On the possibility of using waste disposable gloves as recycled fibers in sustainable 3D concrete printing using different additives

Mousavi, Seyed Sina; Dehestani, Mehdi

doi:10.1038/s41598-023-37803-9

Cited by 7 publications

(2 citation statements)

References 46 publications

(51 reference statements)

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“…It is worth mentioning that the current promising numerical results obtained by the present study can be extended by future experimental works. For instance, more novel and sustainable concrete mixtures can be used instead of ultra-lightweight high-ductility cementitious composite [29,30]. Additionally, one of the main assumptions in the present study was the perfect interaction between concrete and steel layers in SCS composite with no slippage.…”

Section: Resultsmentioning

confidence: 94%

Effect of Ultra-Lightweight High-Ductility Cementitious Composite in Steel–Concrete–Steel (SCS) Plate to Mitigate Ship Slamming Loads

Mousavi

Khoob

2023

J. Compos. Sci.

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Bottom slamming loads cause considerable local damage to a ship’s body and reduce the ship’s structural performance against harsh sea waves. Although extensive studies have worked on stiffening elements to compensate for local damage due to slamming loads, few studies have concentrated on the ship’s body itself while using new generations of composite plates. Accordingly, a numerical study is conducted to determine the effect of using ultra-lightweight high-ductility cementitious composite in steel–concrete–steel (SCS) composite plate to mitigate bottom slamming loads. A large-scale model of the ship using SCS composite plates is modelled in Abaqus software, and fluid–solid (FSI) interaction is precisely modelled using the Coupled Eulerian–Lagrangian (CEL) method. The results show that using the CEL method with a large-scale 3D model precisely simulates FSI by providing a 6.5% deviation from the experimental result. Moreover, using an SCS plate when considering ultra-lightweight high-ductility cementitious composite results in a considerable reduction (around 95%) in the maximum strain of the ship body and, accordingly, reduces local damage so that, although about 22% of the strain of the outer layer is transferred to the inner part of the ship body containing only steel plate, almost 0% stress transfer is observed for the SCS-based ship’s structure.

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Section: Resultsmentioning

confidence: 94%

Effect of Ultra-Lightweight High-Ductility Cementitious Composite in Steel–Concrete–Steel (SCS) Plate to Mitigate Ship Slamming Loads

Mousavi

Khoob

2023

J. Compos. Sci.

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“…The abundant availability of industrial solid waste feedstocks and negligible embodied carbon has rendered geopolymer and alkali-activated materials the most extensively deployed alternative binders for large-scale 3D printing applications . However, concerns exist regarding potential environmental hazards posed by alkali-activators integral to geopolymer 3D printing concrete. , Efforts have also been explored incorporating recycled coarse aggregates , and recycled fibers, but displaying limited emission reduction.…”

Section: Introductionmentioning

confidence: 99%

CO₂-Driven Additive Manufacturing of Sustainable Steel Slag Mortars

Zhong,

Huang,

Liu

et al. 2024

ACS Sustainable Chem. Eng.

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This study presents a sustainable additive manufacturing approach for 3D printing in construction sector, leveraging steel slag as the primary carbonatable binder. Pintable steel slag mortars modified with xanthan gum (XG) as the viscosity modifying agents (VMA) demonstrate superior carbonation reactivity and strength development, thus regarded as the optimal formulation. After 24 h carbonation, the compressive strength of the printed samples generally exceeds 100 MPa and reaches up to 127.1 MPa, the characteristic interlayer bonding strength of the printed samples also reaches 5.5 MPa. Superior mechanical properties can be attributed to the densification and reinforcement mechanisms from the magnesium calcite products. Specifically, the larger magnesium calcite crystals intergrow to densify the matrix, while the tiny crystallites deposit on internal pore walls, repairing these defects. The carbonated printed samples exhibit typical mechanical property anisotropy which, associated with deposition molding process, is further amplified by heterogeneity in the carbonation reaction. Low carbon steel slag feedstock and CO 2 capture from carbonation curing achieves net CO 2 sequestration for the steel slag 3D printing mortar across the integrated manufacturing cycle, with a quantified carbon footprint of −86.77 kg CO 2 /m 3 .

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Utilization of laboratory glove waste for fuel production through pyrolysis-hydrocracking consecutive process catalyzed by sulfated Indonesian natural zeolite

Wangsa,

Saviola,

Wijaya

et al. 2024

Reac Kinet Mech Cat

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On the possibility of using waste disposable gloves as recycled fibers in sustainable 3D concrete printing using different additives

Cited by 7 publications

References 46 publications

Effect of Ultra-Lightweight High-Ductility Cementitious Composite in Steel–Concrete–Steel (SCS) Plate to Mitigate Ship Slamming Loads

Effect of Ultra-Lightweight High-Ductility Cementitious Composite in Steel–Concrete–Steel (SCS) Plate to Mitigate Ship Slamming Loads

CO₂-Driven Additive Manufacturing of Sustainable Steel Slag Mortars

Utilization of laboratory glove waste for fuel production through pyrolysis-hydrocracking consecutive process catalyzed by sulfated Indonesian natural zeolite

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On the possibility of using waste disposable gloves as recycled fibers in sustainable 3D concrete printing using different additives

Cited by 7 publications

References 46 publications

Effect of Ultra-Lightweight High-Ductility Cementitious Composite in Steel–Concrete–Steel (SCS) Plate to Mitigate Ship Slamming Loads

Effect of Ultra-Lightweight High-Ductility Cementitious Composite in Steel–Concrete–Steel (SCS) Plate to Mitigate Ship Slamming Loads

CO2-Driven Additive Manufacturing of Sustainable Steel Slag Mortars

Utilization of laboratory glove waste for fuel production through pyrolysis-hydrocracking consecutive process catalyzed by sulfated Indonesian natural zeolite

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Product

Resources

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CO₂-Driven Additive Manufacturing of Sustainable Steel Slag Mortars