بتن پلیمری تهیه شده از رزین پلی استر حاوی نانو کامپوزیت CNF/SiO2 و بررسی عملکرد مکانیکی و دوام آن (مقاله علمی وزارت علوم)
درجه علمی: نشریه علمی (وزارت علوم)
آرشیو
چکیده
امروزه استفاده از بتن پلیمری به دلیل قیمت بالا، محدود به موارد خاص است. محبوب ترین رزین پلیمری که در بتن استفاده می شود، رزین پلی استر غیر اشباع می باشد. این نوع رزین به دلیل در دسترس بودن، قیمت مناسب، کیفیت مکانیکی خوب و مقاومت فشاری بالا به طور گسترده ای مورد استفاده قرار می گیرد. هدف این مقاله بررسی ویژگی های مکانیکی بتن پلیمری تهیه شده با رزین پلی استر با نانو کامپوزیت CNF/SiO2، مقاومت فشاری، خمشی و سایش، عمق نفوذ آب تحت فشار و دوام آن در محیط های اسیدی است. طرح اختلاط شامل نمونه هایی با 5، 10 و 15 درصد رزین پلی استر و 1، 2، 3 درصد CNF/SiO2 تهیه شد و مقاومت و دوام آنها مورد بررسی قرار گرفته است. یافته های این مطالعه نشان داد که بتن پلیمری در هنگام فرآوری اولیه مقاومت مکانیکی بالایی را نشان داد و با افزایش CNF/SiO2 مقاومت آن بیشتر افزایش یافت. بهترین نمونه CP10-CS2 دارای 10 درصد رزین پلی استر و 2 درصد CNF/ SiO2 است. همچنین، پس از قرار گرفتن در معرض اسید خورنده به مدت 3 و 10 ماه، نمونه ها به ترتیب کمتر از 10 درصد و 20 درصد افت مقاومت فشاری را نشان دادند.Polymer concrete prepared from polyester resin containing CNF/SiO2 nanocomposite and checking mechanical performance and durability
This study focuses on enhancing the performance of polymer concrete (PC) by incorporating a nanocomposite of cellulose nanofibers (CNF) and silica (SiO2) into an unsaturated polyester resin matrix. Polymer concrete, known for its superior mechanical strength, low permeability, and exceptional durability compared to conventional cement-based concrete, is often limited by its high production costs. The motivation behind this research is to optimize the material properties of polymer concrete by modifying its composition to achieve a balance between performance and cost-efficiency. By introducing CNF/SiO2 nanocomposites, the study aims to improve mechanical and chemical performance, thereby expanding the potential applications of polymer concrete in various industries, especially where enhanced durability and mechanical resistance are required.1. IntroductionPolymer concrete, which has been in development since the 1950s, is highly regarded for its remarkable mechanical properties, including high compressive and tensile strengths, superior resistance to chemical attacks, and minimal water permeability. However, the prohibitive cost of polymer resins, particularly unsaturated polyester resins, has limited its adoption in large-scale construction projects. One of the primary objectives of this research is to develop a cost-effective formulation of polymer concrete that retains the material's exceptional properties while reducing overall production costs. The incorporation of nanocomposites, specifically CNF/SiO2, into the polymer matrix is expected to enhance the performance characteristics of polymer concrete, making it more viable for diverse applications, including use in harsh environments and high-stress applications.2. Materials and MethodsThe materials used in this research include unsaturated polyester resin, cellulose nanofibers (CNFs), and silica (SiO2). CNF, known for its high surface area and excellent mechanical properties, was functionalized with carboxyl groups using concentrated nitric acid to facilitate its dispersion within the polymer matrix. Silica (SiO2), a widely used nanofiller, was introduced to further enhance the mechanical properties and increase the surface area for polymer interactions. The CNF/SiO2 nanocomposite was then prepared through electrospinning, followed by mixing with the polyester resin at different concentrations. For the experimental work, various samples of polymer concrete were prepared by varying the polyester resin content (5%, 10%, and 15%) and the nanocomposite concentration (1%, 2%, and 3%). These samples were identified by their respective compositions, such as PC10-CS2, which represents 10% resin and 2% nanocomposite. The key tests performed to evaluate the mechanical and durability properties of the samples include:- Compressive strength: Measured according to European standard EN 12390-3.- Bending strength: Evaluated using German National Standard DIN 1048-5.- Abrasion resistance: Determined based on European standard EN 1338.- Water penetration depth: Measured under pressure as per EN 12390-8.-Durability against sulfuric acid: Samples were exposed to sulfuric acid for 300 days to evaluate their chemical resistance.3.Results and Discussion3.1 Mechanical PropertiesThe addition of CNF/SiO2 nanocomposites significantly enhanced the mechanical properties of the polymer concrete. The compressive strength of the samples showed a marked improvement with the incorporation of 2% CNF/SiO2 nanocomposites. Among all formulations, the PC10-CS2 sample, containing 10% polyester resin and 2% CNF/SiO2 nanocomposites, exhibited the highest compressive strength. This sample achieved a significant increase in compressive strength compared to pure polyester resin samples without nanocomposites. However, further increases in nanocomposite content (3%) did not show any additional benefits, indicating an optimal threshold for nanocomposite inclusion.The bending strength of the polymer concrete was also improved with the addition of nanocomposites. The sample with 2% CNF/SiO2 outperformed other formulations, exhibiting enhanced flexibility and resistance to bending forces. This suggests that the nanocomposites contribute to a more robust bonding between the resin and the aggregates, resulting in better load distribution and higher overall strength.In terms of abrasion resistance, the polymer concrete containing 10% resin and 2% CNF/SiO2 (PC10-CS2) demonstrated superior wear resistance compared to all other formulations. This property is particularly crucial for applications where the material is subject to high abrasion, such as in flooring or infrastructure exposed to heavy traffic.3.2 DurabilityWater penetration tests revealed that the incorporation of CNF/SiO2 nanocomposites significantly reduced the water penetration depth. The PC10-CS2 sample demonstrated the lowest water penetration, indicating that the nanocomposites acted as an effective barrier against moisture ingress. This characteristic is vital for applications in wet or submerged environments, where the material’s resistance to water absorption can prevent degradation and prolong the life of structures.In acidic environments, particularly sulfuric acid exposure, the polymer concrete with CNF/SiO2 nanocomposites exhibited exceptional chemical resistance. After 300 days of exposure, the compressive strength of the PC10-CS2 sample showed only a 23% reduction, a remarkable result considering the aggressive nature of sulfuric acid. This performance highlights the potential of this polymer concrete formulation for use in corrosive environments, such as sewage treatment facilities and industrial applications where exposure to harsh chemicals is common.4.Conclusion and Future WorkThis research demonstrates that the incorporation of CNF/SiO2 nanocomposites into unsaturated polyester resin significantly enhances the mechanical and durability properties of polymer concrete. The optimal formulation, PC10-CS2, consisting of 10% resin and 2% CNF/SiO2 nanocomposites, achieved the best overall performance, showing significant improvements in compressive strength, bending resistance, abrasion resistance, water penetration, and chemical durability. These findings suggest that polymer concrete with CNF/SiO2 can be a promising material for applications in harsh environments, potentially revolutionizing the construction industry by providing a more durable, high-performance alternative to traditional concrete.Further research is recommended to explore the long-term performance of these materials under real-world conditions, such as thermal cycling, exposure to different environmental stresses, and load-bearing tests over extended periods. Additionally, the effects of varying the processing conditions or exploring other types of fibers or nanomaterials could lead to further improvements in the performance and cost-effectiveness of polymer concrete.5. Implications for IndustryThe results of this study have significant implications for industries requiring high-performance materials that can withstand harsh conditions, including marine structures, wastewater treatment facilities, and high-traffic infrastructure. The ability to tailor the mechanical and chemical properties of polymer concrete by adjusting the nanocomposite content provides a flexible approach to meeting the demands of diverse applications.
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