Evaluation of Applied Water in the Farms and Gardens Equipped with the Smart Water Meters in Arsenjan Plain, Fars province

Shahrokhnia, Mohammad Ali; Eslami, Amir; Jokar, Akbar

doi:10.30495/wej.2021.26605.2280

Evaluation of Applied Water in the Farms and Gardens Equipped with the Smart Water Meters in Arsenjan Plain, Fars province

Document Type : Research Paper

Authors

¹ Associate Professor, Agricultural Engineering Research Department, Fars Agricultural and Natural Resources Research and Education Center, Agricultural Research, Education and Extension Organization (AREEO), Shiraz, Iran.

² Assistant Professor, Agricultural Engineering Research Department, Fars Agricultural and Natural Resources Research and Education Center, Agricultural Research, Education and Extension Organization (AREEO), Shiraz, Iran.

10.30495/wej.2021.26605.2280

Abstract

Abstract
Introduction: Volumetric delivery of water by installing smart water meters on the agricultural wells could be an effective action for proper use of water and increase the water productivity. In recent years, the smart water meters were used at Arsenjan plain in Fars province for volumetric water delivery.
Methods: In this study, the applied water and the water productivity in some of the Arsenjan plain farms and gardens were evaluated. Twelve farms were selected for each of the three products; winter wheat, tomato and pomegranate. Well discharge, crop yield, volume of applied water was measured using smart meters. The actual values were also measured. The values of irrigation water productivity and total water productivity was calculated. The differences between applied water and some water requirement scenarios were compared using t-test.
Findings: Results showed that the values of applied water and discharge in the smart meters were 21 and 25 percent less than the actual measured values, respectively. Therefore, the performance accuracy of the studied smart water meters was low. The average irrigation water productivity of wheat, tomato and pomegranate was 0.93, 7.75 and 1.44 kg/m3, respectively. The average applied water in the studied farms and gardens were 43 percent more than the required values estimated by Penman-Montieth method. Finally, it was suggested that in order to improve the performance of smart meters, the calibration of these meters should be considered more carefully.

Keywords

20.1001.1.20086377.1401.15.53.2.5

References

1. Baum, M.C., Dukes, M.D., Haman, D.Z. 2015. Selection and use of water meters for irrigation water measurement. ABE18, IFAS Extension, University of Florida.

2. Bjorneberg, D.L. 2013. Irrigation methods. USDA Agricultural Research Service, Kimberly, ID, USA.

3. EDCFP. 2014. Investigating the status of water and electricity smart meters. Fars Province Electricity Distribution Company of Fars Province. No. 2094/5126. [In Persian]

4. Gupta, A.D., Pandey, P., Feijoo, A., Yaseen, Z.M., and Bokde, N.D. 2020. Smart water technology for efficient water resource management: a review. Energies, 13, 6268; doi:10.3390/en13236268.

5. Haghayeghi-Moghadam, S.A. 2014. The effect of installing smart meters in reducing water and energy consumption of agricultural wells. Technical report, Agricultural Engineering Research Institute. [In Persian]

6. Hanson, B.R., Schwankl, L.J., and Prichard, L. 2007. Measuring irrigation flows in a pipeline. University of California, Division of agriculture and natural resources, publication 8213.

7. Jahromi, H.N., Hamedani, M.J., Dolatabadi, S.F., Abbasi, P. 2014. Smart energy and water meter: a novel vision to groundwater monitoring and management. Procedia Engineering, 70, 877-881.

8. Mohammadi, B., Rezaei, A., and Sohail, H. 2013. Investigating the impact of using smart water and electricity meters on the energy consumption of agricultural customers. Second Sired Regional Conference, December 2013, Tehran, Iran. [In Persian].

9. Naseri, H.A. 2015. Analytical report on the performance of water and electricity smart meters installed in Darab and Arsanjan plains. Regional Water Company of Fars Province, Shiraz, Iran. [In Persian].

10. Ouvrard, B., Préget, R., Reynaud, A., Tuffery, L. 2020. Nudging and subsidizing farmers to foster smart water meter adoption. hal-02958784.

11. Qobadpour, R., Eskandari, F., and Jalali, M. 2018. Farmers’ satisfaction from installing intelligent flowmeter on underground water wells (The case of Mahidasht county, Kermanshah Province). Journal of Agricultural Economics and Development, 32(1): 43-55. [In Persian].

12. RSAC. 2016. Report on the implementation of the project of equipping electric wells in the country with smart water and electricity meters to deliver water volume to the users. Rahrwan Sepehr Andisheh Company, Tehran, Iran. [In Persian]

13. Rajabpour, H., Golzarnjad, M.R. and Ismaili, A. 2010. Smart meter of water and electricity, a solution for change in the amount of withdrawal from underground water. Proceedings of the first national conference to review the achievements of Iranian earth science researchers, 8-9 Khordad 89, Tehran, Iran. [In Persian].

14. Randall, T., and Koech, R. 2019. Smart water metering technology for water management in urban areas (analysing water consumption patterns to optimize water conservation). Water e-journal, online journal of the Australian Water Association, 4, 1, doi:10.21139/wej.2019.001.

15. RWCFP. 2016. Water resources database, Regional Water Company of Fars Province. Shiraz, Iran. [In Persian].

16. Richardson, W.B., Boethel, D.J., and Coreil, P.D. 2008. Irrigation flow measurement. Louisiana State University Agricultural Center, Pub. #3082.

17. Sheffield, R.E., Henry, C.G., Bankston, D., Hadden, W.A. 2013. Measuring irrigation flow. Louisiana State University Agricultural Center, Pub. 3241-L.

18. Sood, R., Kaur, M., and Lenka, H. 2013. Design and development of automatic water flow meter. International Journal of Computer Science, Engineering and Applications, 3(3), 49-59.

19. Styles, S. and Groundwater, L. 2012. Implementation of magnetic meter for irrigation volumetric measurement. ITRC paper No. P 12-006, presented at World Environmental and Water Resources Congress, May 20-24, 2012, Albuquerque, NM.

20. Tsay R.S. 2005. Analysis of financial time series, John Wiley & Sons.

21. van Zyl., J. 2011. Introduction to integrated water meter management. Edition 1, Water Research Commission, Republic of South America.

22. Wahl, T.L. and Magallanez, H. 2014. Low-cost pipeline flow meter. U.S. Department of the Interior, Bureau of Reclamation, Water Resources Research Laboratory, Denver, Colorado.

23. Yazdani, M. 2013. investigating the effect of using smart water and electricity meters on improving the hydrograph of the underground water level in Esfarain Plain. 7th National Congress of Civil Engineering, University of Sistan and Baluchistan, Zahedan, Iran. [In Persian].

Evaluation of Applied Water in the Farms and Gardens Equipped with the Smart Water Meters in Arsenjan Plain, Fars province

References

1. Baum, M.C., Dukes, M.D., Haman, D.Z. 2015. Selection and use of water meters for irrigation water measurement. ABE18, IFAS Extension, University of Florida.

2. Bjorneberg, D.L. 2013. Irrigation methods. USDA Agricultural Research Service, Kimberly, ID, USA.

3. EDCFP. 2014. Investigating the status of water and electricity smart meters. Fars Province Electricity Distribution Company of Fars Province. No. 2094/5126. [In Persian]

4. Gupta, A.D., Pandey, P., Feijoo, A., Yaseen, Z.M., and Bokde, N.D. 2020. Smart water technology for efficient water resource management: a review. Energies, 13, 6268; doi:10.3390/en13236268.

5. Haghayeghi-Moghadam, S.A. 2014. The effect of installing smart meters in reducing water and energy consumption of agricultural wells. Technical report, Agricultural Engineering Research Institute. [In Persian]

6. Hanson, B.R., Schwankl, L.J., and Prichard, L. 2007. Measuring irrigation flows in a pipeline. University of California, Division of agriculture and natural resources, publication 8213.

7. Jahromi, H.N., Hamedani, M.J., Dolatabadi, S.F., Abbasi, P. 2014. Smart energy and water meter: a novel vision to groundwater monitoring and management. Procedia Engineering, 70, 877-881.

8. Mohammadi, B., Rezaei, A., and Sohail, H. 2013. Investigating the impact of using smart water and electricity meters on the energy consumption of agricultural customers. Second Sired Regional Conference, December 2013, Tehran, Iran. [In Persian].

9. Naseri, H.A. 2015. Analytical report on the performance of water and electricity smart meters installed in Darab and Arsanjan plains. Regional Water Company of Fars Province, Shiraz, Iran. [In Persian].

10. Ouvrard, B., Préget, R., Reynaud, A., Tuffery, L. 2020. Nudging and subsidizing farmers to foster smart water meter adoption. hal-02958784.

11. Qobadpour, R., Eskandari, F., and Jalali, M. 2018. Farmers’ satisfaction from installing intelligent flowmeter on underground water wells (The case of Mahidasht county, Kermanshah Province). Journal of Agricultural Economics and Development, 32(1): 43-55. [In Persian].

12. RSAC. 2016. Report on the implementation of the project of equipping electric wells in the country with smart water and electricity meters to deliver water volume to the users. Rahrwan Sepehr Andisheh Company, Tehran, Iran. [In Persian]

14. Randall, T., and Koech, R. 2019. Smart water metering technology for water management in urban areas (analysing water consumption patterns to optimize water conservation). Water e-journal, online journal of the Australian Water Association, 4, 1, doi:10.21139/wej.2019.001.

15. RWCFP. 2016. Water resources database, Regional Water Company of Fars Province. Shiraz, Iran. [In Persian].

16. Richardson, W.B., Boethel, D.J., and Coreil, P.D. 2008. Irrigation flow measurement. Louisiana State University Agricultural Center, Pub. #3082.

17. Sheffield, R.E., Henry, C.G., Bankston, D., Hadden, W.A. 2013. Measuring irrigation flow. Louisiana State University Agricultural Center, Pub. 3241-L.

18. Sood, R., Kaur, M., and Lenka, H. 2013. Design and development of automatic water flow meter. International Journal of Computer Science, Engineering and Applications, 3(3), 49-59.

19. Styles, S. and Groundwater, L. 2012. Implementation of magnetic meter for irrigation volumetric measurement. ITRC paper No. P 12-006, presented at World Environmental and Water Resources Congress, May 20-24, 2012, Albuquerque, NM.

20. Tsay R.S. 2005. Analysis of financial time series, John Wiley & Sons.

21. van Zyl., J. 2011. Introduction to integrated water meter management. Edition 1, Water Research Commission, Republic of South America.

22. Wahl, T.L. and Magallanez, H. 2014. Low-cost pipeline flow meter. U.S. Department of the Interior, Bureau of Reclamation, Water Resources Research Laboratory, Denver, Colorado.

23. Yazdani, M. 2013. investigating the effect of using smart water and electricity meters on improving the hydrograph of the underground water level in Esfarain Plain. 7th National Congress of Civil Engineering, University of Sistan and Baluchistan, Zahedan, Iran. [In Persian].

Volume 15, Issue 53 - Serial Number 53
August 2022
Pages 13-28

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Evaluation of Applied Water in the Farms and Gardens Equipped with the Smart Water Meters in Arsenjan Plain, Fars province

References

1. Baum, M.C., Dukes, M.D., Haman, D.Z. 2015. Selection and use of water meters for irrigation water measurement. ABE18, IFAS Extension, University of Florida.

2. Bjorneberg, D.L. 2013. Irrigation methods. USDA Agricultural Research Service, Kimberly, ID, USA.

3. EDCFP. 2014. Investigating the status of water and electricity smart meters. Fars Province Electricity Distribution Company of Fars Province. No. 2094/5126. [In Persian]

4. Gupta, A.D., Pandey, P., Feijoo, A., Yaseen, Z.M., and Bokde, N.D. 2020. Smart water technology for efficient water resource management: a review. Energies, 13, 6268; doi:10.3390/en13236268.

5. Haghayeghi-Moghadam, S.A. 2014. The effect of installing smart meters in reducing water and energy consumption of agricultural wells. Technical report, Agricultural Engineering Research Institute. [In Persian]

6. Hanson, B.R., Schwankl, L.J., and Prichard, L. 2007. Measuring irrigation flows in a pipeline. University of California, Division of agriculture and natural resources, publication 8213.

7. Jahromi, H.N., Hamedani, M.J., Dolatabadi, S.F., Abbasi, P. 2014. Smart energy and water meter: a novel vision to groundwater monitoring and management. Procedia Engineering, 70, 877-881.

8. Mohammadi, B., Rezaei, A., and Sohail, H. 2013. Investigating the impact of using smart water and electricity meters on the energy consumption of agricultural customers. Second Sired Regional Conference, December 2013, Tehran, Iran. [In Persian].

9. Naseri, H.A. 2015. Analytical report on the performance of water and electricity smart meters installed in Darab and Arsanjan plains. Regional Water Company of Fars Province, Shiraz, Iran. [In Persian].

10. Ouvrard, B., Préget, R., Reynaud, A., Tuffery, L. 2020. Nudging and subsidizing farmers to foster smart water meter adoption. hal-02958784.

11. Qobadpour, R., Eskandari, F., and Jalali, M. 2018. Farmers’ satisfaction from installing intelligent flowmeter on underground water wells (The case of Mahidasht county, Kermanshah Province). Journal of Agricultural Economics and Development, 32(1): 43-55. [In Persian].

12. RSAC. 2016. Report on the implementation of the project of equipping electric wells in the country with smart water and electricity meters to deliver water volume to the users. Rahrwan Sepehr Andisheh Company, Tehran, Iran. [In Persian]

14. Randall, T., and Koech, R. 2019. Smart water metering technology for water management in urban areas (analysing water consumption patterns to optimize water conservation). Water e-journal, online journal of the Australian Water Association, 4, 1, doi:10.21139/wej.2019.001.

15. RWCFP. 2016. Water resources database, Regional Water Company of Fars Province. Shiraz, Iran. [In Persian].

16. Richardson, W.B., Boethel, D.J., and Coreil, P.D. 2008. Irrigation flow measurement. Louisiana State University Agricultural Center, Pub. #3082.

17. Sheffield, R.E., Henry, C.G., Bankston, D., Hadden, W.A. 2013. Measuring irrigation flow. Louisiana State University Agricultural Center, Pub. 3241-L.

18. Sood, R., Kaur, M., and Lenka, H. 2013. Design and development of automatic water flow meter. International Journal of Computer Science, Engineering and Applications, 3(3), 49-59.

19. Styles, S. and Groundwater, L. 2012. Implementation of magnetic meter for irrigation volumetric measurement. ITRC paper No. P 12-006, presented at World Environmental and Water Resources Congress, May 20-24, 2012, Albuquerque, NM.

20. Tsay R.S. 2005. Analysis of financial time series, John Wiley & Sons.

21. van Zyl., J. 2011. Introduction to integrated water meter management. Edition 1, Water Research Commission, Republic of South America.

22. Wahl, T.L. and Magallanez, H. 2014. Low-cost pipeline flow meter. U.S. Department of the Interior, Bureau of Reclamation, Water Resources Research Laboratory, Denver, Colorado.

23. Yazdani, M. 2013. investigating the effect of using smart water and electricity meters on improving the hydrograph of the underground water level in Esfarain Plain. 7th National Congress of Civil Engineering, University of Sistan and Baluchistan, Zahedan, Iran. [In Persian].

Volume 15, Issue 53 - Serial Number 53August 2022Pages 13-28

Files

History

Share

How to cite

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Volume 15, Issue 53 - Serial Number 53
August 2022
Pages 13-28