پديد آورندگان :
مظاهري, احمدرضا دانشگاه آيت الله العظمي بروجردي (ره) - دانشكدۀ فني و مهندسي , نورزاد, علي دانشگاه شهيد بهشتي - دانشكدۀ مهندسي عمران - آب و محيط زيست
كليدواژه :
نانو رس , خود ترميمي آهك , مقاومت تكمحوري , نانورس و آهك
چكيده فارسي :
استفاده از افزودنيها در تثبيت خاك همواره مورد توجه محققان بوده است. در اين مقاله تاثير نانورس بهعنوان يك افزودني جديد، در كنار آهك كه يكي از افزودنيهاي قديمي در تثبيت خاك بهشمار ميرود، بر رفتار خاك بررسي شده است. درصدهاي مختلف نانورس و آهك بر خاك رسي افزوده ميشود و تاثير آن بر درصد رطوبت بهينه، بيشينه دانسيته خشك، مقاومت تكمحوري، حدود اتربرگ و خاصيت خود ترميمي خاكها بررسي ميشود. پژوهشهاي انجام شده حاكي از آن است كه اضافه كردن آهك باعث كاهش دانسيته خشك خاك ميشود اين در حالي است كه افزودن نانورس سبب افزايش اين پارامتر در خاكهاي رسي ميشود. افزودن آهك تاثير زيادي بر افزايش چسبندگي دارد و بر افزايش زاويه اصطكاك تاثير چشمگيري ندارد اين درحالي است كه نانو مواد علاوه بر اينكه چسبندگي را افزايش ميدهد، سبب افزايش زاويه اصطكاك خاك نيز ميشود. نكته مهم و قابل تمركز در اين كار تاثير چشمگير نانو مواد بر خاصيت خود ترميمي خاك رس است. با افزودن 2 درصد نانورس به خاك با گذشت 24 ساعت از ايجاد صفحه گسيختگي در خاك، مصالح قادر هستند حدود 80 درصد مقاومت اوليه خود (زماني كه هيچ افزودني ندارد) را بهدست آورند.
چكيده لاتين :
The use of various additives to improve the properties of soils from past years have been studied by different researchers. Such additives are lime, cement, fly ash and fiber which have been used frequently in combination with soil. Lime is one of the oldest additives that it is utilized with different types of soils. Lime has positive impact on geotechnical properties of soil that alter some of the soil characteristics. Adding lime causes to reduce plasticity ranges, enhanced efficiency, strength and shrinkage of the soil. Extensive researches in the field of sustainability of clay with lime indicate that the optimum percentage of lime in the soil modification is between 1 to 3% by weight of the soil. But some researchers believe 8% by weight of lime are effective for soil stabilization. The presence of lime in clay soil yiels to occur some reaction, that it improves the soil properties. Reactions are included cation exchange flocculation, carbonation and pozzolanic reactions. Cation exchange between the clay cations and calcium cations takes place in lime. Cation exchange causes clay particles to get closer to each other creating complex structures in the clay soil and this improves the clay soil features. In recent years the use of nanoparticles is considered in civil engineering field. The investigations have demonstrated that the use of nanomaterial increases cement reactivity and also improves density because it is filled with particles. Recent research has shown that the use of montmorillonite nano-clay soils to control swelling and to reduce failure potential in the soil. A number of researchers have expressed the use of nanoparticles causes to decrease the hydraulic conductivity of soils. In this paper, the effect of nano-clay and lime on the important soil parameters is evaluated. For this purpose, lime at 2 and 4 percentage and nano-clay at 0.5, 1 and 2 percentages have been added to clay soil and their impact on parameters such as optimized moisture, Atterberg limits, unconfined compressive strength and self-healing properties of soil is evaluated. Self-healing properties is one of the features, to repair damages due to internal erosion in the clay which is very efficient and important.
Materials and experimental
methods
In the present research, the effect of lime and montmorillonite nano–clay to soil strength is evaluated. For this purpose, samples of clay soil (CL) has been used. In the experimental study, the percentages of additives mixed with the dry soil and then the optimum moisture and maximum specific weight of soil are determined with different percentages of additives. Soil Atterberg limits based on the ASTM D4318 standard have been determined. Dry samples have been mixed together and then the water is added and mixed well with each other. Then the sample has been prepared in the form of a steel cylinder (cylindrical specimens) with a diameter of 50 mm and a height of 100 mm. Specimens were molded immediately and the weight and dimensions were carefully measured and then placed in plastic to prevent moisture loss and put them at 20 °c and 90% moisture curing room.
Results and discussion
In this study, the percentage of lime is between 0, 2, 4 percent by weight and nanomaterials percentage is between 0.5 and 1 and 2 percent that can be varied in order to analyze the effect of various additives on the properties of the soil samples. The results indicate that increasing the nano-clay and lime percentage can enhance the optimum specific gravity of soil. The optimum moisture content of sample without any additive is equal to 19.5%. However, samples contain 2% nano-clay and 4% lime, the optimum moisture content increases to 23.5%. But the presence of lime reduces the maximum dry density of soil while adding nano-clay increases this amount. In samples with 4% lime and with no nano-clay, maximum dry density is 17 but in case of lime with 4% and nano-clay with 2% it is increased to 17.5 . In addition, adding lime without the presence of nano-clay only increases strength of soil. When 2 percent of lime is added, the strength of soil increases about 39 percent. As mentioned before, the effect of lime and nano-clay on increasing of unconfined compressive strength is almost the same which means by adding 2% of lime or nano-clay the strength of the soil increases about 40 percent. Using both lime and clay nanoparticles simultaneously (each 2%), a significant increase in strength of soil occurs in approximately 77 percent.
Conclusion
The use of nano-clay and lime improves soil strength parameters. But economically lime is more affordable than nano-clay. Therefore, if you need to increase only unconfined compressive strength, then the nano-clay is not recommended.
When it comes to self-healing in clay, the nano-clay can improve resistance rupture of the soil. By adding 2% of nano-clay in soil, healing of soil resistance after the break and after 24 hours can reach up to 60% of the ultimate strength of the soil. This property can be used to repair of locations that are subjected to internal erosion and scouring.
