[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5658/WOOD.2022.50.3.167

Influence of Manufacturing Environment on Delamination of Mixed Cross Laminated Timber Using Polyurethane Adhesive

SONG, Dabin (Wood Engineering Division, Department of Forest Products and Industry, National Institute of Forest Science)
KIM, Keonho (Wood Engineering Division, Department of Forest Products and Industry, National Institute of Forest Science)

Publication Information

Journal of the Korean Wood Science and Technology / v.50, no.3, 2022 , pp. 167-178 More about this Journal

Abstract

To investigate the influence of manufacturing environment on bonding performance of mixed cross laminated wood (CLT) using polyurethane (PUR) adhesive, a boiling water soak delamination test according to the temperature and relative humidity was conducted. The 5-ply mixed CLT consisted of Japanese Larch for external and middle layer and yellow poplar for internal layer. The PUR adhesives with different opening times of 10 and 30 minutes were used. The mixed CLT was manufactured according to pressing times of PUR and manufacturing environments of summer and winter. In case of summer environment, the delamination rate of the mixed CLT with pressing time of 4 hours using a PUR adhesive with open time of 10 minutes met the requirements of KS F 2081. In case of winter environment, the delamination rate of the mixed CLT didn't meet the requirements of KS standard. However, it was possible to confirm the effect of improving the adhesive performance by adjusting the pressing time according to the open time of the adhesive under the manufacturing conditions. The delamination rate of CLT with open time 30 minutes PUR, manufactured by indirect moisture supply methods was 11.2% better than direct moisture supply methods. As a result of delamination test in the same condition of relative humidity and adhesive, it was found that the temperature of manufacturing environment influences the adhesive performance.

Keywords

larch; yellow poplar; mixed cross-laminated timber (CLT); polyurethane; boiling water soak delamination test; G10 adhesive;

Citations & Related Records

Times Cited By KSCI : 8 (Citation Analysis)

Reference
Cited By KSCI

1	Galih, N.M., Yang, S.M., Yu, S.M., Kang, S.G. 2020. Study on the mechanical properties of tropical hybrid cross laminated timber using bamboo laminated board as core layer. Journal of the Korean Wood Science and Technology 48(2): 245-252. DOI
2	Gong, Y., Wu, G., Ren, H. 2016. Block shear strength and delamination of cross-laminated timber fabricated with Japanese larch. BioResources 11(4): 10240-10250.
3	Han, Y., Park, Y., Yang, S.Y., Chung, H., Chang, Y.S., Yeo, H. 2019. Dimensional changes of cross-laminated specimens produced under different conditions due to humidity variation. BioResources 14(2): 4035-4046.
4	Jung, H., Song, Y., Hong, S. 2020. Effect of glass fiber-reinforced connection on the horizontal shear strength of CLT walls. Journal of the Korean Wood Science and Technology 48(5): 685-695. DOI
5	Korean Standards Association. 2021. KS F 2081 Cross laminated timber. The Ministry of Knowledge Economy, Korean Agency for Technology and Standards, Seoul, Korea.
6	Kramer, A., Barbosa, A.R., Sinha, A. 2014. Viability of hybrid poplar in ANSI approved cross-laminated timber applications. Journal of Materials in Civil Engineering 26(7): 06014009. DOI
7	Tankut, N., Bardak, T., Sozen, E., Tankut, A.N. 2016. The effect of different nanoparticles and open time on bonding strength of poly (vinyl acetate) adhesive. Measurement 81: 80-84. DOI
8	Mohamadzadeh, M., Hindman, D. 2015. Mechanical Performance of Yellow-poplar Cross Laminated Timber. Virginia Polytechnic Institute and State University, Blacksburg, VA, USA.
9	Song, Y.J., Hong, S.I. 2016. Evaluation of bonding strength of larch cross-laminated timber. Journal of the Korean Wood Science and Technology 44(4): 607-615. DOI
10	Yang, S.M., Lee, H.H., Kang, S.G. 2021. Research trends in hybrid cross-laminated timber (CLT) to enhance the rolling shear strength of CLT. Journal of the Korean Wood Science and Technology 49(4): 336-359. DOI
11	Jang, S.S., Lee, H.W. 2019. Lateral resistance of CLT wall panels composed of square timber larch core and plywood cross bands. Journal of the Korean Wood Science and Technology 47(5): 547-556. DOI
12	Li, H., Wang, B.J., Wei, P., Wang, L. 2019. Cross-laminated timber (CLT) in China: A state-of-the-art. Journal of Bioresources and Bioproducts 4(1): 22-31. DOI
13	Choi, G.W., Yang, S.M., Lee, H.J., Kim, J.H., Choi, K.H., Kang, S.G. 2020. A study on the block shear strength according to the layer composition of and adhesive type of ply-lam CLT. Journal of the Korean Wood Science and Technology 48(6): 791-806. DOI
14	Galvez, P., Armentia, S.L., Abenojar, J., Martinez, M.A. 2020. Effect of moisture and temperature on thermal and mechanical properties of structural polyurethane adhesive joints. Composite Structures 247: 112443. DOI
15	Kang, C.W., Jang, S.S., Kang, H.Y., Li, C. 2019. Sound absorption rate and sound transmission loss of CLT wall panels composed of larch square timber core and plywood cross band. Journal of the Korean Wood Science and Technology 47(1): 33-39. DOI
16	Kim, H.J. 2003. Polyurethane adhesives. Rubber Technology 4(2): 77-103.
17	Knorz, M., Torno, S., Kuilen, J.W. 2017. Bonding quality of industrially produced cross-laminated timber (CLT) as determined in delamination tests. Construction and Building Materials 133: 219-225. DOI
18	Sterley, M., Trey, S., Lundevall, A., Olsson, S. 2012. Influence of cure conditions on the properties of a one-component moisture-cured polyurethane adhesive in the context of green gluing of wood. Journal of Applied Polymer Science 126(S1): E297-E304. DOI
19	Lim, J.A., Oh, J.K., Yeo, H.M., Lee, J.J. 2010. Feasibility of domestic yellow poplar (Liriodendron tulipifera) dimension lumber for structural uses. Journal of the Korean Wood Science and Technology 38(6): 470-479. DOI
20	Na, J., Fan, Y., Tan, W., Guo, S., Mu, W. 2017. Mechanical behavior of polyurethane adhesive bonded joints as a function of temperature and humidity. Journal of Adhesion Science and Technology 32(5): 457-472.
21	Yusof, N.M., Tahir, P.M., Lee, S.H., Khan, M.A., James, R.M.S. 2019. Mechanical and physical properties of cross-laminated timber made from Acacia mangiumwood as function of adhesive types. Journal of Wood Science 65(1): 20. DOI
22	Choi, G.W., Yang, S.M., Lee, H.J., Kim, J.H., Choi, K.H., Kang, S.G. 2021. Evaluation of flexural performance according to the plywood bonding method of ply-lam CLT. Journal of the Korean Wood Science and Technology 49(2): 107-121. DOI
23	ANSI, APA. 2018 Standard for Performance-Rated Cross-Laminated Timber (PRG 320). APA-The Engineered Wood Association, Tacoma, WA, USA.
24	Kunniger, T., Clerc, G., Josset, S., Niemz, P., Pichelin, F., Kuilen, J.W.G. 2019. Influence of humidity and frequency on the energy dissipation in wood adhesives. International Journal of Adhesion and Adhesives 92: 99-104. DOI
25	Brandner, R., Flatscher, G., Ringhofer, A., Schickhofer, G., Thiel, A. 2016. Cross laminated timber (CLT): Overview and development. European Journal of Wood and Wood Products 74(3): 331-351. DOI