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Effect of Waste Fines and Fibers on the Strength and Durability Performance of Silica Fume Based Reactive Powder Concrete

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The demand and consumption of conventional concrete materials is increasing day by day, which in turn leads to the extinction of natural resources. Certain researchers tend to draw a circle to solve this global problem by finding alternative materials satisfying all aspects, mainly efficiency, eco-friendly and economical. The present research work aimed to study the combined use of coal bottom ash (CBA) and waste concrete powder (WCP) in silica fume based reactive powder concrete (SF-RPC) subjected to thermal curing. The replacement of cement by silica fume was limited to 20% and the fine aggregate quartz sand replaced by CBA and WCP varied from 5% to 25% each. The material composition of SF-RPC involves the exclusion of coarse aggregates and the inclusion of finer materials with micro-steel fibers. The steel fibers played a significant role in order to obtain a ductile and stable product of SF-RPC. The experimental investigation on SF-RPC comprised of the determination of fresh concrete properties such as slump flow and the compaction factor, as well as mechanical properties like compressive strength, flexural strength and split-tensile strength. The study was also extended to investigate durability properties such as water absorption, sorptivity and resistance to acid attack. The results showed that silica fume proves to be a feasible alternative to partially replace cement and also that optimum incorporation of pre-treated and processed CBA and WCP attains better mechanical and durability performance without compromising the necessary qualities.
Rocznik
Strony
43--49
Opis fizyczny
Bibliogr. 32 poz., rys., tab.
Twórcy
autor
  • EGS Pillay Engineering College, Department of Civil Engineering, Nagappattinam, Tamil Nadu, India
  • EGS Pillay Engineering College, Department of Civil Engineering, Nagappattinam, Tamil Nadu, India
Bibliografia
  • 1. Kannan Rajkumar PR Durga Prasad Mathangi, Sudha C, Neelamegam M. Experimental investigation of Reactive Powder Concrete exposed to elevated temperatures. Construction and Building Materials 2020; 261, 119593.
  • 2. Peng Yanzhou, Zhang Jun, Liu Jiuyan, Ke Jin, Wang Fazhou. Properties and Microstructure of Reactive Powder Concrete Having a High Content of Phosphorous Slag Powder and Silica Fume. Construction and Building Materials 2015; 101, 482-487.
  • 3. Vigneshwari M, Arunachalam K, Angayarkanni A. Replacement of silica fume with thermally treated rice husk ash in Reactive Powder Concrete. Journal of Cleaner Production 2018; 188: 264-277.
  • 4. Ankur Mehta, Deepankar Kumar Ashish. Silica Fume and Waste Glass in Cement Concrete Production: A Review. Journal of Building Engineering 2020; 29: 100888.
  • 5. Ola A. Mayhoub, El-Sayed A.R. Nasr, Yehia A.Ali, Mohamed Kohail. The Influence of Ingredients on the Properties of Reactive Powder Concrete: A Review. Ain Shams Engineering Journal, 2020.
  • 6. Yin-Wen Chan, Shu-Hsien Chu. Effect of Silica Fume on Steel Fiber Bond Characteristics In Reactive Powder Concrete. Cement and Concrete Research 2004; 34: 1167-1172.
  • 7. Mahmudul Hasan Mizan, Tmon Ueda, Koji Matsumoto. Enhancement of the Concrete-PCM Interfacial Bonding Strength using Silica Fume. Construction and Building Materials 2020; 259: 119774.
  • 8. Navdeep Singh, Mithulraj M, Shubham Arya. Influence of Coal Bottom Ash as Fine Aggregates Replacement on Various Properties of Concretes: A Review. Resources, Conservation & Recycling 2018; 138: 257-271.
  • 9. Navdeep Singh, Shehnazdeep, Anjani Bhardwaj. Reviewing the Role of Coal Bottom Ash as an Alternative of Cement. Construction and Building Materials 2020; 233: 117276.
  • 10. Mahdi Rafieizonooz, Jahangir Mirza, Mohd Razman Salim, Mohd Warid Hussin, Elnaz Khankhaje. Investigation of Coal Bottom Ash and Fly Ash in Concrete as Replacement for Sand and Cement. Construction and Building Materials 2016; 116: 15-24.
  • 11. Balapour M, Zhao Weijin, Garboczi EJ, Ye Oo Nay, Spatari S, Hsuan G, Billen P, Farnam Yaghoob. Potential use of Lightweight Aggregate (LWA) Produced from Bottom Coal Ash for Internal Curing of Concrete Systems. Cement and Concrete Composites 2020; 105, 103428.
  • 12. Sukhoon Pyo, Hyeong-Ki Kim. Fresh and Hardened Properties of Ultra-High Performance Concrete Incorporating Coal Bottom Ash and Slag Powder. Construction and Building Materials 2017; 131: 459-466.
  • 13. Soheil Oruji, Nicholas A, Brake, Ramesh K. Guduru, Likhith Nalluri, Ozge Gunaydin-Sen, Krishna Kharel, Saeed Rabbanifar, Seyedsaeid Hosseini, Emily Ingram. Mitigation of ASR Expansion in Concrete Using Ultra-Fine Coal Bottom Ash. Construction and Building Materials 2019; 202: 814-824.
  • 14. Ali Akhtar, Ajit K. Sarmah. Construction and Demolition Waste Generation and Properties of Recycled Aggregate Concrete: A global perspective. Journal of Cleaner Production 2018; 186: 262-281.
  • 15. Mirian Velay-Lizancos, Isabel Martinez-Lage, Miguel Azenha, Jose Granja, Pablo Vazquez-Burgo, Concrete with Fine and Coarse Recycled Aggregates: E-modulus Evolution, Compressive Strength and Non-Destructive Testing at Early Ages. Construction and Building Materials 2018; 193: 323-331.
  • 16. Yi Jiang, Tung-Chai Ling, Minjiao Shi. Strength Enhancement of Artificial Aggregate Prepared with Waste Concrete Powder and Its Impact on Concrete Properties. Journal of Cleaner Production 2020; 257: 120515.
  • 17. Hammad Salahuddin, Liaqat Ali Qureshi, Adnan Nawaz, Syed Safdar Raza. Effect of Recycled Fine Aggregate on Performance of Reactive Powder Concrete. Construction and Building Materials 2020; 243: 118223.
  • 18. Sakthieswaran N, Renisha M. Mutual effect of coal bottom ash and Recycled fines on Reactive Powder Concrete, Revista Romana de Materiale / Romanian Journal of Materials 2020; 50(3): 395-402.
  • 19. Sharon Gooi, Ahmad A. Mousa, Daniel Kong. A Critical Review and Gap Analysis on the Use of Coal Bottom Ash as a Substitute Constituent in Concrete. Journal of Cleaner Production 2020; 268, 121752.
  • 20. IS: 1199(Part 1) – 2018. Sampling of Fresh Concrete, Fresh Concrete – Methods of Sampling, Testing and Analysis, Bureau of Indian Standards, New Delhi, India.
  • 21. ASTM C109/C109M. Standard Test Method for Compressive strength of Hydraulic Cement Mortars, ASTM Standard (2016).
  • 22. ASTM C293/C293M. Standard Test Method for Flexural strength of Concrete, ASTM Standard, 2016.
  • 23. ASTM C496/496M. Standard Test Method for Splitting Tensile Strength of cylindrical concrete specimens, ASTM Standard, 2017.
  • 24. ASTM C642. Standard Test Method for Density, Absorption and Voids in Hardened Concrete, ASTM Standard, 2013.
  • 25. ASTM C1585. Standard Test Method for Measurement of Rate of Absorption of Water by Hydraulic – Cement concretes. ASTM Standard, 2013.
  • 26. ASTM C 267. Standard Test Methods for Chemical Resistance of Mortars, Grouts, and Monolithic Surfacings and Polymer Concretes, ASTM Standard, 2018.
  • 27. IS456 (2000): Plain and Reinforced Concrete-Code of practice [CED 2: Cement and concrete], Bureau of Indian Standards, New Delhi, India.
  • 28. Zhang Yunsheng, Sun Wei, Liu Sifeng, Jiao Chujie, Lai Jianzhong. Preparation of C200 Green Reactive Powder Concrete and Its Static-Dynamic Behaviors. Cement and Concrete Composites 2008; 30: 831-838.
  • 29. Rawaa Jabbar Hussein, Nameer Abdul-Ameer Alwash, and Jinan J. Alwash. Combining Polypropylene and Steel Fiber to Reduce Spalling of Reactive Powder Concrete Subjected To Fire Flame. AIP Conference Proceedings 2020; 2213: 020111.
  • 30. Piotr Smarzewski. Comparative Fracture Properties of Four Fibre Reinforced High Performance Cementitious Composites. Materials 2020; 13: 2612.
  • 31. Zhenyu Pi, Huigang Xiao, Rui Liu, Min Liu, Hui Li. Effects of Brass Coating and Nano-Sio2 Coating on Steel Fiber–Matrix Interfacial Properties of Cement-Based Composite. Composites Part B 2020; 189: 107904.
  • 32. Doo-Yeol Yoo, Jae Young Gim, Booki Chun. Effects of Rust Layer and Corrosion Degree on the Pullout Behaviour of Steel Fibers from Ultra-High-Performance Concrete. Journal of Materials Research and Technology 2020; 9(3): 3632-3648.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f9853fe4-1597-43a2-93af-bc0a4eefae4a
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