Hempcrete building performance in mild and cold climates: Integrated analysis of carbon footprint, energy, and indoor thermal and moisture buffering

The use of hempcrete as a bio-based alternative to conventional building materials was investigated through a building life cycle carbon footprint analysis of a conventional wood-frame enclosure and a hempcrete enclosure. Embodied emissions were determined using the Athena Impact Estimator. An in-ho...

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Bibliographic Details
Published in:Building and environment 2021-12, Vol.206, p.108377, Article 108377
Main Authors: Shang, Yina, Tariku, Fitsum
Format: Article
Language:English
Subjects:
Buffers
Building materials
Carbon
Carbon cycle
Carbon footprint
Climate
Cold weather construction
Construction materials
Cooling
Cooling loads
Cooling systems
Durability
Emissions
Enclosures
Energy conservation
Energy consumption
Energy performance
Environmental impact
Footprint analysis
Heating
Hempcrete
Life cycle analysis
Life cycles
Life span
Moisture
Moisture buffering
Reduction
Solar heat gain
Thermal conductivity
Thermal mass
Whole building HAM simulation
Wood framed
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Summary:The use of hempcrete as a bio-based alternative to conventional building materials was investigated through a building life cycle carbon footprint analysis of a conventional wood-frame enclosure and a hempcrete enclosure. Embodied emissions were determined using the Athena Impact Estimator. An in-house developed whole building hygrothermal model was validated using experimental data and then used to assess the operational energy including the dynamic interaction of thermal and moisture buffering with building heating and cooling loads. The higher thermal mass of hempcrete was shown to increase heating energy consumption and reduce cooling energy consumption due to a reduction in solar heat gain. Therefore, for the mild and cold climates studied here, cooling energy savings were mostly overtaken by increased heating energy consumption. The difference in energy performance was minimal compared to the savings in embodied emissions for the building life cycle carbon footprint, which showed a 23.2% and 9.9% reduction in emissions for the hempcrete building with a 50-year lifespan. Due to the high moisture capacity of hempcrete, ignoring the moisture-dependency of thermal conductivity can result in underestimation of energy consumption. Moisture buffering had little effect on energy performance, however, it can greatly reduce condensation risk, thereby improving IAQ and durability. •Whole-building LCA and HAM simulation of hempcrete and conventional rainscreen buildings.•Difference in operational GWP is minimal compared to embodied GWP savings.•Solar heat gain is reduced for the hempcrete building.•Improved indoor temperature and humidity modulation and condensation resistance for the hempcrete building.•Inclusion of moisture and thermal buffering effects important for accurate results.
ISSN:0360-1323
1873-684X
DOI:10.1016/j.buildenv.2021.108377