Запис Детальніше

THE INFLUENCE OF SELECTED FACTORS ON THE STRENGHT OF WOOD ADHESIVE JOINTS

DSpace at Ternopil State Ivan Puluj Technical University

Переглянути архів Інформація
 
 
Поле Співвідношення
 
Title THE INFLUENCE OF SELECTED FACTORS ON THE STRENGHT OF WOOD ADHESIVE JOINTS
 
Creator Rudawska, A.
Maziarz, M.
Šajgalík, M.
Valášek, P.
Zlamal, T.
Iasnii, V.
 
Contributor Lublin University of Technology, Faculty of Mechanical Engineering, ul. Nadbystrzycka 36, 20-618 Lublin
University of Žilina, Faculty of Mechanical Engineering, Univerzitna 1, 01026, Žilina, Slovakia
Czech University of Life Science Prague, Faculty of Engineering, 16521, Prague, Czech Republic
Technical University of Ostrava, Faculty of Mechanical Engineering, 17 listopadu 15, 70833 Ostrava – Poruba, Czech Republic
ernopil Ivan Puluj National Technical University, Faculty of Engineering of Machines, Structures and Technologies, Ruska str., 56, 46001, Ternopil
 
Subject adhesive joint, strength, pine wood, oak wood
 
Description This paper examines the effect of selected factors on the wood bonded joint strength. The structural factor under scrutiny was the geometry of the surface area; however, other major dimensions of adherends were compared as well. The tests were per-formed on 6 joint types: butt, v-shaped, interlocking, scarf, tongue & groove, and single lap joints, which were formed on two types of substrate materials – pine and oak wood, and adhesively bonded. The joints were bonded with Prefere 6312 wood adhesive and Loctite 3430 two-component epoxy adhesive. Strength testing of the joints was performed on Zwick/Roell Z150 material testing machine, according to DIN EN 1465 standard. The results obtained from the tests indicate that bonded joints of oak wood exhibit higher strength properties than those of pine wood adherends, which was confirmed in nearly all strength tests.
 
Date 2019-07-05T15:07:28Z
2019-07-05T15:07:28Z
2018-09
 
Type Article
 
Identifier A. Rudawska, M. Maziarz, M. Šajgalík, P. Valášek, T. Zlamal, V. Iasnii. The influence of selected factors on the strenght of wood adhesive joints. Advances in Science and Technology, Vol.12, No. 3, 2018, pp. 47–54.
http://elartu.tntu.edu.ua/handle/lib/28686
10.12913/22998624/92099
 
Language en
 
Relation http://www.astrj.com/THE-INFLUENCE-OF-SELECTED-FACTORS-ON-THE-STRENGHT-OF-WOOD-ADHESIVE-JOINTS,92099,0,2.html
1. Adams R.D. (ed.). Adhesive bonding. Science, technology and applications. Woodhead Publish-ing, United Kingdom, 2010.
2. Adams R.D., Comyn J. and Wake W.C. Structural Adhesive Joints in Engineering Book, 2nd edition, United Kingdom, Springer, 1997.
3. Bachtiar E.V., Clerc G., Brunner A.J., Kaliske M. and Niemz P. Static and dynamic tensile shear test of glued lap wooden joint with four different types of adhesives, International Jour-nal of the Biology, Chemistry, Physics, and Technology of Wood, 5, 2017, DOI: https://doi.org/10.1515/hf-2016-0154.
4. Bławucki S. and Zaleski K. The Effect of the Alu-minum Alloy Surface Roughness on the Restitu-tion Coefficient. Advances in Science and Technol-ogy Research Journal, 9(27), 2015, 66–71.
5. BrockmannW., Geiß P.L., Klingen J. and Schröder B. Adhesive bonding. Materials, Applications and Tech-nology, Weinheim, Germany, Wiley-Vch Press, 2009.
6. Conrad M.P.C., Smith G.D. and Fernlund G. Fracture of wood composites and wood-adhesive joints: A comparative review. Wood and Fibre Sci-ence, 1, 2004, 26–39.
7. Custódio J., Broughton J., Cruz H. and Winfield P. Activation of timber surface by flame and corona treatments to improve adhesion. International Jour-nal of Adhesion and Adhesives, 29, 2009, 167–172.
8. Da Silva L.F.M., Carbas R.J.C., Critchlow G.W., Figueiredo M.A.V. and Brown K. Effect of mate-rial, geometry, surface treatment and environment on the shear strength of single lap joints. Inter-national Journal of Adhesion and Adhesives, 29, 2009, 621–632.
9. Desai S.D., Patel J.V. and Sinka V.K. Polyurethane adhesive system from biomaterial-based polyol for bonding wood. International Journal of Adhesion and Adhesives, 23, 2003, 393–399.
10. DIN EN 1465. Adhesives. Determination of tensile lap-shear strength of bonded joints.
11. Godzimirski J., Kozakiewicz J., Łunarski J. and Zie-lecki W. Konstrukcyjne połączenia klejowe elemen-tów metalowych w budowie maszyn. Oficyna Wy-dawnicza Politechniki Rzeszowskiej, Rzeszów, 1997.
12. Grant L.D.R., Adams R.D. and da Silva L.F.M. Effect of the temperature on the strength of adhe-sively bonded single lap and T joints for the automotive industry, International Journal of Adhesion and Adhesives, 29, 2009, 535–524.
13. Hass P., Kläusler O., Schlegel S. and Niemz P. Ef-fects of mechanical and chemical surface prepara-tion on adhesively bonded wooden joints. Inter-national Journal of Adhesion and Adhesives, 51, 2014, 95–102.
14. http://www.loctite.co.uk (access on 31-05-2017).
15. https://www.bijlard.com (access on 31-05-2017).
16. Pizzi A.Advanced Wood Adhesive Technology. Marcel Dekker, New York, 1994.
17. River B.H. Fracture ofadhesive-bondedwood joints. In: Handbook ofadhesivetechnology, re-vised and expanded, ed. A Pizzi, KL Mittal, Marcel Dekker, Switzerland, 2003.
18. Rudawska A., Danczak I., Müller M. and Valsek P. The effect of sandblasting on surface properties for adhesion. International Journal of Adhesion and Adhesives, 70, 2016, 176–190.
19. Rudawska A. Pressure during curing and the strength of 2024, 2017A and 1050 aluminium alloy sheet ad-hesive joints. Advances in Science and Technology Research Journal, 9(26), 2015, 96 –103.
20. Rudawska A. Surface free energy and 7075 alu-minium bonded joint strength following degreasing only and without any prior treatment. Journal Adhe-sion Science and Technology, 26, 2012, 1233–1247.
21. Rudawska A. Influence of the thickness of joined elements on lap length of aluminium alloy sheet bonded joints. Advances in Science and Technol-ogy Research Journal, 9(27), 2015, 35–44.
22. Serrano E. Adhesive Joints in Timber Engineering. Modelling and Testing of Fracture Properties. Di-vision of Structural Mechanics, Lund University, LUND, Sweden, 2000.
23. Świć A., Draczew A. and Gola A. Method of achiev-ing accuracy of thermo-mechanical treatment of low-rigidity shafts, Advances in Science and Tech-nology Research Journal, 10(29), 2016, 62–70.
24. Veigel S., Müller U., Keckes J., Obersriebnig M. and Gindl-Almutter W. Cellulose nanofibrils as filler for adhesives: effect on specific fracture en-ergy of solid wood-adhesive bonds. Cellulose, 18, 2011, 1227, doi:10.1007/s10570-011-9576-1
 
Format 47-54
 
Coverage PL