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توسعۀ مدل پیوند آب، انرژی و غذا در سطح شبکههای آبیاری بر اساس شاخصهای کفایت و پایداری آب (مطالعۀ موردی شبکۀ آبیاری قزوین) | ||
| تحقیقات مهندسی سازه های آبیاری و زهکشی | ||
| مقاله 5، دوره 21، شماره 80، آذر 1399، صفحه 61-80 اصل مقاله (875.72 K) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.22092/idser.2020.343189.1432 | ||
| نویسندگان | ||
| الهام قربانی1؛ محمدجواد منعم* 2؛ مهسا واعظ تهرانی3 | ||
| 1دانش آموخته کارشناسی ارشد گروه مهندسی و مدیریت آب، دانشگاه تربیت مدرس، تهران، ایران. | ||
| 2استاد گروه مهندسی و مدیریت آب، دانشگاه تربیت مدرس، تهران، ایران. | ||
| 3رئیس گروه بهره برداری آب، معاونت راهبری و نظارت بر بهره برداری، شرکت مهندسی آب و فاضلاب کشور، تهران، ایران. | ||
| چکیده | ||
| آب، غذا و انرژی اصلی ترین منابع مورد نیاز برای توسعه جوامع هستند. دیدگاه نکسوس برمدیریت به هم پیوسته این منابع تاکید دارد. دیدگاه نکسوس با تمرکز بر سه منبع در سطح کلان حوضه به کار گرفته شده است، اما در شبکههای آبیاری بعنوان محدوده ای که ضمن مصرف انرژی، بیشترین مصرف آب و تولید غذا را دارد کمتر مورد توجه قرار گرفته است. روابط آب، انرژی و غذا در سطح شبکههای آبیاری پیچیده است. در این تحقیق از رویکرد دینامیک سیستمها برای بررسی ساختارهای موجود بین این منابع استفاده شده، و روابط علت و معلولی بین آنها بهصورت مدل مفهومی ارائه شده است. با توسعه مدل کمی، مدل نکسوس برای شبکه آبیاری قزوین با هدف ارتقاء بهرهوری و مطلوبیت که عبارت است از ترکیبی از شاخصهای کفایت و پایداری تحویل آب، تدوین شد. سناریوهایی در بخش آب، غذا و انرژی شامل، کاهش منابع آب سطحی، افزایش سطح زیر کشت، و افزایش مصرف انرژی مورد ارزیابی قرار گرفت. افزایش مصرف انرژی موجب افزایش تولید محصول شد اما اثرات مکانیزم های کنترلی، با تاخیر 4 ساله مشاهده شد. مطلوبیت آب نیز به میزان 7% بیشتر شده. افزایش سطح زیر کشت، تاثیر زیادی بر افزایش تولید محصول و مطلوبیت نداشته. کاهش منابع آب سطحی بیشترین تاثیر را در کاهش تولید محصول و مطلوبیت نسبت به ادامه وضع موجود داشته. حداکثرکاهش تولید محصول23% و مطلوبیت 32% بوده است. با توجه به تاثیر قابل توجه محدودیت منابع آب، توصیه می شود در رویکرد نکسوس سناریوهای مرتبط با مدیریت آب از اولویت بالاتری برخوردار باشند. | ||
| کلیدواژهها | ||
| سیستم دینامیک؛ شبکه آبیاری قزوین؛ نکسوس | ||
| عنوان مقاله [English] | ||
| Development of Water, Energy and Food Nexus Model in Irrigation Networks Based on Water Adequacy and Stability Indicators (Qazvin Irrigation Network Case Study) | ||
| نویسندگان [English] | ||
| Elham Ghorbani1؛ Mohammad Javad Monem2؛ Mahsa Vaez Tehrani3 | ||
| 1Department of Water Structures, Tarbiat Modares University, Tehran, Iran | ||
| 2Professor, Department of Water Engineering and Management, Faculty of Agriculture, Tarbiat Modares University, Tehran, Iran. | ||
| 3Department of Water Operation, Deputy of Guidance and Operation Supervision, Water & Wastewater Co. Tehran, Iran | ||
| چکیده [English] | ||
| Water, food and energy are the main resources needed for the development of societies. Recently, comprehensive management from Nexus' point of view has been examined and evaluated by focusing on these three sources at the macro, regional and basin levels. However Nexus approach has received less attention in irrigation networks, which consumes energy, and the most water, and produce the most food. (Mabhaudhi et al., 2018). International Commission of Irrigation and Drainage (ICID) announced the Nexus as one of the main topics for 2017 and 2018 congress. Some papers were presented with the focus on food security, energy consumption for ground water extraction, and climate change. As conclusion of both congress it is stated that even though the nexus approach is fast growing, however its application is very limited. Therefore Nexus knowledge and capacity building among stakeholders should be developed, and its application in development planning of irrigation networks should be considered (Hassan, et al. 2017 & Pandya, et al. 2018). Relationships of water, food, and energy at irrigation networks, due to the problems of each component, and their interactions are quite complex. In this study systems dynamics approach used to investigate existing structures between these sources, and causal relationship between different components is determined as a conceptual model. Subsequently, by development of quantified model, the Nexus model of Qazvin Irrigation Network from productivity, adequacy and sustainability of water delivery has been produced. Three scenarios regarding water, food and energy, including, reducing surface water resources, increasing cultivated area, and increasing energy consumption, were evaluated. System Dynamic approach enables us to consider the complex interactions between water, food and energy components in long term in irrigation networks, and examined the impact of different scenarios, to decide on more sustainable policies. In this approach by problem definition, and determination of the boundaries of the system, the dynamics of the system in form of casual loops are defined. Four archetypes are identified which are Limits to Growth, Shifting the Burden, Fixes that Fail, and Eroding Goals. Considering casual loops in water, food, and energy systems, the conceptual model of the Nexus in irrigation networks is developed. By collecting the required data from Ghazvin irrigation network the quantitative model is developed and verified using VENSIM model. The quantitative model is developed by defining mathematical relations between different components. The equations are defined in four subsystems including water demand and supply, food production, productivity, and water utility. In these relations, different information such as ground water extraction, surface water supply, required agricultural inputs, etc. are defined based on collected data in form of 10 year time series. Model verification is done by behavior investigation and boundary value test. The model estimated crop production, show good consistency with actual data with average error of 0.1%, and boundary value test show expected results. Therefore the verification results show appropriate performance of the model. Three scenarios for each resources (water, Food, and Energy) were examined which include, increasing energy consumption for ground water extraction, increasing cultivated area, and decreasing surface water. Testing three scenarios provide the following results: Continuation of the present condition, will led to increase of crop production up to 60% in early 10 years. However due to activation of controlling mechanisms it sharply decreases by 50% in 5 years. Water utility shows similar manner, initially 20% increase, and 10% decrease afterward. Increasing energy consumption and ground water extraction causes crop production increase in almost all the simulation period with lower variations. Four years delay in impact of controlling mechanism is visible. Water utility has been increased as well, and it is 7% more at the end of simulation period. Due to limited potentials of increasing cropped area, this scenario performs similar to continuation of present condition, with marginal improvement in crop production and water utility. Decreasing surface water has the greatest impact in decreasing crop production and water utility, with respect to continuation of present condition. The maximum decrease in crop production and water utility are 23%, and 32% respectively. Even though due to activation of balancing mechanisms crop production shows 60% increase, however it happens with 5 year delay and decreases sharply afterward. Considering limited water resources, and its greatest impact on crop production and water utility, it could be suggested that water management policies, take higher priority in Nexus approach. As a general conclusion it could be stated that, system dynamic is a suitable method to implement Nexus approach in irrigation networks, and to investigate the long term impact of different scenarios, to select more sustainable policies for irrigation development. | ||
| کلیدواژهها [English] | ||
| Nexus, Dynamic system, Qazvin Irrigation and Drainage Network | ||
| مراجع | ||
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Artioli. F. Acuto. M. & McArthur. J. (2017). The water-energy-food nexus: An integration agenda and implications for urban governance. Political Geography 61, 215-223 Braun. W. (2002). The system archetypes. The Systems Modeling Workbook.26P Chang. Y. Li. G. Yao. Y. & Zhang, L. (2016). Quantifying the water-energy-food nexus: current status and trends. Energies, 9(2), 1-17 El-Gafy. I. Grigg. N. & Reagan. w. (2016). Dynamic Behaviour of The Water–Food–Energy Nexus: Focus On Crop Production And Consumption. Jour. of Irrig. & Drain, 66, 19–33 FAO Publication No. 58. (2014). Walking the Nexus Talk: Assessing the Water-Energy-Food Nexus in the Context of the Sustainable Energy for All Initiative. July 2014. PP. 147 Fernandez Garcia. I. & Merida Garcia. A. (2018). Water Energy Nexus in Irrigated Areas. Lessons from Real Case Studies. Research Report University of Cordoba. Cordoba. Spain Hassan. G. Hassan. F. & Ghulam. S. (2017). Food Security Challenges under Climatic Changes and Groundwater-Energy, Nexus- Case Study of Punjab Pakistan. Modernizing Irrigation and Drainage for a new Green Revolution. Transactions of the 23rd ICID Congress on Irrigation and Drainage – Abstract Volume: Question 60 and 61. 418 pp. ISBN: 978-81-89610-24-1 Hatam. A. Monem. M. J. & Bagheri. A. (2012). Development of Dynamic Model of Irrigation Network Improvement System with Consideration of Farmers' Participation and Improving Network Management. Journal of Agricultural Engineering Research, 4(13), 1-24 (In Persian) Hosseinzade. z. Pagsuyoin. S. H. Ponnambalam. k. & Monem. M. J. (2017). Decision-making in irrigation networks: Selecting appropriate canal structures using multi-attribute decision analysis, Jour. Of Science of the Total Environmen, 177-185 Kitani, O. Jungbluth. T. Peart. R. M. & Ramdani. A. (1999). CIGR Handbook of AgriculturalEngineering. 5: Energy and Biomass Engineering. ASAE. Pub.351P Mabhaudhi. T. Sylvester. M. Dhesigen. N. Luxon. N. & Aiden. S. (2018). Integrating the Water – Energy – Food nexus into National Irrigation Planning: South African Perspectives, 24th International Congress on Irrigation and Drainage ICID. Saskatoon, Canada Monem. M. J. Delavar. M. & Hosseini. M. (2020). Application and Evaluation of Water, Food and Energy (NEXUS) in Irrigation Networks Management: Case Study of Zayandehrud Irrigation Network, Iranian Jour. of Irrigation & Drainage,14, 276-285. (In Persian) Pandya. A. B. Varma. H. K. Singh. S. Mohanan. M. (2018). Report of the 23rd International Congress on Irrigation and Drainage. Mexico City, Mexico, 8-14 October 2017, International Commission on Irrigation and Drainage (ICID), ISBN: 978-81-89610-26-5, PP. 72. Ravar. Z. Zahraie. B. Sharifinejad. A. Gozini. H. & Jafari. S. (2020). System Dynamics Modeling for Assessment of Water- Food- Energy Resources Security and Nexus in Gavkhuni Basin in Iran, Jour. of Ecological Indicators,108,1-18. Shabani. S. Monem. M. J. & Bagheri. A. (2014). System Dynamics Model for Foomanat Irrigation Network, from Adequacy and Equity Point of view, Iranian Jour. of Irrigation and Drainage, 8(4),836-826 (In Persian) Smajgl. A. Ward. J. & Pluschke. L. (2016). The water-food-energy Nexus e realizing a new paradigm. Journal of Hydrology,533, 533-540 Vaez Tehrani. M. Monem. M. J. & Bagheri. A. (2013). A system dynamics approach to model rehabilitation of irrigation networks case study: Qazvin irrigation network, Iranian Jour. of Irrigation and Drainage, 62, 193–207 (In Persian) Xu. Y. & Szmerekovsky. J. (2017). System dynamic modeling of energy savings in the US food industry. Journal of Cleaner Production, 165, 13-26. | ||
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