Life cycle energy analysis of residential wooden buildings versus concrete and steel buildings: A review

Schenk, Daniela; Amiri, Ali

doi:10.3389/fbuil.2022.975071

Cited by 6 publications

(4 citation statements)

References 75 publications

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“…Figures [13][14][15][16] show the detailed relative humidity (RH) distribution in the analyzed walls. Figures 13 and 14 present the RH distribution in the winter time (end of February) both for dry and wet conditions.…”

Section: Relative Humidity Distributionmentioning

confidence: 99%

“…One of the alternative, more environmentally sustainable substitutes for industrially produced load-bearing materials is structural timber. According to research conducted by Schenek and Amiri [15], buildings constructed with timber elements, depending on the type of technology used, exhibit a 28-47% lower carbon footprint compared to buildings constructed with traditional materials [15]. Furthermore, the dismantling processes of timber-framed buildings require approximately 50% less energy input compared to buildings made from traditional materials [15].…”

Section: Introductionmentioning

confidence: 99%

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Practical Use of Materials of Natural Origin as Loose-Fill Insulations in Open-Diffusion Constructions—Observation and Numerical Simulation

Kosiński,

Patyna

2024

Sustainability

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The increasing requirements concerning the consideration of the environmental impact of building materials, along with the simultaneous preservation and enhancement of building thermal parameters, have led to a surge in interest in insulations based on organic or recycled materials. Despite the growing interest in these materials, there remains a scarcity of scientific studies regarding their hygrothermal properties. Within the scope of the research described in the text, the insulation properties of loose-fill materials (hemp shives, cellulose fibers, loose wood wool, and mineral wool as a reference) in wooden frame walls were analyzed. The authors simulated walls with the same U value filled with these materials using Delphin 6.1 software. The simulation time was 3 years, considering the appropriate climatic conditions of Olsztyn and different microclimatic conditions inside the rooms. Insulations made of natural organic can absorb and reveal moisture to the internal environment, while mineral wool transports the moisture to the outside, which may cause condensation problems. Insulations made of hemp shives or wood wool do not increase the level of accumulated moisture over time, which results in thermal stability. In contrast, cellulose and mineral wool store more moisture, which in wet conditions increases the heat flux by 6.9% and 5.2%, respectively.

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Section: Relative Humidity Distributionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Practical Use of Materials of Natural Origin as Loose-Fill Insulations in Open-Diffusion Constructions—Observation and Numerical Simulation

Kosiński,

Patyna

2024

Sustainability

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“…Previous studies have found that residential timber buildings with one up to twelve stories could reduce the amount of embodied energy by 28%-47% in comparison to concrete and steel buildings (Schenk and Amiri, 2022). Additionally, another study estimated a reduction in energy consumption by 25% for a 8-story residential timber building compared to a concrete building (Chen et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Future buildings as carbon sinks: Comparative analysis of timber-based building typologies regarding their carbon emissions and storage

Dzhurko,

Haacke,

Haberbosch

et al. 2024

Front. Built Environ.

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The building and construction sector is responsible for a large share of carbon emissions resulting in the need to reduce them to mitigate climate change. Timber construction methods promise to lower emissions combined with biogenic carbon storage in the built environment. While there are several studies comparing the emissions of mineral-based and timber-based buildings, a consistent comparison of different timber-based building assemblies is still missing. This study compares carbon emissions from material production and carbon storage capabilities of four timber-based and two brick and reinforced concrete building assemblies. These assemblies were designed for a residential multi-storey building in Berlin, Germany. To compare and rank the carbon impacts of these assemblies we introduce a carbon storage-to-emission ratio. The calculations were performed using a Carbon Cycle Assessment Model implementation in Python. The results indicate an average reduction in carbon emissions of timber-based building assemblies by 32.6% to “Brick” and 40.4% to “Reinforced Concrete”, respectively. Across the timber-based building assemblies, the carbon emissions range between 85 t and 115 t, leading to an average of 105 t per building. Pronounced differences were observed in carbon storage, with the “Dowel Laminated Timber” building assembly storing more than three times the amount of carbon compared to “Light Weight Timber” assembly. To further reduce emissions from buildings and the construction sector and potentially enhance urban carbon storage, “Glue Laminated Timber” and “Dowel Laminated Timber” building assemblies were identified as the most promising.

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“…Norman et al studied the energy use and greenhouse gas emissions of highly and lowpopulated buildings to demonstrate the effects of urban density [14]. Schenk et al compared the ecological impacts of wooden buildings versus concrete and steel-framed buildings utilizing the LCA [15]. Furthermore, various other types of buildings were also analyzed using LCA [16].…”

Section: Introductionmentioning

confidence: 99%

BIM- and GIS-Based Life-Cycle-Assessment Framework for Enhancing Eco Efficiency and Sustainability in the Construction Sector

Zubair,

Ali,

Khan

et al. 2024

Buildings

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The world is progressing towards sustainable, eco-friendly, recyclable materials to enhance the circular economy and mitigate the issues of carbon footprint, overburdened landfills, and waste of natural resources. As increasing greenhouse gas (GHG) emissions are a major contributor towards climate change and given that the construction industry is one of the major producers of GHG emissions, it is crucial to meticulously quantify and lower its emissions, especially in the context of developing countries. This research presents a novel framework by combining advanced tools i.e., building information modeling (BIM), life-cycle assessment (LCA), geographic information systems (GISs), and quantification of embodied emissions to optimize construction’s design, material-selection, operations, maintenance, and waste-management processes. The effectiveness of the proposed approach has been demonstrated with the help of a real-world case study in Islamabad, Pakistan. A building model has been generated using BIM, and a comprehensive LCA has been conducted. Additionally, GIS tools have been utilized to identify the locations and accessibility of available-waste-management facilities. Based on this data, embodied emissions related to handling and transportation of waste material to disposal facilities have been computed using mathematical analyses. Furthermore, targeted mitigation strategies have been proposed and an optimized route has been designed using GIS-based route-optimization tools along the suggested facility centers in the Islamabad region. The case study has been reassessed with alleviation strategies, and the results show that 29.35% of the materialization stage, 16.04% of the operational stage, and 21.14% of the end-of-life-phase GHG emissions can be effectively reduced. Hence, pre-evaluating the environmental degradation caused by construction projects throughout their life cycle might offer an opportunity to comprehend and reduce prospective environmental impacts.

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Life cycle energy analysis of residential wooden buildings versus concrete and steel buildings: A review

Cited by 6 publications

References 75 publications

Practical Use of Materials of Natural Origin as Loose-Fill Insulations in Open-Diffusion Constructions—Observation and Numerical Simulation

Practical Use of Materials of Natural Origin as Loose-Fill Insulations in Open-Diffusion Constructions—Observation and Numerical Simulation

Future buildings as carbon sinks: Comparative analysis of timber-based building typologies regarding their carbon emissions and storage

BIM- and GIS-Based Life-Cycle-Assessment Framework for Enhancing Eco Efficiency and Sustainability in the Construction Sector

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