Cork thermal insulation

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Cork thermal insulation refers to the use of cork as a material to provide thermal insulation against heat transfer. Cork is suitable as thermal insulator, as it is characterized by lightness, elasticity, impermeability, and fire resistance. In construction, cork can be applied in various construction elements like floors, walls, roofs, and lofts to reduce the need for heating or cooling and enhance energy efficiency. Studies indicate that cork's thermal insulation performance remains unaffected by moisture absorption during rainy seasons, making it suitable for diverse climates. Additionally, research on cork-based composites, such as cork-gypsum structures, suggests a substantial improvement in energy efficiency for buildings.

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Cork

Cork is a lightweight, reusable, and biodegradable material that is harvested every 9–12 years from the bark of the cork oak (Quercus Suber L.). It has a homogeneous cell structure with thin, regularly arranged cell walls without intercellular spaces. North Africa, as well as parts of Portugal, Spain, and Italy, are home to the cork oak. Cork production in the world is expected to be 201,428 tonnes per year, with approximately 2139942 ha of cork forests. [1]

Details of cork thermal insulation

Due to its combination of characteristics of lightness, elasticity, impermeability, insulation, wear resistance, fire retardant qualities, hypoallergenic properties, and mould resistance, cork is a material suitable for a variety of construction needs. [2] It has a wide range of uses in construction industry, including floor and wall coverings, loft insulation, floor insulation, and roof insulation. Cork used for thermal insulation is usually made from cork oak or recycled cork. It is then either used in bulk or agglomerated in panels, usually as expanded cork. Research on cork is active. It includes various aspects of the material's characterisation, distribution, and application. Several research studies have evaluated the effects of using cork oak materials as thermal insulation in buildings. The thermal conductivity of these materials ranges from 0.036 to 0.065 W m−1 K−1, the density varies from 65 to 240 kg/m3, while the specific heat ranges from 350 to 3370. [3] [4] [5] [6] [7] [8]

With a water vapour diffusion resistance factor of 5–54.61, [9] [10] cork materials have good hydric properties for moisture insulation. Fino et al. [11] investigated the thermal insulation of walls covered with medium density expanded cork panes. To determine the impact of moisture on heat transfer through the cork wall, they conducted a comparative simulation of the insulation's behaviour in winter and summer conditions on the one side, and in dry and wet conditions on the other. The findings clearly demonstrated that moisture absorption during the rainy season is confined to the surface layers and has no effect on the cork's thermal insulation performance. Other research has focused on cork-based composites. The insulation used in the studies by Cherki et al. [12] and Monir et al., [13] is a cork-gypsum composite structure. Its usage would help to improve energy efficiency of buildings. According to this analysis, integrating cork crushes into the gypsum structure decreases the effective thermal conductivity of the latter by more than 70%. Indeed, gypsum has a thermal conductivity of about 0.406 W m−1 K−1 while the average thermal conductivity of the composite is about 0.11 W m−1 K−1.

Cork cement

Boussetoua et al. [14] developed a new insulating material using cork aggregates and cement. Natural cork aggregates, sand, cement, and water are mixed together to prepare the samples. Different cork-to-sand ratios were considered. The findings indicate that increasing the amount of cork aggregate increases moisture retention, with water buffer values ranging from 0.39 to 1.2 g/(m2.%HR) and water vapour permeability ranging from 2.7 × 10−12 to 21.4 × 10−12 kg/(m s Pa) as density decreases. Cork concrete can be used as a thermal insulator, according to these reports.

Efficiency of cork thermal insulation

The thermal efficiency and hygrothermal behaviour of timber frame walls with various external insulation layers were studied by Fu et al. [15] They observed that expanded cork panels provide better hygrothermal performance and building comfort than an anti-corrosion pine board. Barreca et al. [16] used cork residues and giant reed for panels in buildings in the Mediterranean region. The energy saved by using agglomerated cork walls for the envelope is more than 75% of the energy spent for the construction with brick walls. Not only is there a financial advantage, but there is also an environmental benefit. Indeed, the estimated annual production of carbon dioxide for heating and cooling of the various houses studied was estimated to be 2517 kg for brick walls, 623 kg for agglomerated cork walls, and 1905 kg for giant reed walls. In addition, Maalouf et al. [17] carried out a one-year hygrothermal simulation of a room for the weather conditions of Constantine in Algeria. According to preliminary findings, cork concrete can reduce energy consumption by about 29% as compared to hollow brick construction. The consideration of Moisture transfer increases energy consumption marginally in the winter due to desorption phenomenon and decreases cooling energy in the summer. El Wardi et al. [18] investigated a new sandwich material using a clay-cork composite as a base material with a protective layer of plaster and cement mortar. Simulations on a small model house in the village of Bensmim in Morocco showed better energy and environmental performance with sandwich panel walls than with conventional hollow earth bricks or Bensmim clay bricks.

Related Research Articles

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Thermal insulation is the reduction of heat transfer between objects in thermal contact or in range of radiative influence. Thermal insulation can be achieved with specially engineered methods or processes, as well as with suitable object shapes and materials.

<span class="mw-page-title-main">Engineered wood</span> Range of derivative wood products engineered for uniform and predictable structural performance

Engineered wood, also called mass timber, composite wood, human-made wood, or manufactured board, includes a range of derivative wood products which are manufactured by binding or fixing the strands, particles, fibres, or veneers or boards of wood, together with adhesives, or other methods of fixation to form composite material. The panels vary in size but can range upwards of 64 by 8 feet and in the case of cross-laminated timber (CLT) can be of any thickness from a few inches to 16 inches (410 mm) or more. These products are engineered to precise design specifications, which are tested to meet national or international standards and provide uniformity and predictability in their structural performance. Engineered wood products are used in a variety of applications, from home construction to commercial buildings to industrial products. The products can be used for joists and beams that replace steel in many building projects. The term mass timber describes a group of building materials that can replace concrete assemblies.

<span class="mw-page-title-main">Straw-bale construction</span> Building method that uses bales of straw

Straw-bale construction is a building method that uses bales of straw as structural elements, building insulation, or both. This construction method is commonly used in natural building or "brown" construction projects. Research has shown that straw-bale construction is a sustainable method for building, from the standpoint of both materials and energy needed for heating and cooling.

<span class="mw-page-title-main">Building material</span> Material which is used for construction purposes

Building material is material used for construction. Many naturally occurring substances, such as clay, rocks, sand, wood, and even twigs and leaves, have been used to construct buildings. Apart from naturally occurring materials, many man-made products are in use, some more and some less synthetic. The manufacturing of building materials is an established industry in many countries and the use of these materials is typically segmented into specific specialty trades, such as carpentry, insulation, plumbing, and roofing work. They provide the make-up of habitats and structures including homes.

<span class="mw-page-title-main">Syntactic foam</span> Composite material filled with low-density spheres

Syntactic foams are composite materials synthesized by filling a metal, polymer, cementitious or ceramic matrix with hollow spheres called microballoons or cenospheres or non-hollow spheres as aggregates. In this context, "syntactic" means "put together." The presence of hollow particles results in lower density, higher specific strength, lower coefficient of thermal expansion, and, in some cases, radar or sonar transparency.

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<span class="mw-page-title-main">Vapor barrier</span> Damp proofing material in sheet form

A vapor barrier is any material used for damp proofing, typically a plastic or foil sheet, that resists diffusion of moisture through the wall, floor, ceiling, or roof assemblies of buildings and of packaging to prevent interstitial condensation. Technically, many of these materials are only vapor retarders as they have varying degrees of permeability.

A building envelope or building enclosure is the physical separator between the conditioned and unconditioned environment of a building, including the resistance to air, water, heat, light, and noise transfer.

<span class="mw-page-title-main">Building insulation</span> Material to reduce heat transfer in structures

Building insulation is material used in a building to reduce the flow of thermal energy. While the majority of insulation in buildings is for thermal purposes, the term also applies to acoustic insulation, fire insulation, and impact insulation. Often an insulation material will be chosen for its ability to perform several of these functions at once.

<span class="mw-page-title-main">Building insulation material</span>

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<span class="mw-page-title-main">Thermal bridge</span>

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<span class="mw-page-title-main">Cellulose insulation</span>

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<span class="mw-page-title-main">Rigid panel</span>

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<span class="mw-page-title-main">Cross-laminated timber</span> Wood panel product made from solid-sawn lumber

Cross-laminated timber (CLT) is a subcategory of engineered wood with panel product made from gluing together at least three layers of solid-sawn lumber. Each layer of boards is usually oriented perpendicular to adjacent layers and glued on the wide faces of each board, usually in a symmetric way so that the outer layers have the same orientation. An odd number of layers is most common, but there are configurations with even numbers as well. Regular timber is an anisotropic material, meaning that the physical properties change depending on the direction at which the force is applied. By gluing layers of wood at right angles, the panel is able to achieve better structural rigidity in both directions. It is similar to plywood but with distinctively thicker laminations.

<span class="mw-page-title-main">Hempcrete</span> Biocomposite material used for construction and insulation

Hempcrete or hemplime is biocomposite material, a mixture of hemp hurds (shives) and lime, sand, or pozzolans, which is used as a material for construction and insulation. It is marketed under names like Hempcrete, Canobiote, Canosmose, Isochanvre and IsoHemp. Hempcrete is easier to work with than traditional lime mixes and acts as an insulator and moisture regulator. It lacks the brittleness of concrete and consequently does not need expansion joints.

<span class="mw-page-title-main">Sandwich panel</span> Structure made of three layers

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Alternative natural materials are natural materials like rock or adobe that are not as commonly in use as materials such as wood or iron. Alternative natural materials have many practical uses in areas such as sustainable architecture and engineering. The main purpose of using such materials is to minimize the negative effects that our built environment can have on the planet while increasing the efficiency and adaptability of the structures.

Geopolymer bonded wood composite (GWC) are similar and a green alternatives to cement bonded wood composites. These products are composed of geopolymer binder, wood fibers/ wood particles. Depending on the wood and geopolymer ratio in the material, the properties of the wood-geopolymer composite material vary. The main functions of wood in the composite material are weight reduction, reduction of thermal conductivity and the fixture function whereas the main functions of geopolymer are bonding of wood particles, improvement of fire resistance, providing mechanical strength, improvement of humidity resistance and protection against fungal and insect damages.

Textile-reinforced mortars (TRM) (also known as fabric-reinforced cementitious mortars are composite materials used in structural strengthening of existing buildings, most notably in seismic retrofitting. The material consists of bidirectional orthogonal textiles made from knitted, woven or simply stitched rovings of high-strength fibres, embedded in a inorganic matrices. The textiles can also be made from natural fibres, e.g. hemp or flax.

References

Creative Commons by small.svg  This article incorporates text by S. Bourbia1 · H. Kazeoui · R. Belarbi available under the CC BY 4.0 license.

  1. Pacheco Menor, M.C., Serna Ros, P., Macías García, A., Arévalo Caballero, M.J.: Granulated cork with bark characterised as environment-friendly lightweight aggregate for cement based materials. J Clean Prod. 229, 358–373 (2019). https://doi.org/10.1016/j.jclepro.2019.04.154
  2. Knapic, S., Oliveira, V., Machado, J.S., Pereira, H., et al.: Cork as a building material: a review. Eur. J. Wood Prod. 74(6), 775–791 (2016). https://doi.org/10.1007/s00107-016-1076-4
  3. Limam, A., Zerizer, A., Quenard, D., Sallee, H., Chenak, A.: Experimental thermal characterization of bio-based materials (Aleppo Pine wood, cork and their composites) for building insulation. Energy Build 116, 89–95 (2016). https://doi.org/10.1016/j.enbuild.2016.01.007
  4. Simões, N., Fino, R., Tadeu, A., et al.: Uncoated medium density expanded cork boards for building façades and roofs: mechanical, hygrothermal and durability characterization. Constr Build Mater 200, 447–464 (2019). https://doi.org/10.1016/j.conbuildmat.2018.12.116
  5. Francesco, B., Fichera, C.R.: Thermal insulation performance assessment of agglomerated cork boards. Wood Fiber Sci 48(2), 96–103 (2016)
  6. Tedjditi, A.K., Ghomari, F., Taleb, O., Belarbi, R., Tarik Bouhraoua, R., et al.: Potential of using virgin cork as aggregates in development of new lightweight concrete. Constr Build Mater 265, 120734 (2020). https://doi.org/10.1016/j.conbuildmat.2020.120734
  7. Barreca, F., Martinez Gabarron, A., Flores Yepes, J.A., Pastor Pérez, J.J., et al.: Innovative use of giant reed and cork residues for panels of buildings in mediterranean area. Resour Conserv Recycl 140, 259–266 (2019). https://doi.org/10.1016/j.resconrec.2018.10.005
  8. Torres-Rivas, A., Pozo, C., Palumbo, M., Ewertowska, A., Jiménez, L., Boer, D., et al.: Systematic combination of insulation biomaterials to enhance energy and environmental efficiency in buildings. Constr Build Mater (2020). https://doi.org/10.1016/j.conbuildmat.2020.120973
  9. 2014-energivie-guide-des-materiaux-isolants_1478167535.pdf. consulted on: juill. 16, 2020. [En ligne]. Disponible sur: http://www.vegetal-e.com/fichiers/2014-energivie-guide-des-materiaux-isolants_1478167535.pdf.
  10. Simões, N., Fino, R., Tadeu, A., et al.: Uncoated medium density expanded cork boards for building façades and roofs: mechanical, hygrothermal and durability characterization. Constr Build Mater 200, 447–464 (2019). https://doi.org/10.1016/j.conbuildmat.2018.12.116
  11. Fino, R., Tadeu, A., Simões, N., et al.: Influence of a period of wet weather on the heat transfer across a wall covered with uncoated medium density expanded cork. Energy Build 165, 118–131 (2018). https://doi.org/10.1016/j.enbuild.2018.01.020
  12. Cherki, A., Remy, B., Khabbazi, A., Jannot, Y., Baillis, D., et al.: Experimental thermal properties characterization of insulating cork–gypsum composite. Constr Build Mater 54, 202–209 (2014). https://doi.org/10.1016/j.conbuildmat.2013.12.076
  13. Mounir, S., Maaloufa, Y., Bakrcherki, A., Khabbazi, A., et al.: Thermal properties of the composite material clay/granular cork. Constr Build Mater 70, 183–190 (2014). https://doi.org/10.1016/j.conbuildmat.2014.07.108
  14. Boussetoua, H.: Caractérisation mécanique et hygrothermique du composite de béton de liège: étude expérimentale et de modélisation. Eur J Environ Civil Eng. 4(4). https://www.tandfonline.com/doi/abs/, https://doi.org/10.1080/19648189.2017.1397551. Accessed 12 Nov 2020
  15. Fu, H., Ding, Y., Li, M., Li, H., Huang, X., Wang, Z., et al.: Research on thermal performance and hygrothermal behavior of timber-framed walls with different external insulation layer: insulation cork board and anti-corrosion pine plate. J Build Eng 28, 101069 (2020). https://doi.org/10.1016/j.jobe.2019.101069
  16. Barreca, F., Martinez Gabarron, A., Flores Yepes, J.A., Pastor Pérez, J.J., et al.: Innovative use of giant reed and cork residues for panels of buildings in mediterranean area. Resour Conserv Recycl 140, 259–266 (2019). https://doi.org/10.1016/j.resconrec.2018.10.005
  17. Maalouf, C., Boussetoua, H., Moussa, T., Lachi, M., Belhamri, A.: Experimental and numerical investigation of the hygrothermal behaviour of cork concrete panels in north Algeria. (2015)
  18. El Wardi, F.Z., Khabbazi, A., Cherki, A.-B., Khaldoun, A.: Thermomechanical study of a sandwich material with ecological additives. Constr Build Mater 252, 119093 (2020). https://doi.org/10.1016/j.conbuildmat.2020.119093
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