Archive
Online first
Current issue
Instructions for Authors
Guide for authors
Peer Review Policy
Research Ethics Policy
Crossmark Policy
Ghostwriting and Guest Authorship
Copyright
Open Access Policy
Plagiarism
About the Journal
Aim and Scope
Scientific Board
Publisher
Editorial Board
Indexing in databases
Personal Data Protection
Repository policy
Contact
ORIGINAL PAPER
Influences of UF adhesive consumption on HDF properties
1
Interior Design, Kırıkkale University, Turkey
2
Machine, Isparta University of Applied Sciences, Turkey
Submission date: 2024-12-31
Final revision date: 2025-02-14
Acceptance date: 2025-03-21
Online publication date: 2025-06-02
KEYWORDS
TOPICS
ABSTRACT
In this study, high-density fiberboards were produced using five different Urea-Formaldehyde resin (0.98 mole) consumption amount (12.47, 11.55, 11.12, 10.65, and 10.1 % wt. of dry fiber), and physical, mechanical, and formaldehyde content properties of fiberboards were determined. Tested boards were produced using the continuous through-feed press in an operating factory instead of laboratory-type press equipment. According to results, a linear and stable increase or decrease tendencies with the increase in adhesive consumption was not observed for almost all properties. Contrary, values of properties oscillated with the increase in adhesive consumption. Except for the Surface Soundness (SS), means of the physical and mechanical properties presented significant differences. The most advanced properties was SS by 25.4% when UF consumption was 105 kg/m³. For the physical properties, it was Surface Abrasion by 15.7% improvement at the same consumption amount. For thickness swelling (TS 2h and 24 h) and water absorption 115 kg/m³ consumption provided highest improvement by 15.3%, 6.8% and 8.7% decreases. Therefore, considering all evaluated properties, a common consumption amount could not be determined which pointed out the best improvement. One of the most important points about the panels was the formaldehyde emission value. The FE around 17.6% decreased when UF consumption was 115 kg/m³. However, FE values are determined above the E1 class value which should be reduced for the market.
REFERENCES (44)
1.
Açık, C., & Tutuş, A. (2012). Effects of Various Synthetic Surface Coatings on Thermal Conductivity of Fiberboard. Duzce Universitesi Ormancılık Dergisi, 8(2), 1–8.
2.
Antov, P., Savov, V., Krišt’ák, L., Réh, R., & Mantanis, G. I. (2021). Eco-friendly, high-density fiberboards bonded with urea-formaldehyde and ammonium lignosulfonate. Polymers, 13(2), 1–13. https://doi.org/10.3390/polym1....
3.
Bayram, B. Ç., Ersen, N., Akyüz, İ., Üçüncü, T., & Akyüz, K. C. (2018). An analytical Hierarchy Process application: Determining the most important board type of Turkey regarding exportation in recent years. International Journal of Environmental Trends, 2(2), 53–58.
4.
Çamlıbel, O. (2020a). Investigation of the Physical Properties and Mechanical Properties of Hight Density Fiberboard (HDF) Board Produced with Low Mole Urea Formaldehyde Resin. In Ö. C. Hergül & P. Göker (Eds.), 3rd. International Congress of Academic Research (pp. 629–635). Asos Press.
5.
Çamlıbel, O. (2020b). Investigation of the Physical Some Properties of HDF Boards Produced with Urea Formaldehyde Different Moles Ratios. In Ö. Çakır (Ed.), 8th International Scientific Research Congress-Science and Engineering (pp. 25–36). Asos Press.
6.
Çetin, F., & Kaygın, B. (2016). Three dimensional plating of wooden fibrous composite materials by using the technique of pyrolytic plating. Journal of Bartın Faculty of Forestry, 18(1), 93–102.
7.
Döngel, N., Küreli, İ., & Söğütlü, C. (2008). Kuru Sıcaklığın Ahşap ve Ahşap Esaslı Döşeme Kaplama Malzemelerinde Parlaklık ve Renk Değişimine Etkisi. Politeknik Dergisi, 11(3), 255–263.
8.
Güler, C., Çöpür, Y., Taşcıoğlu, C., & Büyüksarı, Ü. (2007). Utilization potential of HDF (High Density Fiberboard) in Laminated Parquet Production. Duzce Universitesi Ormancılık Dergisi, 3(2), 16–32.
9.
Hernán Poblete, W., & Roque Vargas, C. (2006). Relationship between density and properties of HDF manufactured by a dry process. Maderas: Ciencia y Tecnología, 8(3), 169–182. https://doi.org/10.4067/S0718-....
10.
Hızıroğlu, S. (2008). Internal Bond Strength of Laminated Flooring as Function of Water Exposure. 51st International Convention of Society of Wood Science and Technology, 4.
11.
Hong, M. K., Lubis, M. A. R., & Park, B. D. (2017). Effect of panel density and resin content on properties of medium density fiberboard. Journal of the Korean Wood Science and Technology, 45(4), 444–455. https://doi.org/10.5658/WOOD.2....
12.
Hunt, J. F., O’Dell, J., & Turk, C. (2008). Fiberboard bending properties as a function of density, thickness, resin, and moisture content. Holzforschung, 62(5), 569–576. https://doi.org/10.1515/HF.200....
13.
İstek, A. (2006). Effects of pressure and temperature on physical and mechanical properties of high density fiberboard. ZKÜ Bartın Orman Fakültesi Dergisi, 8(10), 29–35.
14.
İstek, A., Özlüsoylu, İ., & Kızılkaya, A. (2017). Turkish Wood Based Panel Sector Analysis. Journal of Bartin Faculty of Forestry, 19(1), 132–138.
15.
Jaber, M. A., Hammadi, K. J., Karem, A. A. A., & Abd-Alrazak, M. (2016). Physical and Mechanical Properties of Medium Density Fiberboard Made of Palm Fronds and Trunks. Asian Journal of Applied Sciences, 4(4), 972–978.
16.
Kara, M. E., Yerlikaya, Z., Ateş, S., & Olgun, Ç. (2016). Effect of pressing conditions on some surface properties of HDF laminate parquets. Indian Journal of Engineering and Materials Sciences, 23(4), 274–278.
17.
Kartal, S. N., Burdsall, H. H., & Green, F. (2003). Accidental mold/termite testing of high density fiberboard (HDF) treated with boric acid, borax and N’N-aphthoylhydroxylamine (NHA).
18.
Kartal, S. N., & Green, F. (2003). Decay and termite resistance of medium density fiberboard (MDF) made from different wood species. International Biodeterioration and Biodegradation, 51(1), 29–35. https://doi.org/10.1016/S0964-....
19.
Korkut, S., Çabukoğlu, F., & Özdemir, H. (2015). Effects of Post Heat-Treatment on Certain Characteristics of High Density Fiberboard. Duzce Universitesi Ormancılık Dergisi, 11(1), 83–87.
20.
Labans, E., Kalnins, K., & Bisagni, C. (2019). Flexural behavior of sandwich panels with cellular wood, plywood stiffener/foam and thermoplastic composite core. Journal of Sandwich Structures and Materials, 21(2), 784–805. https://doi.org/10.1177/109963....
21.
Lee, B. H., Kim, H. S., Kim, S., Kim, H. J., Lee, B., Deng, Y., Feng, Q., & Luo, J. (2011). Evaluating the flammability of wood-based panels and gypsum particleboard using a cone calorimeter. Construction and Building Materials, 25(7), 3044–3050. https://doi.org/10.1016/j.conb....
22.
Mamiński, M., Trzepałka, A., Auriga, R., H’Ng, P. S., & Chin, K. L. (2020). Physical and mechanical properties of thin high density fiberboard bonded with 1,3-dimethylol-4,5-dihydroxyethyleneurea (DMDHEU). Journal of Adhesion, 96(7), 679–690. https://doi.org/10.1080/002184....
23.
Mantanis, G., Athanassiadou, E., Nakos, P., & Coutinho, A. M. J. (2004). A New Process for Recycling Waste Fiberboards. In R. J. Tichy & V. Yadama (Eds.), 38th International Wood Composites Symposium (pp. 119–122). Washington State University.
24.
Mihajlova, J., & Savov, V. (2018). Physical Indicators of High-Density Fibreboards (HDF) Manufactured from Wood of Hard Broadleaved Species. 8th Hardwood Conference – New Aspects of Hardwood Utilization – From Science to Technology, 142–143.
25.
Nemli, G., Öztürk, I., & Aydın, A. (2004). Laminates. Artvin Orman Fakültesi Dergisi, 1–2, 55–60.
26.
Oh, Y. S. (2010). Effects of recycled fiber addition on high-density fiberboard for laminated flooring bonded with phenol-formaldehyde resin adhesive. Journal of Applied Polymer Science, 115(2), 641–645. https://doi.org/10.1002/app.30....
27.
Özdemir, F. (2016). Investigate on effect of dolomite mineral on some properties of high density fiberboard (HDF). KSU. Journal of Engineering Sciences, 19(2), 93–98.
28.
Özdemir, F., Özyurt, H., Dalgıç, E., Ramazanoğlu, D., & Tutuş, A. (2018). Investigation of Surface Quality of High Density Fiberboard (HDF) Boards Produced by Adding Muscovite Mineral. Kahramanmaras Sutcu Imam University Journal of Engineering Sciences, 21(2), 166–171.
29.
Özdemir, F., Tutuş, A., & Bal, B. C. (2013). Effect of fire retardants on thermal conductivity and limited oxygen index of high density fiberboard. Turkish Journal of Forestry, 14(2), 121–126. https://doi.org/10.18182/tjf.4....
30.
Özdemir, F., Tutuş, A., & Çiçekler, M. (2016). Effect of dolomite mineral on surface roughness of high density fiberboard (HDF). International Furniture Congress, 498–501.
31.
Rozins, R., & Iejavs, J. (2014). Evaluation of thermal properties of wood based composite panel walls. Research for Rural Development, 2, 109–114.
32.
Sala, C. M., Robles, E., & Kowaluk, G. (2020). Influence of adding offcuts and trims with a recycling approach on the properties of high-density fibrous composites. Polymers, 12(6). https://doi.org/10.3390/POLYM1....
33.
Sari, B., Nemli, G., Baharoǧlu, M., Bardak, S., & Zekoviç, E. (2013). The role of solid content of adhesive and panel density on the dimensional stability and mechanical properties of particleboard. Journal of Composite Materials, 47(10), 1247–1255. https://doi.org/10.1177/002199....
34.
Suchsland, O., & Woodson, G. E. (1986). Fiberboard manufacturing practices in the United States. In USDA Forest Service, Agriculture Handbook No 640. USDA Forest Service.
35.
TS EN ISO 12460-5 (2016). Wood based panels – Determination of formaldehyde release – Part 5: Extraction method (called the perforator method).
36.
TS EN 310. (1999). Wood-based panels – Determination of modulus of elasticity in bending and of bending strength.
38.
TS EN 317. (1999). Particleboards and fibreboards – Determination of swelling in thickness after immersion in water.
39.
TS EN 319. (1999). Particleboards and fibreboards – Determination of tensile strength perpendicular to the plane of the board.
42.
TS EN 324-1. (1999). Wood-based panels – Determination of dimensions of boards – Part 1: Determination of thickness, width and length.
43.
TS EN 382-1. (1999). Fibreboards – Determination of surface absorption part 1: Test method for dry process fibreboards.
44.
Xu, B., Chen, Z., & Ma, Q. (2015). Experimental Study of Formaldehyde Diffusion with in Building Materials in Different High-Voltage Electric Field. Procedia Engineering, 121, 256–261. https://doi.org/10.1016/j.proe....
| eISSN: | 2956-9141 |
We process personal data collected when visiting the website. The function of obtaining information about users and their behavior is carried out by voluntarily entered information in forms and saving cookies in end devices. Data, including cookies, are used to provide services, improve the user experience and to analyze the traffic in accordance with the Privacy policy. Data are also collected and processed by Google Analytics tool (more).
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
