Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...

The life cycle optimization (LCO) of zero carbon buildings (ZC) was examined, using a laneway house built with photovoltaic and solar air wall (SAW) renewable energy collection, air-to-water heat pump, smart grid-integrated thermal storage (SGTS) hydronic battery with an internet-connected stochasti...

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Bibliographic Details
Main Author: Stoyke, Godo Albert
Format: Article in Journal/Newspaper
Language:English
Published: Environmental Design 2018
Subjects:
Green building rating systems
climate change
CO2e
Carbon return on investment
CROI
IRR
cost-benefit analysis
least-cost climate abatement
residual carbon debt
stochastic control
heat pump
thermal storage
global warming potential
energy efficiency
model predictive control
energy efficiency retrofit
residential
Architecture
FOS Civil engineering
commercial
GHG emission reduction
energy consumption
Life cycle assessment
Life cycle costing
LCA
LCC
CAGBC LEED
net zero energy building
zero carbon building
ZEB
PassivHaus
passive house
laneway house
Garden suite
zero-peak house
Edmonton
Alberta
Canada
Smart grid-integrated thermal storage SGTS
Coefficient of performance
COP
Photovoltaic
solar thermal air wall
solar thermal collector
predictive controls
weather forecast
Environmental Sciences
Energy
Engineering
Engineering > Electronics and Electrical
Subarctic
Online Access:https://dx.doi.org/10.11575/prism/31737
https://prism.ucalgary.ca/handle/1880/106444
id ftdatacite:10.11575/prism/31737
record_format openpolar
spelling ftdatacite:10.11575/prism/31737 2023-11-05T03:45:18+01:00 Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ... Stoyke, Godo Albert 2018 https://dx.doi.org/10.11575/prism/31737 https://prism.ucalgary.ca/handle/1880/106444 en eng Environmental Design University of Calgary graduate students retain copyright ownership and moral rights for their thesis. You may use this material in any way that is permitted by the Copyright Act or through licensing that has been assigned to the document. For uses that are not allowable under copyright legislation or licensing, you are required to seek permission. Green building rating systems climate change CO2e Carbon return on investment CROI IRR cost-benefit analysis least-cost climate abatement residual carbon debt stochastic control heat pump thermal storage global warming potential energy efficiency model predictive control energy efficiency retrofit residential Architecture FOS Civil engineering commercial GHG emission reduction energy consumption Life cycle assessment Life cycle costing LCA LCC CAGBC LEED net zero energy building zero carbon building ZEB PassivHaus passive house laneway house Garden suite zero-peak house Edmonton Alberta Canada Smart grid-integrated thermal storage SGTS Coefficient of performance COP Photovoltaic solar thermal air wall solar thermal collector predictive controls weather forecast Environmental Sciences Energy Engineering Engineering--Electronics and Electrical article doctoral thesis CreativeWork Other 2018 ftdatacite https://doi.org/10.11575/prism/31737 2023-10-09T10:52:03Z The life cycle optimization (LCO) of zero carbon buildings (ZC) was examined, using a laneway house built with photovoltaic and solar air wall (SAW) renewable energy collection, air-to-water heat pump, smart grid-integrated thermal storage (SGTS) hydronic battery with an internet-connected stochastic (predictive) control system in subarctic Edmonton, Alberta, Canada. LCO is for global warming potential (GWP), energy, cost, and renewable friendliness. A life cycle assessment (LCA) based methodology (carbon return on investment – CROI) is proposed for design and retrofit decisions on the basis of GWP and cost. Sustainable building rating systems are modelled for their effectiveness in reducing GWP and energy use and are found to reduce life cycle GWP by 18.3% (LEED 2009 certified), 60.7% (PassivHaus 9.30), 96.9% (net zero) and 97.2% (zero carbon) compared to a home built to Alberta Building Code 2014 (base model – BM) over an 80 year life cycle. LCA of the ZC laneway house found a 94.4% reduction in GWP ... Article in Journal/Newspaper Subarctic DataCite Metadata Store (German National Library of Science and Technology)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic Green building rating systems
climate change
CO2e
Carbon return on investment
CROI
IRR
cost-benefit analysis
least-cost climate abatement
residual carbon debt
stochastic control
heat pump
thermal storage
global warming potential
energy efficiency
model predictive control
energy efficiency retrofit
residential
Architecture
FOS Civil engineering
commercial
GHG emission reduction
energy consumption
Life cycle assessment
Life cycle costing
LCA
LCC
CAGBC LEED
net zero energy building
zero carbon building
ZEB
PassivHaus
passive house
laneway house
Garden suite
zero-peak house
Edmonton
Alberta
Canada
Smart grid-integrated thermal storage SGTS
Coefficient of performance
COP
Photovoltaic
solar thermal air wall
solar thermal collector
predictive controls
weather forecast
Environmental Sciences
Energy
Engineering
Engineering--Electronics and Electrical
spellingShingle Green building rating systems
climate change
CO2e
Carbon return on investment
CROI
IRR
cost-benefit analysis
least-cost climate abatement
residual carbon debt
stochastic control
heat pump
thermal storage
global warming potential
energy efficiency
model predictive control
energy efficiency retrofit
residential
Architecture
FOS Civil engineering
commercial
GHG emission reduction
energy consumption
Life cycle assessment
Life cycle costing
LCA
LCC
CAGBC LEED
net zero energy building
zero carbon building
ZEB
PassivHaus
passive house
laneway house
Garden suite
zero-peak house
Edmonton
Alberta
Canada
Smart grid-integrated thermal storage SGTS
Coefficient of performance
COP
Photovoltaic
solar thermal air wall
solar thermal collector
predictive controls
weather forecast
Environmental Sciences
Energy
Engineering
Engineering--Electronics and Electrical
Stoyke, Godo Albert
Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...
topic_facet Green building rating systems
climate change
CO2e
Carbon return on investment
CROI
IRR
cost-benefit analysis
least-cost climate abatement
residual carbon debt
stochastic control
heat pump
thermal storage
global warming potential
energy efficiency
model predictive control
energy efficiency retrofit
residential
Architecture
FOS Civil engineering
commercial
GHG emission reduction
energy consumption
Life cycle assessment
Life cycle costing
LCA
LCC
CAGBC LEED
net zero energy building
zero carbon building
ZEB
PassivHaus
passive house
laneway house
Garden suite
zero-peak house
Edmonton
Alberta
Canada
Smart grid-integrated thermal storage SGTS
Coefficient of performance
COP
Photovoltaic
solar thermal air wall
solar thermal collector
predictive controls
weather forecast
Environmental Sciences
Energy
Engineering
Engineering--Electronics and Electrical
description The life cycle optimization (LCO) of zero carbon buildings (ZC) was examined, using a laneway house built with photovoltaic and solar air wall (SAW) renewable energy collection, air-to-water heat pump, smart grid-integrated thermal storage (SGTS) hydronic battery with an internet-connected stochastic (predictive) control system in subarctic Edmonton, Alberta, Canada. LCO is for global warming potential (GWP), energy, cost, and renewable friendliness. A life cycle assessment (LCA) based methodology (carbon return on investment – CROI) is proposed for design and retrofit decisions on the basis of GWP and cost. Sustainable building rating systems are modelled for their effectiveness in reducing GWP and energy use and are found to reduce life cycle GWP by 18.3% (LEED 2009 certified), 60.7% (PassivHaus 9.30), 96.9% (net zero) and 97.2% (zero carbon) compared to a home built to Alberta Building Code 2014 (base model – BM) over an 80 year life cycle. LCA of the ZC laneway house found a 94.4% reduction in GWP ...
format Article in Journal/Newspaper
author Stoyke, Godo Albert
author_facet Stoyke, Godo Albert
author_sort Stoyke, Godo Albert
title Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...
title_short Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...
title_full Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...
title_fullStr Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...
title_full_unstemmed Life Cycle Optimization of a Zero Carbon Building for CO2e, Energy, and Cost Using Stochastic Controls for an Energy System Integrating a Heat Pump, Solar Air Wall, PV, and a Smart Grid-integrated Thermal Storage (SGTS) Hydronic Battery ...
title_sort life cycle optimization of a zero carbon building for co2e, energy, and cost using stochastic controls for an energy system integrating a heat pump, solar air wall, pv, and a smart grid-integrated thermal storage (sgts) hydronic battery ...
publisher Environmental Design
publishDate 2018
url https://dx.doi.org/10.11575/prism/31737
https://prism.ucalgary.ca/handle/1880/106444
genre Subarctic
genre_facet Subarctic
op_rights University of Calgary graduate students retain copyright ownership and moral rights for their thesis. You may use this material in any way that is permitted by the Copyright Act or through licensing that has been assigned to the document. For uses that are not allowable under copyright legislation or licensing, you are required to seek permission.
op_doi https://doi.org/10.11575/prism/31737
_version_ 1781707161462636544

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