Abstract
İlaçlar,
sucul çevrede düşük konsantrasyonlarda bulunan önemli kirleticilerdir. Bu
bileşikler, üretim sırasındaki atılımlarla, kullanılmayan veya kullanım süresi
sona eren ilaçların atılmasıyla, insan ve hayvan boşaltımlarıyla birlikte
çevreye farklı yollarla giriş yapmaktadırlar. Aspirin, steroid olmayan
antienflamatuar (NSAID) bir ilaç olup, dünyanın hemen hemen her bölgesinde
yaygın olarak kullanılmaktadır. Klasik atıksu arıtma tesisleri
mikrokirleticilerin gideriminde yeterli olmamaktadır. Bu nedenle mikrokirletici
giderimleri için ileri oksidasyon proseslerinin kullanılması iyi bir çözüm olmaktadır.
Fenton ve fotofenton prosesleri ileri oksidayon proseslerinin alt basamağında
bulunmaktadır. Bu çalışmada fenton ve fotofenton prosesleri kullanılarak
aspirinin atıksudan giderimi amaçlanmıştır. Laboratuvar şartları altında,
atıksuda bulunan aspirinin giderimi için H2O2 ve FeSO4
kullanılarak koagülasyon ve ileri oksidasyon yöntemleri uygulanmıştır. Aspirin
tablet, musluk suyunda çözündürülerek konsantrasyonu 20 mg/L olacak şekilde hazırlanmıştır.
Aspirinin giderim verimliliğini belirlemek için KOI ve TOK testleri
yapılmıştır. Optimum H2O2 ve FeSO4
konsantrasyonlarını belirlemek için, farklı pH değerleri (3, 3.5, 4), reaksiyon
süresi (10, 20, 30 dk) ve bekleme süresi (120 dk) seçilerek oda sıcaklığında
deneyler gerçekleştirilmiştir. Fotofenton prosesinde ek olarak 254 nm dalgaboyu
ışık tüm deneyler sırasında sürekli olarak uygulanmıştır. H2O2
ve FeSO4 konsantrasyonları (10, 20, 30 mg/L) denemiştir. Sonuçlar,
fenton prosesi için %83.91 KOI ve %57.52 TOK giderimi ve fotofenton prosesi
için %90.97 ve %85.89 TOK giderimi olduğunu göstermektedir.
References
- Bouzenno H., Hfaiedh N., Giroux-Metges M., Elfeki A., Talarmin H., “Biological properties of citral and its potential protective effects against cytotoxicity caused by aspirin in the IEC-6 cells” Biomedicine & Pharmacotheraphy, 87, 653- 660, 2017.
- Deminiat B., Razavipanah I., Rounaghi G. H., Arab-Zavar M. H., “A novel electrochemical imprinted sensor for acetylsalicyclic acid based on polyprole, sol-gel and SiO2@Au core-shell nanoparticles” Sensor and Actuaters B, 244, 785-795, 2017.
- Kummerer K., “Pharmaceuticals in the environment” Springer, 527s, USA, 2004.
- Heberer T., “Occurance fate and effects of pharmaceutical residues on the aquatic environment: A review of recent research data” Toxicology Letters, 131 (1/2), 5-17, 2002.
- Yunlong L., Wenshan G., Huu H. N., Long D. N., Faisal T.H., Jian Z., Shang L, Xiaocheng C. W., “A review on the occurence of micropollutants in the aquatic environment and their fate and removal during wastewater treatment, Science of the Total Environment, 4734-4740, 619-641, 2014.
- Liu W., Wang Y., Zhang L., “Hydrothermal synthesis of FeS2 as a high effiency fenton reagent to degrade alachlor via superoxide-mediated Fe (II)/ Fe(III) cycle, ACS Applied Materials&Interfaces, 7, 28534-28544, 2015.
- Sonmez G., “İleri oksidasyon prosesleri ile bazı ilaç kalıntılarının giderimi” Aksaray Üniversitesi, Fen Bilimleri Enstitüsü, Doktora Tezi, 97s, Aksaray, 2015.
- Anipsitakis G. P., Dionysiou D. D., “Transition metal/UV based advanced oxidation technologies for water decontamination, Applied Catalysis B: Environmental, 54(3), 155-163, 2004.
- Li W., Nanaboina V., Zhou Q., Korshin G. V., “Effects of fenton treatment on the properties of effluent organic matter and their relationship with degradation of pharmaceuticals and personal care products” Water Research, 46, 403-412, 2012.
- Akbal F., Balkaya N., “Toksik organik kirleticilerin gideriminde ileri oksidasyon teknolojileri, Yıldız Teknik Üniversitesi Dergisi, 4, 47-55, 2002.
- http://www.enviolet.com/en/uv-oxidation/uvoxidation/photo-fenton-reaction.html [Erişim Tarihi:3.05.17]
- https://www.astm.org/Standards/D1252.htm [Erişim Tarihi: 3.05.2017]
- Trapido M., Kulik N., Goi A., Veressinina Y., Muntar R., “ Fenton treatment efficacy for the purification of different kinds of wastewater” Water Science and Technology, 60(7), 1795-1801, 2009.
- Tekin H., Bilkay O., Ataberk S. S., Balta T. H., Ceribasi I. H., Sanin F. D., Dilek F. B., Yetis U., “Use of fenton oxidation to improve the biodegradability of a pharmaceutical wastewater” Journal of Hazardous Materials B, 136, 258-265, 2006.
- Ustun Odabasi S., Maryam B., Buyukgungor H., “Assessment and investigation of paracetamol from wastewater by using oxidation process and TOC” 3rd International on Recycling and Reuse, 28-30 Eylül, Full paper book, 161s, İstanbul, 2016.
- Ustun Odabasi S., Buyukgungor H., “Investigation and evaluation of degradability of ibuprofen from wastewater by using fenton process” EJENS- European Journal of Engineering And Natural Sciences, 2(1), 114-119, 2017.
- Kang Y. W., Hwang K., “Effect of reaction conditions on the oxidation efficiency in the fenton process” Water Research, 10, 2786-2790, 2000.
Abstract
Pharmaceuticals, as an
emerging pollutant, are found in low concentration in aquatic environment. The
residues of these compounds can enter the environment in different ways: during
manufacturing and during the disposal of unused or expired drugs and with human
and animal excretion. Aspirin (ASA), a non-steroidal anti-inflammatory drug
(NSAID), is a most widely used medicine in almost every part of world. Classic
wastewater treatment plants are not enough to remove micropollutants therefore
advanced oxidation process have a good solution. Fenton and photo-fenton is a
branch of advanced oxidation process. In this study, degradation of aspirin
(ASA) using fenton and Photo-Fenton was studied in wastewater. Under laboratory
conditions, coagulation and advance oxidation using H2O2
and FeSO4 was applied to degrade the concentrations of aspirin from
wastewater. Aspirin tablet (20 mg/L) was dissolved in tap water to prepare
aspirin solution as synthetic wastewater. COD and TOC test were conducted to
observe the removal efficiency of drug. Experiments with optimal concentrations
of H2O2 and FeSO4 were carried out by chancing
pH (3-3.5-4), reaction time (10,20,30 min) and residence time (120 min) of
solution at room temperature and in the constant supply of UV 250 nm
wavelength. Concentration of H2O2 and FeSO4were
selected as (10-20-30 mg/L). Results showed 83.91 % COD and 57.52 % TOC removal
for fenton process and 90.97 % COD and 85.89 % TOC removal for photo-fenton
process.
References
- Bouzenno H., Hfaiedh N., Giroux-Metges M., Elfeki A., Talarmin H., “Biological properties of citral and its potential protective effects against cytotoxicity caused by aspirin in the IEC-6 cells” Biomedicine & Pharmacotheraphy, 87, 653- 660, 2017.
- Deminiat B., Razavipanah I., Rounaghi G. H., Arab-Zavar M. H., “A novel electrochemical imprinted sensor for acetylsalicyclic acid based on polyprole, sol-gel and SiO2@Au core-shell nanoparticles” Sensor and Actuaters B, 244, 785-795, 2017.
- Kummerer K., “Pharmaceuticals in the environment” Springer, 527s, USA, 2004.
- Heberer T., “Occurance fate and effects of pharmaceutical residues on the aquatic environment: A review of recent research data” Toxicology Letters, 131 (1/2), 5-17, 2002.
- Yunlong L., Wenshan G., Huu H. N., Long D. N., Faisal T.H., Jian Z., Shang L, Xiaocheng C. W., “A review on the occurence of micropollutants in the aquatic environment and their fate and removal during wastewater treatment, Science of the Total Environment, 4734-4740, 619-641, 2014.
- Liu W., Wang Y., Zhang L., “Hydrothermal synthesis of FeS2 as a high effiency fenton reagent to degrade alachlor via superoxide-mediated Fe (II)/ Fe(III) cycle, ACS Applied Materials&Interfaces, 7, 28534-28544, 2015.
- Sonmez G., “İleri oksidasyon prosesleri ile bazı ilaç kalıntılarının giderimi” Aksaray Üniversitesi, Fen Bilimleri Enstitüsü, Doktora Tezi, 97s, Aksaray, 2015.
- Anipsitakis G. P., Dionysiou D. D., “Transition metal/UV based advanced oxidation technologies for water decontamination, Applied Catalysis B: Environmental, 54(3), 155-163, 2004.
- Li W., Nanaboina V., Zhou Q., Korshin G. V., “Effects of fenton treatment on the properties of effluent organic matter and their relationship with degradation of pharmaceuticals and personal care products” Water Research, 46, 403-412, 2012.
- Akbal F., Balkaya N., “Toksik organik kirleticilerin gideriminde ileri oksidasyon teknolojileri, Yıldız Teknik Üniversitesi Dergisi, 4, 47-55, 2002.
- http://www.enviolet.com/en/uv-oxidation/uvoxidation/photo-fenton-reaction.html [Erişim Tarihi:3.05.17]
- https://www.astm.org/Standards/D1252.htm [Erişim Tarihi: 3.05.2017]
- Trapido M., Kulik N., Goi A., Veressinina Y., Muntar R., “ Fenton treatment efficacy for the purification of different kinds of wastewater” Water Science and Technology, 60(7), 1795-1801, 2009.
- Tekin H., Bilkay O., Ataberk S. S., Balta T. H., Ceribasi I. H., Sanin F. D., Dilek F. B., Yetis U., “Use of fenton oxidation to improve the biodegradability of a pharmaceutical wastewater” Journal of Hazardous Materials B, 136, 258-265, 2006.
- Ustun Odabasi S., Maryam B., Buyukgungor H., “Assessment and investigation of paracetamol from wastewater by using oxidation process and TOC” 3rd International on Recycling and Reuse, 28-30 Eylül, Full paper book, 161s, İstanbul, 2016.
- Ustun Odabasi S., Buyukgungor H., “Investigation and evaluation of degradability of ibuprofen from wastewater by using fenton process” EJENS- European Journal of Engineering And Natural Sciences, 2(1), 114-119, 2017.
- Kang Y. W., Hwang K., “Effect of reaction conditions on the oxidation efficiency in the fenton process” Water Research, 10, 2786-2790, 2000.
Details
| Subjects | Engineering |
|---|---|
| Journal Section | ICOCEE 2017 (International Conference on Civil and Environmental Engineering) Özel Sayısı |
| Authors | |
| Publication Date | December 27, 2017 |
| Acceptance Date | October 12, 2017 |
| Published in Issue | Year 2017 Volume:6 ICOCEE Special Issue |
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