بهينه سازي فرآيند پيروليز سريع ضايعات نيشكر به كمك روش سطح پاسخ

Optimization of sugarcane bagasse fast pyrolysis conditions using response surface method

در حال حاضر زيست‌توده به عنوان منبعي اقتصادي و تجديد پذير مورد توجه بسياري از محققان قرار گرفته است. توليد زغال زيستي از منابع زيست‌توده مي‌تواند علاوه بر توليد انرژي از اين منابع، از اثرات مخرب زيست محيطي ناشي از استفاده بي رويه سوخت‌هاي فسيلي نيز بكاهد. در اين تحقيق به بررسي فرآيند پيروليز در حضور آب در شرايط بحراني، دما و فشارهاي بالا كه به اصطلاح كربونيزه كردن هيدروترمال مي‌نامند، جهت توليد زغال زيستي از باگاس نيشكر كه از ضايعات نيشكر مي‌باشد، پرداخته شد. عوامل مورد مطالعه در اين تحقيق شامل زمان ماند مواد درون رآكتور (30، 75 و 120 دقيقه)، نسبت جرمي باگاس به آب (0/15 ، 0/20 و 0/30) و فشار درون رآكتور (10، 12/5 و 15 بار) بود. در اين تحقيق از روش باكس بنكن به منظور طراحي آزمايش‌ها استفاده شد و همچنين جهت يافتن شرايط عملكردي رآكتور از روش سطح پاسخ استفاده گرديد. بر اساس نتايج بدست آمده، ميزان نسبت جرمي باگاس به آب معادل 0/15، زمان ماند 38 دقيقه و فشار11 بار به عنوان نقطه بهينه عملكردي سامانه پيروليز سريع انتخاب شدند. براي اين نقطه بهينه، ميزان ارزش حرارتي بالاي نمونه‌ها معادل Mj/kg 21 و ميزان انرژي مصرفي سامانه برابر kwh 09/0 به دست آمد.

Introduction Today, with advances in all sciences, we must always look for a way to make the best use of plant residues and turn them into valuable products. A consequence of improving family life standards and consistent industrial development is a higher demand for energy usage. Nowadays, agricultural residues are produced in huge quantities and could be considered as a promising source for renewable energy generation. Bagasse is one of the major sources of sugarcane production. The production of valuable products from Bagas, in addition to having economic benefits, can reduce the environmental damage caused by burning them. In recent years, there has been an increasing trend in the utilization of sugarcane bagasse as a major by-product of the sugarcane industry. Another very valuable substance produced from sugarcane bagasse, which we will discuss in this study, is bio compressed coal. Valorization of sugarcane bagasse to engineered biochar using hydrothermal carbonization (HTC) presents a perspective source to substitute conventional fossil fuels. HTC process offers the benefits of converting the sugarcane bagasse into biochar and bio-oil. In this process, biomass is usually conducted in the temperature range of 180–250 ◦C. HTC technique is promoted as one way of reducing carbon dioxide (CO) emissions, which mostly generated through open burning of crop residues. Besides the utilization for power/heat generation for sugarcane industries, Bagasse may find other potential applications, for instance: electricity generation, biogas production, livestock feed/compost production, and also bioethanol production. The unique features of biochar generated through HTC process are its portability, high volumetric energy density, hydrophobicity, and wear ability. Materials and Methods In this research, sugarcane waste was obtained from Hakim Farabi Sugarcane Cultivation and Industry Company in Ahvaz. The hydrothermal carbonization process was performed in a batch reactor at Shahid Chamran University of Ahvaz. The parameters studied in this study include the retention time of the material inside the reactor (30, 75, and 120 minutes), bagasse mass to water ratio (0.15, 0.20, and 0.30) and the pressure inside the reactor (10, 12.5 an‎d 15 bar). In order to measure the pressure, a Nuova FiMa barometer was used, which was able to measure the pressure values up to 25 bar. A temperature control system model HANYoung ED6 was used, which was equipped with a ceramic heater with a diameter of 230 mm and a height of 230 mm to provide heat for the process. The PARR1266 calorie bomb device was employed to measure the calorific value of the samples. The moisture content of the samples was also measured using ASTM-2010a standard. In this experimental work, the response surface method was employed to investigate the effect of input parameters (i.e., pressure, residence time, and water-to-biomass) on the response parameter (i.e., HHV and energy consumption). Design Expert ver.10 software was used to predict the corresponding models. The obtained models provided a good relationship between the independent/dependent parameters. Results and Discussion The HTC process has been analyzed using a Response Surface Method to derive predicted models for the HHV and energy parameters. The results obtained showed that all models provided could successfully predict the HTC process. According to the results, the models developed were statistically significant at the level of 1%. The multi-regression models between the input/response variables were obtained as second-order quadratic equations. The F-value for the residence time, and water-to- bagasse, and pressure were 2417, 286, and 1185, respectively. The value of F-value of each derived model indicates the significance of the studied parameters. The parameters of water-to-bagasse and pressure had a more significant effect compared to the residence time factor. The R-square value for this study was achieved as 0.0996, indicating that the proposed model was able to evaluate the experimental data thoroughly. A multi-objective optimization technique was used to achieve an optimal HTC process condition with the maximum possible amount of desirability value. Conclusion The optimum amount of water-to-bagasse, pressure, and residence time was calculated using the response surface techniques. A pressure of 11 bar, the residence time of 38 min, and water-to-bagasse of 0.15 were found to be optimal values. The findings of this study indicate that at optimal input variables, the value of calorific value and used energy was 21 Mj/kg and 0.09 kWh, respectively.