Geri Dönüştürülebilir Atık Malzemelerin Geoteknik Özelliklerinin Karşılaştırmalı Olarak İncelenmesi
Yıl 2023,
Cilt: 39 Sayı: 1, 1 - 12, 02.05.2023
Bilal Korkmaz
,
Şüheda Taştan
,
Aslı Yalçın Dayıoğlu
,
Mustafa Hatipoğlu
Öz
Yol inşaatlarında dolgu malzemesi olarak kullanılan doğal zemin kaynaklarının giderek azalması, alternatif malzeme ihtiyacı doğurmaktadır. Bu ihtiyaç doğrultusunda büyük miktarlarda yapı malzemesi gerektiren yol inşaatı gibi yapım işlerinde, atık malzemelerin kullanılabilirliği güncel bir araştırma konusu olarak karşımıza çıkmaktadır. Bu çalışmada; geri dönüştürülmüş beton agregası (RCA), geri dönüştürülmüş asfalt agregası (RAP), elektrik ark fırın cürufu (EAF) ve pota cürufu (PF) gibi atık malzemelerin geoteknik uygulamalarda dolgu malzemesi olarak kullanılabilirliği araştırılmaktadır. Bu amaçla temin edilen atık malzemelerin; dane çapı dağılımı, özgül ağırlığı, kompaksiyon özelliklerileri, permeabilite katsayıları, kayma mukavemeti parametreleri, ıslak ve kuru CBR değerlerini belirlemek üzere deneyler yapılmıştır. Bunlara ek olarak, çelik cüruflarının şişme potansiyelleri hızlandırılmış şişme deneyleri ile belirlenmiştir.
Destekleyen Kurum
İstanbul Teknik Üniversitesi Bilimsel Araştırma Projeleri Birimi
Proje Numarası
43769 ve 42841
Teşekkür
Prof. Dr. Aykut ŞENOL'a verdiği desteklerden ötürü teşekkür ederiz.
Kaynakça
- TÇÜD, T.C. Çevre ve Şehircilik Bakanlığı. (2015) Demir Çelik Cüruf Raporu. Türkiye Çelik Üreticileri Derneği.
2015.
- Abbaspour, A., B.F. Tanyu, and B. Cetin, Impact of aging on leaching characteristics of recycled concrete
aggregate. Environmental Science and Pollution Research, 2016. 23: p. 20835-20852.
- Arulrajah, A., et al., Geotechnical properties of recycled concrete aggregate in pavement sub-base
applications. Geotechnical Testing Journal, 2012. 35(5): p. 743-751.
- Bestgen, J.O., et al., Mechanical and environmental suitability of recycled concrete aggregate as a highway
base material. Journal of Materials in Civil Engineering, 2016. 28(9): p. 04016067.
- Cetin, B., A.H. Aydilek, and Y. Guney, Stabilization of recycled base materials with high carbon fly ash.
Resources, Conservation and Recycling, 2010. 54(11): p. 878-892.
- Cooley, L.A., H. Hornsby, and B.C. Dennis, Evaluation of crushed concrete base strength. 2012, Mississippi.
Dept. of Transportation.
- Dayioglu, A.Y. and A.H. Aydilek, Effect of pH and subgrade type on trace-metal leaching from steel-slag
embankments into groundwater. Journal of Materials in Civil Engineering, 2019. 31(8): p. 04019149.
- Engelsen, C.J., H.A. van der Sloot, and G. Petkovic, Long-term leaching from recycled concrete aggregates
applied as sub-base material in road construction. Science of the Total Environment, 2017. 587: p. 94-101.
- Haider, I., et al. Evaluation of the mechanical performance of recycled concrete aggregates used in highway
base layers. in Geo-Congress 2014: Geo-characterization and Modeling for Sustainability. 2014.
- Jahren, C.T. and D. Chen. Long-term performance of cold in-place recycled asphalt roads. in Proceedings of
the 2005 Mid-Continent Transportation Research Symposium Ames, Iowa. 2005.
- Li, L., et al., Sustainable construction case history: Fly ash stabilization of recycled asphalt pavement material.
Geotechnical and Geological Engineering, 2008. 26: p. 177-187.
- Augiseau, V., Construction materials flows and stocks in Paris region: An overview. Ecocycles, 2020. 6(1): p.
18-22.
- Uysal, F.F. and S. Bahar, Cüruf Çeşitleri ve Kullanim Alanlari. Trakya Üniversitesi Mühendislik Bilimleri
Dergisi, 2018. 19(1): p. 37-52.
- Yi, H., et al., An overview of utilization of steel slag. Procedia Environmental Sciences, 2012. 16: p. 791-801.
- Yildirim, I.Z. and M. Prezzi, Chemical, mineralogical, and morphological properties of steel slag. Advances in
Civil Engineering, 2011. 2011.
- Association, W.S., World steel in figures. World Steel Association: Brussels, Belgium, 2022.
- Dayioglu, A.Y., et al., Trace metal leaching from steel slag used in structural fills. Journal of Geotechnical and
Geoenvironmental Engineering, 2018. 144(12): p. 04018089.
- Dayioglu, A.Y., A.H. Aydilek, and B. Cetin, Preventing swelling and decreasing alkalinity of steel slags used in
highway infrastructures. Transportation Research Record, 2014. 2401(1): p. 52-57.
- Mina, E., R. Kusuma, and N. Ulfah. Utilization of steel slag and fly ash in soil stabilization and their effect to
california bearing ratio (CBR) value.(Case study: Kp. Kadusentar road Medong village Mekarjaya Subdistrict
Pandeglang District). in IOP Conference Series: Materials Science and Engineering. 2019. IOP Publishing.
- Shi, C., Steel slag—its production, processing, characteristics, and cementitious properties. Journal of
materials in civil engineering, 2004. 16(3): p. 230-236.
- Wang, S., et al., Experimental Research on Steel slag Stabilized Soil and its Application in Subgrade
Engineering. Geotechnical and Geological Engineering, 2020. 38(5): p. 4603-4615.
- Yildirim, I.Z. and M. Prezzi, Subgrade stabilisation mixtures with EAF steel slag: an experimental study
followed by field implementation. International Journal of Pavement Engineering, 2022. 23(6): p. 1754-1767.
Geri Dönüştürülebilir Atık Malzemelerin Geoteknik Özelliklerinin Karşılaştırılmalı Olarak İncelenmesi
11
- Senol, A. and B. Erol. 2D Numerical Settlement Analysis of A Slag Aggregated Test Road on Weak Soils. in
Material Design, Construction, Maintenance, and Testing of Pavements: Selected Papers from the 2009
GeoHunan International Conference. 2009.
- Dayioglu, A.Y. and A.H. Aydilek, Evaluation of mitigation techniques for the expansive behavior of steel slag,
in Geotechnical Frontiers 2017. 2017. p. 360-368.
- Şeref, O., B. YILMAZ, and M.S. Mazlum, Geri kazanılan asfalt kaplamaların sıcak asfalt karışımlarda yeniden
kullanabilirliğinin araştırılması. Fırat Üniversitesi Mühendislik Bilimleri Dergisi, 2018. 30(1): p. 87-93.
- Hung, V.Q., et al., Investigating Potential Environmental Issues of using Recycled Materials in Road
Construction.
- Cabrera, M.B., T. Satomi, and H. Takahashi, Study on recycling of waste asphalt blocks containing roadbed
materials using new screenless separation equipment with a vibration device. International Journal of
Pavement Research and Technology, 2017. 10(3): p. 228-244.
- Akbaş M., D.A.Y., Hatipoğlu M., İyisan R., Geri Dönüştürülmüş Beton Agregaların Geoteknik Mühendisliğinde
Kullanımı, in Conference Paper September. 2018.
- Zhang, Y., D. Goulias, and A. Aydilek, Sustainability evaluation of pavements using recycled materials, in
Bearing Capacity of Roads, Railways and Airfields. 2017, CRC Press. p. 1283-1291.
- ASTM-D422-63, D422–63. Standard Test Method for Particle-Size Analysis of Soils, ASTM International, West
Conshohocken, PA: 2007. 2007.
- KTŞ, T.C. Karayolları Genel Müdürlüğü. (2013) Karayolları Teknik Şartnamesi 2013.
- ASTM D854-14, Standard Test Methods for Specific Gravity of Soil Solids by Water Pyncometer. 2014: ASTM
International, West Conshohocken, PA: 2014. In.
- Deniz, D., E. Tutumluer, and J.S. Popovics, Expansive characteristics of reclaimed asphalt pavement (RAP)
used as base materials. 2009, Illinois. Dept. of Transportation. Bureau of Materials and Physical Research.
- ASTM-D698, Standard practice for laboratory compaction characteristics of soil using standard effort (12 400
ft-lbf/ft3 (600 kN-m/m3)). Book of Standards 04.08, 2003.
- Rohde, L., W. Peres Núñez, and J. Augusto Pereira Ceratti, Electric arc furnace steel slag: base material for lowvolume roads. Transportation research record, 2003. 1819(1): p. 201-207.
- Yildirim, I.Z. and M. Prezzi, Use of steel slag in subgrade applications. 2009.
- Noureldin, A.S. and R.S. McDaniel, Evaluation of surface mixtures of steel slag and asphalt. Transportation
Research Record, 1990(1269).
- ASTM D2434–68, Standard Test Method for Permeability of Granular Soils (Constant Head): ASTM D2434–
2006, ASTM International West Conchohocken, PA.
- McCulloch, T., et al., Long-term performance of recycled concrete aggregate for subsurface drainage. Journal
of Performance of Constructed Facilities, 2017. 31(4): p. 04017015.
- ASTM D4318-17, Standard Test Methods for Liquid Limit, Plastic Limit, and Plasticity Index of Soils. 2017:
West Conshohocken, PA; ASTM International.
- ASTM D1883-21, Standard test method for California bearing ratio (CBR) of laboratory-compacted soils, in
ASTM International. 2021.
- Cikmit, A.A., et al., Expansion characteristic of steel slag mixed with soft clay. Construction and Building
Materials, 2019. 227: p. 116799.
- Dayioglu, A.Y., Geotechnical and environmental impacts of steel slag in highway embankments. 2016,
University of Maryland, College Park.
- Feng, P., et al., Steel slag aggregate concrete filled-in FRP tubes: Volume expansion effect and axial
compressive behaviour. Construction and Building Materials, 2022. 318: p. 125961.
- Ramonich, E.V. and M. Barra, Reactivity and expansion of electric arc furnace slag in their application in
construction. Materiales de Construcción, 2001. 51(263-264): p. 137-148.
- Montenegro-Cooper, J., et al., Study of the expansive behavior of ladle furnace slag and its mixture with low
quality natural soils. Construction and Building Materials, 2019. 203: p. 201-209.
- ASTM D4792-13, Standard test method for potential expansion of aggregates from hydration reactions. 2019.
Geri Dönüştürülebilir Atık Malzemelerin Geoteknik Özelliklerinin Karşılaştırılmalı Olarak İncelenmesi
12
- ASTM D1883-07, Standard test method for CBR (California bearing ratio) of laboratory compacted soils.
ASTM International, West Conshohocken, PA.
- Yzenas, J. Utilization of Steel Furnace Slag in Asphalt. in Presentation in ADC60 Waste Management and
Resource Efficiency in Transportation Summer Conference, July. 2008.
- Juckes, L.M., The volume stability of modern steelmaking slags. Mineral Processing and Extractive Metallurgy,
2003. 112(3): p. 177-197.
- Verhasselt, A. and F. Choquet, Steel slags as unbound aggregate in road construction: problems and
recommendations, in Unbound Aggregates in Roads. 1989, Elsevier. p. 204-211.
- Ghionna, V., et al. Geotechnical investigation on steel slags mixtures for landfills embankments construction.
in Environmental geotechnics. 1996.