Publikationer av Magnus Wålinder
Refereegranskade
Artiklar
[1]
Y. Wang et al., "Design of birch plywood as gusset plates in timber-timber uniaxial tension connections : Influence of fastener pattern, face grain orientation, and discussions based on the Whitmore effective width theory," Journal of Building Engineering, vol. 86, 2024.
[2]
T. Wang et al., "Glulam beams adhesively bonded by birch plywood plates in moment-resisting beam-to-beam connections," Engineering structures, vol. 302, s. 117471, 2024.
[3]
T. Wang et al., "Adhesively bonded joints between spruce glulam and birch plywood for structural applications: experimental studies by using different adhesives and pressing methods," Wood Material Science & Engineering, vol. 18, no. 3, s. 1141-1150, 2023.
[4]
Y. Wang et al., "Birch plywood as gusset plates in glulam frame via mechanical connectors : A combined experimental and numerical study," Journal of Building Engineering, vol. 65, s. 105744, 2023.
[5]
Y. Wang et al., "Embedment behavior of dowel-type fasteners in birch plywood : Influence of load-to-face grain angle, test set-up, fastener diameter, and acetylation," Construction and Building Materials, vol. 384, 2023.
[6]
H. Yin et al., "Susceptibility of surface-modified superhydrophobic wood and acetylated wood to mold and blue stain fungi," Progress in organic coatings, vol. 182, 2023.
[7]
Y. Wang et al., "Testing and analysis of screw-connected moment joints consisting of glued-laminated timbers and birch plywood plates," Engineering structures, vol. 290, 2023.
[8]
J. Žigon, M. S. Moghaddam och M. Wålinder, "Wettability and surface interactions of natural and thermally modified beech wood with water and water-based coatings : the effect of surface pre-treatment type," European Journal of Wood and Wood Products, vol. 81, no. 1, s. 73-88, 2023.
[9]
Y. Wang et al., "Experimental investigation on mechanical properties of acetylated birch plywood and its angle-dependence," Construction and Building Materials, vol. 344, s. 128277, 2022.
[10]
T. Wang et al., "In-plane mechanical properties of birch plywood," Construction and Building Materials, vol. 340, 2022.
[11]
T. Wang et al., "Influence of face grain angle, size, and moisture content on the edgewise bending strength and stiffness of birch plywood," Materials & design, vol. 223, s. 111227, 2022.
[12]
H. Yin et al., "Wettability performance and physicochemical properties of UV exposed superhydrophobized birch wood," Applied Surface Science, vol. 584, 2022.
[13]
T. Wang et al., "An innovative timber-steel hybrid beam consisting of glulam mechanically reinforced by means of steel rod : Analytical and preliminary numerical investigations," Journal of Building Engineering, vol. 43, 2021.
[14]
H. Yin et al., "Non-fluorine surface modification of acetylated birch for improved water repellence," Holzforschung, vol. 75, no. 9, s. 857-868, 2021.
[15]
S. Källbom et al., "Effects of water soaking-drying cycles on thermally modified spruce wood-plastic composites," Wood and Fiber Science, vol. 52, no. 1, s. 2-12, 2020.
[16]
H. Yin et al., "Superamphiphobic plastrons on wood and their effects on liquid repellence," Materials & design, vol. 195, 2020.
[17]
T. Sjökvist, Å. Blom och M. Wålinder, "The infuence of heartwood, sapwood and density on moisture fuctuations and crack formations of coated Norway spruce in outdoor exposure," Journal of Wood Science, vol. 65, no. 45, 2019.
[18]
D. Peñaloza et al., "Future scenarios for climate mitigation of new construction in Sweden : Effects of different technological pathways," Journal of Cleaner Production, vol. 187, s. 1025-1035, 2018.
[19]
T. Sjökvist, M. Wålinder och A. Blom, "Liquid sorption characterisation of Norway spruce heartwood and sapwood using a muiticycle Wilhelmy plate method," International Wood Products Journal, vol. 9, no. 2, s. 58-65, 2018.
[20]
S. Källbom, M. S. Moghaddam och M. Wålinder, "Liquid sorption, swelling and surface energy properties of unmodified and thermally modified Scots pine heartwood after extraction," Holzforschung, vol. 72, no. 3, s. 251-258, 2018.
[21]
S. Källbom et al., "Sorption and surface energy properties of thermally modified spruce wood components," Wood and Fiber Science, vol. 50, no. 3, s. 346-357, 2018.
[22]
M. Larsson, M. Wålinder och A. Falk, "Teleodynamic timber façades," Frontiers in Built Environment, vol. 4, 2018.
[23]
T. Li et al., "Effect of conditioning history on the characterization of hardness of thermo-mechanical densified and heat treated poplar wood," Holzforschung, vol. 71, no. 6, s. 515-520, 2017.
[24]
M. Sedighi Moghaddam et al., "Microstructure of chemically modified wood using X-ray computed tomography in relation to wetting properties," Holzforschung, vol. 71, no. 2, s. 119-128, 2017.
[25]
T. Li et al., "Response of hygroscopicity to heat treatment and its relation to durability of thermally modified wood," Construction and Building Materials, vol. 144, s. 671-676, 2017.
[26]
M. Sedighi Moghaddam et al., "Hydrophobisation of wood surfaces by combining liquid flame spray (LFS)and plasma treatment : dynamic wetting properties," Holzforschung, vol. 70, no. 6, s. 527-537, 2016.
[27]
M. Tuominen et al., "Superamphiphobic overhang structured coating on a biobased material," Applied Surface Science, vol. 389, s. 135-143, 2016.
[28]
K. Laine et al., "Surface densification of acetylated wood," European Journal of Wood and Wood Products, vol. 74, no. 6, s. 829-835, 2016.
[29]
G. A. Ormondroyd et al., "Water sorption, surface structure and surface energy characteristics of wood composite fibres refined at different pressures," Wood Material Science & Engineering, s. 1-8, 2016.
[30]
S. Källbom et al., "Water vapour sorption characteristics and surface chemical composition of thermally modified spruce (Picea abies karst)," International Wood Products Journal, vol. 7, no. 3, s. 116-123, 2016.
[31]
M. Sedighi Moghaddam et al., "Wettability and swelling of acetylated and furfurylated wood analyzed by multicycle Wilhelmy plate method," Holzforschung, vol. 70, no. 1, s. 69-77, 2016.
[32]
K. Laine et al., "Wood densification and thermal modification : hardness, set-recovery and micromorphology," Wood Science and Technology, vol. 50, no. 5, s. 883-894, 2016.
[33]
S. Källbom et al., "Surface energy characterization of thermally modified spruce using inverse gas chromatography under cyclic humidity conditions," Wood and Fiber Science, vol. 47, no. 4, s. 410-420, 2015.
[34]
T. Li et al., "Wettability of oil heat-treated bamboo and bonding strength of laminated bamboo board," Industrial crops and products (Print), vol. 69, s. 15-20, 2015.
[35]
K. Laine et al., "Micromorphological studies of surface densified wood," Journal of Materials Science, vol. 49, no. 5, s. 2027-2034, 2014.
[36]
M. Sedighi Moghaddam et al., "Wettability and liquid sorption of wood investigated by Wilhelmy plate method," Wood Science and Technology, vol. 48, no. 1, s. 161-176, 2014.
[37]
M. Sedighi Moghaddam et al., "Multicycle wilhelmy plate method for wetting properties, swelling and liquid sorption of wood," Langmuir, vol. 29, no. 39, s. 12145-12153, 2013.
[38]
M. Wålinder et al., "Wettability of acetylated Southern yellow pine," International Wood Products Journal, vol. 4, no. 3, s. 197-203, 2013.
[39]
K. Segerholm, R. E. Ibach och M. Wålinder, "Moisture sorption in artificially aged wood-plastic composites," BioResources, vol. 7, no. 1, s. 1283-1293, 2012.
[40]
B. K. Segerholm, S. Vellekoop och M. Wålinder, "Process-related mechanical degradation of the wood component in high-wood-content wood-plastic composites," Wood and Fiber Science, vol. 44, no. 2, s. 145-154, 2012.
[41]
L.-E. Bryne och M. Wålinder, "Ageing of modified wood : Part 1: Wetting properties of acetylated, furfurylated, and thermally modified," Holzforschung, vol. 64, no. 3, s. 295-304, 2010.
[42]
L.-E. Bryne et al., "Ageing of modified wood : Part 2: Determination of surface composition of acetylated, furfurylated, and thermally modified wood by XPS and ToF-SIMS," Holzforschung, vol. 64, no. 3, s. 305-313, 2010.
[43]
M. Wålinder et al., "Micromorphological studies of modified wood using a surface preparation technique based on ultraviolet laser ablation," Wood Material Science & Engineering, vol. 4, no. 1-2, s. 46-51, 2009.
[44]
F. Englund et al., "Spectroscopic studies of surface chemical composition and wettability of modified wood," Wood Material Science & Engineering, vol. 4, no. 1-2, s. 80-85, 2009.
[45]
M. Inoue et al., "Dimensional stabilization of compressed laminated veneer lumber by hot pressing in an airtight frame," Wood Material Science & Engineering, vol. 3, no. 3-4, s. 119-125, 2008.
[46]
P. Larsson-Brelid et al., "Ecobuild a center for development of fully biobased material systems and furniture applications," Molecular Crystals and Liquid Crystals, vol. 484, s. 623-630, 2008.
[47]
K. Segerholm et al., "Micromorphology, moisture sorption and mechanical properties of a biocomposite based on acetylated wood particles and cellulose ester," Wood Material Science and Engineering, vol. 3-4, no. 2, s. 106-117, 2007.
[48]
W. T. Y. Tze, M. E. P. Wålinder och D. J. Gardner, "Inverse gas chromatography for studying interaction of materials used for cellulose fiber/polymer composites," Journal of Adhesion Science and Technology, vol. 20, no. 8, s. 743-759, 2006.
[49]
M. Sterley, H. Blümer och M. Wålinder, "Edge and face gluing of green timber using a one-component polyurethane adhesive," European Journal of Wood and Wood Products, vol. 62, no. 6, s. 479-482, 2004.
[50]
M. Wålinder och G. Ström, "Measurement of wood wettability by the Wilhelmy method - Part 2. Determination of apparent contact angles," Holzforschung, vol. 55, no. 1, s. 33-41, 2001.
Konferensbidrag
[51]
T. Wang et al., "Glulam Frames Adhesively Bonded by Means of Birch Plywood Plates : Preliminary Investigations," i 13th World Conference on Timber Engineering, WCTE 2023, 2023, s. 1453-1461.
[52]
M. Debertolis et al., "Investigation on mechanical connections with birch plywood gusset plates," i 19th Annual Meeting of the Northern European Network for Wood Science and Engineering, 2023, s. 96-98.
[53]
Y. Wang et al., "Preliminary experimental investigations on frame corner joints built of glulam beams, birch plywood via mechanical connectors," i 19th Annual Meeting of the Northern European Network for Wood Science and Engineering, 2023.
[54]
Y. Wang et al., "Effect of moisture content on the angle-dependent edgewise flexural properties of unmodified and acetylated birch plywood," i Proceedings of the 18th Annual Meeting of the Northern European Network for Wood Science and Engineering (WSE), 2022.
[55]
T. Wang et al., "In-plane load-to-grain angle dependency of the compressive behavior of birch plywood," i CEM·2022 19th International Conference on Experimental Mechanics 17-21Jul 2022, Kraków, Poland, 2022.
[56]
Y. Wang et al., "Experimental study on an innovative timber-steel hybrid system," i Proceedings of the 17th Annual Meeting of the Northern European Network for Wood Science and Engineering, 2021, s. 152-154.
[57]
Y. Wang et al., "Mechanical properties of acetylaetd birch plywood loaded parallel to the face grain," i World Conference on Timber Engineering 2021, WCTE 2021, 2021.
[58]
Y. Wang et al., "Mechanical properties of acetylated birch plywood loaded parallel to the face grain," i World Conference on Timber Engineering WCTE2021, 2021.
[59]
R. Crocetti et al., "Multiple shear plane connections with timber based gusset plates," i World Conference on Timber Engineering 2021, WCTE 2021, 2021.
[60]
T. Wang et al., "Multiple shear plane timber connections with birch plywood and dowel-type fasteners," i Proceedings of the 17th Annual Meeting of the Northern European Network for Wood Science and Engineering (WSE 2021), 2021.
[61]
Y. Wang et al., "Numerical investigations on an innovative timber-steel hybrid system," i Proceedings of the 16th Annual Meeting of the Northern European Network for Wood Science and Engineering – WSE2020, 2020, s. 92-94.
[62]
A. Falk och M. Wålinder, "Function and design of innovative bio-based products for the building sector," i Structures and Architecture - Proceedings of the 3rd International Conference on Structures and Architecture, ICSA 2016, 2016, s. 93-101.
[63]
J. Ruponen et al., "Tensile-shear strength studies on self-bonded 2-ply birch veneer joint manufactured and tested by applying Automated Bonding Evaluation System (ABES) hot press," i WCTE 2016 - World Conference on Timber Engineering, 2016.
[64]
K. Segerholm et al., "Biological outdoor durability of WPC with chemically modified wood," i Proceedings of the 6th European conference on wood modification, 2012, s. 47-54.
[65]
K. Segerholm och M. Wålinder, "Inverse gas chromatography characterization of wood composite components," i Proceedings of the 8th meeting of the Northern European Network for Wood Science and Engineering (WSE), 2012, s. 58-63.
[66]
K. Segerholm, M. Wålinder och S. L. Bardage, "Mould growth resistance of fungicide-containing WPC," i Proceedings of the 7th meeting of the Nordic-Baltic Network in Wood Material Science & Engineering (WSE), 2011, s. 25-30.
[67]
M. Wålinder och D. Gardner, "Surface energy characteristics of maple wood particles coated with polystyrene-acrylic acid (PSAA) block copolymer," i Proceedings of the 2011 IAWS Annual Meeting on Novel Materials from Wood or Cellulose, 2011, s. 66-67.
[68]
K. Segerholm, M. Wålinder och D. Holmberg, "Adhesion studies of scots pine-polypropylene bond using ABES," i In Proceedings of the 6th meeting of the Nordic-Baltic Network in Wood Material Science and Engineering, WSE, 2010.
[69]
K. Segerholm och M. Wålinder, "Dimensional changes due to water sorption in high wood-content WPCs prepared with modified wood," i In Proceedings of the fifth European Conference on Wood Modification, ECWM5, 2010.
[70]
M. Wålinder, K. Segerholm och M. Westin, "Durability of high wood content WPCs," i Proceedings of the International Convention of Society of Wood Science and Technology andUnited Nations Economic Commission for Europe – Timber Committee, 2010.
[71]
M. Wålinder et al., "Liquids and coatings wettability and penetrability of acetylated scots pine sapwood," i In Proceedings of the fifth European Conference on Wood Modification, ECWM5, 2010, s. 381-388.
[72]
K. Segerholm, A. Omidvar och M. Wålinder, "Acetylation to Minimize Water Uptake and Deformation of High Wood Content WPC," i The Fourth European Conference on Wood Modification, 2009, s. 239-242.
[73]
M. Wålinder et al., "Micromorphology Studies of Modified Wood Using a Surface Preparation Technique Based on UV-Laser Ablation," i The Fourth European Conference on Wood Modification, 2009, s. 103-110.
[74]
F. Englund et al., "Some Aspects on the Determination of Surface Chemical Composition and Wettability of Modified Wood," i Proceedings of the Fourth European Conference on Wood Modification, 2009, s. 553-560.
[75]
M. Wålinder, K. Segerholm och O. Söderström, "Water sorption properties and dimensional changes of high wood-content WPC," i Proceedings of the 5th meeting of the Nordic Baltic Network in Wood Material Science and Engineering, 2009, s. 153-160.
[76]
K. Segerholm et al., "Wood Plastic Composites from Modified Wood and CAP," i 4th Wood Fibre Polymer Composites International Symposium, 2009.
[77]
L. E. Bryne et al., "UV-laser irradiated wood : Some aspects on micromorphology, wettability, surface composition and liquid permeability," i Proceedings of the 4th meeting of the Nordic-Baltic network in wood material science and engineering (WSE), 2008, s. 75-82.
[78]
K. Segerholm et al., "Improved Durability and Moisture Sorption Characteristics of Extruded WPCs made from Chemically Modified Wood," i Proceedings of the 9th International Conference on Wood & Biofiber Plastic Composites., 2007, s. 251-256.
[79]
K. Segerholm et al., "Micromorphology and Durability of WPCs made from Chemically Modified Wood," i Proceedings of the 3rd meeting of the Nordic Baltic Network in Wood Material Science and Engineering, 2007.
[80]
B. Källander och M. E. P. Wålinder, "European Industry-Academic Cooperation," i Wood Adhesives 2005, 2006, s. 15-22.
[81]
M. E. P. Wålinder och L.-E. Bryne, "Wood adhesion mechanisms : prediction of wood-thermoplastic-water interactions," i Wood Adhesives 2005, 2006, s. 385-392.
[82]
K. Segerholm et al., "Wood plastic composites made from acetylated wood : Effects on water vapour sorption behaviour and durability," i Proceedings of the 9th European Panel Products Symposium, 2005, s. 233-242.
Kapitel i böcker
[83]
D. J. Gardner, C. Tascioglu och M. E. P. Wålinder, "Wood composite protection," i Wood Deterioration and Preservation, B. Goodell, D. Nicholas, and T.P. Schultz, red., : American Chemical Society, 2003, s. 399-419.
Icke refereegranskade
Artiklar
[84]
D. J. Gardner och M. Wålinder, "Editorial note," Journal of Adhesion Science and Technology, vol. 20, no. 8, s. 723-723, 2006.
[85]
D. J. Gardner och M. Wålinder, "Special Issue on Wood Adhesion and Adhesives," Journal of Adhesion Science and Technology, vol. 20, no. 8, s. 725-727, 2006.
[86]
M. Wålinder, "The new journal Wood Material Science and Engineering," Wood Material Science & Engineering, vol. 1, no. 1, s. 2-3, 2006.
[87]
M. Wålinder och M. Westin, "Kompositer av trä och plast framtidens byggmaterial," Provning och Forskning, no. 2, s. 10-11, 2005.
[88]
M. Wålinder och M. Westin, "Hållbart utomhus," Miljöforskning: Formas tidning för ett uthålligt samhälle, no. 1, s. 10-10, 2004.
Konferensbidrag
[89]
T. Wang et al., "The Embedment Behavior of Acetylated and Unmodified Birch Plywood," i Proceedings of the Tenth European Conference on Wood Modification, 2022.
[90]
T. Wang et al., "Prediction of the tensile strength of birch plywood at varying angles to grain," i Proceedings of the 16th Annual Meeting of the Northern European Network for Wood Science and Engineering - WSE2020, 2020, s. 80-82.
[91]
H. Yin et al., "Fabrication of superamphiphobic wood surface based on silicone nanofilaments," i Proceedings of the 15th annual meeting of the Northern European Network for Wood Science and Engineering, 2019, s. 135-137.
[92]
T. Sjökvist, M. Wålinder och Å. Blom, "Liquid sorption and swelling behaviour of Norway spruce heartwood and sapwood veneers studied by the multicycle Wilhelmy plate method," i Proceedings of the 13th annual meeting of the Northern European Network for Wood Science and Engineering, September 28-29, 2017, s. 140.
[93]
M. Larsson och M. Wålinder, "Optimisation of timber structures based on weighted objectives," i Proceedings of the 13th annual meeting of the Northern European Network for Wood Science and Engineering , September 28-29, 2017, s. 79-84.
[94]
K. Lillqvist et al., "THE INFLUENCE OF THERMAL MODIFICATION ON VENEER BOND STRENGTH," i Proceedings of the 13th annual meeting of the Northern European Network for Wood Science and Engineering, September 28-29, 2017, s. 56.
[95]
S. Källbom et al., "The influence of log soaking temperature and thermal modification on the properties of birch veneers," i IRG Annual Meeting, 2016.
[96]
K. Laine et al., "Acetylation and densification of wood," i 11th Meeting of the Northern European Network for Wood Science and Engineering – WSE. 14.-15.9.2015, Poznan, Poland, 2015.
[97]
K. Laine et al., "Hardness, set-recovery and micromorphology studies of densified and thermally modified wood," i The 8th European Conference of Wood Modification. 26.-27.10.2015, Helsinki, Finland., 2015.
[98]
S. Källbom et al., "Surface chemical analysis and water vapour sorpion of thermally modified wood exposed to increased relative humidity," i The Eighth European Conference on Wood Modification (ECWM8) 2015, 2015.
[99]
S. Källbom et al., "Surface energy characteristics of refined fibres at different pressures," i Proceedings of 10th Meeting of the Northern European Network for Wood Science & Engineering (WSE 2014), 2014, s. 134-138.
[100]
S. Källbom et al., "Surface energy characterization of thermally modified wood particles exposed to humidity cycling using inverse gas chromatography," i The Seventh European Conference on Wood Modification (ECWM7)., 2014.
[101]
S. Källbom et al., "Water vapour sorption properties and surface chemical analysis of thermally modified wood particles," i Recent Advances in the field of TH and THM Wood Treatment, 2014.
[102]
S. Källbom et al., "Physico-chemical characterization of THM modified wood using inverse gas chromatography (IGC)," i Evaluation, processing and prediction of THM treated wood behaviour by experimental and numerical methods, 2013, s. 35-36.
[103]
S. Källbom et al., "Surface energy characterization at different moisture levels of thermally modified wood using inverse gas chromatography," i Proceedings of the 9th meeting of the Northern European Network for Wood Science and Engineering (WSE), 2013, s. 130-135.
[104]
S. Källbom et al., "Surface energy characterization of thermally modified wood using inverse gas chromatography," i The 44th Annual Meeting of the International Research Group on Wood Preservation, 2013.
[105]
M. Wålinder, "EcoBuild – En plattform för utveckling av eko-effektiva och beständiga trämaterial," i Ekmandagarna, Stockholm, januari 27-28, 2009, 2009.
[106]
M. E. P. Wålinder, "EcoBuild – centrum för eko-effektiva träbaserade material och produkter. Samverkan mellan SP, 36 företag och universitet," i Energisessionen, Skövde, February 5–6, 2009.
[107]
P. Larsson Brelid et al., "Wood Plastic Composites from Modified Wood : Part 1 - Conceptual idea, mechanical and physical properties," i The 37th Annual Meeting of the International Research Group on Wood Preservation, 2006.
[108]
P. Larsson Brelid et al., "Wood Plastic Composites with Improved Dimensional Stability and Biological Resistance," i 2nd International Conference on Environmentally-Compatible Forest Products, 2006.
Samlingsverk (redaktörskap)
[109]
"Special issue on wood adhesion and adhesives," , VSP, Journal of Adhesion Science and Technology, 20:8, 2006.
Övriga
[110]
M. Wålinder och F. Englund, "EcoBuild – a competence centre for eco-efficient and innovative wood-based materials : Message from the Manager," Stockholm : SP Technical Research Institute of Sweden, Wood Technology, 2011.
[111]
T. Wang et al., "Bonding strength between spruce glulam and birch plywood at different load-to-plywood face grain angles," (Manuskript).
[112]
[113]
M. Sedighi Moghaddam et al., "Microstructure of chemically modified wood using X-ray computedtomography scanning in relation to wetting properties," (Manuskript).
[114]
H. Yin et al., "Non-fluorine surface modification of acetylated birch for improved water repellence," (Manuskript).
[115]
[116]
T. Wang et al., "Spreading angle analysis on the tensile capacities of birch plywood plates in adhesively bonded timber connections," (Manuskript).
[117]
H. Yin et al., "Susceptibility of surface-modified superhydrophobic wood and acetylated wood to mold and blue stain fungi," (Manuskript).
[118]
S. Källbom et al., "Water vapour sorption characteristics and surface chemical composition of thermally modified spruce," (Manuskript).
[119]
Senaste synkning med DiVA:
2024-04-25 00:33:43