperature increase of 2oC over the last 140 years in Toronto may not seem significant, but in reality heating demand for buildings will go down by impacting natural gas usage while cooling demand will go up by impacting electricity-usage. For preparedness against hot summer in cold climate, passive cooling needs to be adopted for building energy efficiency. In warm climate, cool roof technology proves effectiveness in reducing cooling energy demand of buildings but its use in cold climate is not much seen. Thus it is interesting to investigate the effectiveness of cool roofs in cold climate. This study investigates the properties of cool coatings available in North America, their performance on aging and energy saving benefits. The first phase of research includes selection of building, collection of information, field measurement of surface temperatures of the studied building and also lab testing of collected samples. The second phase includes energy modelling of the studied building with validation to understand their energy saving benefits. Finally the most effective cool coating for the studied building is recommended.

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