Compatibility of vegetable fibers with Portland cement and its relationship with the physical properties

Marques, Maria Lidiane; Luzardo, Francisco Heriberto Martínez; Velasco, Fermín García; González, Luis Nieto; Silva, Everton J. da; Lima, Wellington G. de

doi:10.1590/1807-1929/agriambi.v20n5p466-472

Cited by 16 publications

(16 citation statements)

References 20 publications

(27 reference statements)

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“…Previous research to estimate the compatibility or inhibitory index of a mixture of cement with lignocellulosic biomass was carried out using the approach of Hofstrand, Moslemi, and Garcia (1984). Some lignocellulosic biomass used in the measurement of the inhibitory index includes Chinese fir and poplar (Wang & Yu, 2012), vegetable residues (Marques et al, 2016), and eight types of hardwood residues from Amazonia Brasil (Castro et al, 2018). This study aimed to determine the compatibility between cement with four tropical wood and sago trunks and to determine the effect of the catalyst MgCl 2 at various levels to its compatibility (inhibition index value).…”

Section: Introduction Imentioning

confidence: 99%

Compatibility of Four Tropical Wood Species and Sago Stem to Cement and Properties of Mangium Cement Bonded Particleboard

Hermawan¹,

Budiman²,

Siruru³

et al. 2020

J. penelit. has. kehutan

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The quality of the cement board depends on the compatibility between cement and particles from lignocellulosic biomass. The purpose of this study was to determine the compatibility between cement and particles from four tropical wood namely mangium (Acacia mangium Willd), teak (Tectona grandis Linn. F.), gelam (Melaleuca leucadendron (L.), dadap (Erythrina variegata L.), and sago stem (Metroxylon sago Rottb.), and to determine the physical and mechanical properties of the mangium cement board produced by adding magnesium chloride (MgCl 2) as an accelerator. This research was conducted in two steps. The first step consisted of measuring the hydration temperature of a mixture of cement with particles from the four wood species and sago stems by adding magnesium chloride (MgCl 2), with variations of 0%, 2.5%, 5%, and 7.5% based on the cement weight. Two types of mixtures from the first step were then used in the second step, namely the manufacture of cement board. The cement board was made using a weight ratio of mangium particles:cement:water of 1:2.7:1.35. The board is made with a target density of 1.2 g/cm 3. Physical and mechanical testing refers to the ISO 8335-1987 standard. The results of the hydration temperature showed that all of the mixtures were classified into "low inhibition", except for mixture between cement and mangium particles without a catalyst which was included in the classification of "moderate inhibition". While the results of cement board tests indicate that the cement boards made from mangium wood particles with 5% MgCl 2 addition had better properties compared to mangium cement boards without catalysts.

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Section: Introduction Imentioning

confidence: 99%

Compatibility of Four Tropical Wood Species and Sago Stem to Cement and Properties of Mangium Cement Bonded Particleboard

Hermawan¹,

Budiman²,

Siruru³

et al. 2020

J. penelit. has. kehutan

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“…Although it was used in the handicraft sector [20], Water Hyacinth Petiole (WHP) as a construction material has been studied since the 1980s, when plant fibres appeared as an alternative solution to asbestos [21,22]. In addition, it has been analysed as a reinforcement material in concrete, mortars, and cement pastes [23,24,25,26,27], geotextiles [28], soil [8,29,30], or plastic matrices [31,32]. However, its inefficient use in the sector is due to the lack of a complete understanding of the anatomy, structure, and chemical composition of WHP.…”

Section: Introductionmentioning

confidence: 99%

Microstructural and Thermo-Physical Characterization of a Water Hyacinth Petiole for Thermal Insulation Particle Board Manufacture

2019

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Water Hyacinth (Eichhornia crassipes) is a dangerous and invasive aquatic species, of which global concern has sharply risen due to its rapid growth. Despite ample research on its possible applications in the construction field, there are no clear references on the optimal use of the plant in finding the most efficient-use building material. In this paper, a microstructural and chemical characterization of the Water Hyacinth petiole was performed, in order to find the most efficient use as a construction material. Subsequently, two types of binder-less insulation panels were developed, with two types of particle size (pulp and staple). A physical, mechanical, and thermal characterization of the boards was performed. These results demonstrated that it is possible to manufacture self-supporting Water Hyacinth petiole panels without an artificial polymer matrix for thermal insulation. The boards showed good thermal conductivity values, ranging from 0.047–0.065 W/mK. In addition, clear differences were found in the properties of the boards, depending on the type of Water Hyacinth petiole particle size, due to the differences in the microstructure.

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“…In particular, manufacturers of fiber-reinforced cement (FRC) sheets were forced to shift from using asbestos to using other sources of fiber due to health concerns. Synthetic (PVA, glass, steel, carbon, kevlar, polypropylene) as well as natural fibers have been used as possible sources for nonasbestos FRC products (Marques et al 2016, Soydan et al 2018, Frazão et al 2018. Cellulose fibers have emerged as the major replacement material for reinforcing fiber cement composites due to their competitive cost, acceptable fiber properties, and relative energy-efficiency (Cheng et al 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Although use of asbestos fiber must continue for some time in some countries due to economic and political factors, there is a gap that will eventually need to be filled in developing countries when asbestos is replaced. Inorganic bonded fiber composites studies include alternative fiber sources such as OCC, bagasse, coir, bamboo, groundwood, wheat straw, babaçu fibers, plastic, sisal pulp, coconut (Cocos nucifera L.) and brown pulp (Almeida et al 2002, Abdel-Kader and Darweesh 2010, Araújo et al 2011, Ferraz et al 2011, Teixeira 2012, Marques et al 2016, Farrapo et al 2017.…”

Section: Introductionmentioning

confidence: 99%

Asbestos-free autoclaved wood fiber-cement sheets from recycled old corrugated containers and kraft pulp of Douglas fir: properties and scanning electron microscopy

Teixeira¹

2018

Maderas, Cienc. tecnol.

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This study was conducted in cooperation with a United States pulp and paper company targeting part of the pulp production as raw material for fiber-reinforced cement sheets manufacturing. Virgin kraft pulp of Douglas fir (Pseudotsuga menziesii) and recycled fiber of old corrugated containers were used in making wood fiber-cement flat sheets. The physical and mechanical properties of the sheets were compared with an available commercial product. Results showed that Douglas fir fiber is a potential choice as reinforcement for wood fiber-cement sheets, as this fiber type outperformed the commercial ones for most of the properties studied. The difference in kappa number from 25 to 35 did not have any effect on the properties of Douglas fir sheets. Even recycled old corrugated containers fiber provided sheets with some properties comparable to the commercial product. Scanning electron microscopy analysis showed that a dual mechanism of fiber breakage and pull out occurred at rupture.

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Compatibility of vegetable fibers with Portland cement and its relationship with the physical properties

Cited by 16 publications

References 20 publications

Compatibility of Four Tropical Wood Species and Sago Stem to Cement and Properties of Mangium Cement Bonded Particleboard

Compatibility of Four Tropical Wood Species and Sago Stem to Cement and Properties of Mangium Cement Bonded Particleboard

Microstructural and Thermo-Physical Characterization of a Water Hyacinth Petiole for Thermal Insulation Particle Board Manufacture

Asbestos-free autoclaved wood fiber-cement sheets from recycled old corrugated containers and kraft pulp of Douglas fir: properties and scanning electron microscopy

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