Plenty of research works in India and abroad focusing on the reuse or recycling of waste materials from many industries. Among that finding out suitable cementitious material for the replacement of cement is significant. Many waste materials such as fly ash, silica fume, GGBS, metakaoline, micro materials, quartz power, etc. are tried out for replacing partially or full of cement in concrete. A new ultrafine material called Alccofine is tried out for replacing partially in this research. M20 and M60 grade of concrete is intended to study the performance of normal and high strength concrete by replacing the cement with alccofine of different dosages.  Previous researches showed that the replacement of alccofine increases the strength. Design mix made for M20 and M60 grade and cubes casted with various percentage of alccofine with cement. Hence the study is aimed to assess the bond behavior of M20 and M60 grade of concrete structures as an alternate to the conventional materials. The cubes are prepared initially for the design mix and determined the strength of concrete. Then specimens are prepared for the bond test and tested using pullout test methods. The results are analyzed and observed that the bond strength is increased with increase of alccofine replacement to certain dosage.

Riaz Ahmad Goraya, Kamal Ahmed, and Muhammad Akram Tahir. “Effect of Surface Texture on Bond Strength of GFRP Rebar in Concrete.” Mehran University Research Journal of Engineering & Technology 30(1) (January 2011):45-52.

Marco Valente. “Bond Strength between Corroded Steel Rebar and Concrete”. IACSIT International Journal of Engineering and Technology 4(5) (October 2012): 65-73.

Barnaf, J., M. Bajer, and M. Vyhnankova. “Bond Strength of Chemical Anchor in High-Strength Concrete.” Procedia Engineering 40 (2012): 38–43. doi:10.1016/j.proeng.2012.07.052.

Maria Teresa, Gomes Barbosa, & Souza Sánchez Filho. “Investigation of Bond Stress in Pull out Specimens with High Strength Concrete”. Global Journal of Researches in Engineering Civil and Structural Engineering 13(3) (2013): 55-64.

Tayeh, Bassam A., B.H. Abu Bakar, M.A. Megat Johari, and Yen Lei Voo. “Evaluation of Bond Strength between Normal Concrete Substrate and Ultra High Performance Fiber Concrete as a Repair Material.” Procedia Engineering 54 (2013): 554–563. doi:10.1016/j.proeng.2013.03.050.

Ismaeel H.Musa Albarwary. “Bond Strength of Concrete with the Reinforcement Bars Polluted with Oil”. European Scientific Journal 9 (February 2013): 255-272.

Sawant, R.M.,Jabeen Khan, Minal Aher, Akash Bundele. “Compressive Study of High Strength Fiber Reinforced Concrete under Pull out Strngth”. International Journal of Civil Engineering and Technology (IJCIET) 6(1) (January 2015): 14-22.

Nithya, B., Srinivasan, P., Suji, M., Lokesh kumar, P. “A Comparative Study on Bond Strength of Reinforcing Steel in Bottom Ash Concrete and Controlled Concrete”. International Journal of Innovative Research in Science, Engineering and Technology 4(6) (May 2015): 1770-1776.

Yoon-Si Lee, Brent Phares. “Bond Strength and Development Length of Galvanized Reinforcing Steel”. International Journal of Civil and Structural Engineering Research 3(1) (April 2015): 311-317.

Lin, Hongwei, and Yuxi Zhao. “Effects of Confinements on the Bond Strength between Concrete and Corroded Steel Bars.” Construction and Building Materials 118 (August 2016): 127–138. doi:10.1016/j.conbuildmat.2016.05.040.

Zhang, Xue, Zhimin Wu, Jianjun Zheng, Wei Dong, and Abdelhamid Bouchair. “Ultimate Bond Strength of Plain Round Bars Embedded in Concrete Subjected to Uniform Lateral Tension.” Construction and Building Materials 117 (August 2016): 163-170. doi:10.1016/j.conbuildmat.2016.05.029.

Shen, Dejian, Xiang Shi, Hui Zhang, Xiaofang Duan, and Guoqing Jiang. “Experimental Study of Early-Age Bond Behavior Between High Strength Concrete and Steel Bars Using a Pull-Out Test.” Construction and Building Materials 113 (June 2016): 653-663. doi:10.1016/j.conbuildmat.2016.03.094.

Bilek, Vlastimil, Sabina Bonczková, Jan Hurta, David Pytlík, and Martin Mrovec. “Bond Strength between Reinforcing Steel and Different Types of Concrete.” Procedia Engineering 190 (2017): 243–247. doi:10.1016/j.proeng.2017.05.333.

Mohammad Jamal Al-Shannag and Abdelhamid Charif. “Bond behavior of steel bars embedded in concretes made with natural lightweight aggregates”. Journal of King Saud University - Engineering Sciences 29(4) (October 2017):365-372. doi: org/10.1016/j.jksues.2017.05.002

Faye, Papa Niane, Yinghua Ye, and Bo Diao. “Bond Effects Between Concrete and Steel Bar Using Different Diameter Bars and Different Initial Crack Width.” Advances in Civil Engineering 2017 (2017): 1–11. doi:10.1155/2017/8205081.

Li, C. Q. and Melchers, R. E. “Time-dependent risk assessment of structural deterioration caused by reinforcement corrosion,” ACI Structural Journal 102 (5) (2005): 754–762. doi:10.14359/14671.

Yan, Fei, Zhibin Lin, and Mijia Yang. “Bond Mechanism and Bond Strength of GFRP Bars to Concrete: A Review.” Composites Part B: Engineering 98 (August 2016): 56–69. doi:10.1016/j.compositesb.2016.04.068.

IS2386 (Part VI). “Measuring Mortar Making Properties of Fine Aggregate”. Bureau of Indian Standards, New Delhi, India (1963).

IS 10262. “Concrete mix proportioning - Guide Lines”. Bureau of Indian Standards, New Delhi, India (2009).

IS 432 - I. “Mild Steel and Medium Tensile Steel Bars”. Bureau of Indian Standards, New Delhi, India (1982).

IS 226. “Structural Steel Hand Book”. Bureau of Indian Standards, New Delhi, India (1992).

IS 11309. “Conducting Pull-Out Test on Anchor Bars and Rock Bolts”. Bureau of Indian Standards, New Delhi, India (1985).