A Comprehensive Review on Construction Applications and Life Cycle Sustainability of Natural Fiber Biocomposites

Ahmad, Hammad; Chhipi‐Shrestha, Gyan; Hewage, Kasun; Sadiq, Rehan

doi:10.3390/su142315905

Cited by 32 publications

(17 citation statements)

References 145 publications

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“…Recently, scholars have researched the refinement of bio-based building materials, including straw bales [62]. Based on the research, quick-growing bio-materials show greater potential as carbon sinks due to their shorter rotation period, offering a greater capacity for carbon sequestration (Figure 5) [63]. Crop cycles of wheat and rice span less than a year, making them promising bio-based building materials.…”

Section: Reducing Carbon Emissionsmentioning

confidence: 99%

Promoting Circular Economy of the Building Industry by the Use of Straw Bales: A Review

Li,

Guo,

et al. 2024

Buildings

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Over the past decade, the concept of a circular economy has increasingly gained attention as a framework for guiding businesses and policymakers. Given its significant environmental impact, the building industry plays a pivotal role in the transition toward a circular economy. To address this, our review proposes a bio-based building material, specifically straw bale, which elaborates on the circularity of bio-based buildings based on the 3R principles of a circular economy: reduce, reuse, and recycle. In terms of the “reduce” principle, straw-bale buildings can reduce construction waste, the environmental impact, energy requirements, and carbon emissions. Regarding the “reuse” principle, straw-bale buildings utilize agricultural waste resources and are easily disassembled due to their prefabrication. As for the “recycle” principle, straw-bale buildings can undergo physical, biological, and biochemical conversion processes (thermochemical conversion), yielding both wooden composite boards and potential biogas and biomass fuels for electricity and heating. This study evaluates the contribution of straw packaging construction and the use of straw as a raw material, using the 3R principles to determine future research opportunities for the construction industry to achieve a circular economy. The results of this study offer circular economy solutions and interdisciplinary research insights for researchers and practitioners interested in the building environment.

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Section: Reducing Carbon Emissionsmentioning

confidence: 99%

Promoting Circular Economy of the Building Industry by the Use of Straw Bales: A Review

Li,

Guo,

et al. 2024

Buildings

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“…Similarly, Gupta et al [151] introduced green tags that be assigned to explicit materials by taking into account various factors such as the route towards the end of the material's life cycle and green manufacturing. Likewise, Ahmad et al [152] analyzed life cycle assessment with natural fibre and synthetic fibre and found that biofibre saves 55% energy when compared with synthetic materials. As a result, plantbased bio-fibre processing has an environmental footprint that must be quantified, critical environmental aspects identified, and systems optimized so that overall impacts can be reduced, as well as the environmental impact of anticipated improvements in the supply chain and manufacturing processes.…”

Section: Crashworthiness Performance Of Natural Fibrementioning

confidence: 99%

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Gurupranes¹,

Rajendran²,

Gokulkumar

et al. 2023

International Journal of Polymer Science

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Various environmental concerns motivate scientists and researchers to look out for unique new materials in science and technology. In order to address the demand for polymeric materials with partial biodegradability, the usage of lignocellulosic fibre in the polymer matrix has risen. Lignocellulosic fibres are a cheap, easily renewable resource that is readily available in all regions. Cellulosic plant fibres also have a plethora of possibilities for use in polymer reinforcement because of their properties. Many researchers put their effort into developing a natural polymer with better mechanical properties and thermal stability using nanotechnology and the use of natural polymers to make its composites with lignocellulosic fibres. This study provides a review of the biodegradable composite market, processing methods, matrix-reinforcement phases, morphology, and characteristic improvements. In addition, it provides a concise summary of the findings of significant research on natural fibre polymer composites (NFRCs) that have been published. Indeed, a noticeably brief discussion is provided on the significant issues faced during composite extraction as well as the challenges encountered during the machining. Recent developments in the study of lignocellulosic fibre composites or NFRCs have demonstrated their enormous potential as structural elements in vehicles, aerospace structures, buildings, ballistics, soundproofing, and other structures.

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“…In this way, biocomposites serve these purposes, as they present attractive characteristics such as: biodegradability, reduced costs, and wide availability and/or lower energy demand in their production, making them capable of competing with traditional materials existing in the current market. This type of materials can find application in various sectors, such as automotive, marine, aerospace, structural applications, infrastructure, packaging, and electronics [ 1 , 2 , 3 , 4 , 5 , 6 ].…”

Section: Introductionmentioning

confidence: 99%

Viability Study of Serra da Estrela Dog Wool to Produce Green Composites

Gomes,

Fiadeiro,

Vieira

et al. 2024

Polymers

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The environmental emergency has alerted consumers and industries to choose products derived from renewable sources over petroleum derivatives. Natural fibers of plant origin for reinforcing composite materials dominate the field of research aiming to replace synthetic fibers. The field of application of green dog wool composite materials needs to be reinforced and proven, as the industry is looking for more sustainable solutions and on the other hand this type of raw material (pet grooming waste) tends to grow. Hence, in the present work, the feasibility of applying natural fibers of dog origin (mainly composed by keratin) in green composites was studied. The green composites were developed using chemically treated dog wool of the breed Serra da Estrela (with NaOH and PVA) as reinforcement and a green epoxy resin as a matrix. The chemical treatments aimed to improve adhesion between fibers and matrix. The fibers’ composition was determined using X-ray Diffraction (X-RD). Their morphology was determined using a scanning electron microscope (SEM). The wettability of the fiber was also evaluated qualitatively by analyzing drops of resin placed on the fibers treated with the different treatments. The mechanical properties of the composites were also studied through mechanical tensile, flexural, and relaxation tests. Overall, the best results were obtained for the dog wool fibers without treatment. The tensile and flexural strength of this biocomposite were 11 MPa and 26.8 MPa, respectively, while the tensile and flexural elastic modulus were 555 MPa and 1100 MPa, respectively. It was also possible to verify that the PVA treatment caused degradation of the fiber, resulting in a decrease in mechanical tensile strength of approximately 42.7%, 59.7% in flexural strength and approximately 59% of the stress after 120 min of relaxation when compared to fiber made from untreated dog wool. On the other hand, the NaOH treatment worked as a fiber wash process, removing waxes and fats naturally present on the fiber surface.

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A Comprehensive Review on Construction Applications and Life Cycle Sustainability of Natural Fiber Biocomposites

Cited by 32 publications

References 145 publications

Promoting Circular Economy of the Building Industry by the Use of Straw Bales: A Review

Promoting Circular Economy of the Building Industry by the Use of Straw Bales: A Review

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Viability Study of Serra da Estrela Dog Wool to Produce Green Composites

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