Added-value for wood bark as a coating layer for flooring tiles

E.M. Tudor; M.C. Barbu; A. Petutschnigg; R. Réh

doi:10.1016/j.jclepro.2017.09.156

Added-value for wood bark as a coating layer for flooring tiles

E.M. Tudor^*, M.C. Barbu, A. Petutschnigg, R. Réh

^*Corresponding author for this work

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

Abstract

Worldwide more than 50% of the bark amount is used for energy generation. In this research, physico-mechanical and surface properties of flooring tiles coated with thin layers made of larch bark are presented for the first time. Two types of adhesives were involved to bond the bark particles, namely polyurethane and a formaldehyde-free tannin-hexamine resin. Larch (Larix decidua Mill.) bark was used to produce layers with 3 mm thickness at three levels of density, from 0.6 to 0.8 g/cm³ to coat standard high density fiberboard (HDF) as core material. Mechanical and physical properties of the specimens including surface soundness, Brinell hardness, dimensional stability, abrasion resistance, cross-cut test, resistance to chemicals and fire resistance of the bark coated panels were determined and compared with the properties of industrial multilayered boards with granulated cork as wear layer. Overall, excepting the Brinell hardness, all the properties of the boards produced with wear layer made of larch bark were lower compared to cork-based coated control. Surface soundness of panels with larch wear layer was 30% or 60% lower compared to control. Both thickness swelling and water absorption after 24 h of the panels were too high. Neither polyurethane nor formaldehyde-free tannin adhesive influenced better the panel's properties. Surface properties were similar to control. Although mechanical properties of the samples considered in this work were inferior to those of typical flooring material coated with cork layer, it can be stated that such a little used material like bark may have a useful potential as a value-added product for such application. © 2017 Elsevier Ltd

Original language	English
Pages (from-to)	1354-1360
Number of pages	7
Journal	J. Clean. Prod.
Volume	170
DOIs	https://doi.org/10.1016/j.jclepro.2017.09.156
Publication status	Published - 2018

Keywords

Floorings
Larch bark
Polyurethane
Tannin
Value-added
Wear layers
Building materials
Coremaking
Flavonoids
Floors
Formaldehyde
Industrial chemicals
Polyurethanes
Surface properties
Tannins
Water absorption
Flooring materials
Mechanical and physical properties
Multilayered boards
Thickness swelling
Value added products
Fire resistance
Bark
Coating
Fiber Boards
Surface Properties
Tile
Wood

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10.1016/j.jclepro.2017.09.156

Cite this

@article{daa1c401a6b847009c7999bc5de9b42e,

title = "Added-value for wood bark as a coating layer for flooring tiles",

abstract = "Worldwide more than 50\% of the bark amount is used for energy generation. In this research, physico-mechanical and surface properties of flooring tiles coated with thin layers made of larch bark are presented for the first time. Two types of adhesives were involved to bond the bark particles, namely polyurethane and a formaldehyde-free tannin-hexamine resin. Larch (Larix decidua Mill.) bark was used to produce layers with 3 mm thickness at three levels of density, from 0.6 to 0.8 g/cm³ to coat standard high density fiberboard (HDF) as core material. Mechanical and physical properties of the specimens including surface soundness, Brinell hardness, dimensional stability, abrasion resistance, cross-cut test, resistance to chemicals and fire resistance of the bark coated panels were determined and compared with the properties of industrial multilayered boards with granulated cork as wear layer. Overall, excepting the Brinell hardness, all the properties of the boards produced with wear layer made of larch bark were lower compared to cork-based coated control. Surface soundness of panels with larch wear layer was 30\% or 60\% lower compared to control. Both thickness swelling and water absorption after 24 h of the panels were too high. Neither polyurethane nor formaldehyde-free tannin adhesive influenced better the panel's properties. Surface properties were similar to control. Although mechanical properties of the samples considered in this work were inferior to those of typical flooring material coated with cork layer, it can be stated that such a little used material like bark may have a useful potential as a value-added product for such application. {\textcopyright} 2017 Elsevier Ltd",

keywords = "Floorings, Larch bark, Polyurethane, Tannin, Value-added, Wear layers, Building materials, Coremaking, Flavonoids, Floors, Formaldehyde, Industrial chemicals, Polyurethanes, Surface properties, Tannins, Water absorption, Flooring materials, Mechanical and physical properties, Multilayered boards, Thickness swelling, Value added products, Fire resistance, Bark, Coating, Fiber Boards, Surface Properties, Tile, Wood",

author = "E.M. Tudor and M.C. Barbu and A. Petutschnigg and R. R{\'e}h",

note = "Cited By :28 Export Date: 14 December 2023 CODEN: JCROE Correspondence Address: Tudor, E.M.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected] References: Barbu, M., Current developments in the forestry and wood industry (2011) ProLigno, 7 (4), pp. 111-124; Dix, B., Marutzky, R., Verleimung von Spanplatten mit Tannin-Formaldehydharzen aus dem Rindenextrakt von Pinus radiata (1984) Holz als Roh- Werkst. Band, 42, pp. 209-217; Einspahr, D.W., Harder, M., Hardwood Bark Properties Important to the Manufacture of Fiber Products (1975), Institute of paper chemistry Appleton, Wisconsin; EN 11925-2, Reaction to Fire Tests - Ignitability of Products Subjected to Direct Impingement of Flame - Part 2: Single-flame Source Test (2010); Packaging - Requirements for Packaging Recoverable through Composting and Biodegradation - Test Scheme and Evaluation Criteria for the Final Acceptance of Packaging, —test Method (2000), EN 13432, CEN, European Committee for Standardization Brussels; Wood flooring and Wood Panneling and Cladding – Determination of the Resistance to Chemical Agents (2013), EN 13442, CEN, European Committee for Standardization Brussels; Wood-based Panels - Wood Veneer Floor Coverings (2014), EN 14354, CEN, European Committee for Standardization Brussels; Wood flooring - Determination of Resistance to Indentation - Test Method, —test Method (2011), EN 1534, CEN, European Committee for Standardization Brussels; Wood-based Panels. Surface Soundness. Test Method, —test Method (2002), EN 311, CEN, European Committee for Standardization Brussels; Particleboards and Fibreboards; Determination of Swelling in Thickness after Immersion in Water, —test Method (2005), EN 317, CEN, European Committee for Standardization Brussels; Wood-based Panels - Determination of Moisture Content, —test Method (2005), EN 322, CEN, European Committee for Standardization Brussels; Wood-based Panels - Sampling, Cutting and Inspection - Part 1: Sampling and Cutting of Test Pieces and Expression of Test Results, —test Method (1994), EN 326-1, CEN, European Committee for Standardization Brussels; Reaction to Fire Tests - Ignitability of Products Subjected to Direct Impingement of Flame - Part 2: Single-flame Source Test, —test Method (2011), EN ISO 11925–2, CEN, European Committee for Standardization Brussels; Franek, F., Badisch, E., Kirchga{\ss}ner, M., Advanced methods for characterisation of abrasion/erosion resistance of wear protection materials (2009) FME Trans., 2 (37), pp. 61-70. , April; Grabner, M., Wimmer, R., Gierlinger, N., Evans, R., Downes, G., Heartwood extractives in larch and effects on X-ray densitometry (2005) Can. J. For. Res., 35, pp. 2781-2786; Han, G., Wu, Q., Lu, J.Z., The influence of fines content and panel density on properties of mixed hardwood oriented strand boards (2007) Wood Fiber Sci., 39 (1), pp. 2-15; Heinzmann, B., Barbu, M.C., Untersuchungen zur Steigerung der Wertsch{\"o}pfung von Rinde durch Verperssen zu Pallettenk{\"o}tzen (2013) Holztechnologie, 54 (5), pp. 25-32; Hirata, S., Ohta, M., Honma, Y., Hardness distribution on wood surface (2001) J. Wood Sci., 47 (1), pp. 1-7; Janssen, J., Laatz, W., Statistische Datenanalyse mit SPSS. 8 Hrsg (2013), Springer Gabler Heidelberg; Kain, G., Stoffliche Rindennutzung in Form von D{\"a}mmstoffe (2013), p. 164. , AV Akademikerverlag; Kain, G., Density related properties of bark insulation boards bonded with tannin hexamine resin (2014) Eur. J. Wood Prod., 72, pp. 417-424. , Band; Krauhausen, J., Kaskaden-nutzung Zur{\"u}ckhalten (2013), p. 1. , Holz-Zentrallblatt Band 48; Link, C., Kraft, R., Kharazipour, A., Baumrinden als Alternativrohstoff zur Spanplattenherstellung (2013), 3, pp. 21-26. , Holztechnologie Band; Mantau, U., Real Potential for Changes in Growth and Use of EU Forests, Final Report (2010), p. 160. , Hamburg/Germany; Papadopoulos, A.N., Property comparisons and bonding efficiency of UF and pMDI bonded particleboards as affected by key process variables (2006) Bioresources, 1, pp. 201-208; Pasztory, Z., Ronyecz, I., The thermal insulation capacity of tree bark (2013) Acta Silv. lign. hung., 9, pp. 111-117. , Band; Paulitsch, M., Barbu, M., Holzwerkstoffe der Moderne (2015), p. 532. , DRW-Verlag Leinfelden-Echterdingen; Pelz, S., Eigenschaften und Verwendung des Holzes der Europ{\"a}ischen L{\"a}rche (Larix decidua MILL.) unter besonderer Ber{\"u}cksichtigung des Reaktionsholzes (2002), Universit{\"a}t Freiburg Dissertation; Pereira, H., Chemical composition and variability of cork from Quercus suber L (1998) Wood Sci. Technol., 22 (3), pp. 211-218; Pereira, H., Cork: Biology, Production and Uses (2007), p. 346. , Elsevier Amsterdam; Pizzi, A., Mittal, K.L., Handbook of Adhesive Technology (2003), second ed. Taylor and Francis Group, LLC New York; Raymond, C., Influence of wood density and fibre length on properties of medium density fibreboard manufactured from Pinus radiata (2008) J. Tech. Assoc. Aust. N. Z. Pulp Pap. Ind., 60 (3), pp. 204-208; Sachsse, H., Eigenschaften und Verwertung des L{\"a}rchenholzes (1979) Allg. Forstz., 34 (6), pp. 118-122; Schadauer, K., Lackner, C., {\"O}sterreichische Waldinventur 2007/09, Bundesforschungs- und Ausbildungszentrum f{\"u}r Wald (2011), Naturgefahren und Landschaft; Tritkov, N., Mihailova, J., Jordanova, S., Possibilities for Utilization of Bark of Scots Pine for Particleboards Manufacturing. COST Action (2006), pp. E44-E49. , Valencia, Spain; Tudor, E., Bark as a Substitute of Cork for Flooring Tiles (2014), Salzburg University of Applied Sciences Kuchl Master thesis); Wollenberg, R., Warnecke, C., Neue Einsatzgebiete f{\"u}r Rinden durch Produktentwicklung, Abschlussbericht zu dem vom Bundesministerium f{\"u}r Verbraucherschutz (2004), Ern{\"a}hrung und Landwirtschaft gef{\"o}rdertem Projekt; Wolpers, S., Eignung von D{\"u}nnschichtplatten aus Baumrinde zur Verwendung als Fu{\ss}bodenbelag (2015), Salzburg University of Applied Sciences Kuchl Master thesis)UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85031919966\&doi=10.1016\%2fj.jclepro.2017.09.156\&partnerID=40\&md5=e628c03e0a908c104c74ad255c1498ae",

year = "2018",

doi = "10.1016/j.jclepro.2017.09.156",

language = "English",

volume = "170",

pages = "1354--1360",

journal = "J. Clean. Prod.",

issn = "0959-6526",

publisher = "Elsevier Ltd",

}

TY - JOUR

T1 - Added-value for wood bark as a coating layer for flooring tiles

AU - Tudor, E.M.

AU - Barbu, M.C.

AU - Petutschnigg, A.

AU - Réh, R.

N1 - Cited By :28 Export Date: 14 December 2023 CODEN: JCROE Correspondence Address: Tudor, E.M.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected] References: Barbu, M., Current developments in the forestry and wood industry (2011) ProLigno, 7 (4), pp. 111-124; Dix, B., Marutzky, R., Verleimung von Spanplatten mit Tannin-Formaldehydharzen aus dem Rindenextrakt von Pinus radiata (1984) Holz als Roh- Werkst. Band, 42, pp. 209-217; Einspahr, D.W., Harder, M., Hardwood Bark Properties Important to the Manufacture of Fiber Products (1975), Institute of paper chemistry Appleton, Wisconsin; EN 11925-2, Reaction to Fire Tests - Ignitability of Products Subjected to Direct Impingement of Flame - Part 2: Single-flame Source Test (2010); Packaging - Requirements for Packaging Recoverable through Composting and Biodegradation - Test Scheme and Evaluation Criteria for the Final Acceptance of Packaging, —test Method (2000), EN 13432, CEN, European Committee for Standardization Brussels; Wood flooring and Wood Panneling and Cladding – Determination of the Resistance to Chemical Agents (2013), EN 13442, CEN, European Committee for Standardization Brussels; Wood-based Panels - Wood Veneer Floor Coverings (2014), EN 14354, CEN, European Committee for Standardization Brussels; Wood flooring - Determination of Resistance to Indentation - Test Method, —test Method (2011), EN 1534, CEN, European Committee for Standardization Brussels; Wood-based Panels. Surface Soundness. Test Method, —test Method (2002), EN 311, CEN, European Committee for Standardization Brussels; Particleboards and Fibreboards; Determination of Swelling in Thickness after Immersion in Water, —test Method (2005), EN 317, CEN, European Committee for Standardization Brussels; Wood-based Panels - Determination of Moisture Content, —test Method (2005), EN 322, CEN, European Committee for Standardization Brussels; Wood-based Panels - Sampling, Cutting and Inspection - Part 1: Sampling and Cutting of Test Pieces and Expression of Test Results, —test Method (1994), EN 326-1, CEN, European Committee for Standardization Brussels; Reaction to Fire Tests - Ignitability of Products Subjected to Direct Impingement of Flame - Part 2: Single-flame Source Test, —test Method (2011), EN ISO 11925–2, CEN, European Committee for Standardization Brussels; Franek, F., Badisch, E., Kirchgaßner, M., Advanced methods for characterisation of abrasion/erosion resistance of wear protection materials (2009) FME Trans., 2 (37), pp. 61-70. , April; Grabner, M., Wimmer, R., Gierlinger, N., Evans, R., Downes, G., Heartwood extractives in larch and effects on X-ray densitometry (2005) Can. J. For. Res., 35, pp. 2781-2786; Han, G., Wu, Q., Lu, J.Z., The influence of fines content and panel density on properties of mixed hardwood oriented strand boards (2007) Wood Fiber Sci., 39 (1), pp. 2-15; Heinzmann, B., Barbu, M.C., Untersuchungen zur Steigerung der Wertschöpfung von Rinde durch Verperssen zu Pallettenkötzen (2013) Holztechnologie, 54 (5), pp. 25-32; Hirata, S., Ohta, M., Honma, Y., Hardness distribution on wood surface (2001) J. Wood Sci., 47 (1), pp. 1-7; Janssen, J., Laatz, W., Statistische Datenanalyse mit SPSS. 8 Hrsg (2013), Springer Gabler Heidelberg; Kain, G., Stoffliche Rindennutzung in Form von Dämmstoffe (2013), p. 164. , AV Akademikerverlag; Kain, G., Density related properties of bark insulation boards bonded with tannin hexamine resin (2014) Eur. J. Wood Prod., 72, pp. 417-424. , Band; Krauhausen, J., Kaskaden-nutzung Zurückhalten (2013), p. 1. , Holz-Zentrallblatt Band 48; Link, C., Kraft, R., Kharazipour, A., Baumrinden als Alternativrohstoff zur Spanplattenherstellung (2013), 3, pp. 21-26. , Holztechnologie Band; Mantau, U., Real Potential for Changes in Growth and Use of EU Forests, Final Report (2010), p. 160. , Hamburg/Germany; Papadopoulos, A.N., Property comparisons and bonding efficiency of UF and pMDI bonded particleboards as affected by key process variables (2006) Bioresources, 1, pp. 201-208; Pasztory, Z., Ronyecz, I., The thermal insulation capacity of tree bark (2013) Acta Silv. lign. hung., 9, pp. 111-117. , Band; Paulitsch, M., Barbu, M., Holzwerkstoffe der Moderne (2015), p. 532. , DRW-Verlag Leinfelden-Echterdingen; Pelz, S., Eigenschaften und Verwendung des Holzes der Europäischen Lärche (Larix decidua MILL.) unter besonderer Berücksichtigung des Reaktionsholzes (2002), Universität Freiburg Dissertation; Pereira, H., Chemical composition and variability of cork from Quercus suber L (1998) Wood Sci. Technol., 22 (3), pp. 211-218; Pereira, H., Cork: Biology, Production and Uses (2007), p. 346. , Elsevier Amsterdam; Pizzi, A., Mittal, K.L., Handbook of Adhesive Technology (2003), second ed. Taylor and Francis Group, LLC New York; Raymond, C., Influence of wood density and fibre length on properties of medium density fibreboard manufactured from Pinus radiata (2008) J. Tech. Assoc. Aust. N. Z. Pulp Pap. Ind., 60 (3), pp. 204-208; Sachsse, H., Eigenschaften und Verwertung des Lärchenholzes (1979) Allg. Forstz., 34 (6), pp. 118-122; Schadauer, K., Lackner, C., Österreichische Waldinventur 2007/09, Bundesforschungs- und Ausbildungszentrum für Wald (2011), Naturgefahren und Landschaft; Tritkov, N., Mihailova, J., Jordanova, S., Possibilities for Utilization of Bark of Scots Pine for Particleboards Manufacturing. COST Action (2006), pp. E44-E49. , Valencia, Spain; Tudor, E., Bark as a Substitute of Cork for Flooring Tiles (2014), Salzburg University of Applied Sciences Kuchl Master thesis); Wollenberg, R., Warnecke, C., Neue Einsatzgebiete für Rinden durch Produktentwicklung, Abschlussbericht zu dem vom Bundesministerium für Verbraucherschutz (2004), Ernährung und Landwirtschaft gefördertem Projekt; Wolpers, S., Eignung von Dünnschichtplatten aus Baumrinde zur Verwendung als Fußbodenbelag (2015), Salzburg University of Applied Sciences Kuchl Master thesis)UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85031919966&doi=10.1016%2fj.jclepro.2017.09.156&partnerID=40&md5=e628c03e0a908c104c74ad255c1498ae

PY - 2018

Y1 - 2018

N2 - Worldwide more than 50% of the bark amount is used for energy generation. In this research, physico-mechanical and surface properties of flooring tiles coated with thin layers made of larch bark are presented for the first time. Two types of adhesives were involved to bond the bark particles, namely polyurethane and a formaldehyde-free tannin-hexamine resin. Larch (Larix decidua Mill.) bark was used to produce layers with 3 mm thickness at three levels of density, from 0.6 to 0.8 g/cm³ to coat standard high density fiberboard (HDF) as core material. Mechanical and physical properties of the specimens including surface soundness, Brinell hardness, dimensional stability, abrasion resistance, cross-cut test, resistance to chemicals and fire resistance of the bark coated panels were determined and compared with the properties of industrial multilayered boards with granulated cork as wear layer. Overall, excepting the Brinell hardness, all the properties of the boards produced with wear layer made of larch bark were lower compared to cork-based coated control. Surface soundness of panels with larch wear layer was 30% or 60% lower compared to control. Both thickness swelling and water absorption after 24 h of the panels were too high. Neither polyurethane nor formaldehyde-free tannin adhesive influenced better the panel's properties. Surface properties were similar to control. Although mechanical properties of the samples considered in this work were inferior to those of typical flooring material coated with cork layer, it can be stated that such a little used material like bark may have a useful potential as a value-added product for such application. © 2017 Elsevier Ltd

AB - Worldwide more than 50% of the bark amount is used for energy generation. In this research, physico-mechanical and surface properties of flooring tiles coated with thin layers made of larch bark are presented for the first time. Two types of adhesives were involved to bond the bark particles, namely polyurethane and a formaldehyde-free tannin-hexamine resin. Larch (Larix decidua Mill.) bark was used to produce layers with 3 mm thickness at three levels of density, from 0.6 to 0.8 g/cm³ to coat standard high density fiberboard (HDF) as core material. Mechanical and physical properties of the specimens including surface soundness, Brinell hardness, dimensional stability, abrasion resistance, cross-cut test, resistance to chemicals and fire resistance of the bark coated panels were determined and compared with the properties of industrial multilayered boards with granulated cork as wear layer. Overall, excepting the Brinell hardness, all the properties of the boards produced with wear layer made of larch bark were lower compared to cork-based coated control. Surface soundness of panels with larch wear layer was 30% or 60% lower compared to control. Both thickness swelling and water absorption after 24 h of the panels were too high. Neither polyurethane nor formaldehyde-free tannin adhesive influenced better the panel's properties. Surface properties were similar to control. Although mechanical properties of the samples considered in this work were inferior to those of typical flooring material coated with cork layer, it can be stated that such a little used material like bark may have a useful potential as a value-added product for such application. © 2017 Elsevier Ltd

KW - Floorings

KW - Larch bark

KW - Polyurethane

KW - Tannin

KW - Value-added

KW - Wear layers

KW - Building materials

KW - Coremaking

KW - Flavonoids

KW - Floors

KW - Formaldehyde

KW - Industrial chemicals

KW - Polyurethanes

KW - Surface properties

KW - Tannins

KW - Water absorption

KW - Flooring materials

KW - Mechanical and physical properties

KW - Multilayered boards

KW - Thickness swelling

KW - Value added products

KW - Fire resistance

KW - Bark

KW - Coating

KW - Fiber Boards

KW - Surface Properties

KW - Tile

KW - Wood

U2 - 10.1016/j.jclepro.2017.09.156

DO - 10.1016/j.jclepro.2017.09.156

M3 - Article

SN - 0959-6526

VL - 170

SP - 1354

EP - 1360

JO - J. Clean. Prod.

JF - J. Clean. Prod.

ER -

Added-value for wood bark as a coating layer for flooring tiles

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