Abstract
Climate predictions indicate a strong likelihood of more frequent, intense heat events. Resource-vulnerable, low-income neighbourhood populations are likely to be strongly impacted by future climate change, especially with respect to an energy burden. In order to identify existing and new vulnerabilities to climate change, local authorities need to understand the dynamics of extreme heat events at the neighbourhood level, particularly to identify those people who are adversely affected. A new comprehensive framework is presented that integrates human and biophysical data: occupancy/behaviour, building energy use, future climate scenarios and near-building microclimate projections. The framework is used to create an urban energy model for a low-resource neighbourhood in Des Moines, Iowa, US. Data were integrated into urban modelling interface (umi) software simulations, based on detailed surveys of residents’ practices, their buildings and near-building microclimates (tree canopy effects, etc.). The simulations predict annual and seasonal building energy use in response to different climate scenarios. Preliminary results, based on 50 simulation runs with different variable combinations, indicate the importance of using locally derived building occupant schedules and point toward increased summer cooling demand and increased vulnerability for parts of the population. Practice relevanceTo support planning responses to increased heat, local authorities need to ascertain which neighbourhoods will be negatively impacted in order to develop appropriate strategies. Localised data can provide good insights into the impacts of human decisions and climate variability in low-resource, vulnerable urban neighbourhoods. A new detailed modelling framework synthesises data on occupant–building interactions with present and future urban climate characteristics. This identifies the areas most vulnerable to extreme heat using future climate projections and community demographics. Cities can use this framework to support decisions and climate-adaptation responses, especially for low-resource neighbourhoods. Fine-grained and locally collected data influence the outcome of combined urban energy simulations that integrate human–building interactions and occupancy schedules as well as microclimate characteristics influenced by nearby vegetation.
Highlights
Within a society, some groups will be more adversely affected by climate change than others, due to a lack of available resources for adaptation or harsher existing conditions
A 2012 survey revealed that only Canada and select Asian and Latin American countries had over 20% of cities which had planned climate adaptions working with non-governmental organisations
The urban modelling interface was used to extract geometric and geographically precise building footprint data and building assembly information from assessor and from geographical information system (GIS) databases and to connect performance indicators from existing American Society of Heating, Refrigerating and Air Conditioning Engineers (ASHRAE) databases stored in umi. umi is a plug-in for the Rhinoceros 3D computer-aided design (CAD) environment combining building location data with EnergyPlus and DaySim as modelling engines for energy, radiation and daylighting (Reinhart et al 2013)
Summary
Some groups will be more adversely affected by climate change than others, due to a lack of available resources for adaptation or harsher existing conditions. Biophysical data used included a comprehensive neighbourhood-scale tree inventory (conducted by the research team), data sets for the urban heat island (UHI) collected via remote satellite sensing (processed by the team), building characteristics from geographical information system (GIS) and county assessor data (PCHD 2019), and future climate predictions (developed by Patton 2013 and described by Rabideau et al 2012) based on the North American Regional Climate Change Assessment Program (NARCCAP). In Phase 2, computational models were developed to represent and analyse the human and biophysical systems based on locally collected data These included developing probabilistic input for building occupancy and energy use (schedules), and visualisation schemes using umi. Future Phase 3 work will include UHI data and agent-based modelling to refine the neighbourhood specificity further, and produce integrated urban energy models to generate scenarios that provide data for decision support to civic stakeholders
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