پوزولان ضایعاتی خاکسترمیوه درخت بنه در بتن

نوع مقاله : پژوهشی اصیل (کامل)

نویسنده
شهریار شهبازپناهی
دانشکده فنی مهندسی،گروه مهندسی عمران، دانشگاه آزاد اسلامی واحد سنندج
چکیده
درخت "بَنِه" یا " ون" درختی خودرو است که در بعضی از مناطق سردسیرمانند کردستان ایران می روید. نام دیگر آن پسته کوهی است، میوه آن کاربرد زیادی ندارد و جز مواد اضافی کشاورزی می باشد. این مقاله برای اولین بار، پوزولان خاکسترمیوه درخت بنه را برای جایگزینی درصدی از سیمان در بتن معرفی می‌کند. در این تحقیق، ترکیب مواد معدنی خاکسترمیوه درخت بنه توسط آزمایش تشعشع‌ انکسار ایکس و تصاویر ساختارمیکرسکوپی با دستگاه میکروسکوپ الکترونی جهت ارزیاب بعنوان پوزولان بررسی می شود. در این مطالعه ویژگی های بتن بر روی مخلوط های بتن ساخته شده با درصدهای متفاوتی خاکسترمیوه درخت بنه (5, 10، 15و 20 درصدسیمان) با جایگزینی در سیمان و مقایسه نتایج آنها با بتن کنترل (بدون خاکستر) بررسی می شود. اسلامپ بتن تازه، ضریب الاستیسیته، مقاومت فشاری، سرعت پالس اولتراسونیک و تصاویر ساختارمیکرسکوپی با دستگاه میکروسکوپ الکترونی با بتن کنترل (بدون پوزولان) مقایسه شده است. نتایج نشان می دهد که بتن پوزولانی خاکسترمیوه درخت بنه مدول ارتجاعی بزرگتری نسبت به نمونه بتن کنترل دارد. همچنین، با استفاده از 20 درصد خاکسترمیوه درخت بنه، افزایش 18.3 درصدی مقاومت فشاری در سن 28 روزه نسبت به نمونه بتن کنترل مشاهده شده است. تصاویر ساختارمیکرسکوپی با دستگاه میکروسکوپ الکترونیکی نشان می دهد که پوزولان خاکسترمیوه درخت بنه، تخلخل و ترکهای کوچک را کاهش داده و موجب شکل گیری کلسیم سیلیکات هیدرات بیشتری شده است.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Mechanical and microstructural properties of Pistacia Atlantica Ash concrete

نویسنده English

shahriar shahbazpanahi
Department of Civil Engineering,Sanandaj Branch, Islamic Azad University
چکیده English

Concrete is the most used building material in the world. Many studies have targeted concrete due to its numerous benefits over other building materials. Being a moldable and rather cheap building material, it has provided good motives for engineers to further investigate the mechanical and microstructural properties of concrete with the incorporation of different kinds of additives. To do so, waste materials admixtures were suggested into the matrix to lessen the amount of cement through cement replacement as Pozzolanic mineral admixtures. These admixtures are used in concrete to enhance the mechanical properties. Waste materials not only reduces the cement content but enhances the qualities of concrete such as mechanical and the microstructural properties. However, only limited amounts of replacement were suggested. In this research, a new waste material is introduced to use in concrete as a pozzolanic material. In this paper, for the first time, Pistacia Atlantica Ash is used into the matrix of concrete to reduce the amount of cement and then, the effects of Pistacia Atlantica Ash on the concrete are investigated. Pistacia atlantica is a species of wild pistachio tree. In Iran, it is called Baneh or Van.

Fruit of Pistacia Atlantica is collected from the Saghez city located in north Kurdistan, Iran. The fruit of Pistacia Atlantica is first burned at 500 ºC for 3 hours. Then, Pistacia Atlantica Ash is sieved. Cement is replaced Pistacia Atlantica Ash. To do so, 5, 10, 15 and 20% Pistacia Atlantica Ash is admixed in the concrete samples. The Water to cement (W/c) ratio are kept constant at 0.45 for the entire mixes. Amount of aggregates are kept constant for all series of mixes. All of the samples are cured in water.

Four design mixes of Pistacia Atlantica Ash separately are casted for compression tests, slump, modulus of elasticity, ultrasonic pulse velocity (UPV), and microstructural properties. The compressive strength of samples at ages of 7, 14, 28, and 90 days are recorded. Cement replacement with Pistacia Atlantica Ash decreased the early age compressive strength. However, the compressive strength in the specimens increased in the course of time. The target compressive strength of control samples is set to be 39MPa at 28 days. Compressive strength of samples with 20% Pistacia Atlantica Ash is improved up to 18.3% at 28 days.

One of the major findings is that concrete that incorporates twenty percent of Pistacia Atlantica Ash weight of cement showed better mechanical properties. Concrete slump in the specimens are considerable decreased comparing to the control samples. The replacement of Pistacia Atlantica Ash with cement increased the elastic modulus. Also, scanning electron microscopy (SEM) results showed that admixing Pistacia Atlantica Ash led to improvement in the microstructure, and pozzolanic behavior of mixtures. The results from microstructural analysis are conclusive that C-S-H formation increased when of Pistacia Atlantica Ash is added to the samples. In general, the results are conclusive that the addition of 20% Pistacia Atlantica Ash enhances the properties of concrete such as compressive strength modulus of elasticity and density of microstructure.

کلیدواژه‌ها English

Pozzolan
concrete
Pistacia Atlantica Ash
1 Vays D, Vays MC, Pitroda J. Utilization of barley husk ash in clay bricks in aspect of indian context: A literature review. International Journal of Civil, Structural,Environmental and Infrastructure Engineering. 2014;4(1):61-68.
2 Luukkonen T, Abdollahnejad , Yliniemi J, Kinnunen P, Illikainen M. One-part alkali-activated materials: A review. Cement and Concrete Research. 2018;103:21-34.
3 Farzadnia N, Bahmani SH, Asadi A, Hosseini S. Mechanical and microstructural properties of cement pastes with rice husk ash coated with carbon nanofibers using a natural polymer binder. Construction and Building Materials. 2018;175:691-704.
4 Ahsan MB, Hossain Z. Supplemental use of rice husk ash (RHA) as a cementitious material in concrete industry. Construction and Building Materials. 2018;178:1-9.
5 Karim MR, Zain MFM, Jamil M, La FC. Fabrication of a non using slag, palm oil fuel ash and rice husk ash with sodium hydroxide. Construction and Building Materials. 2013;49:894-902.
6 Hadi MNS, Yu T, Al-Azzawi M. Effects of fly ash characteristics and alkaline activator components on compressive strength of fly ash-based geopolymer mortar. Construction and Building Materials. 2018;175:41-54.
7 Zhang MH, Islam J. Use of nano-silica to reduce setting time and increase early strength of concretes with high volumes of fly ash or slag. Construction and Building Materials. 2012;29 :573–580.
8 Huang Y, He X, Wang Q, Sun Y. Mechanical properties of sea sand recycled aggregate concrete under axial compression. Construction and Building Materials. 2018;175:55-63.
9 Khare A, Tiw A. Investigation of strength of concrete containing locally available industrial and agriculture waste. International Journal of Science and Research. 2015;4(5):2319-7064.
10 Isaia GC, Gastaldini ALG, Moraes R. Physical and pozzolanic action of mineral additions on the mechanical strength of high-performance concrete. Cement and Concrete Composits. 2003;25:69-76.
11 Zhang S, Keulen A, Arbi K, Ye G. Waste glass as partial mineral precursor in alkali-activated slag/fly ash system. Cement and Concrete Research. 2017;102:29-40.
12 Moffatt EG, Thomas MDA, Fahim A. Performance of high-volume fly ash concrete in marine environment. Cement and Concrete Research. 2017;102:127-135.
13 Branchn JL, Epps R, Kosso DS. The impact of carbonation on bulk and ITZ porosity in microconcrete materials with fly ash replacement. Cement and Concrete Research. 2018;103:170-178.
14 Yu J, Mishra DK, Wu C. Very high volume fly ash green concrete for applications in India. Waste Management and Research. 2018;36(6):520-526.
15 Chakraborty A, Goswam A. i Conservation of environment by using fly ash and rice husk ash as a partial cement replacement in concrete. Journal of Energy Research and Environmental Technology. 2015;2(1):9-11.
16 Jung SH, Saraswathy V, S. Karthick , Kathi P, Kwon SJ. Microstructure characteristics of fly ash concrete with rice husk ash and lime stone powder. International Journal of Concrete Structures and Materials. 2018;In Pres:12-17.
17 Mehta PK. Advancements in concrete technology. Concrete International Detroit. 1999;21:69-76.
18 Vishwakarma V, Ramachandran D. Green Concrete mix using solid waste and nanoparticles as alternatives – A review. Construction and Building Materials. 2018;162(20):96-103.
19 Prasada Rao DV, Navaneethamma V. Influence of nano-silica on strength properties of concrete containing rice husk ash. International Journal of Advanced Research. 2016;3(1):39-43.
20 Salih MA, Ali AAA, Farzadnia N. Characterization of mechanical and microstructural properties of palm oil fuel ash geopolymer cement paste. Construction and Building Materials. 2014;65:592-603.
21 Li N, Farzadnia N, Shi C. Microstructural changes in alkali-activated slag mortars induced by accelerated carbonation. Cement and Concrete Research. 2017;100:214-226.
22 Xu B, Lothenbach B, Ma H. Properties of fly ash blended magnesium potassium phosphate mortars: Effect of the ratio between fly ash and magnesia. Cement and Concrete Composites. 2018;90:169-177.
23 Yang T, Zhu H, Zhang Z, Gao X, Zhang C, Wu Q. Effect of fly ash microsphere on the rheology and microstructure of alkali-activated fly ash/slag pastes. Cement and Concrete Research. 2018;109:198-207.
24 Hlaváček P, Šulc R, Šmilauer V, Rößler C, Snop R. Ternary binder made of CFBC fly ash, conventional fly ash, and calcium hydroxide: Phase and strength evolution. Cement and Concrete Composites. 2018;90:100-107.
25 Ibrahim , Johari MAM, Rahman MK, Maslehuddin M. Effect of alkaline activators and binder content on the properties of natural pozzolan-based alkali activated concrete. Construction and Building Materials. 2017;147:648-660.
26 Kawashima , Hou P, Wang K, Corr DJ, Shah SP. Activation of fly ash through nanomodification. In: Advances in Green Binder Systems ; 2013; TX. p. 1-11.
27 Heah CY, Kamarudin H, Mustafa Al Bakri Am, Bnhussain M, Luqman M, Khairul Nizar I, Ruzaidi CM, Liew YM. Study on solids-to-liquid and alkaline activator ratios on kaolin-based geopolymers. Construction and Building Materials. 2012;35:912-922.
مهندسی عمران مدرس
دوره 19، شماره 2
خرداد و تیر 1398
صفحه 113-124