ارزیابی پتانسیل خورندگی و ترسیب در چاه‌های تامین کننده آب شرب شهر گرگان

مازنی, حسن; قره محمودلو, مجتبی; جندقی, نادر; رقیمی, مصطفی; حشمت‌پور, علی

doi:10.30495/wej.2024.31749.2383

ارزیابی پتانسیل خورندگی و ترسیب در چاه‌های تامین کننده آب شرب شهر گرگان

نوع مقاله : مقاله پژوهشی

نویسندگان

¹ دانش‌آموخته کارشناسی ارشد آبخیزداری، دانشکده کشاورزی و منابع طبیعی، دانشگاه گنبدکاووس، گنبدکاووس، ایران

² استادیار گروه مرتع و آبخیزداری، دانشکده کشاورزی و منابع طبیعی، دانشگاه گنبدکاووس، ایران

³ استادیار گروه مرتع و آبخیزداری، دانشکده کشاورزی و منابع طبیعی، دانشگاه گنبدکاووس، گنبدکاووس، ایران

⁴ استاد گروه زمین‌شناسی، دانشکده علوم، دانشگاه گلستان، گرگان، ایران

10.30495/wej.2024.31749.2383

چکیده

پژوهش حاضر به‌منظور تعیین پتانسیل رسوب‌گذاری و خورندگی منابع آب آشامیدنی شهر گرگان در دو فصل بهار و پاییز سال 1396 انجام شد. در این پژوهش ابتدا از 63 چاه آب شرب شهر گرگان نمونه‌برداری و 17 پارامترهای فیزیکوشیمیایی در آب آن‌ها آنالیز شد. به منظور بررسی هیدروژئوشیمیایی منابع آبی از دیاگرام‌های استیف و مثلثی استفاده‌شد. سپس شاخص‌های پتانسیل ترسیب کربنات کلسیم، خورندگی لانژلیه، رایزنر، لارسون-اسکلد و نسبت خورندگی منابع آب آشامیدنی شهر گرگان محاسبه‌ و نقشه پراکندگی مکانی آن‌ها با استفاده از نرم‌افزار GIS تهیه شد. در نهایت با استفاده از آزمون آماری واریانس یکطرفه، سطح معناداری شاخص‌ها در منابع آب آشامیدنی شهر گرگان در دو فصل بررسی شد. نتایج نشان داد که غلظت اکثر پارامترهای فیزیکوشیمیایی در طول مسیر حرکت به سمت شمال منطقه افزایش می‌یابد. براساس نحوه پراکنش و الگوی پراکندگی نمونه‌ها در دیاگرام‌های استیف مثلثی، تیپ غالب آب زیرزمینی در حاشیه ارتفاعات Ca-HCO3 می‌باشد و با ورود به دشت به تیپ Na-Cl تغییر می‌یابد. نتایج حاصل از سختی آب زیرزمینی نشان داد بیش‌تر منابع آبی جز آب‌های سخت تا خیلی سخت می‌باشند. هم‌چنین میزان سختی در طول مسیر حرکت آب زیرزمینی افزایش می‌یابد. براساس شاخص‌های خورندگی، در آب بیش از 84% چاه‌ها تمایل به خورندگی وجود دارد. اگرچه خاصیت خورندگی مشابهه سختی آب در حاشیه ارتفاعات بیشتر و به سمت شمال با افزایش املاح، خاصیت رسوبگذاری آب زیرزمینی افزایش می‌یابد. هم‌چنین نتایج آماری نشان داد که بجز شاخص لارسون-اسکلد در بقیه شاخص‌ها اختلاف معنی‌داری در میزان شاخص‌ها در دو فصل بهار و پاییز وجود ندارد.

کلیدواژه‌ها

موضوعات

مقالات برگرفته از پایان نامه

عنوان مقاله [English]

Evaluation of the corrosiveness and precipitation potential in the drinking water supply wells of Gorgan city

نویسندگان [English]

Hassan Mazani ¹
Mojtaba G.Mahmoodlu ²
Nader Jandaghi ³
Mostafa Raghimi ⁴
Ali Heshmatpour ³

¹ Former Master Student in Watershed, Faculty of Agricultural Sciences and Natural Resources, Gonbad Kavous University, Gonbad Kavous, Iran

² Associate Professor at Faculty of Agriculture and Natural Resources, Gonbad Kavous University, Gonbad Kavous, Iran

³ Assistant Professor at Faculty of Agriculture and Natural Resources, Gonbad Kavous University, Gonbad Kavous, Iran

⁴ Professor at Faculty of Basic Sciences, Golestan University, Gorgan, Iran

چکیده [English]

Abstract
Introduction: Corrosion and precipitation are two problems of water quality management for the water transmission and distribution systems. Hence, the present research was conducted to investigate the potential of corrosiveness and precipitation in the drinking water supply wells of Gorgan city using some indicators.
Methods: Here, the results of chemical analysis of 63 wells supplying drinking water in spring and autumn were used. First the temporal and spatial changes of physicochemical parameters were investigated using one-way variance statistical test and IDW method, respectively. The dominant type, the origin of chemical ions, and their evolution process in Gorgan aquifer were studied. In this research, water hardness, LSI, RSI, CR and LS were used to determine the corrosion and precipitation potential of drinking water in Gorgan city. Finally, the temporal and spatial changes of indices calculated in two seasons were investigated.
Findings: The high concentration of calcium ions in groundwater, due to the recharge of the aquifer by the limestone series located in the southern highlands, has increased its hardness. The results of RSI and LSI revealed that the majority of wells are corrosive and their water has the potential to decompose CaCO₃. Also, the corrosive property of water in the direction of groundwater movement is significantly reduced and the water precipitation property is increased. Also, 90 and 98% of the groundwater resources of Gorgan city have a corrosion ratio of less than one. Therefore, it is possible to transfer water from most wells with any type of metal pipes.

کلیدواژه‌ها [English]

Groundwater
Water quality
Hydrogeochemistry
Water supply facilities
Gorgan city

مراجع

1. Faridirad F, Gholinezhad M. Investigating corrosion and scaling Indices of potable water in city of Pardis water treatment plant. Journal of Water & Wastewater Science and Engineering. 2021; 6(3): 16-24. [In Persian]

2. Refait P, Jeannin M, Sabot R, Antony H, Pineau S. (2015). Corrosion and cathodic protection of carbon steel in the tidal zone: Products, mechanisms and kinetics. Corrosion Science. 2021; 90: 375-382.

3. Palazzo A, van der Merwe J, Combrink G. The accuracy of calcium-carbonate-based saturation indices in predicting the corrosivity of hot brackish water towards mild steel. Journal of the Southern African Institute of Mining and Metallurgy. 2015; 115 (12):1229-1238.

4. Vasconcelos HC, Fernández-Pérez BM, González S, Souto RM, Santana JJ. Characterization of the corrosive action of mineral waters from thermal sources: a case study at Azores Archipelago, Portugal. Water. 2015; 7 (7): 3515-3530.

5. Reyes, A., Letelier, M., Delaiglesia, R., Gonzalez, B. Lagos, G. (2008). Microbiologically induced corrosion of copper pipes in low-pH water. International Biodeterioration and Biodegradation. 61, 135-141.

6. Ghareh Mahmoodlu, M., Jandaghi, N., Sayadi, M. Investigating the factors affecting corrosion and precipitation changes along Gorganroud River, Golestan Province, Environmental Science Quarterly. 2021; 19 (2): 71-90 [In Persian].

7. Fazel Valipour ME. Evaluation of underground water resources southwest of Qochan (Razavi Khorasan Province) for drinking and industrial purposes based on quality indicators. New Approaches in Civil Engineering. 2021; 5(3): 68-81. [In Persian].

8. Omeka ME, Egbueri JC, Unigwe CO. Investigating the hydrogeochemistry, corrosivity and scaling tendencies of groundwater in an agrarian area (Nigeria) using graphical, indexical and statistical modelling. Arabian Journal of Geosciences. 2022; 15 (13): p.1233.

9. Sarkar B, Islam A, Das BC, Nandy S. Corrosion and scaling potential of groundwater in Quaternary aquifers of Bengal Basin, India. Arabian Journal of Geosciences. 2022; 15 (12): p.1152.

10. Nabizadeh Nodehi R, Mesdaghinia AR, Nasseri S, Hadi M, Soleimani H, Bahmani P. Analysis of water corrosion tendency in water supply system using qualitative indices and calcium carbonate precipitation potential index. Iranian Journal of Health and Environment. 2017; 9 (4): 457-470. [In Persian]

11. Hoseinzadeh E, Yusefzadeh A, Rahimi N, Khorsandi H. Evaluation of corrosion and scaling potential of a water treatment plant. Archives of Hygiene Sciences. 2013; 2 (2): 41-47.

12. Raghimi M, Rahimi Chakdel A, Ghareh Mahmoodlu M, Shahpasandzadeh M, Khademi SM. The effects of geological factors on chemical quality of drinking water of Gorgan, Iran, Journal of Agricultural Sciences and Natural Resources. 2008; 15(1): 1-13. [In Persian]

13. Mazani H. Investigation of hydrogeochemistry and contamination of Gorgan aquifer. MSc Thesis, Gonbad Kavous University. 2022. [In Persian]

14. Ghezelsofloo E, Raghimi M, Mahmoodlu MG, Rahimi-Chakdel A, Khademi SMS. Saltwater intrusion in drinking water wells of Kordkuy, Iran: an integrated quantitative and graphical study. Environmental Earth Sciences. 2021; 80 (16): p.520.

15. Izanloo S, Ghareh Mahmoodlu M, Jandaghi N, Ghorbani Vaghei H. Evaluation of Saturated Hydraulic Conductivity Changes in Surface and Subsurface Layers of Loess Soils of East of Golestan Province, Applied Soil Research. 2022; 10(2): 103-119. [In Persian]

16. Durvey VS, Sharma LL, Saini VP, Sharma BK. Handbook on the Methodology of Water Quality Assessment. Rajasthan Agriculture University, India. 1991.

17. Bhat MA, Wani AS, Vijay K, Jyotirmaya S, Dinesh T, Sanswal R. An overview of the assessment of groundwater quality for irrigation. Journal of Agricultural Science and Food Research. 2018; 9 (1): 1-9.

18. You SH, Tseng DH, Guo GL. A case study on the wastewater reclamation and reuse in the semiconductor industry. Resources, Conservation and Recycling. 2001; 32: 73-81.

19. Marangou V S, Savvides K. First desalination plant in Cyprus-product water aggresivity and corrosion control. Desalination. 2001; 138 (1-3): 251-258.

دوره 17، شماره 61 - شماره پیاپی 61
مرداد 1403
صفحه 52-64

فایل ها

سابقه مقاله

تاریخ دریافت: 15 فروردین 1402
تاریخ بازنگری: 04 دی 1402
تاریخ پذیرش: 25 بهمن 1402

تعداد مشاهده مقاله: 40
تعداد دریافت فایل اصل مقاله: 54

ارزیابی پتانسیل خورندگی و ترسیب در چاه‌های تامین کننده آب شرب شهر گرگان

Evaluation of the corrosiveness and precipitation potential in the drinking water supply wells of Gorgan city

مراجع

1. Faridirad F, Gholinezhad M. Investigating corrosion and scaling Indices of potable water in city of Pardis water treatment plant. Journal of Water & Wastewater Science and Engineering. 2021; 6(3): 16-24. [In Persian]

2. Refait P, Jeannin M, Sabot R, Antony H, Pineau S. (2015). Corrosion and cathodic protection of carbon steel in the tidal zone: Products, mechanisms and kinetics. Corrosion Science. 2021; 90: 375-382.

3. Palazzo A, van der Merwe J, Combrink G. The accuracy of calcium-carbonate-based saturation indices in predicting the corrosivity of hot brackish water towards mild steel. Journal of the Southern African Institute of Mining and Metallurgy. 2015; 115 (12):1229-1238.

4. Vasconcelos HC, Fernández-Pérez BM, González S, Souto RM, Santana JJ. Characterization of the corrosive action of mineral waters from thermal sources: a case study at Azores Archipelago, Portugal. Water. 2015; 7 (7): 3515-3530.

5. Reyes, A., Letelier, M., Delaiglesia, R., Gonzalez, B. Lagos, G. (2008). Microbiologically induced corrosion of copper pipes in low-pH water. International Biodeterioration and Biodegradation. 61, 135-141.

6. Ghareh Mahmoodlu, M., Jandaghi, N., Sayadi, M. Investigating the factors affecting corrosion and precipitation changes along Gorganroud River, Golestan Province, Environmental Science Quarterly. 2021; 19 (2): 71-90 [In Persian].

7. Fazel Valipour ME. Evaluation of underground water resources southwest of Qochan (Razavi Khorasan Province) for drinking and industrial purposes based on quality indicators. New Approaches in Civil Engineering. 2021; 5(3): 68-81. [In Persian].

8. Omeka ME, Egbueri JC, Unigwe CO. Investigating the hydrogeochemistry, corrosivity and scaling tendencies of groundwater in an agrarian area (Nigeria) using graphical, indexical and statistical modelling. Arabian Journal of Geosciences. 2022; 15 (13): p.1233.

9. Sarkar B, Islam A, Das BC, Nandy S. Corrosion and scaling potential of groundwater in Quaternary aquifers of Bengal Basin, India. Arabian Journal of Geosciences. 2022; 15 (12): p.1152.

10. Nabizadeh Nodehi R, Mesdaghinia AR, Nasseri S, Hadi M, Soleimani H, Bahmani P. Analysis of water corrosion tendency in water supply system using qualitative indices and calcium carbonate precipitation potential index. Iranian Journal of Health and Environment. 2017; 9 (4): 457-470. [In Persian]

11. Hoseinzadeh E, Yusefzadeh A, Rahimi N, Khorsandi H. Evaluation of corrosion and scaling potential of a water treatment plant. Archives of Hygiene Sciences. 2013; 2 (2): 41-47.

12. Raghimi M, Rahimi Chakdel A, Ghareh Mahmoodlu M, Shahpasandzadeh M, Khademi SM. The effects of geological factors on chemical quality of drinking water of Gorgan, Iran, Journal of Agricultural Sciences and Natural Resources. 2008; 15(1): 1-13. [In Persian]

13. Mazani H. Investigation of hydrogeochemistry and contamination of Gorgan aquifer. MSc Thesis, Gonbad Kavous University. 2022. [In Persian]

14. Ghezelsofloo E, Raghimi M, Mahmoodlu MG, Rahimi-Chakdel A, Khademi SMS. Saltwater intrusion in drinking water wells of Kordkuy, Iran: an integrated quantitative and graphical study. Environmental Earth Sciences. 2021; 80 (16): p.520.

15. Izanloo S, Ghareh Mahmoodlu M, Jandaghi N, Ghorbani Vaghei H. Evaluation of Saturated Hydraulic Conductivity Changes in Surface and Subsurface Layers of Loess Soils of East of Golestan Province, Applied Soil Research. 2022; 10(2): 103-119. [In Persian]

16. Durvey VS, Sharma LL, Saini VP, Sharma BK. Handbook on the Methodology of Water Quality Assessment. Rajasthan Agriculture University, India. 1991.

17. Bhat MA, Wani AS, Vijay K, Jyotirmaya S, Dinesh T, Sanswal R. An overview of the assessment of groundwater quality for irrigation. Journal of Agricultural Science and Food Research. 2018; 9 (1): 1-9.

18. You SH, Tseng DH, Guo GL. A case study on the wastewater reclamation and reuse in the semiconductor industry. Resources, Conservation and Recycling. 2001; 32: 73-81.

19. Marangou V S, Savvides K. First desalination plant in Cyprus-product water aggresivity and corrosion control. Desalination. 2001; 138 (1-3): 251-258.

دوره 17، شماره 61 - شماره پیاپی 61
مرداد 1403
صفحه 52-64

فایل ها

سابقه مقاله

هم رسانی

ارجاع به این مقاله

آمار

ارزیابی پتانسیل خورندگی و ترسیب در چاه‌های تامین کننده آب شرب شهر گرگان

Evaluation of the corrosiveness and precipitation potential in the drinking water supply wells of Gorgan city

مراجع

1. Faridirad F, Gholinezhad M. Investigating corrosion and scaling Indices of potable water in city of Pardis water treatment plant. Journal of Water & Wastewater Science and Engineering. 2021; 6(3): 16-24. [In Persian]

2. Refait P, Jeannin M, Sabot R, Antony H, Pineau S. (2015). Corrosion and cathodic protection of carbon steel in the tidal zone: Products, mechanisms and kinetics. Corrosion Science. 2021; 90: 375-382.

3. Palazzo A, van der Merwe J, Combrink G. The accuracy of calcium-carbonate-based saturation indices in predicting the corrosivity of hot brackish water towards mild steel. Journal of the Southern African Institute of Mining and Metallurgy. 2015; 115 (12):1229-1238.

4. Vasconcelos HC, Fernández-Pérez BM, González S, Souto RM, Santana JJ. Characterization of the corrosive action of mineral waters from thermal sources: a case study at Azores Archipelago, Portugal. Water. 2015; 7 (7): 3515-3530.

5. Reyes, A., Letelier, M., Delaiglesia, R., Gonzalez, B. Lagos, G. (2008). Microbiologically induced corrosion of copper pipes in low-pH water. International Biodeterioration and Biodegradation. 61, 135-141.

6. Ghareh Mahmoodlu, M., Jandaghi, N., Sayadi, M. Investigating the factors affecting corrosion and precipitation changes along Gorganroud River, Golestan Province, Environmental Science Quarterly. 2021; 19 (2): 71-90 [In Persian].

7. Fazel Valipour ME. Evaluation of underground water resources southwest of Qochan (Razavi Khorasan Province) for drinking and industrial purposes based on quality indicators. New Approaches in Civil Engineering. 2021; 5(3): 68-81. [In Persian].

8. Omeka ME, Egbueri JC, Unigwe CO. Investigating the hydrogeochemistry, corrosivity and scaling tendencies of groundwater in an agrarian area (Nigeria) using graphical, indexical and statistical modelling. Arabian Journal of Geosciences. 2022; 15 (13): p.1233.

9. Sarkar B, Islam A, Das BC, Nandy S. Corrosion and scaling potential of groundwater in Quaternary aquifers of Bengal Basin, India. Arabian Journal of Geosciences. 2022; 15 (12): p.1152.

10. Nabizadeh Nodehi R, Mesdaghinia AR, Nasseri S, Hadi M, Soleimani H, Bahmani P. Analysis of water corrosion tendency in water supply system using qualitative indices and calcium carbonate precipitation potential index. Iranian Journal of Health and Environment. 2017; 9 (4): 457-470. [In Persian]

11. Hoseinzadeh E, Yusefzadeh A, Rahimi N, Khorsandi H. Evaluation of corrosion and scaling potential of a water treatment plant. Archives of Hygiene Sciences. 2013; 2 (2): 41-47.

12. Raghimi M, Rahimi Chakdel A, Ghareh Mahmoodlu M, Shahpasandzadeh M, Khademi SM. The effects of geological factors on chemical quality of drinking water of Gorgan, Iran, Journal of Agricultural Sciences and Natural Resources. 2008; 15(1): 1-13. [In Persian]

13. Mazani H. Investigation of hydrogeochemistry and contamination of Gorgan aquifer. MSc Thesis, Gonbad Kavous University. 2022. [In Persian]

14. Ghezelsofloo E, Raghimi M, Mahmoodlu MG, Rahimi-Chakdel A, Khademi SMS. Saltwater intrusion in drinking water wells of Kordkuy, Iran: an integrated quantitative and graphical study. Environmental Earth Sciences. 2021; 80 (16): p.520.

15. Izanloo S, Ghareh Mahmoodlu M, Jandaghi N, Ghorbani Vaghei H. Evaluation of Saturated Hydraulic Conductivity Changes in Surface and Subsurface Layers of Loess Soils of East of Golestan Province, Applied Soil Research. 2022; 10(2): 103-119. [In Persian]

16. Durvey VS, Sharma LL, Saini VP, Sharma BK. Handbook on the Methodology of Water Quality Assessment. Rajasthan Agriculture University, India. 1991.

17. Bhat MA, Wani AS, Vijay K, Jyotirmaya S, Dinesh T, Sanswal R. An overview of the assessment of groundwater quality for irrigation. Journal of Agricultural Science and Food Research. 2018; 9 (1): 1-9.

18. You SH, Tseng DH, Guo GL. A case study on the wastewater reclamation and reuse in the semiconductor industry. Resources, Conservation and Recycling. 2001; 32: 73-81.

19. Marangou V S, Savvides K. First desalination plant in Cyprus-product water aggresivity and corrosion control. Desalination. 2001; 138 (1-3): 251-258.

دوره 17، شماره 61 - شماره پیاپی 61مرداد 1403صفحه 52-64

فایل ها

سابقه مقاله

هم رسانی

ارجاع به این مقاله

آمار

دوره 17، شماره 61 - شماره پیاپی 61
مرداد 1403
صفحه 52-64