Acoustic Properties of Larch Bark Panels

E.M. Tudor; L. Kristak; M.C. Barbu; T. Gergel’; M. Němec; G. Kain; R. Réh

doi:10.3390/f12070887

Acoustic Properties of Larch Bark Panels

E.M. Tudor
, L. Kristak
, M.C. Barbu
, T. Gergel’
, M. Němec
, G. Kain
, R. Réh

Faculty of Furniture Design and Wood Engineering, Transilvania University of Brasov
Faculty of Wood Sciences and Technology, Technical University in Zvolen
National Forest Centre, Forest Research Institute

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

Abstract

The potential of tree bark, a by-product of the woodworking industry, has been studied for more than seven decades. Bark, as a sustainable raw material, can replace wood or other resources in numerous applications in construction. In this study, the acoustic properties of bark-based panels were analyzed. The roles of the particle size (4–11 mm and 10–30 mm), particle orientation (parallel and perpendicular) and density (350–700 kg/m3 ) of samples with 30 mm and 60 mm thicknesses were studied at frequencies ranging from 50 to 6400 Hz. Bark-based boards with fine-grained particles have been shown to be better in terms of sound absorption coefficient values compared with coarse-grained particles. Bark composites mixed with popcorn bonded with UF did not return the expected results, and it is not possible to recommend this solution. The best density of bark boards to obtain the best sound absorption coefficients is about 350 kg/m3 . These lightweight panels achieved better sound-absorbing properties (especially at lower frequencies) at higher thicknesses. The noise reduction coefficient of 0.5 obtained a sample with fine particles with a parallel orientation and a density of around 360 kg/m3 .

Original language	English
Journal	Forests
Volume	12
Issue number	7
DOIs	https://doi.org/10.3390/f12070887
Publication status	Published - 7 Jul 2021

Keywords

Acoustic performance
Bark-based panels
Construction materials
Sound absorption coefficient
Sustainable materials
Acoustic properties
Noise abatement
Particle size
Sound insulating materials
Woodworking
Coarse grained particles
Fine-grained particles
Parallel orientation
Particle orientation
Reduction coefficient
Sound absorption coefficients
Sustainable raw materials
Woodworking industry
Acoustic wave absorption
absorption coefficient
acoustic data
construction material
frequency analysis
wood
Acoustic Properties
Bark
Density
Orientation
Panels
Particle Size
Particles
Sound Absorption

Access to Document

10.3390/f12070887

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85110907560&doi=10.3390%2ff12070887&partnerID=40&md5=ed18c4ecc8b4ce2a1ba827eb4934a9f7

Cite this

@article{34b3886caf7044619015d8e0f796beaa,

title = "Acoustic Properties of Larch Bark Panels",

abstract = "The potential of tree bark, a by-product of the woodworking industry, has been studied for more than seven decades. Bark, as a sustainable raw material, can replace wood or other resources in numerous applications in construction. In this study, the acoustic properties of bark-based panels were analyzed. The roles of the particle size (4–11 mm and 10–30 mm), particle orientation (parallel and perpendicular) and density (350–700 kg/m3 ) of samples with 30 mm and 60 mm thicknesses were studied at frequencies ranging from 50 to 6400 Hz. Bark-based boards with fine-grained particles have been shown to be better in terms of sound absorption coefficient values compared with coarse-grained particles. Bark composites mixed with popcorn bonded with UF did not return the expected results, and it is not possible to recommend this solution. The best density of bark boards to obtain the best sound absorption coefficients is about 350 kg/m3 . These lightweight panels achieved better sound-absorbing properties (especially at lower frequencies) at higher thicknesses. The noise reduction coefficient of 0.5 obtained a sample with fine particles with a parallel orientation and a density of around 360 kg/m3 .",

keywords = "Acoustic performance, Bark-based panels, Construction materials, Sound absorption coefficient, Sustainable materials, Acoustic properties, Noise abatement, Particle size, Sound insulating materials, Woodworking, Coarse grained particles, Fine-grained particles, Parallel orientation, Particle orientation, Reduction coefficient, Sound absorption coefficients, Sustainable raw materials, Woodworking industry, Acoustic wave absorption, absorption coefficient, acoustic data, construction material, frequency analysis, wood, Acoustic Properties, Bark, Density, Orientation, Panels, Particle Size, Particles, Sound Absorption",

author = "E.M. Tudor and L. Kristak and M.C. Barbu and T. Gergel{\textquoteright} and M. N{\v e}mec and G. Kain and R. R{\'e}h",

note = "Cited By :14 Export Date: 14 December 2023 Correspondence Address: Kristak, L.; Faculty of Wood Sciences and Technology, Slovakia; 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 details: Vedeck{\'a} Grantov{\'a} Agent{\'u}ra M{\v S}VVa{\v S} SR a SAV, VEGA, 1/0714/21, 1/0717/19 Funding text 1: Funding: 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. Funding text 2: This research was supported by the Slovak Research and Development Agency under contracts No. APVV-18-0378, APVV-19-0269, VEGA 1/0717/19 and VEGA 1/0714/21. References: Zalejska-Jonsson, A., Perceived Acoustic Quality and Effect on Occupants{\textquoteright} Satisfaction in Green and Conventional Residential Buildings (2019) Buildings, 9, p. 24. , [CrossRef]; Wilhelmsson, M., The Impact of Traffic Noise on the Values of Single-family Houses (2000) J. Environ. Plan. Manag, 43, pp. 799-815. , [CrossRef]; Camara, T., Kamsu-Foguem, B., Diourt{\'e}, B., Faye, J.P., Hamadoun, O., Management of acoustic risks for buildings near airports (2018) Ecol. Inform, 44, pp. 43-56. , [CrossRef]; Mueller, N., Rojas-Rueda, D., Khreis, H., Cirach, M., Andr{\'e}s, D., Ballester, J., Bartoll, X., Echave, C., Changing the urban design of cities for health: The superblock model (2020) Environ. Int, 134, p. 105132. , [CrossRef] [PubMed]; Shield, B., Conetta, R., A survey of acoustic conditions and noise levels in secondary school classrooms in England (2015) J. Acoust. Soc. Am, 137, p. 177. , [CrossRef]; Azkorra, Z., P{\'e}rez, G., Coma, J., Cabeza, L.F., Bures, S., Alvaro, J.E., Erkoreka, A., Urrestarazu, M., Evaluation of green walls as a passive acoustic insulation system for buildings (2015) Appl. Acoust, 89, pp. 46-56. , [CrossRef]; Gonzales, D.M., Barrigon Morillas, J.M., Godinho, L., Amado-Mendes, P., Acoustic screening effect on building facades due to parking lines in urban environments. Effects in noise mapping (2018) Appl. Acoust, 130, pp. 1-14. , [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] [PubMed]; Danihelov{\'a}, A., N{\v e}mec, M., Gergel{\textquoteright}, T., Gejdo{\v s}, M., Gordanov{\'a}, J., S{\v c}ensn{\'y}, P., Usage of Recycled Technical Textiles as Thermal Insulation and an Acoustic Absorber (2019) Sustainaility, 11, p. 2968. , [CrossRef]; {\v C}ul{\'i}k, M., Danihelov{\'a}, A., Ondrejka, V., Al{\'a}{\v c}, P., Sound Absorption on Board Construction Materials Used in Wood Buildings (2020) Akustika, 37, pp. 51-57. , [CrossRef]; Silva, D.A.L., Lahr, F.A.R., Garcia, R.P., Freire, F.M.C.S., Ometto, A.R., Life cycle assessment of medium density particleboard (MDP) produced in Brazil (2013) Int. J. Life Cycle Assess, 18, pp. 1404-1411. , [CrossRef]; Branowski, B., Zab{\l}ocki, M., Sydor, M., The Material Indices Method in the Sustainable Engineering Design Process: A Review (2019) Sustainaility, 11, p. 5465. , [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. Xylologiae Zvolen, 62, pp. 27-34; Souza, A.M., Nascimento, M.F., Almeida, D.H., Lopes Silva, D.A., Almeida, T.H., Christoforo, A.L., Lahr, F.A.R., 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]; Vanova, R., Vlcko, M., Stefko, J., Life Cycle Impact Assessment of Load-Bearing Straw Bale Residential Building (2021) Materials, 14, p. 3064. , [CrossRef]; Moresova, M., Sedliacikova, M., Stefko, J., Bencikova, D., Perception of wooden houses in the Slovak Republic (2019) Acta Fac. Xylologiae Zvolen, 61, pp. 121-135; 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]; Aristri, M.A., Lubis, M.A.R., Yadav, S.M., Antov, P., Papadopoulos, A.N., Pizzi, A., Fatriasari, W., Iswanto, A.H., Recent Developments in Lignin-and Tannin-Based Non-Isocyanate Polyurethane Resins for Wood Adhesives—A Review (2021) Appl. Sci, 11, p. 4242. , [CrossRef]; dos Santos, M.F.N., Battistelle, R.A.G., Bezerra, B.S., Varum, H.S.A., Comparative study of the life cycle assessment of particle-boards made of residues from sugarcane bagasse (Saccharum spp.) and pine wood shavings (Pinus elliottii) (2014) J. Clean. Prod, 64, pp. 345-355. , [CrossRef]; Battistelle, R.A.G., Fujino, D.M., Silva, A.L.C., Bezerra, B.S., Valarelli, I.D., Physical and mechanical characterization of sugarcane bagasse particleboards for civil construction (2016) J. Sustain. Dev. Energy Water Environ. Syst, 4, pp. 408-417. , [CrossRef]; Hejna, A., Barczewski, M., Sk{\'o}rczewska, K., Szulc, J., Chmielnicki, B., Korol, J., Formela, K., Sustainable upcycling of brewers{\textquoteright} spent grain by thermo-mechanical treatment in twin-screw extruder (2021) J. Clean. Prod, 285, p. 124839. , [CrossRef]; Liuzzi, S., Rubino, C.H., Stefanizzi, P., Martellotta, F., Performance Characterization of Broad Band Sustainable Sound Absorbers Made of Almond Skins (2020) Materials, 13, p. 5474. , [CrossRef] [PubMed]; Rammou, E., Mitani, A., Ntalos, G., Koutsianitis, D., Taghiyari, H.R., Papadopoulos, A.N., The Potential Use of Seaweed (Posidonia oceanica) as an Alternative Lignocellulosic Raw Material for Wood Composites Manufacture (2021) Coatings, 11, p. 69. , [CrossRef]; 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]; Bohatkiewicz, J., Noise Control Plans in Cities–Selected Issues and Necessary Changes in Approach to Measures and Methods of Protectin (2016) Transp. Res. Procedia, 14, pp. 2744-2753. , [CrossRef]; Peng, L., Sound absorption and insulation functional composites (2017) Advanced High Strength Natural Fibre Composites in Construction, pp. 333-373. , Woodhead Publishing: Cambridge, UK; 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]; Desarnaulds, V., Costanzo, E., Carvalho, A., Aurlaud, B., Sustainability of acoustic materials and acoustic characterization of sustainable materials (2005) Proceedings of the 12th International Congress on Sound and Vibration (ICSV12), , Lisbon, Portugal, 11–14 July; Pedroso, M., de Brito, J., Silvestre, J., Characterization of eco-efficient acoustic insulation materials (traditional and innovative) (2017) Constr. Build. Mater, 140, pp. 221-228. , [CrossRef]; Jensen, M.S., Alfieri, P.V., Design and manufacture of insulation panels based on recycled lignocellulosic waste (2021) Clean. Eng. Technol, 3, p. 100111. , [CrossRef]; Asdrubali, F., Schiavoni, S., Horoshenkov, K.V., A Review of Sustainable Materials for Acoustic Applications (2012) Build. Acoust, 19, pp. 283-311. , [CrossRef]; D{\textquoteright}Alessandro, F., Pispola, G., Sound absorption properties of sustainable fibrous materials in an enhanced reverberation room (2005) Proceedings of the Internoise 2005, , Rio de Janeiro, Brazil, 7–10 August; Fouladi, M.H., Ayub, M., Nor, M.J.M., Analysis of coir fiber acoustical characteristics (2011) Appl. Acoust, 72, pp. 35-42. , [CrossRef]; Oldham, D.J., Egan, C.A., Cookson, R.D., Sustainable acoustic absorbers from the biomass (2011) Appl. Acoust, 72, pp. 350-363. , [CrossRef]; Jiang, W., Adamopoulos, S., Hosseinpourpia, R., {\v Z}igon, J., Petri{\v c}, M., {\v S}ernek, M., Medved, S., Utilization of Partially Liquefied Bark for Production of Particleboards (2020) Appl. Sci, 10, p. 5253. , [CrossRef]; Fatima, S., Mohanty, A.R., Acoustical and fire-retardant properties of jute composite materials (2011) Appl. Acoust, 72, pp. 108-114. , [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]; Salit, M.S., Tropical natural fibres and their properties (2014) Tropical Natural Fibre Composites. Engineering Materials, pp. 15-38. , Springer: Singapore; 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]; Kairytė, A., Kremensas, A., Bal{\v c}iūnas, G., Matulaitiene, I., Cz{\l}onka, S., Sienkiewicz, N., Evaluation of self-thermally treated wood plastic composites from wood bark and rapeseed oil-based binder (2020) Constr. Build. Mater, 250, p. 118842. , [CrossRef]; Abilleira, F., Varela, P., Cancela, A., Alvarez, X., Sanchez, A., Valero, E., Tannins extraction from Pinus pinaster and Acacia dealbata bark with applications in the industry (2021) Ind. Crop. Prod, 164, p. 113394. , [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]; 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]; Martin, R.E., Thermal properties of bark (1963) For. Prod. J, 13, pp. 419-426; 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]; 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]; 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., 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]; 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] [PubMed]; 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] [PubMed]; 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]; Tudor, E.M., Zwickl, C., Eichinger, C., Petutschnigg, A., Barbu, M.C., Performance of softwood bark comminution technologies for determinantion of targeted particle size in further upcycling applications (2020) J. Clean. Prod, 269, p. 122412. , [CrossRef]; Tudor, E.M., Barbu, M.C., Cost analysis of larch bark coatings for flooring tiles (2020) ProLigno, 16, pp. 46-51; P{\'a}sztory, Z., B{\"o}rcs{\"o}k, Z., Tsalagkas, D., Density optimization for the manufacturing of bark-based thermal insulation panels (2019) IOP Conference Series: Earth and Environmental Science, Proceedings of the 5th International Conference on Environment and Renewable Energy, 307. , Ho Chi Minh City, Vietnam, 25–28 February IOP Publishing Ltd.: Bristol, UK, 2019; Tsalagkas, D., B{\"o}rcs{\"o}k, Z., P{\'a}sztory, Z., Thermal, physical and mechanical properties of surface overlaid bark-based insulation panels (2019) Eur. J. Wood Prod, 77, pp. 721-730. , [CrossRef]; Taban, E., Mirzaei, R., Faridan, M., Samaei, E., Salimi, F., Tajpoor, A., Ghalenoei, M., Morphological, acoustical, mechanical and thermal properties of sustainable green Yucca (Y. gloriosa) fibers: An exploratory investigation (2020) J. Environ. Health Sci. Eng, 18, pp. 883-896. , [CrossRef]; Smardzewski, J., Batko, W., Kamisi{\'n}ski, T., Flach, A., Pilch, A., Dziurka, D., Mirski, R., Majewski, A., Experimental study of wood acoustic absorption characteristics (2013) Holzforschung, 68, p. 160. , [CrossRef]; (2005) EN 326-1:2005 Wood Based Panels—Sampling, Cutting and Inspection—Part 1: Sampling and Cutting of Test Pieces and Expression of Test Results, , European Committee for Standardization. European Committee for Standardization: Brussels, Belgium; Graphite Polystyren, Isover EPS Greywall, , https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk\_technicky-list\_isover-eps\_greywall.pdf, (accessed on 1 June 2021); https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk\_technicky-list\_isover-eps\_200s.pdf, White Polystyrene—Polyform EPS 200S. (accessed on 1 June 2021); https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk\_isover-styrodur\_3000\_cs\_technicky\_list.pdf, Extruded Polystyrene—Isover. (accessed on 1 June 2021); https://tepore.sk/wp-content/uploads/2018/03/STEICO-Flex-036\_CZ.pdf, Fiberboard—Steico Flex 036. (accessed on 1 June 2021); Mineral Wool—Isover TF Thermo, , https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk\_isover\_tf\_thermo\_epd\_en.pdf, (accessed on 1 June 2021); Masonite Board—Steico Protect, , https://www.jafholz.sk/action/shop/pdf?product=1351400, (accessed on 1 June 2021); https://www.korok.sk/data/files/jcg\_insulation-cataloque-eng\_43.pdf, Cork Boards. (accessed on 1 June 2021); (2002) Acoustics—Determination of Sound Absorption Coefficient and Impedance in Impedance Tubes—Part 2: Transfer-Function Method, , EN ISO 10534-2. European Committee for Standardization (CEN): Br{\"u}ssel, Belgium; Morgans, R.C., Li, X., Zander, A.C., Hansen, C.H., Statistics and the Two Microphone Method for the Measurement of Sound Absorption Coefficient (2004) Proc. Acoust, 15, pp. 3-5; (2017) Acoustics—Sound Absorbers—Rating of Sound Absorption Coefficients, , EN ISO 11654. European Committee for Standardization (CEN): Br{\"u}ssel, Belgium; Nordin, M.N.A.A., Wan, L.M., Zainulabidin, M.H., Kassim, A.S.M., Aripin, A.M., Research finding in natural fibers sound absorbing material (2016) ARPN J. Eng. Appl. Sci, 11, pp. 8579-8584; Echeverria, C.A., Pahlevani, F., Handoko, W., Jiang, C., Doolan, C., Sahajwalla, V., Engineered hybrid fibre reinforced composites for sound absorption building applications (2019) Resour. Conserv. Recycl, 143, pp. 1-14. , [CrossRef]; Boubel, A., Garoum, M., Bousshine, S., Bybi, A., Investigation of loose wood chips and sawdust as alternative sustainable sound absorber materials (2021) Appl. Acoust, 172, p. 107639. , [CrossRef]; Limited, K., (2005) Acoustic Performance Guide, , Kingspan Limited: Holywell, UK; Koizumi, T., Tsujiuchi, N., Adachi, A., The development of sound absorbing materials using natural bamboo fibers (2002) WIT Trans. Built Environ, 59, pp. 157-166; Arenas, J.P., Asdrubali, F., Eco-Materials with Noise Reduction Properties (2018) Handbook of Ecomaterials, , Martinez, L.M.T., Kharissova, O.V., Kharisov, B.I., Eds.; Springer International Publishing AG: New York, NY, USA; Hassani, P., Soltani, P., Ghane, M., Zarrebini, M., Porous resin-bonded recycled denim composite as an efficient sound-absorbing material (2021) Appl. Acoust, 173, p. 107710. , [CrossRef]; Arenas, J.P., Crocker, M.J., Recent Trends in Porous Sound-Absorbing Materials (2010) Sound Vib, 44, pp. 12-18; Akay, A., Acoustics of friction (2002) J. Acoust. Soc. Am, 111, pp. 1525-1548. , [CrossRef]; Amares, S., Sujatmika, E., Hong, T.W., Durairaj, R., Hamid, H.S.H.B., A Review: Characteristics of Noise Absorption Material (2017) J. Phys. Conf. Ser, 908, p. 012005. , [CrossRef]; Soltani, P., Zerrebini, M., The analysis of acoustical characteristics and sound absorption coefficient of woven fabrics (2012) Text. Res. J, 82, pp. 875-882. , [CrossRef]; Karlinasari, L., Hermawan, D., Maddu, A., Bagus, M., Lucky, I.K., Nugroho, N., Hadi, Y.S., Acoustical Properties of Particleboards Made from Betung Bamboo (Dendrocalamus asper) as Building Construction Material (2012) Bioresources, 7, pp. 5700-5709. , [CrossRef]; Karlinasari, L., Hermawan, D., Maddu, A., Martiandi, B., Hadi, Y.S., Development of particleboard from tropical fast-growing Species for acoustic panel (2012) J. Trop. For. Sci, 24, pp. 64-69; Luu, H.T., Perrot, C., Panneton, R., Influence of porosity, fiber radius and fiber orientation on the transport and acoustic properites of random fiber structures (2017) Acta Acust. United Acust, 103, pp. 1050-1063. , [CrossRef]; Aditya, L., Mahlia, T.M.I., Rismanchi, B., Ng, H.M., Hasan, M.H., Metselaar, H.S.C., Muraza, O., Aditiya, H.B., A review on insulation materials for energy conservation in buildings (2017) Renew. Sustain. Energy Rev, 73, pp. 1352-1365. , [CrossRef]; Niu, M., Hagman, O., Wang, X., Xie, Y., Karlsson, O., Cai, L., Effect of Si-Al Compounds on Fire Properties of Ultra-low Density Fiberboard (2014) Bioresources, 9, pp. 2415-2430. , [CrossRef]; Chen, T., Liu, J., Wu, Z., Wang, W., Niu, M., Wang, X., Xie, Y., Evaluating the Effectiveness of Comples Fire-Retardants on the Fire Properties of Ultra-low Density Fiberboard (ULDF) (2016) Bioresources, 11, pp. 1796-1807; Pausas, J.G., Bark thickness and fire regime (2014) Funct. Ecol, 29, pp. 315-327. , [CrossRef]; D{\textquoteright}Alessandro, F., Schiavoni, S., Bianchi, F., Straw as an acoustic material (2017) Proceedings of the 24th International Congress on Sound and Vibration, , London, UK, 23–27 July; Dalmeijer, R., Straw bale sound insulation and acoustics (2006) Last Straw. Int. J. Straw Bale Nat. Buid, p. 53. , http://www.thelaststraw.org/strawbale-sound-isolation-acoustics/, (accessed on 1 July 2013); Deverell, R., Goodhew, S., Griffiths, R., De Wilde, P., The noise insulation properties of non-food-crop walling for schools and colleges: A case study (2009) J. Build. Apprais, 5, pp. 29-40. , [CrossRef]; Dance, S., Herwin, P., Straw bale sound insulation: Blowing awy the chaff (2013) Proceedings of the Meerings on Acoustics ICA 2013, , Montreal, QC, Canada, 2–7 June; Schiavoni, S., D{\textquoteright}Alessandro, F., Bianchi, F., Asdrubali, F., Insulation materials for the building sector: A review and comparative analysis (2016) Renew. Sustain. Energy Rev, 62, pp. 988-1011. , [CrossRef]",

year = "2021",

month = jul,

day = "7",

doi = "10.3390/f12070887",

language = "English",

volume = "12",

journal = "Forests",

issn = "1999-4907",

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

number = "7",

}

TY - JOUR

T1 - Acoustic Properties of Larch Bark Panels

AU - Tudor, E.M.

AU - Kristak, L.

AU - Barbu, M.C.

AU - Gergel’, T.

AU - Němec, M.

AU - Kain, G.

AU - Réh, R.

N1 - Cited By :14 Export Date: 14 December 2023 Correspondence Address: Kristak, L.; Faculty of Wood Sciences and Technology, Slovakia; 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 details: Vedecká Grantová Agentúra MŠVVaŠ SR a SAV, VEGA, 1/0714/21, 1/0717/19 Funding text 1: Funding: 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. Funding text 2: This research was supported by the Slovak Research and Development Agency under contracts No. APVV-18-0378, APVV-19-0269, VEGA 1/0717/19 and VEGA 1/0714/21. References: Zalejska-Jonsson, A., Perceived Acoustic Quality and Effect on Occupants’ Satisfaction in Green and Conventional Residential Buildings (2019) Buildings, 9, p. 24. , [CrossRef]; Wilhelmsson, M., The Impact of Traffic Noise on the Values of Single-family Houses (2000) J. Environ. Plan. Manag, 43, pp. 799-815. , [CrossRef]; Camara, T., Kamsu-Foguem, B., Diourté, B., Faye, J.P., Hamadoun, O., Management of acoustic risks for buildings near airports (2018) Ecol. Inform, 44, pp. 43-56. , [CrossRef]; Mueller, N., Rojas-Rueda, D., Khreis, H., Cirach, M., Andrés, D., Ballester, J., Bartoll, X., Echave, C., Changing the urban design of cities for health: The superblock model (2020) Environ. Int, 134, p. 105132. , [CrossRef] [PubMed]; Shield, B., Conetta, R., A survey of acoustic conditions and noise levels in secondary school classrooms in England (2015) J. Acoust. Soc. Am, 137, p. 177. , [CrossRef]; Azkorra, Z., Pérez, G., Coma, J., Cabeza, L.F., Bures, S., Alvaro, J.E., Erkoreka, A., Urrestarazu, M., Evaluation of green walls as a passive acoustic insulation system for buildings (2015) Appl. Acoust, 89, pp. 46-56. , [CrossRef]; Gonzales, D.M., Barrigon Morillas, J.M., Godinho, L., Amado-Mendes, P., Acoustic screening effect on building facades due to parking lines in urban environments. Effects in noise mapping (2018) Appl. Acoust, 130, pp. 1-14. , [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] [PubMed]; Danihelová, A., Němec, M., Gergel’, T., Gejdoš, M., Gordanová, J., Sčensný, P., Usage of Recycled Technical Textiles as Thermal Insulation and an Acoustic Absorber (2019) Sustainaility, 11, p. 2968. , [CrossRef]; Čulík, M., Danihelová, A., Ondrejka, V., Aláč, P., Sound Absorption on Board Construction Materials Used in Wood Buildings (2020) Akustika, 37, pp. 51-57. , [CrossRef]; Silva, D.A.L., Lahr, F.A.R., Garcia, R.P., Freire, F.M.C.S., Ometto, A.R., Life cycle assessment of medium density particleboard (MDP) produced in Brazil (2013) Int. J. Life Cycle Assess, 18, pp. 1404-1411. , [CrossRef]; Branowski, B., Zabłocki, M., Sydor, M., The Material Indices Method in the Sustainable Engineering Design Process: A Review (2019) Sustainaility, 11, p. 5465. , [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. Xylologiae Zvolen, 62, pp. 27-34; Souza, A.M., Nascimento, M.F., Almeida, D.H., Lopes Silva, D.A., Almeida, T.H., Christoforo, A.L., Lahr, F.A.R., 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]; Vanova, R., Vlcko, M., Stefko, J., Life Cycle Impact Assessment of Load-Bearing Straw Bale Residential Building (2021) Materials, 14, p. 3064. , [CrossRef]; Moresova, M., Sedliacikova, M., Stefko, J., Bencikova, D., Perception of wooden houses in the Slovak Republic (2019) Acta Fac. Xylologiae Zvolen, 61, pp. 121-135; 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]; Aristri, M.A., Lubis, M.A.R., Yadav, S.M., Antov, P., Papadopoulos, A.N., Pizzi, A., Fatriasari, W., Iswanto, A.H., Recent Developments in Lignin-and Tannin-Based Non-Isocyanate Polyurethane Resins for Wood Adhesives—A Review (2021) Appl. Sci, 11, p. 4242. , [CrossRef]; dos Santos, M.F.N., Battistelle, R.A.G., Bezerra, B.S., Varum, H.S.A., Comparative study of the life cycle assessment of particle-boards made of residues from sugarcane bagasse (Saccharum spp.) and pine wood shavings (Pinus elliottii) (2014) J. Clean. Prod, 64, pp. 345-355. , [CrossRef]; Battistelle, R.A.G., Fujino, D.M., Silva, A.L.C., Bezerra, B.S., Valarelli, I.D., Physical and mechanical characterization of sugarcane bagasse particleboards for civil construction (2016) J. Sustain. Dev. Energy Water Environ. Syst, 4, pp. 408-417. , [CrossRef]; Hejna, A., Barczewski, M., Skórczewska, K., Szulc, J., Chmielnicki, B., Korol, J., Formela, K., Sustainable upcycling of brewers’ spent grain by thermo-mechanical treatment in twin-screw extruder (2021) J. Clean. Prod, 285, p. 124839. , [CrossRef]; Liuzzi, S., Rubino, C.H., Stefanizzi, P., Martellotta, F., Performance Characterization of Broad Band Sustainable Sound Absorbers Made of Almond Skins (2020) Materials, 13, p. 5474. , [CrossRef] [PubMed]; Rammou, E., Mitani, A., Ntalos, G., Koutsianitis, D., Taghiyari, H.R., Papadopoulos, A.N., The Potential Use of Seaweed (Posidonia oceanica) as an Alternative Lignocellulosic Raw Material for Wood Composites Manufacture (2021) Coatings, 11, p. 69. , [CrossRef]; Potkány, M., Gejdoš, M., Debnár, M., Sustainable Innovation Approach for Wood Quality Evaluation in Green Business (2018) Sustainability, 10, p. 2984. , [CrossRef]; Bohatkiewicz, J., Noise Control Plans in Cities–Selected Issues and Necessary Changes in Approach to Measures and Methods of Protectin (2016) Transp. Res. Procedia, 14, pp. 2744-2753. , [CrossRef]; Peng, L., Sound absorption and insulation functional composites (2017) Advanced High Strength Natural Fibre Composites in Construction, pp. 333-373. , Woodhead Publishing: Cambridge, UK; 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]; Desarnaulds, V., Costanzo, E., Carvalho, A., Aurlaud, B., Sustainability of acoustic materials and acoustic characterization of sustainable materials (2005) Proceedings of the 12th International Congress on Sound and Vibration (ICSV12), , Lisbon, Portugal, 11–14 July; Pedroso, M., de Brito, J., Silvestre, J., Characterization of eco-efficient acoustic insulation materials (traditional and innovative) (2017) Constr. Build. Mater, 140, pp. 221-228. , [CrossRef]; Jensen, M.S., Alfieri, P.V., Design and manufacture of insulation panels based on recycled lignocellulosic waste (2021) Clean. Eng. Technol, 3, p. 100111. , [CrossRef]; Asdrubali, F., Schiavoni, S., Horoshenkov, K.V., A Review of Sustainable Materials for Acoustic Applications (2012) Build. Acoust, 19, pp. 283-311. , [CrossRef]; D’Alessandro, F., Pispola, G., Sound absorption properties of sustainable fibrous materials in an enhanced reverberation room (2005) Proceedings of the Internoise 2005, , Rio de Janeiro, Brazil, 7–10 August; Fouladi, M.H., Ayub, M., Nor, M.J.M., Analysis of coir fiber acoustical characteristics (2011) Appl. Acoust, 72, pp. 35-42. , [CrossRef]; Oldham, D.J., Egan, C.A., Cookson, R.D., Sustainable acoustic absorbers from the biomass (2011) Appl. Acoust, 72, pp. 350-363. , [CrossRef]; Jiang, W., Adamopoulos, S., Hosseinpourpia, R., Žigon, J., Petrič, M., Šernek, M., Medved, S., Utilization of Partially Liquefied Bark for Production of Particleboards (2020) Appl. Sci, 10, p. 5253. , [CrossRef]; Fatima, S., Mohanty, A.R., Acoustical and fire-retardant properties of jute composite materials (2011) Appl. Acoust, 72, pp. 108-114. , [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]; Salit, M.S., Tropical natural fibres and their properties (2014) Tropical Natural Fibre Composites. Engineering Materials, pp. 15-38. , Springer: Singapore; 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]; Kairytė, A., Kremensas, A., Balčiūnas, G., Matulaitiene, I., Członka, S., Sienkiewicz, N., Evaluation of self-thermally treated wood plastic composites from wood bark and rapeseed oil-based binder (2020) Constr. Build. Mater, 250, p. 118842. , [CrossRef]; Abilleira, F., Varela, P., Cancela, A., Alvarez, X., Sanchez, A., Valero, E., Tannins extraction from Pinus pinaster and Acacia dealbata bark with applications in the industry (2021) Ind. Crop. Prod, 164, p. 113394. , [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]; 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]; Martin, R.E., Thermal properties of bark (1963) For. Prod. J, 13, pp. 419-426; 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]; 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]; 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., 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]; 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] [PubMed]; 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] [PubMed]; 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]; Tudor, E.M., Zwickl, C., Eichinger, C., Petutschnigg, A., Barbu, M.C., Performance of softwood bark comminution technologies for determinantion of targeted particle size in further upcycling applications (2020) J. Clean. Prod, 269, p. 122412. , [CrossRef]; Tudor, E.M., Barbu, M.C., Cost analysis of larch bark coatings for flooring tiles (2020) ProLigno, 16, pp. 46-51; Pásztory, Z., Börcsök, Z., Tsalagkas, D., Density optimization for the manufacturing of bark-based thermal insulation panels (2019) IOP Conference Series: Earth and Environmental Science, Proceedings of the 5th International Conference on Environment and Renewable Energy, 307. , Ho Chi Minh City, Vietnam, 25–28 February IOP Publishing Ltd.: Bristol, UK, 2019; Tsalagkas, D., Börcsök, Z., Pásztory, Z., Thermal, physical and mechanical properties of surface overlaid bark-based insulation panels (2019) Eur. J. Wood Prod, 77, pp. 721-730. , [CrossRef]; Taban, E., Mirzaei, R., Faridan, M., Samaei, E., Salimi, F., Tajpoor, A., Ghalenoei, M., Morphological, acoustical, mechanical and thermal properties of sustainable green Yucca (Y. gloriosa) fibers: An exploratory investigation (2020) J. Environ. Health Sci. Eng, 18, pp. 883-896. , [CrossRef]; Smardzewski, J., Batko, W., Kamisiński, T., Flach, A., Pilch, A., Dziurka, D., Mirski, R., Majewski, A., Experimental study of wood acoustic absorption characteristics (2013) Holzforschung, 68, p. 160. , [CrossRef]; (2005) EN 326-1:2005 Wood Based Panels—Sampling, Cutting and Inspection—Part 1: Sampling and Cutting of Test Pieces and Expression of Test Results, , European Committee for Standardization. European Committee for Standardization: Brussels, Belgium; Graphite Polystyren, Isover EPS Greywall, , https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk_technicky-list_isover-eps_greywall.pdf, (accessed on 1 June 2021); https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk_technicky-list_isover-eps_200s.pdf, White Polystyrene—Polyform EPS 200S. (accessed on 1 June 2021); https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk_isover-styrodur_3000_cs_technicky_list.pdf, Extruded Polystyrene—Isover. (accessed on 1 June 2021); https://tepore.sk/wp-content/uploads/2018/03/STEICO-Flex-036_CZ.pdf, Fiberboard—Steico Flex 036. (accessed on 1 June 2021); Mineral Wool—Isover TF Thermo, , https://www.isover.sk/sites/isover.sk/files/assets/documents/isover-sk_isover_tf_thermo_epd_en.pdf, (accessed on 1 June 2021); Masonite Board—Steico Protect, , https://www.jafholz.sk/action/shop/pdf?product=1351400, (accessed on 1 June 2021); https://www.korok.sk/data/files/jcg_insulation-cataloque-eng_43.pdf, Cork Boards. (accessed on 1 June 2021); (2002) Acoustics—Determination of Sound Absorption Coefficient and Impedance in Impedance Tubes—Part 2: Transfer-Function Method, , EN ISO 10534-2. European Committee for Standardization (CEN): Brüssel, Belgium; Morgans, R.C., Li, X., Zander, A.C., Hansen, C.H., Statistics and the Two Microphone Method for the Measurement of Sound Absorption Coefficient (2004) Proc. Acoust, 15, pp. 3-5; (2017) Acoustics—Sound Absorbers—Rating of Sound Absorption Coefficients, , EN ISO 11654. European Committee for Standardization (CEN): Brüssel, Belgium; Nordin, M.N.A.A., Wan, L.M., Zainulabidin, M.H., Kassim, A.S.M., Aripin, A.M., Research finding in natural fibers sound absorbing material (2016) ARPN J. Eng. Appl. Sci, 11, pp. 8579-8584; Echeverria, C.A., Pahlevani, F., Handoko, W., Jiang, C., Doolan, C., Sahajwalla, V., Engineered hybrid fibre reinforced composites for sound absorption building applications (2019) Resour. Conserv. Recycl, 143, pp. 1-14. , [CrossRef]; Boubel, A., Garoum, M., Bousshine, S., Bybi, A., Investigation of loose wood chips and sawdust as alternative sustainable sound absorber materials (2021) Appl. Acoust, 172, p. 107639. , [CrossRef]; Limited, K., (2005) Acoustic Performance Guide, , Kingspan Limited: Holywell, UK; Koizumi, T., Tsujiuchi, N., Adachi, A., The development of sound absorbing materials using natural bamboo fibers (2002) WIT Trans. Built Environ, 59, pp. 157-166; Arenas, J.P., Asdrubali, F., Eco-Materials with Noise Reduction Properties (2018) Handbook of Ecomaterials, , Martinez, L.M.T., Kharissova, O.V., Kharisov, B.I., Eds.; Springer International Publishing AG: New York, NY, USA; Hassani, P., Soltani, P., Ghane, M., Zarrebini, M., Porous resin-bonded recycled denim composite as an efficient sound-absorbing material (2021) Appl. Acoust, 173, p. 107710. , [CrossRef]; Arenas, J.P., Crocker, M.J., Recent Trends in Porous Sound-Absorbing Materials (2010) Sound Vib, 44, pp. 12-18; Akay, A., Acoustics of friction (2002) J. Acoust. Soc. Am, 111, pp. 1525-1548. , [CrossRef]; Amares, S., Sujatmika, E., Hong, T.W., Durairaj, R., Hamid, H.S.H.B., A Review: Characteristics of Noise Absorption Material (2017) J. Phys. Conf. Ser, 908, p. 012005. , [CrossRef]; Soltani, P., Zerrebini, M., The analysis of acoustical characteristics and sound absorption coefficient of woven fabrics (2012) Text. Res. J, 82, pp. 875-882. , [CrossRef]; Karlinasari, L., Hermawan, D., Maddu, A., Bagus, M., Lucky, I.K., Nugroho, N., Hadi, Y.S., Acoustical Properties of Particleboards Made from Betung Bamboo (Dendrocalamus asper) as Building Construction Material (2012) Bioresources, 7, pp. 5700-5709. , [CrossRef]; Karlinasari, L., Hermawan, D., Maddu, A., Martiandi, B., Hadi, Y.S., Development of particleboard from tropical fast-growing Species for acoustic panel (2012) J. Trop. For. Sci, 24, pp. 64-69; Luu, H.T., Perrot, C., Panneton, R., Influence of porosity, fiber radius and fiber orientation on the transport and acoustic properites of random fiber structures (2017) Acta Acust. United Acust, 103, pp. 1050-1063. , [CrossRef]; Aditya, L., Mahlia, T.M.I., Rismanchi, B., Ng, H.M., Hasan, M.H., Metselaar, H.S.C., Muraza, O., Aditiya, H.B., A review on insulation materials for energy conservation in buildings (2017) Renew. Sustain. Energy Rev, 73, pp. 1352-1365. , [CrossRef]; Niu, M., Hagman, O., Wang, X., Xie, Y., Karlsson, O., Cai, L., Effect of Si-Al Compounds on Fire Properties of Ultra-low Density Fiberboard (2014) Bioresources, 9, pp. 2415-2430. , [CrossRef]; Chen, T., Liu, J., Wu, Z., Wang, W., Niu, M., Wang, X., Xie, Y., Evaluating the Effectiveness of Comples Fire-Retardants on the Fire Properties of Ultra-low Density Fiberboard (ULDF) (2016) Bioresources, 11, pp. 1796-1807; Pausas, J.G., Bark thickness and fire regime (2014) Funct. Ecol, 29, pp. 315-327. , [CrossRef]; D’Alessandro, F., Schiavoni, S., Bianchi, F., Straw as an acoustic material (2017) Proceedings of the 24th International Congress on Sound and Vibration, , London, UK, 23–27 July; Dalmeijer, R., Straw bale sound insulation and acoustics (2006) Last Straw. Int. J. Straw Bale Nat. Buid, p. 53. , http://www.thelaststraw.org/strawbale-sound-isolation-acoustics/, (accessed on 1 July 2013); Deverell, R., Goodhew, S., Griffiths, R., De Wilde, P., The noise insulation properties of non-food-crop walling for schools and colleges: A case study (2009) J. Build. Apprais, 5, pp. 29-40. , [CrossRef]; Dance, S., Herwin, P., Straw bale sound insulation: Blowing awy the chaff (2013) Proceedings of the Meerings on Acoustics ICA 2013, , Montreal, QC, Canada, 2–7 June; Schiavoni, S., D’Alessandro, F., Bianchi, F., Asdrubali, F., Insulation materials for the building sector: A review and comparative analysis (2016) Renew. Sustain. Energy Rev, 62, pp. 988-1011. , [CrossRef]

PY - 2021/7/7

Y1 - 2021/7/7

N2 - The potential of tree bark, a by-product of the woodworking industry, has been studied for more than seven decades. Bark, as a sustainable raw material, can replace wood or other resources in numerous applications in construction. In this study, the acoustic properties of bark-based panels were analyzed. The roles of the particle size (4–11 mm and 10–30 mm), particle orientation (parallel and perpendicular) and density (350–700 kg/m3 ) of samples with 30 mm and 60 mm thicknesses were studied at frequencies ranging from 50 to 6400 Hz. Bark-based boards with fine-grained particles have been shown to be better in terms of sound absorption coefficient values compared with coarse-grained particles. Bark composites mixed with popcorn bonded with UF did not return the expected results, and it is not possible to recommend this solution. The best density of bark boards to obtain the best sound absorption coefficients is about 350 kg/m3 . These lightweight panels achieved better sound-absorbing properties (especially at lower frequencies) at higher thicknesses. The noise reduction coefficient of 0.5 obtained a sample with fine particles with a parallel orientation and a density of around 360 kg/m3 .

AB - The potential of tree bark, a by-product of the woodworking industry, has been studied for more than seven decades. Bark, as a sustainable raw material, can replace wood or other resources in numerous applications in construction. In this study, the acoustic properties of bark-based panels were analyzed. The roles of the particle size (4–11 mm and 10–30 mm), particle orientation (parallel and perpendicular) and density (350–700 kg/m3 ) of samples with 30 mm and 60 mm thicknesses were studied at frequencies ranging from 50 to 6400 Hz. Bark-based boards with fine-grained particles have been shown to be better in terms of sound absorption coefficient values compared with coarse-grained particles. Bark composites mixed with popcorn bonded with UF did not return the expected results, and it is not possible to recommend this solution. The best density of bark boards to obtain the best sound absorption coefficients is about 350 kg/m3 . These lightweight panels achieved better sound-absorbing properties (especially at lower frequencies) at higher thicknesses. The noise reduction coefficient of 0.5 obtained a sample with fine particles with a parallel orientation and a density of around 360 kg/m3 .

KW - Acoustic performance

KW - Bark-based panels

KW - Construction materials

KW - Sound absorption coefficient

KW - Sustainable materials

KW - Acoustic properties

KW - Noise abatement

KW - Particle size

KW - Sound insulating materials

KW - Woodworking

KW - Coarse grained particles

KW - Fine-grained particles

KW - Parallel orientation

KW - Particle orientation

KW - Reduction coefficient

KW - Sound absorption coefficients

KW - Sustainable raw materials

KW - Woodworking industry

KW - Acoustic wave absorption

KW - absorption coefficient

KW - acoustic data

KW - construction material

KW - frequency analysis

KW - wood

KW - Acoustic Properties

KW - Bark

KW - Density

KW - Orientation

KW - Panels

KW - Particle Size

KW - Particles

KW - Sound Absorption

UR - https://www.mendeley.com/catalogue/99cd1ce9-10c0-3232-8181-a1313f99c13e/

U2 - 10.3390/f12070887

DO - 10.3390/f12070887

M3 - Article

SN - 1999-4907

VL - 12

JO - Forests

JF - Forests

IS - 7

ER -

Acoustic Properties of Larch Bark Panels

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this