Thermophysical Properties of Larch Bark Composite Panels

L. Kristak; I. Ruziak; E.M. Tudor; M.C. Barbu; G. Kain; R. Reh

doi:10.3390/polym13142287

Thermophysical Properties of Larch Bark Composite Panels

L. Kristak
, I. Ruziak
, E.M. Tudor^*
, M.C. Barbu
, G. Kain
, R. Reh

^*Corresponding author for this work

Faculty of Wood Sciences and Technology, Technical University in Zvolen
Faculty of Furniture Design and Wood Engineering, Transilvania University of Brasov

Research output: Contribution to journal › Article › peer-review

Abstract

The effects of using 100% larch bark (Larix decidua Mill) as a raw material for composite boards on the thermophysical properties of this innovative material were investigated in this study. Panels made of larch bark with 4–11 mm and 10–30 mm particle size, with ground bark oriented parallel and perpendicular to the panel’s plane at densities varying from 350 to 700 kg/m3 and bonded with urea-formaldehyde adhesive were analyzed for thermal conductivity, thermal resistivity and specific heat capacity. It was determined that there was a highly significant influence of bulk density on the thermal conductivity of all the panels. With an increase in the particle size, both parallel and perpendicular to the panel´s plane direction, the thermal conductivity also increased. The decrease of thermal diffusivity was a consequence of the increasing particle size, mostly in the parallel orientation of the bark particles due to the different pore structures. The specific heat capacity is not statistically significantly dependent on the density, particle size, glue amount and particle orientation.

Original language	English
Journal	Polym.
Volume	13
Issue number	14
DOIs	https://doi.org/10.3390/polym13142287
Publication status	Published - 12 Jul 2021

Keywords

Ecofriendly composites
Insulation materials
Larch bark
Tannin-based adhesive
Thermophysical properties
Adhesives
Particle size
Pore structure
Specific heat
Urea
Urea formaldehyde resins
Bulk density
Composite boards
Composite panels
Innovative materials
Parallel orientation
Particle orientation
Plane directions
Urea formaldehyde
Thermal conductivity

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10.3390/polym13142287

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85110845923&doi=10.3390%2fpolym13142287&partnerID=40&md5=175a78e646345403297ce1eb43e1c316

Cite this

@article{419646cb436c439b90bced2e3505955c,

title = "Thermophysical Properties of Larch Bark Composite Panels",

abstract = "The effects of using 100\% larch bark (Larix decidua Mill) as a raw material for composite boards on the thermophysical properties of this innovative material were investigated in this study. Panels made of larch bark with 4–11 mm and 10–30 mm particle size, with ground bark oriented parallel and perpendicular to the panel{\textquoteright}s plane at densities varying from 350 to 700 kg/m3 and bonded with urea-formaldehyde adhesive were analyzed for thermal conductivity, thermal resistivity and specific heat capacity. It was determined that there was a highly significant influence of bulk density on the thermal conductivity of all the panels. With an increase in the particle size, both parallel and perpendicular to the panel´s plane direction, the thermal conductivity also increased. The decrease of thermal diffusivity was a consequence of the increasing particle size, mostly in the parallel orientation of the bark particles due to the different pore structures. The specific heat capacity is not statistically significantly dependent on the density, particle size, glue amount and particle orientation.",

keywords = "Ecofriendly composites, Insulation materials, Larch bark, Tannin-based adhesive, Thermophysical properties, Adhesives, Particle size, Pore structure, Specific heat, Urea, Urea formaldehyde resins, Bulk density, Composite boards, Composite panels, Innovative materials, Parallel orientation, Particle orientation, Plane directions, Urea formaldehyde, Thermal conductivity",

author = "L. Kristak and I. Ruziak and E.M. Tudor and M.C. Barbu and G. Kain and R. Reh",

note = "Cited By :17 Export Date: 14 December 2023 Correspondence Address: Tudor, E.M.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected] Funding details: Agent{\'u}ra na Podporu V{\'y}skumu a V{\'y}voja, APVV, APVV-18-0378, APVV-19-0269, VEGA1/0714/21, VEGA1/0717/19 Funding text 1: Author Contributions: Conceptualization, L.K., M.C.B. and G.K.; methodology, I.R.; validation, E.M.T., M.C.B. and G.K.; formal analysis, R.R.; investigation, I.R.; data curation, L.K.; writing—original draft preparation, L.K. and E.M.T.; writing—review and editing, E.M.T.; supervision, M.C.B. original draft preparation, L.K. and E.M.T.; writing—review and editing, E.M.T.; supervision, M.C.B. and R.R. All authors have read and agreed to the published version of the manuscript. Funding: This research received no external funding. Funding: This research received no external funding. Data Availability Statement: Not applicable. Data Availability Statement: Not applicable. Acknowledgments: This research was supported by the Slovak Research and Development Agency under contracts No. APVV-18-0378, APVV-19-0269, VEGA1/0717/19 and VEGA1/0714/21. under contracts No. APVV-18-0378, APVV-19-0269, VEGA1/0717/19 and VEGA1/0714/21. Funding text 2: under contracts No. ThisAPVV-18-0378,research wasAPVV-19-0269,supported byVEGA1/0717/19the Slovak Researchand VEGA1/0714/21. and Development Agency under contracts No. APVV-18-0378, APVV-19-0269, VEGA1/0717/19 and VEGA1/0714/21. References: (2018) European Commission Staff Working Document—Directive (EU) 2018/844 of the European Parliament and the Council of 30 May 2018 Amending Directive 2010/31/EU on the Energy Performance of Buildings and Directive 2012/27/EU on Energy Efficiency, , EC. European Commission: Brussels, Belgium; (2019) European Commission, Energy Strategy. Clean Energy for all Europeans Package, , EC. European Union: Brussels, Belgium, [CrossRef]; (1999) Agenda 21 on Sustainable Construction, p. 122. , CIB. Conseil International du Matiment: Rotterdam, The Netherlands; (2007) Buidlings and Climate Change: Status, Challenges and Opportunities, p. 87. , UNEP. United Nations Environment Programme: New York, NY, USA; Abubakar, M., Raji, A., Hassan, M., Comparative study of thermal insulation boards from leaf and bark fibres of camel{\textquoteright}s foot (Piliostigma thonningii L.) (2018) Niger. J. Technol, 37, p. 108. , [CrossRef]; Tangjuank, S., Kumfu, S., Particle Boards from Papyrus Fibers as Thermal Insulation (2011) J. Appl. Sci, 11, pp. 2640-2645. , [CrossRef]; Gounni, S., Mabrouk, M.T., Wazna, M.E., Kheiri, A., Alami, M.E., Bouari, A.E., Cherkaoui, O., Thermal and economic evalua-tion of new insulation materials for building envelope based on textile waste (2019) Appl. Therm. Eng, 149, pp. 475-483. , [CrossRef]; Bharadwaj, P., Jankovic, L., Self-Organised Approach to Designing Building Thermal Insulation (2020) Sustainability, 12, p. 5764. , [CrossRef]; Gaujena, B., Agapovs, V., Borodinecs, A., Strelets, K., Analysis of Thermal Parameters of Hemp Fiber Insulation (2020) Energies, 13, p. 6385. , [CrossRef]; (2019), http://ec.europa.eu/eurostat/statistics-explained/index.php/Energy\_consumption\_in\_households, Eurostat, Energy Consumption in Households (EU-28, 2017, Data). (accessed on 7 June 2021); (2019) ANNEX to the Communication from the Commission to the European Parliament, the Europe—An Council the European Economic and Social Committee and the Committee of the Regions, , EC/European Commission. The European Green Deal; European Commission: Brussels, Belgium; Havrysh, V., Kalinichenko, A., Brzozowska, A., Stebila, J., Agricultural Residue Management for Sustainable Power Generation: The Poland Case Study (2021) Appl. Sci, 11, p. 5907. , [CrossRef]; Havrysh, V., Kalinichenko, A., Brzozowska, A., Stebila, J., Life Cycle Energy Consumption and Carbon Dioxide Emissions of Agricultural Residue Feedstock for Bioenergy (2021) Appl. Sci, 11, p. 2009. , [CrossRef]; Branowski, B., Zab{\l}ocki, M., Sydor, M., The Material Indices Method in the Sustainable Engineering Design Process: A Review (2019) Sustainability, 11, p. 5465. , [CrossRef]; Anastaselos, D., Giama, E., Papadopoulos, A., An assessment tool for the energy, economic and environmental evaluation of thermal insulation solutions (2009) Energy Build, 41, pp. 1165-1171. , [CrossRef]; (2020) European Commission, Circular Economy Action Plan. For a Cleaner and More Competitive Europe; new\_circular\_economy\_action\_plan, , EC. European Commission: Brussels, Belgium; (2020) European Commission, Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions. Sustainable Europe Investment Plan. European Green Deal Investment Plan, , EC. European Commission: Brussels, Belgium; (2015) Chamber of Commerce Foundation. Achieving a Circular Economy: How the Private Sector is Reimaging the Future of Business, p. 76. , U.S. Chamber of Commerce Foundation. U.S. Chamber of Commerce Foundation: Washington DC, USA; Cetiner, I., Shea, A.D., Wood waste as an alternative thermal insulation for buildings (2018) Energy Build, 168, pp. 374-384. , [CrossRef]; Kania, G., Kwiecie{\'n}, K., Malinowski, M., Gliniak, M., Analyses of the Life Cycles and Social Costs of CO2 Emissions of Single Family Residential Buildings: A Case Study in Poland (2021) Sustainability, 13, p. 6164. , [CrossRef]; Vanova, R., Vlcko, M., Stefko, J., Life Cycle Impact Assessment of Load-Bearing Straw Bale Residential Building (2021) Materials, 14, p. 3064. , [CrossRef]; Mitterpach, J., Igaz, R., {\v S}tefko, J., Environmental evaluation of alternative wood-based external wall assembly (2020) Acta Fac. Xylol, 61, pp. 133-149; Asdrubali, F., Alessandro, F., Schiavoni, S., A review of unconventional sustainable building insulation materials (2015) Sustain. Mater. Technol, 4, pp. 1-17. , D [CrossRef]; Asdrubali, F., Ferracuti, B., Lombardi, L., Guattari, C., Evangelisti, L., Grazieschi, G., A review of structural, thermo-physical, acoustical, and environmental properties of wooden materials for building applications (2017) Build. Environ, 114, pp. 307-332. , [CrossRef]; Nov{\'a}k, I., Krupa, I., Sedlia{\v c}ik, J., {\v Z}igo, O., Jurkovi{\v c}, P., Matya{\v s}ovsk{\'y}, J., Investigation into mechanical, surface and adhesive properties of date palm wood-polyolefin micro composites (2020) Acta Fac. Xylol. Zvolen, 62, pp. 27-34; Fiorelli, J., Ramos, R.D., Sayama, J.T., Barrero, N.G., Palone, E.D.J.A., Particleboards with waste wood from reforestation (2014) Acta Sci. Technol, 36, p. 251. , [CrossRef]; Bekhta, P., Sedlia{\v c}ik, J., Ka{\v c}{\'i}k, F., Noshchenko, G., Kleinov{\'i}, A., Lignocellulosic waste fibers and their application as a component of urea-formaldehyde adhesive composition in the manufacture of plywood (2019) Eur. J. Wood Wood Prod, 77, pp. 495-508. , [CrossRef]; Souza, A.M., Nascimento, M.F., Almeida, D.H., Silva, D., Almeida, T.H., Christoforo, A.L., Lahr, F.A., Wood-based composite made of wood waste and epoxy based ink-waste as adhesive: A cleaner production alternative (2018) J. Clean. Prod, 193, pp. 549-562. , [CrossRef]; Antov, P., Mantanis, G.I., Savov, V., Development of Wood Composites from Recycled Fibres Bonded with Magnesium Lignosulfonate (2020) Forests, 11, p. 613. , [CrossRef]; Savov, V., Antov, P., Engineering the Properties of Eco-Friendly Medium Density Fibreboards Bonded with Lignosulfonate Adhesive (2020) Drv. Ind, 71, pp. 157-162. , [CrossRef]; Antov, P., Kri{\v s}t{\textquoteright}{\'a}k, L., R{\'e}h, R., Savov, V., Papadopoulos, A.N., Eco-Friendly Fiberboard Panels from Recycled Fibers Bonded with Calcium Lignosulfonate (2021) Polymers, 13, p. 639. , [CrossRef] [PubMed]; Madurwar, M.V., Ralegaonkar, R.V., Mandavgane, S.A., Application of agro-waste for sustainable construction materials: A review (2013) Constr. Build. Mater, 38, pp. 872-878. , [CrossRef]; Barbu, M.C., R{\'e}h, R., {\c C}avdar, A.D., Non-wood lignocellulosic composites. Chapter 8 (2014) Research Developments in Wood Engineering and Technology, pp. 281-319. , Aguilera, J.A., Davim, P., Eds.; IGI Global: Hershey, PA, USA; Santos, M.F.N., Battistelle, R.A.G., Bezerra, B.S., Varum, H.S.A., Comparative study of the life cycle assessment of particleboards made of residues from sugarcane bagasse (saccharum spp.) and pine wood shavings (Pinus elliottii) (2014) J. Clean. Prod, 64, pp. 345-355. , [CrossRef]; Dukarska, D., P{\c e}dzik, M., Rogozi{\'n}ska, W., Rogozi{\'n}ski, T., Czarnecki, R., Characteristics of straw particles of selected grain species purposed for the production of lignocellulose particleboards (2021) Part. Sci. Technol, 39, pp. 213-222. , [CrossRef]; Fiorelli, J., Galo, R.G., Castro, S.L., Belini, U.L., Lasso, P.R.O., Savastano, H., Multilayer particleboard produced with agroindustrial waste and amazonian vegetable fibres (2017) Waste Biomass, 8, pp. 1-11; Eschenhagen, A., Raj, M., Rodrigo, N., Zamora, A., Labonne, I., Evon, P., Walemane, H., Investigation of miscanthus and sun-flower stalk fiber-reinforced composites for insulation applications (2019) Adv. Civ. Eng, 2019, p. 9328087; Guna, V., Ilangovan, M., Hu, C., Venkatesh, K., Reddy, N., Valorization of sugarcane bagasse by developing completely biodegradable composites for industrial applications (2019) Ind. Crop. Prod, 131, pp. 25-31. , [CrossRef]; Busquets-Ferrer, M., Czabany, I., Vay, O., Gindl-Altmutter, W., Hansmann, C., Alkali-extracted tree bark for efficient bio-based thermal insulation (2021) Constr. Build. Mater, 271, p. 121577. , [CrossRef]; Xing, C., Zhang, S.Y., Deng, J., Wang, S., Investigation of the effects of bark fiber as core material and its resin content on three-layer MDF performance by response surface methodology (2007) Wood Sci. Technol, 41, pp. 585-595. , [CrossRef]; Kain, G., Tudor, E.M., Barbu, M.-C., Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species (2020) Polymers, 12, p. 2140. , [CrossRef]; Miles, P.D., Smith, W.B., (2009) Specific Gravity and Other Properties of Wood and Bark for 156 Tree Species Found in North America, 38, pp. 1-35. , USDA Forest Service: Madison, WI, USA; Pereira, H., The Rationale behind Cork Properties: A Review of Structure and Chemistry (2015) Bioresources, 10, pp. 6207-6229. , [CrossRef]; Nemli, G., Gezer, E., Yıldız, S., Temiz, A., Aydın, A., Evaluation of the mechanical, physical properties and decay resistance of particleboard made from particles impregnated with Pinus brutia bark extractives (2006) Bioresour. Technol, 97, pp. 2059-2064. , [CrossRef]; Kain, G., Lienbacher, B., Barbu, M.-C., Richter, K., Petutschnigg, A., Larch (Larix decidua) bark insulation board: Interactions of particle orientation, physical–mechanical and thermal properties (2018) Holz Roh Werkst, 76, pp. 489-498. , [CrossRef]; Fengel, D., Wegener, G., (2003) Wood: Chemistry, Ultrastructure, Reactions, p. 613. , Kessel Verlag: Remagen, Germany; Rowell, R., (2012) Handbook of Wood Cchemistry and Wood Composites, , 2nd ed.; CRC Press: Boca Raton, FL, USA; Barbu, M.C., Lohninger, Y., Hofmann, S., Kain, G., Petutschnigg, A., Tudor, E.M., Larch Bark as a Formaldehyde Scavenger in Thermal Insulation Panels (2020) Polymers, 12, p. 2632. , [CrossRef]; Tudor, E.M., Barbu, M.C., Petutschnigg, A., R{\'e}h, R., Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Analysis of Larch-Bark Capacity for Formaldehyde Removal in Wood Adhesives (2020) Int. J. Environ. Res. Public Health, 17, p. 764. , [CrossRef] [PubMed]; Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Igaz, R., Ru{\v z}iak, I., Applying the EDPS Method to the Research into Thermophysical Properties of Solid Wood of Coniferous Trees (2019) Adv. Mater. Sci. Eng, 2019, pp. 1-9. , [CrossRef]; Igaz, R., Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Ru{\v z}iak, I., Gajtanska, M., Ku{\v c}erka, M., Thermophysical Properties of OSB Boards versus Equilibrium Moisture Content (2017) Bioresources, 12, pp. 8106-8118; Suleiman, B.M., Larfeldt, J., Leckner, B., Gustavsson, M., Thermal conductivity and diffusivity of wood (1999) Wood Sci. Technol, 33, pp. 465-473. , [CrossRef]; Kain, G., Tudor, E.M., Dettendorfer, A., Barbu, M.C., Potenzial von Baumrinde fur den Einsatz als Schallabsorptionsmaterial (2020) Bauphysic, 42, pp. 124-130. , [CrossRef]; Gibson, L.J., Ashby, M.F., (1999) Cellular Solids: Structure and Properties, , Cambridge University Press: Cambridge, UK; Kain, G., Barbu, M.-C., Teischinger, A., Musso, M., Petutschnigg, A., Substantial Bark Use as Insulation Material (2012) For. Prod. J, 62, pp. 480-487. , [CrossRef]; Kain, G., Guttler, V., Barbu, M.C., Petutschnigg, A., Richter, K., Tondi, G., Density related properties of bark insulation boards bonded with tannin hexamine resin (2014) Eur. J. Wood Prod, 72, pp. 417-424. , [CrossRef]; Sonderegger, W., Niemz, P., Thermal and moisture flux in soft fibreboards (2012) Holz Roh Werkst, 70, pp. 25-35. , [CrossRef]; G{\"o}{\ss}wald, J., Barbu, M.-C., Petutschnigg, A., Tudor, E., Binderless Thermal Insulation Panels Made of Spruce Bark Fibres (2021) Polymers, 13, p. 1799. , [CrossRef]; Brombacher, V., Michel, F., Niemz, P., Volkmer, T., Untersuchungen zu Warmeleitfahigkeit und Feuchteverhalten von Holzfaserplatten und Materialkombinationen (2012) Bauphysic, 34, pp. 157-169. , [CrossRef]; Haupl, P., (2008) Bauphysik, p. 66. , Ernst and Sohn: Berlin, Germany; Schunk, C., Treml, S., Troger, F., Lose Dammstoffe aus Holz—Warmeleitfahighkeit von speziell hergestellten Frassspanen ausgewahlter Holzarten (2009) Eur. J. Wood Prod, 67, pp. 487-488. , [CrossRef]; Danihelova, A., Nemec, M., Gergel, T., Gejdos, M., Gordanova, J., Scesny, P., Usage of Recycled Technical Textiles as Thermal Insulation and an Acoustic Absorber (2019) Sustainability, 11, p. 2968. , [CrossRef]; Grohe, B., Heat conductivities of insulation mats based on water glass bonded non-textile hemp or flax fibers (2004) Holz Roh Werkstoff, 62, pp. 352-357. , [CrossRef]; Rebolledo, P., Clutier, A., Yemele, M.C., Effect of Density and Fiber Size on Porosity and Thermal Conductivity of Fiber-board Mats (2018) Fibers, 6, p. 81. , [CrossRef]; Bertolini, M.d.S., de Morais, A.G., Christoforo, A.L., Bertoli, S.R., dos Santos, W.N., Lahr, F.A.R., Acoustic absorption and thermal insulation of wood panels: Influence of porosity (2019) Bioresources, 14, pp. 3746-3757; Carson, J.K., Lovatt, S., Tanner, D.J., Cleland, A.C., Thermal conductivity bounds for isotropic, porous materials (2005) Int. J. Heat Mass Transf, 48, pp. 2150-2158. , [CrossRef]; Kain, G., Guttler, V., Lienbacher, B., Barbu, M.C., Petutschnigg, A., Richter, K., Effects of different flavonoid extracts in optimizing tanninglued bark insulation boards (2015) Wood Fiber. Sci, 47, pp. 258-269; Kain, G., Lienbacher, B., Barbu, M.-C., Plank, B., Richter, K., Petutschnigg, A., Evaluation of relationships between particle orientation and thermal conductivity in bark insulation board by means of CT and discrete modeling (2016) Case Stud. Nondestruct. Test. Eval, 6, pp. 21-29. , [CrossRef]; Sonderegger, W., Niemz, P., Thermal conductivity and water vapour transmission properties of wood-based materials (2009) Holz Roh Werkst, 67, pp. 313-321. , [CrossRef]; Jo{\v s}{\v c}{\'a}k, M., Sonderegger, W., Niemy PSchnider, T., Oppikofer, R., Lammar, L., Influence of the air cavities on thermal conductivity of selected wood-based materials and their application for building industry (2012) Bauphysik, 34, pp. 32-37. , [CrossRef]; Gupta, G., Yan, N., Feng, M.W., Effect of pressing temperature and particle size on bark board properties made from beetle-infested lodgepole pine (Pinus contorta) barks (2011) Forest Prod. J, 61, pp. 478-488. , [CrossRef]; Mahlia, T.M.I., Taufiq, B.N., Ismail Masjuki, H.H., Correlation between thermal conductivity and the thickness of selected in-sulation materials for building wall (2007) Energy Build, 39, pp. 182-187. , [CrossRef]; P{\'a}sztory, Z., Moh{\'a}csin{\'e}, I.R., B{\"o}rcs{\"o}k, Z., Investigation of thermal insulation panels made of black locust tree bark (2017) Constr. Build. Mater, 147, pp. 733-735. , [CrossRef]; Reifsnyder, W.E., Herrington, L.P., (1967) Thermophysical Properties of Bark of Shortleaf, Longleaf and Red Pine, 80. , Yale School of Forestry \& Environmental Studies Bulletin Series; Yale School of Forestry: New Haven, CT, USA; Kawasaki, T., Kawai, S., Thermal insulation properties of wood-based sandwich panel for use as structural insulated walls and floors (2006) J. Wood Sci, 52, pp. 75-83. , [CrossRef]; Harada, T., Hata, T., Ishihara, S., Thermal constants of wood during the heating process measured with the laser flash method (1998) J. Wood Sci, 44, pp. 425-431. , [CrossRef]; Rargland, K.W., Aerts, D.J., Baker, A.J., Properties of Wood for Comustion Analysis (1991) Bioresour. Technol, 37, pp. 161-168. , [CrossRef]; Simpson, W., Wolde, A.T., Physical properties and moisture relations of wood (1999) Wood Handbook: Wood as an Engineering Material, , USDA Forest Service: Madison, WI, USA; Koljo, B., Something about the heat phenomena of woods and trees (1950) Forstwiss. Cent, 69, pp. 538-551. , [CrossRef]; Gupta, M., Yang, J., Roy, C., Specific heat and thermal conductivity of softwood bark and softwood char particles (2003) Fuel, 82, pp. 919-927. , [CrossRef]; Koch, P., Specific Heat of Ovendry Spruce Pine Wood and Bark (1969) Wood Sci, 1, pp. 203-214; Aditya, L., Mahlia, T.M.I., Rismanchi, B., Ng, H., Hasan, M., Metselaar, H.S.C., Muraza, O., Aditiya, H., A review on insulation materials for energy conservation in buildings (2017) Renew. Sustain. Energy Rev, 73, pp. 1352-1365. , [CrossRef]; Sari, N.H., Wardana, I.N.G., Irawan, Y.S., Siswanto, E.P., Physical and Acoustical Properties of Corn Husk Fiber Panels (2016) Adv. Acoust. Vib, 2016, p. 5971814. , [CrossRef]; Saha, P., Manna, S., Chowdhury, R., Sen, R., Roy, D., Adhikari, B., Enhancement of tensile strength of lignocellulosic jute fibers by alkali-steam treatment (2010) Bioresour. Technol, 101, pp. 3182-3187. , [CrossRef]; Salit, M.S., Tropical Natural Fibres and Their Properties (2014) Tropical Natural Fibre Composites. Engineering Materials, pp. 15-38. , Springer: Singapore; Papadopoulos, A., State of the art in thermal insulation materials and aims for future developments (2005) Energy Build, 37, pp. 77-86. , [CrossRef]; Taghiyari, H., Militz, H., Antov, P., Papadopoulos, A., Effects of Wollastonite on Fire Properties of Particleboard Made from Wood and Chicken Feather Fibers (2021) Coatings, 11, p. 518. , [CrossRef]; Aristri, M., Lubis, M., Yadav, S., Antov, P., Papadopoulos, A., Pizzi, A., Fatriasari, W., Iswanto, A., Recent Developments in Lignin-and Tannin-Based Non-Isocyanate Polyurethane Resins for Wood Adhesives—A Review (2021) Appl. Sci, 11, p. 4242. , [CrossRef]; Papadopoulos, A., Advances in Wood Composites III (2021) Polymers, 13, p. 163. , [CrossRef]; Osvaldova, L.M., Markova, I., Jochim, S., Bares, J., Experimental Study of Straw-Based Eco-Panel Using a Small Ignition Initiator (2021) Polymers, 13, p. 1344. , [CrossRef] [PubMed]; Tudor, E.M., Scheriau, C., Barbu, M.C., R{\'e}h, R., Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Schnabel, T., Enhanced Resistance to Fire of the Bark-Based Panels Bonded with Clay (2020) Appl. Sci, 10, p. 5594. , [CrossRef]; Tudor, E.M., Dettendorfer, A., Kain, G., Barbu, M.C., R{\'e}h, R., Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Sound-Absorption Coefficient of Bark-Based Insulation Panels (2020) Polymers, 12, p. 1012. , [CrossRef]; Tudor, E., Kristak, L., Barbu, M., Gergel{\textquoteright}, T., N{\v e}mec, M., Kain, G., R{\'e}h, R., Acoustic Properties of Larch Bark Panels (2021) Forests, 12, p. 887. , [CrossRef]; R{\'e}h, R., Igaz, R., Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Ru{\v z}iak, I., Gajtanska, M., Bo{\v z}{\'i}kov{\'a}, M., Ku{\v c}erka, M., Functionality of Beech Bark in Adhesive Mixtures Used in Plywood and Its Effect on the Stability Associated with Material Systems (2019) Materials, 12, p. 1298. , [CrossRef]; Tudor, E.M., Zwickl Ch Eichinger Ch Petutschnigg, A., Barbu, M.C., Performance of softwood bark comminution technologies for determination of targeted particle size in further upcycling applications (2020) J. Cleaner Prod, 269, p. 122412. , [CrossRef]; R{\'e}h, R., Kri{\v s}t{\textquoteright}{\'a}k, L{\textquoteright}., Sedlia{\v c}ik, J., Bekhta, P., Bo{\v z}ikov{\'a}, M., Kunecov{\'a}, D., Voz{\'a}rov{\'a}, V., Savov, V., Utilization of Birch Bark as an Eco-Friendly Filler in Urea-Formaldehyde Adhesives for Plywood Manufacturing (2021) Polymers, 13, p. 511. , [CrossRef]; Pfundsteing, M.R., Gellert, M., Spitzner, H., Rudolphi, A., (2007) Insulation Materials: Basics, Materials, Applications, , Department for International Architecture Documentation Corporation: Munich, Germany; Moresova, M., Sedliacikova, M., Stefko, J., Bencikova, D., Perception of wooden houses in the Slovak Republic (2019) Acta Fac. Xylol. Zvolen, 61, pp. 121-135; Potk{\'a}ny, M., Gejdo{\v s}, M., Debn{\'a}r, M., Sustainable Innovation Approach for Wood Quality Evaluation in Green Business (2018) Sustainability, 10, p. 2984. , [CrossRef]",

year = "2021",

month = jul,

day = "12",

doi = "10.3390/polym13142287",

language = "English",

volume = "13",

journal = "Polym.",

issn = "2073-4360",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "14",

}

TY - JOUR

T1 - Thermophysical Properties of Larch Bark Composite Panels

AU - Kristak, L.

AU - Ruziak, I.

AU - Tudor, E.M.

AU - Barbu, M.C.

AU - Kain, G.

AU - Reh, R.

N1 - Cited By :17 Export Date: 14 December 2023 Correspondence Address: Tudor, E.M.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected] Funding details: Agentúra na Podporu Výskumu a Vývoja, APVV, APVV-18-0378, APVV-19-0269, VEGA1/0714/21, VEGA1/0717/19 Funding text 1: Author Contributions: Conceptualization, L.K., M.C.B. and G.K.; methodology, I.R.; validation, E.M.T., M.C.B. and G.K.; formal analysis, R.R.; investigation, I.R.; data curation, L.K.; writing—original draft preparation, L.K. and E.M.T.; writing—review and editing, E.M.T.; supervision, M.C.B. original draft preparation, L.K. and E.M.T.; writing—review and editing, E.M.T.; supervision, M.C.B. and R.R. All authors have read and agreed to the published version of the manuscript. Funding: This research received no external funding. Funding: This research received no external funding. Data Availability Statement: Not applicable. Data Availability Statement: Not applicable. Acknowledgments: This research was supported by the Slovak Research and Development Agency under contracts No. APVV-18-0378, APVV-19-0269, VEGA1/0717/19 and VEGA1/0714/21. under contracts No. APVV-18-0378, APVV-19-0269, VEGA1/0717/19 and VEGA1/0714/21. Funding text 2: under contracts No. ThisAPVV-18-0378,research wasAPVV-19-0269,supported byVEGA1/0717/19the Slovak Researchand VEGA1/0714/21. and Development Agency under contracts No. APVV-18-0378, APVV-19-0269, VEGA1/0717/19 and VEGA1/0714/21. References: (2018) European Commission Staff Working Document—Directive (EU) 2018/844 of the European Parliament and the Council of 30 May 2018 Amending Directive 2010/31/EU on the Energy Performance of Buildings and Directive 2012/27/EU on Energy Efficiency, , EC. European Commission: Brussels, Belgium; (2019) European Commission, Energy Strategy. Clean Energy for all Europeans Package, , EC. European Union: Brussels, Belgium, [CrossRef]; (1999) Agenda 21 on Sustainable Construction, p. 122. , CIB. Conseil International du Matiment: Rotterdam, The Netherlands; (2007) Buidlings and Climate Change: Status, Challenges and Opportunities, p. 87. , UNEP. United Nations Environment Programme: New York, NY, USA; Abubakar, M., Raji, A., Hassan, M., Comparative study of thermal insulation boards from leaf and bark fibres of camel’s foot (Piliostigma thonningii L.) (2018) Niger. J. Technol, 37, p. 108. , [CrossRef]; Tangjuank, S., Kumfu, S., Particle Boards from Papyrus Fibers as Thermal Insulation (2011) J. Appl. Sci, 11, pp. 2640-2645. , [CrossRef]; Gounni, S., Mabrouk, M.T., Wazna, M.E., Kheiri, A., Alami, M.E., Bouari, A.E., Cherkaoui, O., Thermal and economic evalua-tion of new insulation materials for building envelope based on textile waste (2019) Appl. Therm. Eng, 149, pp. 475-483. , [CrossRef]; Bharadwaj, P., Jankovic, L., Self-Organised Approach to Designing Building Thermal Insulation (2020) Sustainability, 12, p. 5764. , [CrossRef]; Gaujena, B., Agapovs, V., Borodinecs, A., Strelets, K., Analysis of Thermal Parameters of Hemp Fiber Insulation (2020) Energies, 13, p. 6385. , [CrossRef]; (2019), http://ec.europa.eu/eurostat/statistics-explained/index.php/Energy_consumption_in_households, Eurostat, Energy Consumption in Households (EU-28, 2017, Data). (accessed on 7 June 2021); (2019) ANNEX to the Communication from the Commission to the European Parliament, the Europe—An Council the European Economic and Social Committee and the Committee of the Regions, , EC/European Commission. The European Green Deal; European Commission: Brussels, Belgium; Havrysh, V., Kalinichenko, A., Brzozowska, A., Stebila, J., Agricultural Residue Management for Sustainable Power Generation: The Poland Case Study (2021) Appl. Sci, 11, p. 5907. , [CrossRef]; Havrysh, V., Kalinichenko, A., Brzozowska, A., Stebila, J., Life Cycle Energy Consumption and Carbon Dioxide Emissions of Agricultural Residue Feedstock for Bioenergy (2021) Appl. Sci, 11, p. 2009. , [CrossRef]; Branowski, B., Zabłocki, M., Sydor, M., The Material Indices Method in the Sustainable Engineering Design Process: A Review (2019) Sustainability, 11, p. 5465. , [CrossRef]; Anastaselos, D., Giama, E., Papadopoulos, A., An assessment tool for the energy, economic and environmental evaluation of thermal insulation solutions (2009) Energy Build, 41, pp. 1165-1171. , [CrossRef]; (2020) European Commission, Circular Economy Action Plan. For a Cleaner and More Competitive Europe; new_circular_economy_action_plan, , EC. European Commission: Brussels, Belgium; (2020) European Commission, Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions. Sustainable Europe Investment Plan. European Green Deal Investment Plan, , EC. European Commission: Brussels, Belgium; (2015) Chamber of Commerce Foundation. Achieving a Circular Economy: How the Private Sector is Reimaging the Future of Business, p. 76. , U.S. Chamber of Commerce Foundation. U.S. Chamber of Commerce Foundation: Washington DC, USA; Cetiner, I., Shea, A.D., Wood waste as an alternative thermal insulation for buildings (2018) Energy Build, 168, pp. 374-384. , [CrossRef]; Kania, G., Kwiecień, K., Malinowski, M., Gliniak, M., Analyses of the Life Cycles and Social Costs of CO2 Emissions of Single Family Residential Buildings: A Case Study in Poland (2021) Sustainability, 13, p. 6164. , [CrossRef]; Vanova, R., Vlcko, M., Stefko, J., Life Cycle Impact Assessment of Load-Bearing Straw Bale Residential Building (2021) Materials, 14, p. 3064. , [CrossRef]; Mitterpach, J., Igaz, R., Štefko, J., Environmental evaluation of alternative wood-based external wall assembly (2020) Acta Fac. Xylol, 61, pp. 133-149; Asdrubali, F., Alessandro, F., Schiavoni, S., A review of unconventional sustainable building insulation materials (2015) Sustain. Mater. Technol, 4, pp. 1-17. , D [CrossRef]; Asdrubali, F., Ferracuti, B., Lombardi, L., Guattari, C., Evangelisti, L., Grazieschi, G., A review of structural, thermo-physical, acoustical, and environmental properties of wooden materials for building applications (2017) Build. Environ, 114, pp. 307-332. , [CrossRef]; Novák, I., Krupa, I., Sedliačik, J., Žigo, O., Jurkovič, P., Matyašovský, J., Investigation into mechanical, surface and adhesive properties of date palm wood-polyolefin micro composites (2020) Acta Fac. Xylol. Zvolen, 62, pp. 27-34; Fiorelli, J., Ramos, R.D., Sayama, J.T., Barrero, N.G., Palone, E.D.J.A., Particleboards with waste wood from reforestation (2014) Acta Sci. Technol, 36, p. 251. , [CrossRef]; Bekhta, P., Sedliačik, J., Kačík, F., Noshchenko, G., Kleinoví, A., Lignocellulosic waste fibers and their application as a component of urea-formaldehyde adhesive composition in the manufacture of plywood (2019) Eur. J. Wood Wood Prod, 77, pp. 495-508. , [CrossRef]; Souza, A.M., Nascimento, M.F., Almeida, D.H., Silva, D., Almeida, T.H., Christoforo, A.L., Lahr, F.A., Wood-based composite made of wood waste and epoxy based ink-waste as adhesive: A cleaner production alternative (2018) J. Clean. Prod, 193, pp. 549-562. , [CrossRef]; Antov, P., Mantanis, G.I., Savov, V., Development of Wood Composites from Recycled Fibres Bonded with Magnesium Lignosulfonate (2020) Forests, 11, p. 613. , [CrossRef]; Savov, V., Antov, P., Engineering the Properties of Eco-Friendly Medium Density Fibreboards Bonded with Lignosulfonate Adhesive (2020) Drv. Ind, 71, pp. 157-162. , [CrossRef]; Antov, P., Krišt’ák, L., Réh, R., Savov, V., Papadopoulos, A.N., Eco-Friendly Fiberboard Panels from Recycled Fibers Bonded with Calcium Lignosulfonate (2021) Polymers, 13, p. 639. , [CrossRef] [PubMed]; Madurwar, M.V., Ralegaonkar, R.V., Mandavgane, S.A., Application of agro-waste for sustainable construction materials: A review (2013) Constr. Build. Mater, 38, pp. 872-878. , [CrossRef]; Barbu, M.C., Réh, R., Çavdar, A.D., Non-wood lignocellulosic composites. Chapter 8 (2014) Research Developments in Wood Engineering and Technology, pp. 281-319. , Aguilera, J.A., Davim, P., Eds.; IGI Global: Hershey, PA, USA; Santos, M.F.N., Battistelle, R.A.G., Bezerra, B.S., Varum, H.S.A., Comparative study of the life cycle assessment of particleboards made of residues from sugarcane bagasse (saccharum spp.) and pine wood shavings (Pinus elliottii) (2014) J. Clean. Prod, 64, pp. 345-355. , [CrossRef]; Dukarska, D., Pędzik, M., Rogozińska, W., Rogoziński, T., Czarnecki, R., Characteristics of straw particles of selected grain species purposed for the production of lignocellulose particleboards (2021) Part. Sci. Technol, 39, pp. 213-222. , [CrossRef]; Fiorelli, J., Galo, R.G., Castro, S.L., Belini, U.L., Lasso, P.R.O., Savastano, H., Multilayer particleboard produced with agroindustrial waste and amazonian vegetable fibres (2017) Waste Biomass, 8, pp. 1-11; Eschenhagen, A., Raj, M., Rodrigo, N., Zamora, A., Labonne, I., Evon, P., Walemane, H., Investigation of miscanthus and sun-flower stalk fiber-reinforced composites for insulation applications (2019) Adv. Civ. Eng, 2019, p. 9328087; Guna, V., Ilangovan, M., Hu, C., Venkatesh, K., Reddy, N., Valorization of sugarcane bagasse by developing completely biodegradable composites for industrial applications (2019) Ind. Crop. Prod, 131, pp. 25-31. , [CrossRef]; Busquets-Ferrer, M., Czabany, I., Vay, O., Gindl-Altmutter, W., Hansmann, C., Alkali-extracted tree bark for efficient bio-based thermal insulation (2021) Constr. Build. Mater, 271, p. 121577. , [CrossRef]; Xing, C., Zhang, S.Y., Deng, J., Wang, S., Investigation of the effects of bark fiber as core material and its resin content on three-layer MDF performance by response surface methodology (2007) Wood Sci. Technol, 41, pp. 585-595. , [CrossRef]; Kain, G., Tudor, E.M., Barbu, M.-C., Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species (2020) Polymers, 12, p. 2140. , [CrossRef]; Miles, P.D., Smith, W.B., (2009) Specific Gravity and Other Properties of Wood and Bark for 156 Tree Species Found in North America, 38, pp. 1-35. , USDA Forest Service: Madison, WI, USA; Pereira, H., The Rationale behind Cork Properties: A Review of Structure and Chemistry (2015) Bioresources, 10, pp. 6207-6229. , [CrossRef]; Nemli, G., Gezer, E., Yıldız, S., Temiz, A., Aydın, A., Evaluation of the mechanical, physical properties and decay resistance of particleboard made from particles impregnated with Pinus brutia bark extractives (2006) Bioresour. Technol, 97, pp. 2059-2064. , [CrossRef]; Kain, G., Lienbacher, B., Barbu, M.-C., Richter, K., Petutschnigg, A., Larch (Larix decidua) bark insulation board: Interactions of particle orientation, physical–mechanical and thermal properties (2018) Holz Roh Werkst, 76, pp. 489-498. , [CrossRef]; Fengel, D., Wegener, G., (2003) Wood: Chemistry, Ultrastructure, Reactions, p. 613. , Kessel Verlag: Remagen, Germany; Rowell, R., (2012) Handbook of Wood Cchemistry and Wood Composites, , 2nd ed.; CRC Press: Boca Raton, FL, USA; Barbu, M.C., Lohninger, Y., Hofmann, S., Kain, G., Petutschnigg, A., Tudor, E.M., Larch Bark as a Formaldehyde Scavenger in Thermal Insulation Panels (2020) Polymers, 12, p. 2632. , [CrossRef]; Tudor, E.M., Barbu, M.C., Petutschnigg, A., Réh, R., Krišt’ák, L’., Analysis of Larch-Bark Capacity for Formaldehyde Removal in Wood Adhesives (2020) Int. J. Environ. Res. Public Health, 17, p. 764. , [CrossRef] [PubMed]; Krišt’ák, L’., Igaz, R., Ružiak, I., Applying the EDPS Method to the Research into Thermophysical Properties of Solid Wood of Coniferous Trees (2019) Adv. Mater. Sci. Eng, 2019, pp. 1-9. , [CrossRef]; Igaz, R., Krišt’ák, L’., Ružiak, I., Gajtanska, M., Kučerka, M., Thermophysical Properties of OSB Boards versus Equilibrium Moisture Content (2017) Bioresources, 12, pp. 8106-8118; Suleiman, B.M., Larfeldt, J., Leckner, B., Gustavsson, M., Thermal conductivity and diffusivity of wood (1999) Wood Sci. Technol, 33, pp. 465-473. , [CrossRef]; Kain, G., Tudor, E.M., Dettendorfer, A., Barbu, M.C., Potenzial von Baumrinde fur den Einsatz als Schallabsorptionsmaterial (2020) Bauphysic, 42, pp. 124-130. , [CrossRef]; Gibson, L.J., Ashby, M.F., (1999) Cellular Solids: Structure and Properties, , Cambridge University Press: Cambridge, UK; Kain, G., Barbu, M.-C., Teischinger, A., Musso, M., Petutschnigg, A., Substantial Bark Use as Insulation Material (2012) For. Prod. J, 62, pp. 480-487. , [CrossRef]; Kain, G., Guttler, V., Barbu, M.C., Petutschnigg, A., Richter, K., Tondi, G., Density related properties of bark insulation boards bonded with tannin hexamine resin (2014) Eur. J. Wood Prod, 72, pp. 417-424. , [CrossRef]; Sonderegger, W., Niemz, P., Thermal and moisture flux in soft fibreboards (2012) Holz Roh Werkst, 70, pp. 25-35. , [CrossRef]; Gößwald, J., Barbu, M.-C., Petutschnigg, A., Tudor, E., Binderless Thermal Insulation Panels Made of Spruce Bark Fibres (2021) Polymers, 13, p. 1799. , [CrossRef]; Brombacher, V., Michel, F., Niemz, P., Volkmer, T., Untersuchungen zu Warmeleitfahigkeit und Feuchteverhalten von Holzfaserplatten und Materialkombinationen (2012) Bauphysic, 34, pp. 157-169. , [CrossRef]; Haupl, P., (2008) Bauphysik, p. 66. , Ernst and Sohn: Berlin, Germany; Schunk, C., Treml, S., Troger, F., Lose Dammstoffe aus Holz—Warmeleitfahighkeit von speziell hergestellten Frassspanen ausgewahlter Holzarten (2009) Eur. J. Wood Prod, 67, pp. 487-488. , [CrossRef]; Danihelova, A., Nemec, M., Gergel, T., Gejdos, M., Gordanova, J., Scesny, P., Usage of Recycled Technical Textiles as Thermal Insulation and an Acoustic Absorber (2019) Sustainability, 11, p. 2968. , [CrossRef]; Grohe, B., Heat conductivities of insulation mats based on water glass bonded non-textile hemp or flax fibers (2004) Holz Roh Werkstoff, 62, pp. 352-357. , [CrossRef]; Rebolledo, P., Clutier, A., Yemele, M.C., Effect of Density and Fiber Size on Porosity and Thermal Conductivity of Fiber-board Mats (2018) Fibers, 6, p. 81. , [CrossRef]; Bertolini, M.d.S., de Morais, A.G., Christoforo, A.L., Bertoli, S.R., dos Santos, W.N., Lahr, F.A.R., Acoustic absorption and thermal insulation of wood panels: Influence of porosity (2019) Bioresources, 14, pp. 3746-3757; Carson, J.K., Lovatt, S., Tanner, D.J., Cleland, A.C., Thermal conductivity bounds for isotropic, porous materials (2005) Int. J. Heat Mass Transf, 48, pp. 2150-2158. , [CrossRef]; Kain, G., Guttler, V., Lienbacher, B., Barbu, M.C., Petutschnigg, A., Richter, K., Effects of different flavonoid extracts in optimizing tanninglued bark insulation boards (2015) Wood Fiber. Sci, 47, pp. 258-269; Kain, G., Lienbacher, B., Barbu, M.-C., Plank, B., Richter, K., Petutschnigg, A., Evaluation of relationships between particle orientation and thermal conductivity in bark insulation board by means of CT and discrete modeling (2016) Case Stud. Nondestruct. Test. Eval, 6, pp. 21-29. , [CrossRef]; Sonderegger, W., Niemz, P., Thermal conductivity and water vapour transmission properties of wood-based materials (2009) Holz Roh Werkst, 67, pp. 313-321. , [CrossRef]; Joščák, M., Sonderegger, W., Niemy PSchnider, T., Oppikofer, R., Lammar, L., Influence of the air cavities on thermal conductivity of selected wood-based materials and their application for building industry (2012) Bauphysik, 34, pp. 32-37. , [CrossRef]; Gupta, G., Yan, N., Feng, M.W., Effect of pressing temperature and particle size on bark board properties made from beetle-infested lodgepole pine (Pinus contorta) barks (2011) Forest Prod. J, 61, pp. 478-488. , [CrossRef]; Mahlia, T.M.I., Taufiq, B.N., Ismail Masjuki, H.H., Correlation between thermal conductivity and the thickness of selected in-sulation materials for building wall (2007) Energy Build, 39, pp. 182-187. , [CrossRef]; Pásztory, Z., Mohácsiné, I.R., Börcsök, Z., Investigation of thermal insulation panels made of black locust tree bark (2017) Constr. Build. Mater, 147, pp. 733-735. , [CrossRef]; Reifsnyder, W.E., Herrington, L.P., (1967) Thermophysical Properties of Bark of Shortleaf, Longleaf and Red Pine, 80. , Yale School of Forestry & Environmental Studies Bulletin Series; Yale School of Forestry: New Haven, CT, USA; Kawasaki, T., Kawai, S., Thermal insulation properties of wood-based sandwich panel for use as structural insulated walls and floors (2006) J. Wood Sci, 52, pp. 75-83. , [CrossRef]; Harada, T., Hata, T., Ishihara, S., Thermal constants of wood during the heating process measured with the laser flash method (1998) J. Wood Sci, 44, pp. 425-431. , [CrossRef]; Rargland, K.W., Aerts, D.J., Baker, A.J., Properties of Wood for Comustion Analysis (1991) Bioresour. Technol, 37, pp. 161-168. , [CrossRef]; Simpson, W., Wolde, A.T., Physical properties and moisture relations of wood (1999) Wood Handbook: Wood as an Engineering Material, , USDA Forest Service: Madison, WI, USA; Koljo, B., Something about the heat phenomena of woods and trees (1950) Forstwiss. Cent, 69, pp. 538-551. , [CrossRef]; Gupta, M., Yang, J., Roy, C., Specific heat and thermal conductivity of softwood bark and softwood char particles (2003) Fuel, 82, pp. 919-927. , [CrossRef]; Koch, P., Specific Heat of Ovendry Spruce Pine Wood and Bark (1969) Wood Sci, 1, pp. 203-214; Aditya, L., Mahlia, T.M.I., Rismanchi, B., Ng, H., Hasan, M., Metselaar, H.S.C., Muraza, O., Aditiya, H., A review on insulation materials for energy conservation in buildings (2017) Renew. Sustain. Energy Rev, 73, pp. 1352-1365. , [CrossRef]; Sari, N.H., Wardana, I.N.G., Irawan, Y.S., Siswanto, E.P., Physical and Acoustical Properties of Corn Husk Fiber Panels (2016) Adv. Acoust. Vib, 2016, p. 5971814. , [CrossRef]; Saha, P., Manna, S., Chowdhury, R., Sen, R., Roy, D., Adhikari, B., Enhancement of tensile strength of lignocellulosic jute fibers by alkali-steam treatment (2010) Bioresour. Technol, 101, pp. 3182-3187. , [CrossRef]; Salit, M.S., Tropical Natural Fibres and Their Properties (2014) Tropical Natural Fibre Composites. Engineering Materials, pp. 15-38. , Springer: Singapore; Papadopoulos, A., State of the art in thermal insulation materials and aims for future developments (2005) Energy Build, 37, pp. 77-86. , [CrossRef]; Taghiyari, H., Militz, H., Antov, P., Papadopoulos, A., Effects of Wollastonite on Fire Properties of Particleboard Made from Wood and Chicken Feather Fibers (2021) Coatings, 11, p. 518. , [CrossRef]; Aristri, M., Lubis, M., Yadav, S., Antov, P., Papadopoulos, A., Pizzi, A., Fatriasari, W., Iswanto, A., Recent Developments in Lignin-and Tannin-Based Non-Isocyanate Polyurethane Resins for Wood Adhesives—A Review (2021) Appl. Sci, 11, p. 4242. , [CrossRef]; Papadopoulos, A., Advances in Wood Composites III (2021) Polymers, 13, p. 163. , [CrossRef]; Osvaldova, L.M., Markova, I., Jochim, S., Bares, J., Experimental Study of Straw-Based Eco-Panel Using a Small Ignition Initiator (2021) Polymers, 13, p. 1344. , [CrossRef] [PubMed]; Tudor, E.M., Scheriau, C., Barbu, M.C., Réh, R., Krišt’ák, L’., Schnabel, T., Enhanced Resistance to Fire of the Bark-Based Panels Bonded with Clay (2020) Appl. Sci, 10, p. 5594. , [CrossRef]; Tudor, E.M., Dettendorfer, A., Kain, G., Barbu, M.C., Réh, R., Krišt’ák, L’., Sound-Absorption Coefficient of Bark-Based Insulation Panels (2020) Polymers, 12, p. 1012. , [CrossRef]; Tudor, E., Kristak, L., Barbu, M., Gergel’, T., Němec, M., Kain, G., Réh, R., Acoustic Properties of Larch Bark Panels (2021) Forests, 12, p. 887. , [CrossRef]; Réh, R., Igaz, R., Krišt’ák, L’., Ružiak, I., Gajtanska, M., Božíková, M., Kučerka, M., Functionality of Beech Bark in Adhesive Mixtures Used in Plywood and Its Effect on the Stability Associated with Material Systems (2019) Materials, 12, p. 1298. , [CrossRef]; Tudor, E.M., Zwickl Ch Eichinger Ch Petutschnigg, A., Barbu, M.C., Performance of softwood bark comminution technologies for determination of targeted particle size in further upcycling applications (2020) J. Cleaner Prod, 269, p. 122412. , [CrossRef]; Réh, R., Krišt’ák, L’., Sedliačik, J., Bekhta, P., Božiková, M., Kunecová, D., Vozárová, V., Savov, V., Utilization of Birch Bark as an Eco-Friendly Filler in Urea-Formaldehyde Adhesives for Plywood Manufacturing (2021) Polymers, 13, p. 511. , [CrossRef]; Pfundsteing, M.R., Gellert, M., Spitzner, H., Rudolphi, A., (2007) Insulation Materials: Basics, Materials, Applications, , Department for International Architecture Documentation Corporation: Munich, Germany; Moresova, M., Sedliacikova, M., Stefko, J., Bencikova, D., Perception of wooden houses in the Slovak Republic (2019) Acta Fac. Xylol. Zvolen, 61, pp. 121-135; Potkány, M., Gejdoš, M., Debnár, M., Sustainable Innovation Approach for Wood Quality Evaluation in Green Business (2018) Sustainability, 10, p. 2984. , [CrossRef]

PY - 2021/7/12

Y1 - 2021/7/12

N2 - The effects of using 100% larch bark (Larix decidua Mill) as a raw material for composite boards on the thermophysical properties of this innovative material were investigated in this study. Panels made of larch bark with 4–11 mm and 10–30 mm particle size, with ground bark oriented parallel and perpendicular to the panel’s plane at densities varying from 350 to 700 kg/m3 and bonded with urea-formaldehyde adhesive were analyzed for thermal conductivity, thermal resistivity and specific heat capacity. It was determined that there was a highly significant influence of bulk density on the thermal conductivity of all the panels. With an increase in the particle size, both parallel and perpendicular to the panel´s plane direction, the thermal conductivity also increased. The decrease of thermal diffusivity was a consequence of the increasing particle size, mostly in the parallel orientation of the bark particles due to the different pore structures. The specific heat capacity is not statistically significantly dependent on the density, particle size, glue amount and particle orientation.

AB - The effects of using 100% larch bark (Larix decidua Mill) as a raw material for composite boards on the thermophysical properties of this innovative material were investigated in this study. Panels made of larch bark with 4–11 mm and 10–30 mm particle size, with ground bark oriented parallel and perpendicular to the panel’s plane at densities varying from 350 to 700 kg/m3 and bonded with urea-formaldehyde adhesive were analyzed for thermal conductivity, thermal resistivity and specific heat capacity. It was determined that there was a highly significant influence of bulk density on the thermal conductivity of all the panels. With an increase in the particle size, both parallel and perpendicular to the panel´s plane direction, the thermal conductivity also increased. The decrease of thermal diffusivity was a consequence of the increasing particle size, mostly in the parallel orientation of the bark particles due to the different pore structures. The specific heat capacity is not statistically significantly dependent on the density, particle size, glue amount and particle orientation.

KW - Ecofriendly composites

KW - Insulation materials

KW - Larch bark

KW - Tannin-based adhesive

KW - Thermophysical properties

KW - Adhesives

KW - Particle size

KW - Pore structure

KW - Specific heat

KW - Urea

KW - Urea formaldehyde resins

KW - Bulk density

KW - Composite boards

KW - Composite panels

KW - Innovative materials

KW - Parallel orientation

KW - Particle orientation

KW - Plane directions

KW - Urea formaldehyde

KW - Thermal conductivity

UR - https://www.mendeley.com/catalogue/1cc1bec1-a055-3bfc-ad95-f3e422859be8/

U2 - 10.3390/polym13142287

DO - 10.3390/polym13142287

M3 - Article

C2 - 34301041

SN - 2073-4360

VL - 13

JO - Polym.

JF - Polym.

IS - 14

ER -

Thermophysical Properties of Larch Bark Composite Panels

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