مراجعة لأستخدام نشارة الخشب في المواد الأنشائية

محتوى المقالة الرئيسي

Nadia Ghadhanfer Hikmet

الملخص

إن انبعاثات الكاربون المصاحبة للبناء والكلفة الباهظة لمواد البناء الخام إضافة الى مخاطر ندرتها في المستقبل جميعها تهدد الاستدامة وتلحق الضرر بالبيئة. عليه، تسعى العديد من الدول برسم استراتيجيات حديثة للبيئة الخضراء من خلال اعتماد مواد معاد تدويرها وصديقة للبيئة في البناء بما في ذلك مخلفات الخشب أو نشارة الخشب. يقدم البحث الحالي مراجعة لأهم الدراسات المتميزة والطرق الواعدة المتعلقة بتوظيف نشارة الخشب في الخرسانة والطابوق. أظهرت الدراسات ذات الصلة بنجاح اضافة نشارة الخشب محل المواد الأسمنتية أو الركام الطبيعي بصورة جزئية في الخلطة الخرسانية دون حصول تأثير سلبي حاد على الخواص الفيزيائية والميكانيكية. حيث اشارت معظم الدراسات إلى أن النسبة المثلى لأستبدال السمنت أو الرمل بنشارة الخشب كانت بين (5-20%) من الحجم أو الوزن الكلي للخلطة. اما في حال تجاوزت نسبة إضافة نشارة الخشب حدود الـ (%20) فيتوجب اجراء معالجات إضافية للخلطة الحاوية على نشارة الخشب لضمان الحفاظ على الأداء والمقاومة المرغوبة. من جملة هذه المعالجات الناحعة على سبيل المثال لا الحصر، الغليان أوالغسيل الجيد لنشارة الخشب أو إضافة سيليكات الصوديوم اثناء الخلط أو الانضاج بالماء الحاوي على كبريتات الصوديوم. زيادة على ذلك، فإن الدراسات أظهرت ايضا قدرة نشارة الخشب الفعالة في تقليل الكثافة او الوزن للعينات المختبرية، وتحسين العزل الحراري والصوتي في المباني. لذا، فأن النتائج المسردة في هذه المراجعة تدعم اضافة نشارة الخشب في أجزاء البناء مثل الجدران الداخلية والخارجية، والأسقف، وأجزاء البناء الغير معرضة الى الأحمال الثقيلة. ان من شأن هذا الجانب الهام خلق فرصة لبيئة أقل تلوثًا، والمساهمة في تخفيض كلفة البناء، والاستثمار الأمثل والمستدام للموارد الطبيعية.

تفاصيل المقالة

كيفية الاقتباس
"مراجعة لأستخدام نشارة الخشب في المواد الأنشائية" (2024) مجلة الهندسة, 30(11), ص 164–184. doi:10.31026/j.eng.2024.11.10.
القسم
Articles

كيفية الاقتباس

"مراجعة لأستخدام نشارة الخشب في المواد الأنشائية" (2024) مجلة الهندسة, 30(11), ص 164–184. doi:10.31026/j.eng.2024.11.10.

تواريخ المنشور

الإستلام

2024-03-17

النسخة النهائية

2024-06-28

الموافقة

2024-08-27

النشر الالكتروني

2024-11-01

المراجع

Abbas, T.F. and Abbas, Z.K., 2023. Manufacture of load bearing concrete masonry units using waste demolishing material. Journal of Engineering, 29(4), pp. 105-118. https://doi.org/10.31026/j.eng.2023.04.07.

Abbas, Z.K., 2022. The use of lightweight aggregate in concrete: A review. Journal of Engineering, 28(11), pp. 1-13. https://doi.org/10.31026/j.eng.2022.11.01.

Abdul Ameer, O., 2018. Assessment the thermal properties lightweight concrete produced by using local industrial waste materials. In MATEC Web of Conferences, 162, pp. 1-6. https://doi.org/10.1051/matecconf/201816202027.

Abdul-Wahab, S.A., Al-Dhamri, H., Ram, G. and Chatterjee, V.P., 2021. An overview of alternative raw materials used in cement and clinker manufacturing. International Journal of Sustainable Engineering, 14(4), pp. 743-760.

Adebakin, I.H., Adeyemi, A.A., Adu, J.T., Ajayi, F.A., Lawal, A.A. and Ogunrinola, O.B., 2012. Uses of sawdust as admixture in production of low-cost and lightweight hollow sandcrete blocks. American journal of scientific and industrial research, 3(6), pp. 458-463. https://doi.org/10.5251/ajsir.2012.3.6.458.463.

Ahmad, W., Ahmad, A., Ostrowski, K.A., Aslam, F. and Joyklad, P., 2021. A scientometric review of waste material utilization in concrete for sustainable construction. Case Studies in Construction Materials, 15, pp. 1-25. https://doi.org/10.1016/j.cscm.2021.e00683.

Ahmed, W., Khushnood, R.A., Memon, S.A., Ahmad, S., Baloch, W.L. and Usman, M., 2018. Effective use of sawdust for the production of eco-friendly and thermal-energy efficient normal weight and lightweight concretes with tailored fracture properties. Journal of Cleaner Production, 184, pp. 1016-1027. https://doi.org/10.1016/j.jclepro.2018.03.009.

Aigbomian, E.P. and Fan, M., 2013. Development of wood-crete from hardwood and softwood sawdust. The Open Construction & Building Technology Journal, 7(1), pp. 108-117. http://doi.org/10.2174/1874836801307010108.

Alabduljabbar, H., Benjeddou, O., Soussi, C., Khadimallah, M.A. and Alyousef, R., 2021. Effects of incorporating wood sawdust on the firing program and the physical and mechanical properties of fired clay bricks. Journal of Building Engineering, 35, pp. 1-11. https://doi.org/10.1016/j.jobe.2020.102106.

Alabduljabbar, H., Huseien, G.F., Sam, A.R.M., Alyouef, R., Algaifi, H.A. and Alaskar, A., 2020. Engineering properties of waste sawdust-based lightweight alkali-activated concrete: experimental assessment and numerical prediction. Materials, 13(23), pp. 1-30. https://doi.org/10.3390/ma13235490.

Alharishawi, S.S.C., Abd, H.J. and Abass, S.R., 2020. Employment of recycled wood waste in lightweight concrete production. Archives of Civil Engineering, 66(4), pp. 675-688. https://doi.org/10.24425/ace.2020.135244.

Amiri, M., Hatami, F. and Golafshani, E.M., 2021. Evaluating the synergic effect of waste rubber powder and recycled concrete aggregate on mechanical properties and durability of concrete. Case Studies in Construction Materials, 15, pp. 1-18. https://doi.org/10.1016/j.cscm.2021.e00639.

Ansari, F., Maher, A., Luke, A., Zhang, G.Y. and Szary, P., 2000. Recycled materials in Portland cement concrete (No. FHWA 2000-03). United States. Federal Highway Administration.

Appiah, D., 2010. The thermal conductivity and cold crushing strength of locally produced sandcrete bricks of different compositions of sawdust, palm-nut fibre and pozzolana incorporated-a search for room comfort in the tropics (Doctoral dissertation).

Asadi, I., Shafigh, P., Hassan, Z.F.B.A. and Mahyuddin, N.B., 2018. Thermal conductivity of concrete–a review. Journal of Building Engineering, 20, pp. 81-93. https://doi.org/10.1016/j.jobe.2018.07.002.

Asdrubali, F., D'Alessandro, F. and Schiavoni, S., 2015. A review of unconventional sustainable building insulation materials. Sustainable Materials and Technologies, 4, pp. 1-17. https://doi.org/10.1016/j.susmat.2015.05.002.

Asdrubali, F., Ferracuti, B., Lombardi, L., Guattari, C., Evangelisti, L. and Grazieschi, G., 2017. A review of structural, thermo-physical, acoustical, and environmental properties of wooden materials for building applications. Building and Environment, 114, pp. 307-332. https://doi.org/10.1016/j.buildenv.2016.12.033.

Assiamah, S., Agyeman, S., Adinkrah-Appiah, K. and Danso, H., 2022. Utilization of sawdust ash as cement replacement for landcrete interlocking blocks production and mortarless construction. Case Studies in Construction Materials, 16, pp. 1-13. https://doi.org/10.1016/j.cscm.2022.e00945.

Awal, A.A., Mariyana, A.A.K. and Hossain, M.Z., 2016. Some aspects of physical and mechanical properties of sawdust concrete. GEOMATE Journal, 10(21), pp. 1918-1923.

Batayneh, M., Marie, I. and Asi, I., 2007. Use of selected waste materials in concrete mixes. Waste management, 27(12), pp. 1870-1876.

Batool, F., Islam, K., Cakiroglu, C. and Shahriar, A., 2021. Effectiveness of wood waste sawdust to produce medium-to low-strength concrete materials. Journal of Building Engineering, 44, pp. 1-12. https://doi.org/10.1016/j.jobe.2021.103237.

Boubel, A., Garoum, M., Bousshine, S. and Bybi, A., 2021. Investigation of loose wood chips and sawdust as alternative sustainable sound absorber materials. Applied Acoustics, 172, pp. 1-11. https://doi.org/10.1016/j.apacoust.2020.107639.

British Standards Institution, 2005. Code of practice for the use of masonry, BS 5628: Part 1, British Standards Institution, London.

BS 6073-1:1981. Precast concrete masonry units. Specification for precast concrete masonry units. British Standard Institutions.

Bwayo, E. and Obwoya, S.K., 2014. Coefficient of thermal diffusivity of insulation brick developed from sawdust and clays. Journal of ceramics, 2014, pp. 1-7. https://doi.org/10.1155/2014/861726.

Charai, M., Sghiouri, H., Mezrhab, A., Karkri, M., Elhammouti, K. and Nasri, H., 2020. Thermal performance and characterization of a sawdust-clay composite material. Procedia Manufacturing, 46, pp. 690-697. https://doi.org/10.1016/j.promfg.2020.03.098.

Cheah, C.B. and Ramli, M., 2011. The implementation of wood waste ash as a partial cement replacement material in the production of structural grade concrete and mortar: An overview. Resources, Conservation and Recycling, 55(7), pp. 669-685. https://doi.org/10.1016/j.resconrec.2011.02.002.

Chemani, B. and Chemani, H., 2012. Effect of adding sawdust on mechanical-physical properties of ceramic bricks to obtain lightweight building material. International Journal of Mechanical and Mechatronics Engineering, 6(11), pp. 2521-2525.

Cheng, Y., You, W., Zhang, C., Li, H. and Hu, J., 2013. The implementation of waste sawdust in concrete. Engineering, 5(12), pp. 943-947. http://doi.org/10.4236/eng.2013.512115.

Chung, H., Emms, G. and Fox, C., 2014. Vibration reduction in lightweight floor/ceiling systems with a sand-sawdust damping layer. Acta Acustica united with Acustica, 100(4), pp. 628-639. https://doi.org/10.3813/AAA.918742.

Chung, H., Fox, C., Dodd, G. and Emms, G., 2010. Lightweight floor/ceiling systems with improved impact sound insulation. Building Acoustics, 17(2), pp. 129-141. https://doi.org/10.1260/1351-010X.17.2.129.

Cleetus, A., Shibu, R., Sreehari, P.M., Paul, V.K. and Jacob, B., 2018. Analysis and study of the effect of GGBFS on concrete structures. Int. Res. J. Eng. Technol. (IRJET), 5(03), pp. 3033-3037.

Cultrone, G., Aurrekoetxea, I., Casado, C. and Arizzi, A., 2020. Sawdust recycling in the production of lightweight bricks: How the amount of additive and the firing temperature influence the physical properties of the bricks. Construction and Building

Materials, 235, pp. 1-13. https://doi.org/10.1016/j.conbuildmat.2019.117436.

Deac, T., Fechete-Tutunaru, L. and Gaspar, F., 2016. Environmental impact of sawdust briquettes use–experimental approach. Energy procedia, 85, pp. 178-183. https://doi.org/10.1016/j.egypro.2015.12.324.

Denis, A., Attar, A., Breysse, D. and Chauvin, J.J., 2002. Effect of coarse aggregate on the workability of sandcrete. Cement and Concrete Research, 32(5), pp. 701-706. https://doi.org/10.1016/S0008-8846(01)00746-3.

Dias, S., Almeida, J., Santos, B., Humbert, P., Tadeu, A., António, J., de Brito, J. and Pinhao, P., 2022. Lightweight cement composites containing end-of-life treated wood–Leaching, hydration and mechanical tests. Construction and Building Materials, 317, pp. 1-13. https://doi.org/10.1016/j.conbuildmat.2021.125931.

Dias, S., Tadeu, A., Almeida, J., Humbert, P., António, J., de Brito, J. and Pinhão, P., 2022. Physical, mechanical, and durability properties of concrete containing wood chips and sawdust: an experimental approach. Buildings, 12(8), pp. 1-26. https://doi.org/10.3390/buildings12081277.

Elinwa AU, and Ejeh SP, 2004. Effects of the incorporation of sawdust waste incineration fly ash in cement pastes and mortars. Journal of Asian Architecture and Building Engineering, 3(1), pp. 1-7. https://doi.org/10.3130/jaabe.3.1.

Farazela, M.S., Arib, M.N., Azmi, M.M., Aniza, A.S. and Azhan, A.Z., 2021, October. Compressive strength performance of composite sand cement brick with power saw wood. In Journal of Physics: Conference Series, 2051(1), pp. 1-7. https://doi.org10.1088/1742-6596/2051/1/012050.

Fares, H., Toutanji, H., Pierce, K. and Noumowé, A., 2015. Lightweight self-consolidating concrete exposed to elevated temperatures. Journal of Materials in Civil Engineering, 27(12), pp. 1-10. https://doi.org/10.1061/(ASCE)MT.1943-5533.0001285.

Folaranmi, J., 2009. Effect of additives on the thermal conductivity of clay. Leonardo Journal of Sciences, 14, pp. 74-77.

Fregoso-Madueño, J.N., Goche-Télles, J.R., Rutiaga-Quiñones, J.G., González-Laredo, R.F., Bocanegra-Salazar, M. and Chávez-Simental, J.A., 2017. Alternative uses of sawmill industry waste. Revista Chapingo serie ciencias forestales y del ambiente, 23(2), pp. 243-260. https://doi.org/10.5154/r.rchscfa.2016.06.040.

Gagg, C.R., 2014. Cement and concrete as an engineering material: An historic appraisal and case study analysis. Engineering Failure Analysis, 40, pp. 114-140.

Gan, V.J., Cheng, J.C. and Lo, I.M., 2019. A comprehensive approach to mitigation of embodied carbon in reinforced concrete buildings. Journal of Cleaner Production, 229, pp. 582-597.

Ganiron, T.U., 2014. Effect of sawdust as fine aggregate in concrete mixture for building construction. International Journal of Advanced Science and Technology, 63(1), pp. 73-82. http://dx.doi.org/10.14257/ijast.2014.63.07.

Ghimire, A. and Maharjan, S., 2019. Experimental analysis on the properties of concrete brick with partial replacement of sand by saw dust and partial replacement of coarse aggregate by expanded polystyrene. Journal of Advanced College of Engineering and Management, 5, pp. 27-36. https://doi.org/10.3126/jacem.v5i0.26674.

Hu, J., 2014. The implementation of waste sawdust in concrete. Advanced Materials Research, 941, pp. 849-853. https://doi.org/10.4028/www.scientific.net/AMR.941-944.849.

Ikponmwosa, E.E., Falade, F.A., Fashanu, T., Ehikhuenmen, S. and Adesina, A., 2020. Experimental and numerical investigation of the effect of sawdust ash on the performance of concrete. Journal of Building Pathology and Rehabilitation, 5, pp. 1-11. https://doi.org/10.1007/s41024-020-00081-3.

Kang, C.W., Oh, S.W., Lee, T.B., Kang, W. and Matsumura, J., 2012. Sound absorption capability and mechanical properties of a composite rice hull and sawdust board. Journal of Wood Science, 58, pp. 273-278. https://doi.org/10.1007/s10086-011-1243-5.

Khan, M., Cao, M., Chaopeng, X. and Ali, M., 2022. Experimental and analytical study of hybrid fiber reinforced concrete prepared with basalt fiber under high temperature. Fire and Materials, 46(1), pp. 205-226. https://doi.org/10.1002/fam.2968.

Lim, T., Ellis, B.R. and Skerlos, S.J., 2019. Mitigating CO2 emissions of concrete manufacturing through CO2-enabled binder reduction. Environmental Research Letters, 14(11), pp. 1-9.

Lotfy, A., Hossain, K. and Lachemi, M., 2016. Transport and durability properties of self-consolidating concrete using three types of lightweight aggregates. ACI Materials Journal, 113(5), pp. 679-690. https://doi.org/10.14359/51689112.

Majeed, N., 2011. Removal of Chromium (VI) from aqueous solutions using sawdust as adsorbent. Journal of Engineering, 17(5), pp. 1132-1142. https://doi.org/10.31026/j.eng.2011.05.07.

Malik, M.I., Jan, S.R., Peer, J.A., Nazir, S.A. and Mohammad, K.F., 2015. Partial replacement of cement by saw dust ash in concrete a sustainable approach. International Journal of Engineering Research and Development, 11(2), pp. 48-53.

Mallakpour, S., Sirous, F. and Hussain, C.M., 2021. Sawdust, a versatile, inexpensive, readily available bio-waste: from mother earth to valuable materials for sustainable remediation technologies. Advances in Colloid and Interface Science, 295, pp. 1-20. https://doi.org/10.1016/j.cis.2021.102492.

Martínez-Molina, A., Tort-Ausina, I., Cho, S. and Vivancos, J.L., 2016. Energy efficiency and thermal comfort in historic buildings: a review. Renewable and Sustainable Energy Reviews, 61, pp. 70-85. https://doi.org/10.1016/j.rser.2016.03.018.

Meko, B. and Ighalo, J.O., 2021. Utilization of cordia africana wood sawdust ash as partial cement replacement in C 25 concrete. Cleaner Materials, 1, pp. 1-8. https://doi.org/10.1016/j.clema.2021.100012.

Memon, R.P., Sam, A.R.M., Awal, A.A. and Achekzai, L., 2017. Mechanical and thermal properties of sawdust concrete. Jurnal Teknologi, 79(6), pp. 23-27.

Nanayakkara, O. and Xia, J., 2019. Mechanical and physical properties of mortar of partially replaced fine aggregates with sawdust. Academic Journal of Civil Engineering, 37(2), pp. 308-313. https://doi.org/10.26168/icbbm2019.44.

Núñez-Retana, V.D., Wehenkel, C., Vega-Nieva, D.J., García-Quezada, J. and Carrillo-Parra, A., 2019. The bioenergetic potential of four oak species from northeastern Mexico. Forests, 10(10), pp. 1-15. https://doi.org/10.26168/icbbm2019.44.

Nyers, J., Kajtar, L., Tomić, S. and Nyers, A., 2015. Investment-savings method for energy-economic optimization of external wall thermal insulation thickness. Energy and Buildings, 86, pp. 268-274. https://doi.org/10.1016/j.enbuild.2014.10.023.

Ogundipe, O.M. and Jimoh, Y.A., 2009. Durability-based appropriateness of sawdust concrete for rigid pavement. Advanced Materials Research, 62, pp. 11-16.

Okoroafor, S.U., Ibearugbulam, O.M., Onukwugha, E.R., Anyaogu, L. and Adah, E.I., 2017. Structural characteristics of sawdust-sand-cement composite. International Journal of Advancements in Research & Technology, 6(1), pp. 173-180.

Olaiya, B.C., Lawan, M.M. and Olonade, K.A., 2023. Utilization of sawdust composites in construction—a review. SN Applied Sciences, 5(5), p. 1-25. https://doi.org/10.1007/s42452-023-05361-4.

Omar, M.F., Abdullah, M.A.H., Rashid, N.A. and Rani, A.A., 2020. Partially replacement of cement by sawdust and fly ash in lightweight foam concrete. In IOP Conference Series: Materials Science and Engineering, 743(1), pp. 1-6. https://doi.org/10.1088/1757-899X/743/1/012035.

Onyechere, I.C., 2022. Properties of sawdust concrete. Journal of Building Material Science, 4(2), pp. 1-9. https://doi.org/10.30564/jbms.v4i2.4818.

Oyedepo, O.J., Oluwajana, S.D. and Akande, S.P., 2014. Investigation of properties of concrete using sawdust as partial replacement for sand. Civil and Environmental Research, 6(2), pp. 35-42.

Phonphuak, N., Teerakun, M., Srisuwan, A., Ruenruangrit, P. and Saraphirom, P., 2020. The use of sawdust waste on physical

properties and thermal conductivity of fired clay brick production. GEOMATE Journal, 18(69), pp. 24-29.

Raheem, A.A. and Sulaiman, O.K., 2013. Saw dust ash as partial replacement for cement in the production of sandcrete hollow blocks. International Journal of Engineering Research and Applications, 3(4), pp. 713-721.

Raheem, A.A., Adedokun, S.I., Raphael, A.B., Adedapo, A.O. and Olayemi, A.B., 2017. Application of saw dust ash as partial replacement for cement in the production of interlocking paving stones. International Journal of Sustainable Construction Engineering and Technology, 8(1), pp.1-11.

Rizki, M., Tamai, Y., Koda, K., Kojima, Y. and Terazawa, M., 2010. Wood density variations of tropical wood species: implications to the physical properties of sawdust as substrate for mushroom cultivation. Wood Research Journal, 1(1), pp. 34-39. https://doi.org/10.51850/wrj.2010.1.1.34-39.

Saeed, H.H., 2013. Pretreatment of sawdust for producing sawdust concrete. Journal of Engineering &Applied Sciences, 31(3), pp. 541-549.

Sales, A., De Souza, F.R., Dos Santos, W.N., Zimer, A.M. and Almeida, F.D.C.R., 2010. Lightweight composite concrete produced with water treatment sludge and sawdust: thermal properties and potential application. Construction and building materials, 24(12), pp. 2446-2453. https://doi.org/10.1016/j.conbuildmat.2010.06.012.

Salih, S.A. and Kzar, A.M., 2015. Studying the utility of using reed and sawdust as waste materials to produce cementitious building units. Journal of Engineering, 21(10), pp. 36-54. https://doi.org/10.31026/j.eng.2015.10.03.

Sasah, J. and Kankam, C.K., 2017. Study of brick mortar using sawdust as partial replacement for sand. Journal of Civil Engineering and Construction Technology, 8(6), p. 59-66. https://doi.org/10.5897/JCECT2017.0450.

Sawant, A., Sharma, A., Rahate, R., Mayekar, N. and Ghadge, M.D., 2018. Partial replacement of sand with sawdust in concrete. Int Res J Eng Technol, 5, pp. 3098-3101.

Setunge, S. and Gamage, N., 2016. Application of acoustic materials in civil engineering. Acoustic Textiles, pp. 165-183. https://doi.org/10.1007/978-981-10-1476-5_8.

Sharba, A.A.K., Hason, M.M., Hanoon, A.N., Qader, D.N., Amran, M., Abdulhameed, A.A. and Al Zand, A.W., 2022. Push-out test of waste sawdust-based steel-concrete–steel composite sections: experimental and environmental study. Case Studies in Construction Materials, 17, pp. 1-16. https://doi.org/10.1016/j.cscm.2022.e01570.

Siddique, R., Singh, M., Mehta, S. and Belarbi, R., 2020. Utilization of treated saw dust in concrete as partial replacement of natural sand. Journal of Cleaner Production, 261, pp. 1-10. https://doi.org/10.1016/j.jclepro.2020.121226.

Sojobi, A.O., 2016. Evaluation of the performance of eco-friendly lightweight interlocking concrete paving units incorporating sawdust wastes and laterite. Cogent Engineering, 3(1), pp. 1-27. https://doi.org/10.1080/23311916.2016.1255168.

Soundhirarajan, K. and Abirami, T., 2018. Experimental study on strength of concrete by partial replacement of fine aggregate with sawdust and robo sand. National Journal of Multidisciplinary Research and Development, 3(1), pp. 1168-1173.

Surabhi, C., Anish, M.C., Mobin, K.M., Niyas, P. and Sreenivasan, E., 2017. A feasibility study on composite bricks from sawdust and boiler ash using cement as a binder. Trends in Biosciences, 10(3), pp. 1049-1052.

Thienel, K.C., Haller, T. and Beuntner, N., 2020. Lightweight concrete-from basics to innovations. Materials, 13(5), pp. 1-24. https://doi.org/10.3390/ma13051120.

Tiuc, A.E., Nemeş, O., Vermeşan, H. and Toma, A.C., 2019. New sound absorbent composite materials based on sawdust and polyurethane foam. Composites Part B: Engineering, 165, pp. 120-130. https://doi.org/10.1016/j.compositesb.2018.11.103.

Tiuc, A.E., Vasile, O. and Gabor, T., 2014. Determination of anti-vibrational and acoustical properties of some materials made from recycled rubber particles and sawdust. Romanian Journal of Acoustics and Vibration, 11(1), pp. 47-52.

Tulashie, S.K., Akpari, E.E.A., Appiah, G., Adongo, A. and Andoh, E.K., 2023. Acid hydrolysis of sawdust waste into bioethanol. Biomass Conversion and Biorefinery, 13(7), pp. 5743-5756. https://doi.org/10.1007/s13399-021-01725-1.

Turgut, P. and Algin, H.M., 2007. Limestone dust and wood sawdust as brick material. Building and environment, 42(9), pp. 3399-3403. https://doi.org/10.1016/j.buildenv.2006.08.012.

Turgut, P., 2007. Cement composites with limestone dust and different grades of wood sawdust. Building and Environment, 42(11), pp. 3801-3807. https://doi.org/10.1016/j.buildenv.2006.11.008.

Udokpoh, U. and Nnaji, C., 2023. Reuse of sawdust in developing countries in the light of sustainable development goals. Recent Progress in Materials, 5(1), pp. 1-33.

Ugwu, J.N., 2019. Saw dust as full replacement of fine aggregate in lightweight concrete: any comparable strength. The International Journal of Engineering and Sciences, 8(10), pp. 9-11.

Xing, Z., Djelal, C., Vanhove, Y. and Kada, H., 2015. Wood waste in concrete blocks made by vibrocompression. Environmental Processes, 2, pp. 223-232. https://doi.org/10.1007/s40710-015-0104-4.

Yang, Z., Huddleston, J. and Brown, H., 2016. Effects of wood ash on properties of concrete and flowable fill. Journal of materials science and chemical engineering, 4(7), pp. 101-114. https://doi.org/10.4236/msce.2016.47013.

Zakaria, N.Z. and Sulieman, M.Z., 2020. Difference curing conditions on the engineering properties of high strength lightweight reinforced concrete (HSLRC) using sawdust and coconut fiber. International Journal of Sustainable Construction Engineering and Technology, 11(1), pp. 206-214.

Zepeda-Cepeda, C.O., Goche-Télles, J.R., Palacios-Mendoza, C., Moreno-Anguiano, O., Núñez-Retana, V.D., Heya, M.N. and Carrillo-Parra, A., 2021. Effect of sawdust particle size on physical, mechanical, and energetic properties of pinus durangensis briquettes. Applied sciences, 11(9), pp. 1-14. https://doi.org/10.3390/app11093805.

Zou, S., Li, H., Wang, S., Jiang, R., Zou, J., Zhang, X., Liu, L. and Zhang, G., 2020. Experimental research on an innovative sawdust biomass-based insulation material for buildings. Journal of Cleaner Production, 260, pp. 1-13. https://doi.org/10.1016/j.jclepro.2020.121029.

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