مطالعات آزمایشگاهی کارایی، رفتار مکانیکی و خصوصیات دوامی ملات سیمانی مسلح شده به الیاف بازالت و پلی‌پروپیلن

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
مهرداد رزاقیان قادیکلائی 1
مهدی میرزایی 2
اصغر حبیب‌نژاد کورایم 1
1 دانشگاه علم و صنعت ایران
2 دانشگاه تربیت مدرس
چکیده
در این تحقیق تأثیر هم‌زمان درصد‌های مختلف الیاف بازالت و پلی‌پروپیلن بر کارایی، رفتار مکانیکی و خصوصیات دوامی ملات سیمانی مورد تحلیل و بررسی قرارگرفته است. به‌منظور ارزیابی تأثیر الیاف‌ها با ثابت در نظر گرفتن سایر پارامتر‌های مؤثر بر خصوصیات ملات سیمانی (مانند نسبت آب به سیمان و نسبت ماسه به سیمان) از نمونه‌های حاوی ترکیب هیبریدی 0.05 و 0.125 درصد (درصد وزنی مجموع سیمان و سنگدانه) از دو الیاف ذکرشده بهره گرفته‌شده است، به طوریکه درمجموع 4 نوع طرح مخلوط حاوی هیبرید الیاف‌های بازالت و پلی‌پروپیلن ساخته‌شده و نتایج آن با نمونه شاهد مورد مقایسه قرارگرفته است. نتایج حاکی از آن است که استفاده هم‌زمان این دو الیاف تأثیر قابل‌ملاحظه‌ای بر مقاومت فشاری ملات سیمانی نداشته است؛ این در حالی است که نتایج، عملکرد مطلوب و قابل‌توجه الیاف‌های مذکور در افزایش مقاومت خمشی و کششی را نشان دادند. همچنین مشاهده گردید که خصوصیات دوامی شامل نرخ جذب آب، جذب آب حجمی و مقاومت ویژه الکتریکی ملات سیمانی اصلاح‌شده با ترکیب هیبریدی این دو الیاف نسبت به نمونه شاهد بهبودیافته است. افزودن هیبریدی 0.125 درصد (درصد وزنی مجموع سیمان و سنگدانه) الیاف بازالت و پلی‌پروپیلن موجب افزایش به ترتیب 28 و 23 درصدی مقاومت خمشی و کششی نمونه شاهد گردید. همچنین نمونه حاوی هیبرید 0.125 درصد (درصد وزنی مجموع سیمان و سنگدانه) الیاف بازالت و 0.05 درصد الیاف پلی‌پروپیلن موجب افزایش 9.3 درصدی مقاومت فشاری، کاهش 24 درصدی نرخ جذب آب، کاهش 15 درصدی جذب آب حجمی و بهبود 22 درصدی مقاومت ویژه الکتریکی گردید. مطابق نتایج بدست آمده از این تحقیق می‌توان دریافت که حضور هم‌زمان الیاف‌های بازالت و پلی‌پروپیلن موجب بهبود بخش عمده‌ خصوصیات ملات سیمانی شامل خصوصیات مکانیکی و دوامی می‌شود، این درحالی است که در صورت استفاده مجزا از هریک از این الیاف‌ها دستیابی به چنین نتیجه مطلوبی دور از انتظار است، چراکه هر یک از الیاف‌های بازالت و پلی‌پروپیلن با توجه به خصوصیات فیزیکی و شیمیایی توانایی بهبود قابل‌توجه بخشی از خصوصیات ملات سیمانی را دارند.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Experimental studies of workability, mechanical behavior and durability properties of basalt-polypropylene fibers-reinforced cementitious mortar

نویسندگان English

Mehrdad Razzaghian Ghadikolaee 1
Mehdi Mirzaei 2
Asghar Habibnejad Korayem 1
1 Iran University of Science and Technology
2 Tarbiat Modares University
چکیده English

Conventional construction cementitious composites typically contains cement, fine and gravel aggregate and additive in a specific ratio along with water. It is extensively used to bind the structural elements together like the bricks, stones, and concrete blocks, or end connection of the column and beam, and to develop a sufficient bond with the substrate as a repair cementitious composite, due to its several advantages, such as low cost, appropriate compressive strength, and easy access. However, some weaknesses of the cementitious mortar influence its performance under different conditions. For example, low tensile strength, brittle behavior, unacceptable performance against shrinkage cracks, and lack of resistance against stress concentration are some of these critical properties of the mortar, if not modified, the structures will be deteriorated in a short time. These deficiencies emerge from extravagance water, bleeding, plastic settlement, shrinkage stress and strain concentrations due to external limitations. When loads are applied and further increased, type of cracks grow and reach a critical condition, and catastrophic failure is precipitated. In this situation, the mortar will be exposed to severe damaging factors such as premature saturation, disadvantage of freeze-thaw, scaling, and corrosion of steel. In recent years, researchers in the field of concrete technology have focused on the using of a variety of fibers such as carbon, steel, glass, polypropylene and basalt fiber into the cementitious composites to improve their mechanical properties (especially their ductility behavior) and to some extent their durability. Accordingly, in the present study, the hybrid effect of different percentages of basalt and polypropylene fibers on the workability, mechanical behavior and durability properties of cementitious mortar was investigated. Polypropylene fibers are known in the field of reinforced concrete, but basalt fibers are a new potential additive in this field. In recent decades, researchers have studied more about basalt fibers because of their potential reinforcement properties in composite materials. The basalt fibers are an appropriate replacement for another fibers, including glass, steel, and carbon fibers in plenty of applications due to their excellent properties such as high mechanical properties specially tensile strength and flexural strength, good resistance to low and high temperature, low cost, durability, vibration resistance, high elasticity modules, great failure strain, acceptable persistence to chemical assault, impact load and fire with less toxic materials. Samples containing a hybrid composition of 0.05 and 0.125 percent (weight percent of total cement and aggregate) of the basalt and polypropylene fibers have been used in order to evaluate the effect of fibers so that a total of 4 types of mixed designs containing hybrids of basalt and polypropylene fibers were made and its results have been compared with a control sample. As expected, after analyzing the results, the fibers had no significant effect on the compressive strength of the cementitious composite, while the results of this study reported a favorable and remarkable performance of these fibers in increasing flexural and splitting tensile strength, as well as the water absorption of cementitious mortar is favorably decreased by the fiber. The sample containing 0.125% basalt and polypropylene fibers increased flexural and splitting tensile strengths by 28 and 23%, respectively. Also, the sample containing 0.125% basalt fiber and 0.05% polypropylene fibers resulted in 9.3% increase in compressive strength, 24% decrease in sorptivity and 15% water absorption. The results of the current study have shown that the simultaneous use of basalt and polypropylene fibers can improve significantly the mechanical behavior and durability properties of cementitious mortar, whereas according to the previous studies if each of these fibers is used separately, such a desirable result will not be obtained.

کلیدواژه‌ها English

Cementitious mortar
basalt fiber
Polypropylene fiber
Mechanical properties
durability
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مهندسی عمران مدرس
دوره 21، شماره 1
فروردین و اردیبهشت 1400
صفحه 87-102