بررسی تاثیر الیاف‌های فولادی و پلی‌پروپیلن بر ویژگی‌های مکانیکی و دوام بتن‌های توانمند

نارکی, حمید; ساجدی, سیدفتح اله; پاک نهاد, مسعود

doi:10.22065/jsce.2025.479686.3525

بررسی تاثیر الیاف‌های فولادی و پلی‌پروپیلن بر ویژگی‌های مکانیکی و دوام بتن‌های توانمند

نوع مقاله : علمی - پژوهشی

نویسندگان

حمید نارکی ¹

سیدفتح اله ساجدی ²

مسعود پاک نهاد ³

¹ دانشجوی دکترا، گروه عمران، واحد اهواز، دانشگاه آزاد اسلامی، اهواز، ایران،

² استاد، گروه عمران، واحد اهواز، دانشگاه آزاد اسلامی، اهواز، ایران،

³ استادیار، دانشکده مهندسی، مرکز آموزش عالی محلات، محلات، ایران

10.22065/jsce.2025.479686.3525

چکیده

مقاله حاضر به بررسی تاثیر ترکیب الیاف‌های مختلف بر ویژگی‌های مکانیکی و دوام بتن‌های توانمند پرداخته است. بتن‌های ساخته شده با استفاده سنگدانه‌های سیلیسی با حداکثر اندازه 9 میلی‌متر و نسبت آب به سیمان 23/0 ساخته شدند. برای بهبود خواص مکانیکی و دوام آن‌ها، الیاف‌های فولادی در دو شکل صاف و موجدار با نسبت ظاهر 5/37 به بتن‌ها اضافه شدند. جهت رفع برخی معایب بتن‌های حاوی الیاف فولادی، %1 الیاف پلی‌پروپیلن به بتن‌های ساخته افزوده شد. 34 طرح مخلوط در قالب 404 نمونه به اشکال مختلف ساخته شد. خواص مکانیکی شامل مقاومت‌های فشاری، کششی‌دونیم‌شدن در مدت 28 روزه و خواص دوام شامل مقاومت الکتریکی حجمی، جذب آب غوطه‌وری و نفوذ تسریع شده یون کلراید در مدت 180 روزه انجام شدند. نتایج نشان دادند که %3 الیاف فولادی موجدار و %1 الیاف پلی‌پروپیلن منجر به ساخت بتن با مقاومت کششی دونیم‌شدن 7/13 مگاپاسکال شد. تغییر شکل الیاف فولادی از صاف به موجدار در تغییر مقاومت فشاری نامحسوس و در مقاومت‌ کششی دونیم‌شدن تا %22 ثبت شد. الیاف پلی‌پروپیلن نشان داد در ترکیب با %1 الیاف فولادی %25 جذب آب غوطه‌وری را کاهش می‌دهد و قادر است تا جذب آب غوطه‌وری را به‌طور متوسط تا %45 در سایر بتن‌های حاوی %2 تا %4 الیاف فولادی کاهش دهد. تاثیر کاهش فضاهای متخلخل و ایجاد انسجام و یکپارچگی در بتن‌های ساخته شده در اثر ترکیب الیاف فولادی و پلی‌پروپیلن جایی ثبت شد که آزمون‌های مقاومت الکتریکی حجمی و نفوذ پذیری تسریع شده یون کلراید نشان دادند که بتن‌های ساخته شده در معرض احتمال خوردگی میلگرد نبوده و احتمال نفوذ یون کلراید در همگی آن‌ها کم و یا بسیار کم است. انسجام ریز ساختار بتن‌های الیافی در ناحیه انتقال و در ساختار ماتریس سیمانی آن‌ها در تصویر برداری‌های الکترونی نیز نتایج ذکر شده را تایید نمود.

کلیدواژه‌ها

بتن توانمند

خواص مکانیکی

الیاف فولادی

الیاف پلی‌پروپیلن

میکروسیلیس

موضوعات

نقش مصالح در افزایش دوام و مقاومت سازه ها

عنوان مقاله English

Examining the Impact of Steel and Polypropylene Fibers on the Mechanical Properties and Durability of High-Performance Concrete

نویسندگان English

Hamid Naraki ¹

Seyed Fathollah Sajedi ²

Masoud Paknahad ³

¹ PhD Candidate, Department of Civil Engineering, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran

² Professor, Department of Civil Engineering, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran

³ Assistant Professor, Faculty of Engineering, Mahallat Institute of Higher Education, Mahallat, Iran

چکیده English

This study examines the impact of various fiber combinations on the mechanical properties and durability of high-performance concrete. The concretes were made using siliceous aggregates (max size 9 mm) and a water-to-cement ratio of 0.23. Steel fibers in smooth and wavy shapes with an aspect ratio of 37.5 were added to improve mechanical properties and durability. To address the drawbacks of steel fiber-reinforced concrete, 1% polypropylene fibers were also incorporated. A total of 34 mix designs were prepared in 404 specimens of various shapes. Mechanical properties, including compressive and split tensile strengths, were measured at 28 days, while durability properties, including bulk electrical resistivity, water absorption, and accelerated chloride ion penetration, were evaluated over 180 days. Results showed that 3% wavy steel fibers and 1% polypropylene fibers yielded concrete with a split tensile strength of 13.7 MPa. Changing the steel fibers from smooth to wavy had minimal impact on compressive strength but increased split tensile strength by up to 22%. Polypropylene fibers, when combined with 1% steel fibers, reduced water absorption by 25% and reduced absorption by up to 45% in concretes with 2% to 4% steel fibers. The combination of steel and polypropylene fibers reduced porous spaces and improved cohesion and integrity, as demonstrated by the low chloride ion penetration and high electrical resistivity, indicating low corrosion risk. These findings were confirmed by microstructural analysis, showing enhanced cohesion in the transition zone and cement matrix.

کلیدواژه‌ها English

High-Performance Concrete

Mechanical properties

Steel fibers

Polypropylene fibers

micro-silica

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