This paper explores modern technological approaches to recycling dust waste generated during the production of ferrosilicon. The study focuses on metallurgical dusts with a high content of silicon dioxide (SiO₂) as the primary material. Their composition and physicochemical properties were analyzed, and a sodium hydroxide (NaOH)-based processing technology was proposed. In this method, silicon is extracted in the form of water-soluble sodium silicate, which is subsequently converted into amorphous silicon dioxide. Compared to sublimation-based technologies, the proposed method operates at lower temperatures, consumes less energy, and offers greater environmental safety. The potential use of the processed products in the construction materials industry (e.g., slag blocks, silicate bricks, plaster mixtures) is also discussed. The results confirm that the NaOH-based recycling technology is both economically viable and environmentally sustainable.
This paper explores modern technological approaches to recycling dust waste generated during the production of ferrosilicon. The study focuses on metallurgical dusts with a high content of silicon dioxide (SiO₂) as the primary material. Their composition and physicochemical properties were analyzed, and a sodium hydroxide (NaOH)-based processing technology was proposed. In this method, silicon is extracted in the form of water-soluble sodium silicate, which is subsequently converted into amorphous silicon dioxide. Compared to sublimation-based technologies, the proposed method operates at lower temperatures, consumes less energy, and offers greater environmental safety. The potential use of the processed products in the construction materials industry (e.g., slag blocks, silicate bricks, plaster mixtures) is also discussed. The results confirm that the NaOH-based recycling technology is both economically viable and environmentally sustainable.
В данной работе рассматриваются современные технологические подходы к переработке пылевых отходов, образующихся при производстве ферросилиция. В исследовании основное внимание уделено металлургическим пылям с высоким содержанием диоксида кремния (SiO₂) в качестве первичного материала. Проанализированы их состав и физико-химические свойства, а также предложена технология переработки на основе гидроксида натрия (NaOH). В этом методе кремний извлекается в виде водорастворимого силиката натрия, который затем преобразуется в аморфный диоксид кремния. По сравнению с технологиями, основанными на сублимации, предлагаемый метод работает при более низких температурах, потребляет меньше энергии и обеспечивает большую экологическую безопасность. Также обсуждается потенциальное использование переработанных продуктов в промышленности строительных материалов (например, шлакоблоки, силикатный кирпич, штукатурные смеси). Результаты подтверждают, что технология переработки на основе NaOH является как экономически выгодной, так и экологически устойчивой.
Ushbu ishda ferrosilisiy ishlab chiqarish jarayonida hosil bo‘ladigan chang chiqindilarini qayta ishlashning zamonaviy texnologik yondashuvlari ko‘rib chiqiladi. Tadqiqotda asosan tarkibida kremniy dioksidi (SiO₂) yuqori bo‘lgan metallurgik changlar birlamchi material sifatida o‘rganildi. Ularning tarkibi va fizik-kimyoviy xossalari tahlil qilindi hamda natriy gidroksidi (NaOH) asosida qayta ishlash texnologiyasi taklif etildi. Ushbu usulda kremniy suvda eruvchan natriy silikat shaklida ajratib olinadi, so‘ngra u amorf kremniy dioksidiga aylantiriladi. Sublinatsiyaga asoslangan texnologiyalar bilan solishtirganda, taklif etilayotgan usul pastroq haroratlarda ishlaydi, kamroq energiya sarflaydi va yuqoriroq ekologik xavfsizlikni ta’minlaydi. Shuningdek, qayta ishlangan mahsulotlardan qurilish materiallari sanoatida (masalan, shlakobloklar, silikat g‘ishtlar, suvoq aralashmalari) foydalanish imkoniyatlari muhokama qilinadi. Natijalar shuni tasdiqlaydiki, NaOH asosidagi qayta ishlash texnologiyasi iqtisodiy jihatdan ham foydali, ham ekologik barqarordir.
| № | Author name | position | Name of organisation |
|---|---|---|---|
| 1 | Xoliqulov D.B. | direktorning fan va innovatsiyalar bo‘yicha o‘rinbosari | Toshkent Davlat texnika universiteti Olmaliq filiali |
| 2 | Xojiev S.T. | PhD | Toshkent Davlat texnika universiteti Olmaliq filiali |
| 3 | Shaymanov I.I. | PhD nomzod | Toshkent Davlat texnika universiteti Olmaliq filiali |
| 4 | Xudoymuratov S.J. | Assistent | Toshkent Davlat texnika universiteti Olmaliq filiali |
| № | Name of reference |
|---|---|
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