scholarly journals Visualising the Invisible: Displaying Building Resource-use Benchmarks in a 3D City Visualisation

2021 ◽  
Author(s):  
◽  
Alex Josephine Hills
Keyword(s):  
New Zealand ◽  
Built Environment ◽  
Water Use ◽  
Resource Use ◽  
National Level ◽  
Residential Building ◽  
Central Business District ◽  
Building Design ◽  
Commercial Buildings ◽  
Building Stock

<p>This thesis proposes a reinvention of the means of presenting statistical data about 3D urban environments. Conventional GIS use of 3D ’enhances’ hard to understand 2D maps with even harder-to-understand histograms of data. The goal is to demonstrate the means by which data on energy and water-use in buildings can be used to enhance familiar 3D interactive city environments and be made accessible to the widest possible audience. Ultimately, resource benchmarks and other related publicly available information about the built environment could be presented in this highly accessible form. All information would be database driven, so automatically updateable. From this basic platform, applications that allow people to compare their own private records with public norms are easily constructed: a world where a building owner can compare their energy records with benchmarks for similar buildings and take action to improve if necessary, or to advertise accomplishments.  This study draws on data from the ‘BEES’ Building Energy End-use Study - a BRANZ research project documenting energy and water use in New Zealand commercial buildings. During the study a ‘Websearch’ survey was conducted, building a detailed picture of non-residential building stock in New Zealand with data collected on building typologies, characteristics and surroundings. A thorough research methodology was developed to ensure that high level data could be collected from 3,000 randomly selected buildings within the budget allocated for the project. The data was examined for quality, building characteristics and typology mix and a valuable layer of detail was added by inferring additional information from the basic Websearch dataset. Where sub-samples used in the BEES study were subject to refusal / survey participation rates, the level of potential bias in the mix of building typologies could be tested and allowances made. Energy and water use data collected for a random subset of the sample, could then be applied as benchmarks to the census of New Zealand commercial buildings.  In order to trial the communication of the benchmark results to the widest possible audience, an automated 3D city visualisation ‘pilot’ was generated of the Wellington Central Business District and a number of graphic tools were brought together to make the information publicly accessible and as useful as possible. The overall aim was to test the feasibility of applying this technique at a national level.  The research revealed three major recommendations: firstly, a national unique building identifier is required to ensure the accuracy of national building data and enable statistical results about the built environment to be accurately and reliably applied to real buildings; secondly, resource use data in 3D format is urgently required to improve the value of sustainable properties; lastly, creating a significant impact on building stock efficiency will depend upon the engagement of a wider audience. Developed further, this visualisation will enable construction professionals, building owners, developers and tenants to understand the built environment and implications of building design and typology on energy and water use.</p>

scholarly journals Visualising the Invisible: Displaying Building Resource-use Benchmarks in a 3D City Visualisation

2021 ◽  
Author(s):  
◽  
Alex Josephine Hills
Keyword(s):  
New Zealand ◽  
Built Environment ◽  
Water Use ◽  
Resource Use ◽  
National Level ◽  
Residential Building ◽  
Central Business District ◽  
Building Design ◽  
Commercial Buildings ◽  
Building Stock

<p>This thesis proposes a reinvention of the means of presenting statistical data about 3D urban environments. Conventional GIS use of 3D ’enhances’ hard to understand 2D maps with even harder-to-understand histograms of data. The goal is to demonstrate the means by which data on energy and water-use in buildings can be used to enhance familiar 3D interactive city environments and be made accessible to the widest possible audience. Ultimately, resource benchmarks and other related publicly available information about the built environment could be presented in this highly accessible form. All information would be database driven, so automatically updateable. From this basic platform, applications that allow people to compare their own private records with public norms are easily constructed: a world where a building owner can compare their energy records with benchmarks for similar buildings and take action to improve if necessary, or to advertise accomplishments.  This study draws on data from the ‘BEES’ Building Energy End-use Study - a BRANZ research project documenting energy and water use in New Zealand commercial buildings. During the study a ‘Websearch’ survey was conducted, building a detailed picture of non-residential building stock in New Zealand with data collected on building typologies, characteristics and surroundings. A thorough research methodology was developed to ensure that high level data could be collected from 3,000 randomly selected buildings within the budget allocated for the project. The data was examined for quality, building characteristics and typology mix and a valuable layer of detail was added by inferring additional information from the basic Websearch dataset. Where sub-samples used in the BEES study were subject to refusal / survey participation rates, the level of potential bias in the mix of building typologies could be tested and allowances made. Energy and water use data collected for a random subset of the sample, could then be applied as benchmarks to the census of New Zealand commercial buildings.  In order to trial the communication of the benchmark results to the widest possible audience, an automated 3D city visualisation ‘pilot’ was generated of the Wellington Central Business District and a number of graphic tools were brought together to make the information publicly accessible and as useful as possible. The overall aim was to test the feasibility of applying this technique at a national level.  The research revealed three major recommendations: firstly, a national unique building identifier is required to ensure the accuracy of national building data and enable statistical results about the built environment to be accurately and reliably applied to real buildings; secondly, resource use data in 3D format is urgently required to improve the value of sustainable properties; lastly, creating a significant impact on building stock efficiency will depend upon the engagement of a wider audience. Developed further, this visualisation will enable construction professionals, building owners, developers and tenants to understand the built environment and implications of building design and typology on energy and water use.</p>

scholarly journals Building Design Influence On The Energy Performance

2015 ◽  
Vol 5 (1) ◽  
pp. 37-46
Author(s):  
Ligia Moga ◽  
I. Moga
Keyword(s):  
Residential Building ◽  
Building Design ◽  
Energy Performance ◽  
Point Of View ◽  
Hot Water ◽  
Efficient Design ◽  
Building Stock ◽  
Existing Building ◽  
Climatic Regions ◽  
Energy Consumptions

Abstract Energy efficient design is a high priority in the national energy strategy of European countries considering the latest requirements of the European Directive on the Energy Performance of Buildings. The residential sector is responsible for a significant quantity of energy consumptions from the total amount of consumptions on a worldwide level. In residential building most of the energy consumptions are given mainly by heating, domestic hot water and lighting. Retrofitting the existing building stock offers great opportunities for reducing global energy consumptions and greenhouse gas emissions. The first part of the paper will address the need of thermal and energy retrofit of existing buildings. The second part will provide an overview on how various variables can influence the energy performance of a building that is placed in all four climatic zones from Romania. The paper is useful for specialist and designers from the construction field in understanding that buildings behave differently from the energy point of view in different climatic regions, even if the building characteristic remain the same.

scholarly journals Energy flexible commercial buildings and the electricity grid

2021 ◽  
Author(s):  
◽  
Sandi Sirikhanchai
Keyword(s):  
New Zealand ◽  
Electricity Demand ◽  
Commercial Buildings ◽  
Commercial Building ◽  
Building Stock ◽  
Electricity Grid ◽  
Indoor Thermal Comfort ◽  
Grid Operators ◽  
Grid Management

<p>New Zealand’s energy and electricity system is likely to undergo serious changes with climate change and the decarbonisation of the grid playing a significant role. Research in New Zealand around flexibly managing the electricity grid using buildings has focused on thermoelectric appliances in the residential sector while there has been limited research and quantification of the energy flexibility offered by commercial buildings. Despite this, managing the grid using energy flexible commercial buildings represents an opportunity to achieve meaningful reductions in electricity demand from buildings that are far less numerous than residential buildings.  The aim of this thesis was to establish whether energy flexible commercial buildings in New Zealand can maintain the current quality of indoor thermal comfort and achieve reductions in demand that are sufficiently large that grid operators consider them significant contributors to grid management. By understanding the contribution, we can understand whether energy flexible commercial buildings are worth further investigation. In this thesis, energy flexibility means the ability for a building to manage its demand and generation according to user needs, grid needs, and local climate conditions. Energy flexibility in commercial buildings could then support the integration of more variable renewable energy sources and increase demand response capability which is a cost-effective way to manage network constraints and reduce non-renewable  electricity generation.   Case studies of New Zealand commercial buildings represented as Building Energy Models (BEMs) were simulated under energy flexible operation in a building performance simulation software (EnergyPlus). The selected case studies were small commercial buildings less than 1,499m² in size and which all contained heat pumps. The buildings were of office, retail, and mixed-use types. Two simple energy flexibility strategies were simulated in the buildings and the results from each building were then aggregated and extrapolated across the New Zealand commercial building stock. The strategies simply shifted and shed heating electricity demand. This was done to test whether implementing basic energy flexibility strategies have the potential to reduce electricity demand by a meaningful magnitude.   At best the commercial building stock’s peak demand could reduce by 177MW by energy flexibly operating 45% of the commercial building stock, this was equivalent to around 11,700 buildings. In this scenario heating was shifted to start 150 minutes earlier in the morning. The study concluded that there is energy flexibility potential in New Zealand commercial buildings that results in demand reductions sufficiently large enough for grid operators to consider significant for grid management. This could be achieved without seriously jeopardising the current quality of indoor thermal comfort and warrants further investigation into energy flexible commercial buildings. This thesis also presented a refined methodology and energy modelling practice that could be used by other researchers to model and evaluate energy flexible buildings without the need to recreate the same methodology.</p>

scholarly journals Energy flexible commercial buildings and the electricity grid

2021 ◽  
Author(s):  
◽  
Sandi Sirikhanchai
Keyword(s):  
New Zealand ◽  
Electricity Demand ◽  
Commercial Buildings ◽  
Commercial Building ◽  
Building Stock ◽  
Electricity Grid ◽  
Indoor Thermal Comfort ◽  
Grid Operators ◽  
Grid Management

<p>New Zealand’s energy and electricity system is likely to undergo serious changes with climate change and the decarbonisation of the grid playing a significant role. Research in New Zealand around flexibly managing the electricity grid using buildings has focused on thermoelectric appliances in the residential sector while there has been limited research and quantification of the energy flexibility offered by commercial buildings. Despite this, managing the grid using energy flexible commercial buildings represents an opportunity to achieve meaningful reductions in electricity demand from buildings that are far less numerous than residential buildings.  The aim of this thesis was to establish whether energy flexible commercial buildings in New Zealand can maintain the current quality of indoor thermal comfort and achieve reductions in demand that are sufficiently large that grid operators consider them significant contributors to grid management. By understanding the contribution, we can understand whether energy flexible commercial buildings are worth further investigation. In this thesis, energy flexibility means the ability for a building to manage its demand and generation according to user needs, grid needs, and local climate conditions. Energy flexibility in commercial buildings could then support the integration of more variable renewable energy sources and increase demand response capability which is a cost-effective way to manage network constraints and reduce non-renewable  electricity generation.   Case studies of New Zealand commercial buildings represented as Building Energy Models (BEMs) were simulated under energy flexible operation in a building performance simulation software (EnergyPlus). The selected case studies were small commercial buildings less than 1,499m² in size and which all contained heat pumps. The buildings were of office, retail, and mixed-use types. Two simple energy flexibility strategies were simulated in the buildings and the results from each building were then aggregated and extrapolated across the New Zealand commercial building stock. The strategies simply shifted and shed heating electricity demand. This was done to test whether implementing basic energy flexibility strategies have the potential to reduce electricity demand by a meaningful magnitude.   At best the commercial building stock’s peak demand could reduce by 177MW by energy flexibly operating 45% of the commercial building stock, this was equivalent to around 11,700 buildings. In this scenario heating was shifted to start 150 minutes earlier in the morning. The study concluded that there is energy flexibility potential in New Zealand commercial buildings that results in demand reductions sufficiently large enough for grid operators to consider significant for grid management. This could be achieved without seriously jeopardising the current quality of indoor thermal comfort and warrants further investigation into energy flexible commercial buildings. This thesis also presented a refined methodology and energy modelling practice that could be used by other researchers to model and evaluate energy flexible buildings without the need to recreate the same methodology.</p>

scholarly journals An exploration of the feasibility of converting the New Zealand commercial building stock to be Net Zero Energy

2021 ◽  
Author(s):  
◽  
Shaan Cory
Keyword(s):  
Renewable Energy ◽  
Energy Consumption ◽  
New Zealand ◽  
Commercial Buildings ◽  
Commercial Building ◽  
Zero Energy ◽  
Building Stock ◽  
Energy Models ◽  
Net Zero Energy ◽  
Net Zero

This thesis explores the feasibility of converting the current New Zealand commercial building stock to Net Zero Energy (NZE). The analysis presented is grounded in real building performance and construction information. The goal was to establish results that are as realistic as possible to actual building performance. The Net Zero Energy Building (Net ZEB) concept is one of many low energy building movements that respond to the issues of climate change and energy security. The Net ZEB concept strives to reduce demand for energy and then to offset any residual energy consumption with non-CO2 emitting renewable energy technologies. The (re-)design focus for Net ZEBs is to reduce annual energy consumption to be equal to or less than any generated renewable energy. This is an important concept since approximately 40 percent of all energy and emissions worldwide are building related. If all buildings were designed and operated to be NZE, the existing energy can be used by other sectors which will increase energy security. Conversely, reducing the fossil fuel CO2 producing component of the energy consumed by buildings has the benefit of negating building’s contribution to climate change. The Net ZEB concept assumes each building is grid-connected, and balances the energy taken from the grid against the energy put back into the grid over a year. This study exploits the available synergies of the grid connection to achieve NZE for the whole building stock. Thus each individual building does not need to be NZE at the site, but they act as a community to reach NZE collectively. Furthermore, any grid-tied renewable energy does not need to be offset, only the non-renewable portion. A NZE target was calculated to determine the percentage reduction in current energy consumption needed before the current commercial building stock could be considered NZE. It was found that a 45 percent reduction in primary energy would offset all non-renewable CO2 emitting energy supply currently consumed by the New Zealand commercial building stock. Previous studies assessing whether converting an entire stock of commercial buildings to NZE is possible used prototypical building energy models. Prototypical models represent a hypothetical average building and have many assumptions about the way a building is operated. This thesis develops a method that takes a representative sample of real commercial buildings and makes calibrated energy models that can be aggregated to represent energy consumption for all commercial buildings in New Zealand. The developed calibration method makes use of as-built building information and a standardised procedure for identifying the inaccurate model inputs which need to be corrected for a building energy model to be calibrated. To further base the process in reality, a set of Energy Conservation Measures (ECM) that had been implemented in real Net ZEBs worldwide was adopted for the proposed retrofits. These ECMs were combined into Net ZEB solution sets for retrofitting the aggregated commercial building models. Optimisation of the Net ZEB solution sets was performed on hundreds of models to maximise energy savings. It took over six months for all of the optimisations to be completed. This thesis demonstrates the estimated New Zealand commercial building stock’s energy consumption based upon the calibrated energy models was robust by comparing it to an external estimate. It shows that NZE can be achieved by applying well understood Net ZEB solution sets to the New Zealand commercial building stock. 96 percent of the NZE goal is attainable just through demand reduction without the use of onsite renewable energy generation. The additional four percent of reduction required to meet NZE is easily attainable with onsite renewable generation. Another benefit is that the retrofitted commercial buildings will provide improved thermal comfort for the occupants. Having established NZE was possible, this thesis concludes with an analysis of the broader implications of achieving the NZE goal. It identifies the next step would be to design a NZE commercial building stock that reduces the stresses on the existing energy infrastructure. The Solution Set adopted was not developed with the interaction of the building and electrical grid in mind. To have a practical implementation of NZE will require costing and community prioritisation. This would be the next phase of work assessing nationwide NZE retrofit.

Research on the Appropriate Technology of Green Residences Design in Eastern Henan

2014 ◽  
Vol 584-586 ◽  
pp. 845-849 ◽  
Author(s):  
Xue Min Shi ◽  
Dan Zhang
Keyword(s):  
Architectural Design ◽  
Residential Buildings ◽  
Action Plan ◽  
National Level ◽  
Residential Building ◽  
Green Building ◽  
Building Design ◽  
Appropriate Technology ◽  
Energy Utilization ◽  
Low Carbon

In early 2013, the State Council promulgated the "green building action plan" .This means that the green building will be implemented from the national level in the future and it is of great significance to reduce energy consumption and to promote the development of energy-saving, green and low carbon architecture. In this paper, the suitable method and strategy of green residential building design in the Eastern Henan which based on the analysis of the planning and layout, architectural design, energy utilization and construction methods of existing residential buildings in the area are expounded through the analysis of the entire process of the construction of residential building.

scholarly journals An exploration of the feasibility of converting the New Zealand commercial building stock to be Net Zero Energy

2021 ◽  
Author(s):  
◽  
Shaan Cory
Keyword(s):  
Renewable Energy ◽  
Energy Consumption ◽  
New Zealand ◽  
Commercial Buildings ◽  
Commercial Building ◽  
Zero Energy ◽  
Building Stock ◽  
Energy Models ◽  
Net Zero Energy ◽  
Net Zero

This thesis explores the feasibility of converting the current New Zealand commercial building stock to Net Zero Energy (NZE). The analysis presented is grounded in real building performance and construction information. The goal was to establish results that are as realistic as possible to actual building performance. The Net Zero Energy Building (Net ZEB) concept is one of many low energy building movements that respond to the issues of climate change and energy security. The Net ZEB concept strives to reduce demand for energy and then to offset any residual energy consumption with non-CO2 emitting renewable energy technologies. The (re-)design focus for Net ZEBs is to reduce annual energy consumption to be equal to or less than any generated renewable energy. This is an important concept since approximately 40 percent of all energy and emissions worldwide are building related. If all buildings were designed and operated to be NZE, the existing energy can be used by other sectors which will increase energy security. Conversely, reducing the fossil fuel CO2 producing component of the energy consumed by buildings has the benefit of negating building’s contribution to climate change. The Net ZEB concept assumes each building is grid-connected, and balances the energy taken from the grid against the energy put back into the grid over a year. This study exploits the available synergies of the grid connection to achieve NZE for the whole building stock. Thus each individual building does not need to be NZE at the site, but they act as a community to reach NZE collectively. Furthermore, any grid-tied renewable energy does not need to be offset, only the non-renewable portion. A NZE target was calculated to determine the percentage reduction in current energy consumption needed before the current commercial building stock could be considered NZE. It was found that a 45 percent reduction in primary energy would offset all non-renewable CO2 emitting energy supply currently consumed by the New Zealand commercial building stock. Previous studies assessing whether converting an entire stock of commercial buildings to NZE is possible used prototypical building energy models. Prototypical models represent a hypothetical average building and have many assumptions about the way a building is operated. This thesis develops a method that takes a representative sample of real commercial buildings and makes calibrated energy models that can be aggregated to represent energy consumption for all commercial buildings in New Zealand. The developed calibration method makes use of as-built building information and a standardised procedure for identifying the inaccurate model inputs which need to be corrected for a building energy model to be calibrated. To further base the process in reality, a set of Energy Conservation Measures (ECM) that had been implemented in real Net ZEBs worldwide was adopted for the proposed retrofits. These ECMs were combined into Net ZEB solution sets for retrofitting the aggregated commercial building models. Optimisation of the Net ZEB solution sets was performed on hundreds of models to maximise energy savings. It took over six months for all of the optimisations to be completed. This thesis demonstrates the estimated New Zealand commercial building stock’s energy consumption based upon the calibrated energy models was robust by comparing it to an external estimate. It shows that NZE can be achieved by applying well understood Net ZEB solution sets to the New Zealand commercial building stock. 96 percent of the NZE goal is attainable just through demand reduction without the use of onsite renewable energy generation. The additional four percent of reduction required to meet NZE is easily attainable with onsite renewable generation. Another benefit is that the retrofitted commercial buildings will provide improved thermal comfort for the occupants. Having established NZE was possible, this thesis concludes with an analysis of the broader implications of achieving the NZE goal. It identifies the next step would be to design a NZE commercial building stock that reduces the stresses on the existing energy infrastructure. The Solution Set adopted was not developed with the interaction of the building and electrical grid in mind. To have a practical implementation of NZE will require costing and community prioritisation. This would be the next phase of work assessing nationwide NZE retrofit.

Applicability of management guidelines for surfing resources in California

Shore & Beach ◽  
2020 ◽  
pp. 53-64
Author(s):  
Edward Atkin ◽  
Dan Reineman ◽  
Jesse Reiblich ◽  
David Revell
Keyword(s):  
New Zealand ◽  
National Level ◽  
State Level ◽  
The United States ◽  
Management Guidelines ◽  
For Profit ◽  
Aotearoa New Zealand ◽  
Coastal Marine ◽  
Management Measures ◽  
Legal Frameworks

Surf breaks are finite, valuable, and vulnerable natural resources, that not only influence community and cultural identities, but are a source of revenue and provide a range of health benefits. Despite these values, surf breaks largely lack recognition as coastal resources and therefore the associated management measures required to maintain them. Some countries, especially those endowed with high-quality surf breaks and where the sport of surfing is accepted as mainstream, have recognized the value of surfing resources and have specific policies for their conservation. In Aotearoa New Zealand surf breaks are included within national environmental policy. Aotearoa New Zealand has recently produced Management Guidelines for Surfing Resources (MGSR), which were developed in conjunction with universities, regional authorities, not-for-profit entities, and government agencies. The MGSR provide recommendations for both consenting authorities and those wishing to undertake activities in the coastal marine area, as well as tools and techniques to aid in the management of surfing resources. While the MGSR are firmly aligned with Aotearoa New Zealand’s cultural and legal frameworks, much of their content is applicable to surf breaks worldwide. In the United States, there are several national-level and state-level statutes that are generally relevant to various aspects of surfing resources, but there is no law or policy that directly addresses them. This paper describes the MGSR, considers California’s existing governance frameworks, and examines the potential benefits of adapting and expanding the MGSR in this state.

scholarly journals TOPOI RESOURCES: Quantification and Assessment of Global Warming Potential and Land-Uptake of Residential Buildings in Settlement Types along the Urban–Rural Gradient—Opportunities for Sustainable Development

2021 ◽  
Vol 13 (8) ◽  
pp. 4099
Author(s):  
Ann-Kristin Mühlbach ◽  
Olaf Mumm ◽  
Ryan Zeringue ◽  
Oskars Redbergs ◽  
Elisabeth Endres ◽  
...  
Keyword(s):  
Sustainable Development ◽  
Global Warming ◽  
Energy Consumption ◽  
Global Warming Potential ◽  
Residential Buildings ◽  
Residential Building ◽  
Negative Effects ◽  
Building Stock ◽  
Residential Building Stock ◽  
Urban Rural

The METAPOLIS as the polycentric network of urban–rural settlement is undergoing constant transformation and urbanization processes. In particular, the associated imbalance of the shrinkage and growth of different settlement types in relative geographical proximity causes negative effects, such as urban sprawl and the divergence of urban–rural lifestyles with their related resource, land and energy consumption. Implicitly related to these developments, national and global sustainable development goals for the building sector lead to the question of how a region can be assessed without detailed research and surveys to identify critical areas with high potential for sustainable development. In this study, the TOPOI method is used. It classifies settlement units and their interconnections along the urban–rural gradient, in order to quantify and assess the land-uptake and global warming potential driven by residential developments. Applying standard planning parameters in combination with key data from a comprehensive life cycle assessment of the residential building stock, a detailed understanding of different settlement types and their associated resource and energy consumption is achieved.

scholarly journals Mechanics-based fragility curves for Italian residential URM buildings

2020 ◽  
Author(s):  
Marco Donà ◽  
Pietro Carpanese ◽  
Veronica Follador ◽  
Luca Sbrogiò ◽  
Francesca da Porto
Keyword(s):  
Reference Model ◽  
Fragility Curves ◽  
National Level ◽  
Building Stock ◽  
Damage Scenarios ◽  
Complex Evaluation ◽  
Proposed Model ◽  
2009 L’Aquila Earthquake ◽  
Damage States ◽  
Observed Damage

Abstract Seismic risk assessment at the territorial level is now widely recognised as essential for countries with intense seismic activity, such as Italy. Academia is called to give its contribution in order to synergically deepen the knowledge about the various components of this risk, starting from the complex evaluation of vulnerability of the built heritage. In line with this, a mechanics-based seismic fragility model for Italian residential masonry buildings was developed and presented in this paper. This model is based on the classification of the building stock in macro-typologies, defined by age of construction and number of storeys, which being information available at national level, allow simulating damage scenarios and carrying out risk analyses on a territorial scale. The model is developed on the fragility of over 500 buildings, sampled according to national representativeness criteria and analysed through the Vulnus_4.0 software. The calculated fragility functions were extended on the basis of a reference model available in the literature, which provides generic fragilities for the EMS98 vulnerability classes, thus obtaining a fragility model defined on the five EMS98 damage states. Lastly, to assess the reliability of the proposed model, this was used to simulate damage scenarios due to the 2009 L’Aquila earthquake. Overall, the comparison between model results and observed damage showed a good fit, proving the model effectiveness.

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