Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species

G. Kain; E.M. Tudor; M.-C. Barbu

doi:10.3390/POLYM12092140

Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species

G. Kain, E.M. Tudor, M.-C. Barbu^*

^*Corresponding author for this work

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

Abstract

Tree bark is a byproduct of the timber industry which accrues in large amounts, because approximately 10% of the volume a log is bark. Bark is used primarily for low-value applications such as fuel or as a soil covering material in agriculture. Within the present study, thermal insulation panels made from larch, pine, spruce, fir and oak tree bark with different resins (urea formaldehyde, melamine formaldehyde, Quebracho, Mimosa) as a binder are discussed. Also, the properties of panels made from larch bark mixed with industrial popcorn are investigated. The physical-mechanical properties of the panels, which are dependent on panel density, bark species, resin type, resin content and particle size, are analyzed. The bark species has a minor effect on the mechanical characteristics of the panels, while the compression ratio is important for the panel strength, and hence, barks with lower bulk density are preferable. Under laboratory conditions, panels made with green tannin resins proved to have adequate properties for practical use. The addition of popcorn is a means to lower the panel density, but the water absorption of such panels is comparably high. The bark type has a minor effect on the thermal conductivity of the panels; rather, this parameter is predominantly affected by the panel density.

Original language	English
Journal	Polymers
Volume	12
Issue number	9
DOIs	https://doi.org/10.3390/POLYM12092140
Publication status	Published - 19 Sept 2020

Keywords

Green building materials
Thermal conductivity
Thermal insulation panels
Tree bark
Agricultural robots
Density (specific gravity)
Forestry
Formaldehyde
Melamine formaldehyde resins
Particle size
Resins
Urea
Urea formaldehyde resins
Water absorption
Laboratory conditions
Mechanical characteristics
Melamine formaldehyde
Physical-mechanical properties
Resin content
Soil coverings
Timber industry
Urea formaldehyde
Thermal insulation

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10.3390/POLYM12092140

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85092077215&doi=10.3390%2fPOLYM12092140&partnerID=40&md5=037684e70dd1492705ebdaed0858f642

Cite this

@article{eab69ef6262e41788b15955bed47d512,

title = "Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species",

abstract = "Tree bark is a byproduct of the timber industry which accrues in large amounts, because approximately 10\% of the volume a log is bark. Bark is used primarily for low-value applications such as fuel or as a soil covering material in agriculture. Within the present study, thermal insulation panels made from larch, pine, spruce, fir and oak tree bark with different resins (urea formaldehyde, melamine formaldehyde, Quebracho, Mimosa) as a binder are discussed. Also, the properties of panels made from larch bark mixed with industrial popcorn are investigated. The physical-mechanical properties of the panels, which are dependent on panel density, bark species, resin type, resin content and particle size, are analyzed. The bark species has a minor effect on the mechanical characteristics of the panels, while the compression ratio is important for the panel strength, and hence, barks with lower bulk density are preferable. Under laboratory conditions, panels made with green tannin resins proved to have adequate properties for practical use. The addition of popcorn is a means to lower the panel density, but the water absorption of such panels is comparably high. The bark type has a minor effect on the thermal conductivity of the panels; rather, this parameter is predominantly affected by the panel density.",

keywords = "Green building materials, Thermal conductivity, Thermal insulation panels, Tree bark, Agricultural robots, Density (specific gravity), Forestry, Formaldehyde, Melamine formaldehyde resins, Particle size, Resins, Urea, Urea formaldehyde resins, Water absorption, Laboratory conditions, Mechanical characteristics, Melamine formaldehyde, Physical-mechanical properties, Resin content, Soil coverings, Timber industry, Urea formaldehyde, Thermal insulation",

author = "G. Kain and E.M. Tudor and M.-C. Barbu",

note = "Cited By :20 Export Date: 14 December 2023 Correspondence Address: Barbu, M.-C.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected] Funding details: Austrian Science Fund, FWF, 843540, TRP 254-N13 Funding details: {\"O}sterreichische Forschungsf{\"o}rderungsgesellschaft, FFG Funding text 1: Acknowledgments: The project was supported by the FWF programme TRP 254-N13. CT scans were financed by the K-Project ZPT+, supported by the COMET programme 843540 of FFG and by the federal government of Upper Austria and Styria. References: Paine, C.E., Stahl, C., Courtois, E.A., Pati{\~n}o, S., Sarmiento, C., Baraloto, C., Functional explanations for variation in bark thickness in tropical rain forest trees (2010) Funct. Ecol., 24, pp. 1202-1210; Phillips, M.A., Croteau, R.B., Resin-based defenses in conifers (1999) Trends Plant Sci., 4, pp. 184-190; Niklas, K.J., The mechanical role of bark (1999) Am. J. Bot., 86, pp. 465-469; Evert, R.F., Eichhorn, S.E., (2006) Esaus's Plant Anatomy: Meristems, Cells, and Tissue of the Plant Body: Their Structure, Function, and Development, 3rd ed., , Wiley and Sons: New York, NY, USA; Rosell, J.A., Gleason, S., M{\'e}ndez-Alonzo, R., Chang, Y., Westoby, M., Bark functional ecology: Evidence for tradeoffs, functional coordination, and environment producing bark diversity (2014) New Phytol., 201, pp. 486-497; Pausas, J.G., Bark thickness and fire regime (2015) Funct. Ecol., 29, pp. 315-327; Teskey, R.O., Saveyn, A., Steppe, K., McGuire, M.A., Origin, fate and significance of CO2 in tree stems (2008) New Phytol., 177, pp. 17-32; Lendzian, K.J., Survival strategies of plants during secondary growth: Barrier properties of phellems and lenticels towards water, oxygen, and carbon dioxide (2006) J. Exp. Bot., 57, pp. 2535-2546; Martin, R.E., Thermal properties of bark (1963) Forest Prod. J., 13, pp. 419-426; Bauer, G., Speck, T., Bl{\"o}mer, J., Bertling, J., Speck, O., Insulation capability of the bark of trees with different fire adaptation (2010) J. Mater. Sci., 45, pp. 5950-5959; Kain, G., Barbu, M.C., Teischinger, A., Musso, M., Petutschnigg, A., Substantial bark use as insulation material (2012) Forest Prod. J., 62, pp. 480-487; Kain, G., Barbu, M.C., Hinterreiter, S., Richter, K., Petutschnigg, A., Using bark as heat insulation material (2013) Bioresources, 8, pp. 3718-3731; Kain, G., G{\"u}ttler, 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; www.solardecathlon.at, (accessed on 25 March 2020); Lakes, R., Materials with structural hierarchy (1993) Nature, 361, pp. 479-564; 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; (2015) Nachhaltige Waldwirtschaft in {\"O}sterreich, , AV+Astoria: Vienna, Austria; Jochem, D., Weimar, H., B{\"o}sch, M., Mantau, U., Dieter, M., Estimation of wood removals and fellings in Germany: A calculation approach based on the amount of used roundwood (2015) Eur. J. Forest Res., 134, pp. 869-888; Kain, G., (2013) D{\"a}mmstoffe aus Baumrinden, , Akademikerverlag: Saarbr{\"u}cken, Germany; (2014) Holzstr{\"o}me in {\"O}sterreich, , Bundesministerium f{\"u}r Land- und Forstwirtschaft, Umwelt und Wasserwirtschaft: Vienna, Austria; (2006) {\"O}sterreichische Holzhandelsusancen, , Service-GmbH der Wirtschaftskammer {\"O}sterreich: Vienna, Austria; (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: Brussels, Belgium; (2005) EN 310:2005 Wood Based Panels-Determination of Modulus of Elasticity in Bending and of Bending Strength, , European Committee for Standardization: Brussels, Belgium; (2005) EN 319:2005 Particleboards and Fibreboards-Determination of Tensile Strength Perpendicular to the Plane of the Board, , European Committee for Standardization: Brussels, Belgium; (2005) EN 317:2005 Particleboards and Fibreboards-Determination of Swelling in Thickness after Immersion in Water, , European Committee for Standardization: Brussels, Belgium; (2001) EN 12667: 2001 Determination of the Thermal Resistance with the Panel and Heat Flow Panel Measuring Device, , European Committee for Standardization: Brussels, Belgium; Backhaus, K., Erichson, B., Plinke, W., Weiber, R., (2011) Multivariate Analysemethoden, , Springer: Berlin, Germany; Standke, W., Schneider, A., Untersuchungen {\"u}ber das Sorptionsverhalten des Bast- und Borkeanteils verschiedener Baumrinden (1984) Holz Roh Werkst., 39, pp. 489-493; Niemz, P., (1993) Physik des Holzes und der Holzwerkstoffe, , DRW: Leinfelden-Echterdingen, Germany; Kawai, S., Sasaki, H., Nakaji, M., Physical properties of low-density particleboard (1986) Wood Res. Kyoto Jpn., 72, pp. 27-36; Sakai, K., Chemistry of bark (2001) Wood and Cellulosic Chemistry, 2nd ed., pp. 243-273. , Hon, D.N., Shiraishi, N., Eds.; Marcel Dekker: New York, NY, USA; Martin, R.E., Crist, J.B., Selected physical-mechanical properties of eastern tree barks (1968) Forest Prod. J., 13, pp. 419-426; Nemli, G., Colakoglu, G., Effects of mimosa bark usage on some properties of particleboard (2005) Turk. J. Agric. For., 29, pp. 227-230; Xu, J., Sugawara, R., Widyorini, R., Han, G., Kawai, S., Manufacture and properties of low-density binderless particleboard from kenaf core (2004) J. Wood Sci., 50, pp. 62-67; Liao, R., Xu, J., Umemura, K., Low density sugarcane bagasse particleboard bonded with citric acid and sucrose: Effect of board density and additive content (2016) Bioresources, 11, pp. 2174-2185; Thoemen, H., (2010) Vom Holz zum Holzwerkstoff-Grundlegende Untersuchungen zur Herstellung und Struktur von Holzwerkstoffen, , Berner Fachhochschule Architektur, Holz und Bau: Biel, Switzerland; Kawai, S., Sasaki, H., Low-density particleboard (1993) Recent Research on Wood and Wood-Based Materials: Current Japanese Materials Research, pp. 33-41. , Shiraishi, N., Kajita, H., Norimoto, M., Eds.; Elsevier: Essex, UK; Arabi, M., Faezipour, M., Gholizadeh, H., Reducing resin content and board density without adversely affecting the mechanical properties of particleboard through controlling particle size (2011) J. Forestry Res., 22, pp. 659-664; Schwemmer, R., (2010) Entwicklung der Fertigungstechnologie f{\"u}r Rohrkolben-D{\"a}mmstoffe, , Federal Ministry for Association, Innovation and Technology: Vienna, Austria; Kim, S., Lee, Y.K., Kim, H.J., Lee, H.H., Physico-mechanical properties of particleboards bonded with pine and wattle tannin-based adhesives (2003) J. Adhes. Sci. Technol., 17, pp. 1863-1875; Paulitsch, M., Barbu, M.C., (2015) Holzwerkstoffe der Moderne, , DRW-Verlag: Leinfelden-Echterdingen, Germany; Brombacher, V., Michel, F., Niemz, P., Volkmer, T., Untersuchungen zu W{\"a}rmeleitf{\"a}higkeit und Feuchteverhalten von Holzfaserplatten und Materialkombinationen (2012) Bauphysik, 34, pp. 157-169; Kain, G., Charwat-Pessler, J., Barbu, M.C., Plank, B., Richter, K., Petutschnigg, A., Analyzing wood bark insulation board structure using X-ray computed tomography and modeling its thermal conductivity by means of finite difference method (2016) J. Compos. Mater., 50, pp. 795-806; Sackey, E.K., Smith, G.D., Characterizing macro-voids of uncompressed mats and finished particleboard panels using response surface methodology and X-ray CT (2010) Holzforschung, 64, pp. 343-352; Shalbafan, A., Tackmann, O., Welling, J., Using of expandable fillers to produce low density particleboard (2016) Eur. J. Wood Prod., 74, pp. 15-22; Henze, G.P., Le, T.H., Florita, A.R., Felsmann, C., Sensitivity analysis of optimal building thermal mass control (2007) J. Sol. Energ., 129, pp. 473-485; Tudor, E.M., Scheriau, C., Barbu, M.C., R{\'e}h, R., Kri{\v s}t'{\'a}k, L., Schnabel, T., Enhanced Resistance to Fire of the Bark-Based Panels Bonded with Clay (2020) Appl. Sci., 10",

year = "2020",

month = sep,

day = "19",

doi = "10.3390/POLYM12092140",

language = "English",

volume = "12",

journal = "Polymers",

issn = "2073-4360",

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

number = "9",

}

TY - JOUR

T1 - Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species

AU - Kain, G.

AU - Tudor, E.M.

AU - Barbu, M.-C.

N1 - Cited By :20 Export Date: 14 December 2023 Correspondence Address: Barbu, M.-C.; Forest Products Technology and Timber Construction Department, Markt 136a, Austria; email: [email protected] Funding details: Austrian Science Fund, FWF, 843540, TRP 254-N13 Funding details: Österreichische Forschungsförderungsgesellschaft, FFG Funding text 1: Acknowledgments: The project was supported by the FWF programme TRP 254-N13. CT scans were financed by the K-Project ZPT+, supported by the COMET programme 843540 of FFG and by the federal government of Upper Austria and Styria. References: Paine, C.E., Stahl, C., Courtois, E.A., Patiño, S., Sarmiento, C., Baraloto, C., Functional explanations for variation in bark thickness in tropical rain forest trees (2010) Funct. Ecol., 24, pp. 1202-1210; Phillips, M.A., Croteau, R.B., Resin-based defenses in conifers (1999) Trends Plant Sci., 4, pp. 184-190; Niklas, K.J., The mechanical role of bark (1999) Am. J. Bot., 86, pp. 465-469; Evert, R.F., Eichhorn, S.E., (2006) Esaus's Plant Anatomy: Meristems, Cells, and Tissue of the Plant Body: Their Structure, Function, and Development, 3rd ed., , Wiley and Sons: New York, NY, USA; Rosell, J.A., Gleason, S., Méndez-Alonzo, R., Chang, Y., Westoby, M., Bark functional ecology: Evidence for tradeoffs, functional coordination, and environment producing bark diversity (2014) New Phytol., 201, pp. 486-497; Pausas, J.G., Bark thickness and fire regime (2015) Funct. Ecol., 29, pp. 315-327; Teskey, R.O., Saveyn, A., Steppe, K., McGuire, M.A., Origin, fate and significance of CO2 in tree stems (2008) New Phytol., 177, pp. 17-32; Lendzian, K.J., Survival strategies of plants during secondary growth: Barrier properties of phellems and lenticels towards water, oxygen, and carbon dioxide (2006) J. Exp. Bot., 57, pp. 2535-2546; Martin, R.E., Thermal properties of bark (1963) Forest 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; Kain, G., Barbu, M.C., Teischinger, A., Musso, M., Petutschnigg, A., Substantial bark use as insulation material (2012) Forest Prod. J., 62, pp. 480-487; Kain, G., Barbu, M.C., Hinterreiter, S., Richter, K., Petutschnigg, A., Using bark as heat insulation material (2013) Bioresources, 8, pp. 3718-3731; 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; www.solardecathlon.at, (accessed on 25 March 2020); Lakes, R., Materials with structural hierarchy (1993) Nature, 361, pp. 479-564; 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; (2015) Nachhaltige Waldwirtschaft in Österreich, , AV+Astoria: Vienna, Austria; Jochem, D., Weimar, H., Bösch, M., Mantau, U., Dieter, M., Estimation of wood removals and fellings in Germany: A calculation approach based on the amount of used roundwood (2015) Eur. J. Forest Res., 134, pp. 869-888; Kain, G., (2013) Dämmstoffe aus Baumrinden, , Akademikerverlag: Saarbrücken, Germany; (2014) Holzströme in Österreich, , Bundesministerium für Land- und Forstwirtschaft, Umwelt und Wasserwirtschaft: Vienna, Austria; (2006) Österreichische Holzhandelsusancen, , Service-GmbH der Wirtschaftskammer Österreich: Vienna, Austria; (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: Brussels, Belgium; (2005) EN 310:2005 Wood Based Panels-Determination of Modulus of Elasticity in Bending and of Bending Strength, , European Committee for Standardization: Brussels, Belgium; (2005) EN 319:2005 Particleboards and Fibreboards-Determination of Tensile Strength Perpendicular to the Plane of the Board, , European Committee for Standardization: Brussels, Belgium; (2005) EN 317:2005 Particleboards and Fibreboards-Determination of Swelling in Thickness after Immersion in Water, , European Committee for Standardization: Brussels, Belgium; (2001) EN 12667: 2001 Determination of the Thermal Resistance with the Panel and Heat Flow Panel Measuring Device, , European Committee for Standardization: Brussels, Belgium; Backhaus, K., Erichson, B., Plinke, W., Weiber, R., (2011) Multivariate Analysemethoden, , Springer: Berlin, Germany; Standke, W., Schneider, A., Untersuchungen über das Sorptionsverhalten des Bast- und Borkeanteils verschiedener Baumrinden (1984) Holz Roh Werkst., 39, pp. 489-493; Niemz, P., (1993) Physik des Holzes und der Holzwerkstoffe, , DRW: Leinfelden-Echterdingen, Germany; Kawai, S., Sasaki, H., Nakaji, M., Physical properties of low-density particleboard (1986) Wood Res. Kyoto Jpn., 72, pp. 27-36; Sakai, K., Chemistry of bark (2001) Wood and Cellulosic Chemistry, 2nd ed., pp. 243-273. , Hon, D.N., Shiraishi, N., Eds.; Marcel Dekker: New York, NY, USA; Martin, R.E., Crist, J.B., Selected physical-mechanical properties of eastern tree barks (1968) Forest Prod. J., 13, pp. 419-426; Nemli, G., Colakoglu, G., Effects of mimosa bark usage on some properties of particleboard (2005) Turk. J. Agric. For., 29, pp. 227-230; Xu, J., Sugawara, R., Widyorini, R., Han, G., Kawai, S., Manufacture and properties of low-density binderless particleboard from kenaf core (2004) J. Wood Sci., 50, pp. 62-67; Liao, R., Xu, J., Umemura, K., Low density sugarcane bagasse particleboard bonded with citric acid and sucrose: Effect of board density and additive content (2016) Bioresources, 11, pp. 2174-2185; Thoemen, H., (2010) Vom Holz zum Holzwerkstoff-Grundlegende Untersuchungen zur Herstellung und Struktur von Holzwerkstoffen, , Berner Fachhochschule Architektur, Holz und Bau: Biel, Switzerland; Kawai, S., Sasaki, H., Low-density particleboard (1993) Recent Research on Wood and Wood-Based Materials: Current Japanese Materials Research, pp. 33-41. , Shiraishi, N., Kajita, H., Norimoto, M., Eds.; Elsevier: Essex, UK; Arabi, M., Faezipour, M., Gholizadeh, H., Reducing resin content and board density without adversely affecting the mechanical properties of particleboard through controlling particle size (2011) J. Forestry Res., 22, pp. 659-664; Schwemmer, R., (2010) Entwicklung der Fertigungstechnologie für Rohrkolben-Dämmstoffe, , Federal Ministry for Association, Innovation and Technology: Vienna, Austria; Kim, S., Lee, Y.K., Kim, H.J., Lee, H.H., Physico-mechanical properties of particleboards bonded with pine and wattle tannin-based adhesives (2003) J. Adhes. Sci. Technol., 17, pp. 1863-1875; Paulitsch, M., Barbu, M.C., (2015) Holzwerkstoffe der Moderne, , DRW-Verlag: Leinfelden-Echterdingen, Germany; Brombacher, V., Michel, F., Niemz, P., Volkmer, T., Untersuchungen zu Wärmeleitfähigkeit und Feuchteverhalten von Holzfaserplatten und Materialkombinationen (2012) Bauphysik, 34, pp. 157-169; Kain, G., Charwat-Pessler, J., Barbu, M.C., Plank, B., Richter, K., Petutschnigg, A., Analyzing wood bark insulation board structure using X-ray computed tomography and modeling its thermal conductivity by means of finite difference method (2016) J. Compos. Mater., 50, pp. 795-806; Sackey, E.K., Smith, G.D., Characterizing macro-voids of uncompressed mats and finished particleboard panels using response surface methodology and X-ray CT (2010) Holzforschung, 64, pp. 343-352; Shalbafan, A., Tackmann, O., Welling, J., Using of expandable fillers to produce low density particleboard (2016) Eur. J. Wood Prod., 74, pp. 15-22; Henze, G.P., Le, T.H., Florita, A.R., Felsmann, C., Sensitivity analysis of optimal building thermal mass control (2007) J. Sol. Energ., 129, pp. 473-485; 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

PY - 2020/9/19

Y1 - 2020/9/19

N2 - Tree bark is a byproduct of the timber industry which accrues in large amounts, because approximately 10% of the volume a log is bark. Bark is used primarily for low-value applications such as fuel or as a soil covering material in agriculture. Within the present study, thermal insulation panels made from larch, pine, spruce, fir and oak tree bark with different resins (urea formaldehyde, melamine formaldehyde, Quebracho, Mimosa) as a binder are discussed. Also, the properties of panels made from larch bark mixed with industrial popcorn are investigated. The physical-mechanical properties of the panels, which are dependent on panel density, bark species, resin type, resin content and particle size, are analyzed. The bark species has a minor effect on the mechanical characteristics of the panels, while the compression ratio is important for the panel strength, and hence, barks with lower bulk density are preferable. Under laboratory conditions, panels made with green tannin resins proved to have adequate properties for practical use. The addition of popcorn is a means to lower the panel density, but the water absorption of such panels is comparably high. The bark type has a minor effect on the thermal conductivity of the panels; rather, this parameter is predominantly affected by the panel density.

AB - Tree bark is a byproduct of the timber industry which accrues in large amounts, because approximately 10% of the volume a log is bark. Bark is used primarily for low-value applications such as fuel or as a soil covering material in agriculture. Within the present study, thermal insulation panels made from larch, pine, spruce, fir and oak tree bark with different resins (urea formaldehyde, melamine formaldehyde, Quebracho, Mimosa) as a binder are discussed. Also, the properties of panels made from larch bark mixed with industrial popcorn are investigated. The physical-mechanical properties of the panels, which are dependent on panel density, bark species, resin type, resin content and particle size, are analyzed. The bark species has a minor effect on the mechanical characteristics of the panels, while the compression ratio is important for the panel strength, and hence, barks with lower bulk density are preferable. Under laboratory conditions, panels made with green tannin resins proved to have adequate properties for practical use. The addition of popcorn is a means to lower the panel density, but the water absorption of such panels is comparably high. The bark type has a minor effect on the thermal conductivity of the panels; rather, this parameter is predominantly affected by the panel density.

KW - Green building materials

KW - Thermal conductivity

KW - Thermal insulation panels

KW - Tree bark

KW - Agricultural robots

KW - Density (specific gravity)

KW - Forestry

KW - Formaldehyde

KW - Melamine formaldehyde resins

KW - Particle size

KW - Resins

KW - Urea

KW - Urea formaldehyde resins

KW - Water absorption

KW - Laboratory conditions

KW - Mechanical characteristics

KW - Melamine formaldehyde

KW - Physical-mechanical properties

KW - Resin content

KW - Soil coverings

KW - Timber industry

KW - Urea formaldehyde

KW - Thermal insulation

UR - https://www.mendeley.com/catalogue/faa283e3-614b-39fc-b638-f805faf8ca6b/

U2 - 10.3390/POLYM12092140

DO - 10.3390/POLYM12092140

M3 - Article

C2 - 32961694

SN - 2073-4360

VL - 12

JO - Polymers

JF - Polymers

IS - 9

ER -

Bark Thermal Insulation Panels: An Explorative Study on the Effects of Bark Species

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