TY - JOUR
T1 - Specific Gravity of Inner and Outer Larch Bark
AU - Kain, G.
AU - Morandini, M.
AU - Barbu, M.-C.
AU - Petutschnigg, A.
AU - Tippner, J.
N1 - Cited By :2
Export Date: 14 December 2023
Correspondence Address: Kain, G.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected]
References: Sakai, K., Chemistry of bark (2001) Wood and Cellulosic Chemistry, pp. 243-273. , 2nd ed.; Hon, D.N., Shiraishi, N., Eds.; Marcel Dekker: New York, NY, USA; Evert, R.F., Eichhorn, S.E., (2006) Esaus’s Plant Anatomy: Meristems, Cells, and Tissue of the Plant Body: Their Structure, Function, and Development, , Wiley and Sons: New York, NY, USA; Walker, C.F., (2006) Primary Wood Processing, , 2nd ed.; Springer: Dordrecht, The Netherlands; Vaucher, H., (1997) Baumrinden: Aussehen, Struktur, Funktion, Eigenschaften, , Naturbuch-Verlag: Augsburg, Germany; Feng, S., Cheng, S., Yuan, Z., Leitch, M., Xu, C., Valorization of bark for chemicals and materials: A review (2013) Renew. Sust. Energ. Rev, 26, pp. 560-578. , [CrossRef]; (2006) Österreichische Holzhandelsusancen, , Kooperationsplattform Forst Holz Papier. Service-GmbH der Wirtschaftskammer Österreich: Vienna, Austria; Niemz, P., Sonderegger, W.U., (2017) Physik des Holzes und der Holzwerkstoffe, , Carl Hanser: München, Germany; Standke, W., Schneider, A., Untersuchungen über das Sorptionsverhalten des Bast-und Borkeanteils verschiedener Baumrinden (1984) Holz Roh Werkst, 39, pp. 489-493. , [CrossRef]; Martin, R.E., Crist, J.B., Selected physical-mechanical properties of eastern tree barks (1968) For. Prod. J, 13, pp. 419-426; Bauer, G., Speck, T., Blömer, J., Bertling, J., Speck, O., Insulation capability of the bark of trees with different fire adaptation (2010) J. Mater. Sci, 45, pp. 5950-5959. , [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, , U.S. Forest Service: Delaware, DE, USA; Winter, H., Specific gravity of inner and outer beech bark (2020) Eur. J. Wood Prod, 78, pp. 413-416. , [CrossRef]; Fengel, D., Wegener, G., (2003) Wood-Chemistry, Ultrastructure, Reactions, , Kessel: Remagen, Germany; Barabash, N.D., Levin, É.D., The chemical composition of the bark of Larix sibirica (1970) Chem. Nat. Compd, 6, pp. 386-387. , [CrossRef]; Bianchi, S., Kroslakova, I., Janzon, R., Mayer, I., Saake, B., Pichelin, F., Characterization of condensed tannins and carbohydrates in hot water bark extracts of European softwood species (2015) Phytochemistry, 120, pp. 53-61. , [CrossRef] [PubMed]; Nemli, G., Gezer, E.D., 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] [PubMed]; Kain, G., Güttler, 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]; 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]; Rwawiire, S., Tomkova, B., Militky, J., Jabbar, A., Kale, B.M., Development of a biocomposite based on green epoxy polymer and natural cellulose fabric (bark cloth) for automotive instrument panel applications (2015) Compos. Part. B Eng, 81, pp. 149-157. , [CrossRef]; Tudor, E.M., Barbu, M.C., Petutschnigg, A., Réh, R., Added-value for wood bark as a coating layer for flooring tiles (2018) J. Clean. Prod, 170, pp. 1354-1360. , [CrossRef]; Kain, G., Rizzo, P., Österreichisches Gebrauchsmuster: Dekorative Rindenpresskörper, , http://see-ip.patentamt.at/GebrauchsmusterSuche/SearchResult, GM 214/2017. (accessed on 24 October 2020); Lienbacher, B., Morandini, M., Patronus Getränkekühler, , www.barkinsulation.com, (accessed on 21 March 2020); Living Inspired by Sustainable Innovation, , www.solardecathlon.at, Solar Decathlon Team Austria. (accessed on 25 March 2020); 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] [PubMed]; Kain, G., Barbu, M.C., Hinterreiter, S., Richter, K., Petutschnigg, A., Using bark as heat insulation material (2013) Bioresources, 8, pp. 3718-3731. , [CrossRef]; Kain, G., Lienbacher, B., Barbu, M.C., Senck, S., Petutschnigg, A., Water vapour diffusion resistance of larch (Larix decidua) bark insulation panels and application considerations based on numeric modelling (2018) Constr. Build. Mater, 164, pp. 308-316. , [CrossRef]; Kain, G., Güttler, V., Lienbacher, B., Barbu, M.C., Petutschnigg, A., Richter, K., Tondi, G., Effects of different flavonoid extracts in optimizing tannin-glued bark insulation boards (2015) Wood Fiber Sci, 47, pp. 258-269; Kain, G., Stratev, D., Tudor, E., Lienbacher, B., Weigl, M., Barbu, M.-C., Petutschnigg, A., Qualitative investigation on VOC-emissions from spruce (Picea abies) and larch (Larix decidua) loose bark and bark panels (2020) Eur. J. Wood Prod, 78, pp. 403-412. , [CrossRef]; (2016) Directive on the Acquisition of Fuel Wood Based on Mass and Energy Content, , Kooperationsplattform Forst Holz Papier. Forst Holz Papier: Vienna, Austria; (2007) ASTM D 2395-07a Standard Test Methods for Specific Gravity of Wood and Wood-Based Materials, , ASTM International. ASTM International: West Conshohocken, PA, USA; Holdheide, W., Huber, B., Ähnlichkeiten und Unterschiede im Feinbau von Holz und Rinde (1952) Holz Roh Werkst, 10, pp. 263-268. , [CrossRef]; Malkov, S., Tikka, P., Gullichsen, J., Towards complete impregnation of wood chips with aqueous solutions. Part 2. Studies on water penetration into softwood chips (2001) Pap. Puu Paper Timber, 83, pp. 1-6; Wagenführ, R., (2006) Holzatlas, , Carl Hanser: München, Germany; Jelonek, T., Pazdrowski, W., Tomczak, A., The effect of biological class and age on physical and mechanical properties of European larch (Larix decidua Mill.) in Poland (2009) Wood Res, 54, pp. 1-14
PY - 2020/10/25
Y1 - 2020/10/25
N2 - Larch bark is an interesting resource for the production of insulation panels. As it consists of a sugar-rich inner bark and an outer bark containing more durable components, there is the requirement to separate these compartments. Additionally, bark is often mixed with wooden pieces after industrial debarking processes. In this study, the wet density, dry density, and specific gravity of wood, whole bark, and inner and outer bark are investigated using the pycnometer method, which has been proven to be adequate for the volume measurement of irregularly shaped, light objects such as bark flakes. Soaked with water, the density of the inner bark is highest, followed by wood, and the lightest is the outer bark. Because of different moisture contents, the wet density is not directly comparable. The outer bark sucked up less water than the inner bark. Focusing on the specific gravity, the wood is the heaviest, followed by the outer bark and the inner bark. The differences are significant for both methods, displaying a promising physical basis for separation methods based on density differences. These might be a means to pick out more durable and less hygroscopic outer bark particles from a bark mixture in order to produce optimized bark composites.
AB - Larch bark is an interesting resource for the production of insulation panels. As it consists of a sugar-rich inner bark and an outer bark containing more durable components, there is the requirement to separate these compartments. Additionally, bark is often mixed with wooden pieces after industrial debarking processes. In this study, the wet density, dry density, and specific gravity of wood, whole bark, and inner and outer bark are investigated using the pycnometer method, which has been proven to be adequate for the volume measurement of irregularly shaped, light objects such as bark flakes. Soaked with water, the density of the inner bark is highest, followed by wood, and the lightest is the outer bark. Because of different moisture contents, the wet density is not directly comparable. The outer bark sucked up less water than the inner bark. Focusing on the specific gravity, the wood is the heaviest, followed by the outer bark and the inner bark. The differences are significant for both methods, displaying a promising physical basis for separation methods based on density differences. These might be a means to pick out more durable and less hygroscopic outer bark particles from a bark mixture in order to produce optimized bark composites.
KW - Larch bark
KW - Natural resources
KW - Physical properties
KW - Specific gravity
KW - Tree bark
KW - Density difference
KW - Different moisture contents
KW - Dry density
KW - Inner and outer barks
KW - Insulation panel
KW - Separation methods
KW - Wet density
KW - Density (specific gravity)
KW - bark
KW - coniferous tree
KW - forest management
KW - forestry production
KW - natural resource
KW - physical property
KW - Density
KW - Larix
KW - Methods
KW - Phloem
KW - Water
KW - Wood
UR - https://www.mendeley.com/catalogue/08814eff-3382-3935-ba73-d496a2c9e50a/
U2 - 10.3390/f11111132
DO - 10.3390/f11111132
M3 - Article
SN - 1999-4907
VL - 11
SP - 1
EP - 8
JO - Forests
JF - Forests
IS - 11
ER -