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Entegre Kentsel Su Yönetimi, Kentsel Su Güvenliği ve Değerlendirme Yöntemi Üzerine Bir Çalışma

Yıl 2022, , 282 - 295, 31.08.2022
https://doi.org/10.31590/ejosat.1104414

Öz

Günümüzde birçok kent su kaynağı ve yönetimi açısından önemli güçlükler ile karşı karşıyadır. Entegre Kentsel Su Yönetimi, sürdürülebilir ekonomik, sosyal ve çevresel amaçlara ulaşabilmek için kentsel gelişme ile havza yönetimini aynı eksende ele almayı gerektirir. Arazi kullanım planlaması ve ekonomik kalkınma, su temini, sanitasyon, yağmur suyu ve atık su yönetim konularıyla birlikte bir bütün olarak ele alınmalıdır. Entegre Kentsel Su Yönetim yaklaşımı, kamuoyu oluşturma ve siyasi karar alma süreçlerinde bölünme veya tekrardan sakınmak için su sektörünü planlarken arazi, konut, enerji ve ulaşım gibi diğer kentsel sektörleri de bütünleştirmelidir. Birçok ülkede kentsel su güvenliğini sağlamak oldukça zordur. Az sayıdaki çalışma, su güvenliğini bölgesel düzeyde değerlendirirken, birçok çalışma, kentsel düzeyde başarılı olmak amacıyla ölçümlerin uygulanması ve su güvenliğini değerlendirmenin eksikliğini vurgulamıştır. Kentsel su güvenliğini ölçmeye odaklanan çalışmalar bütünsel olmayıp, su güvenliğinin mevcut durumunu ve dinamiklerini ölçmek için bir değerlendirme çerçevesinin nasıl tanımlanacağı ve kullanılacağı konusunda hala fikir birliğine varılamamıştır. Günümüzde, kentsel su güvenliğinin açıkça tanımlanmış ve geniş çapta onaylanmış bir tanımı da yoktur. Bu zorluğun üstesinden gelmeyi amaçlayan bu çalışma, kent yerleşimi ve kentsel alanlarda uygulanabilecek bir değerlendirme çerçevesi ve kentsel su güvenliğini daha iyi anlamak için sistematik bir iş tanımlaması sağlayacaktır. Kentsel su güvenliğinin önerilen iş tanımı Birleşmiş Milletler'in su ve sanitasyonla ilgili sürdürülebilir kalkınma hedefine ve insan haklarına dayanmaktadır. Kentsel su güvenliğini sağlamak için kullanılan değerlendirme çerçevesi, içme suyu ve insanlar, ekosistem, iklim değişikliği ve suyla ilgili tehlikeler ve sosyo ekonomik faktörleri temel almaktadır. Bu çerçeveyi uygulamak hükümetlere, politikacılara ve su paydaşlarına kıt kaynakları daha etkili ve sürdürülebilir bir hedefleme konusunda yardımcı olacaktır.

Kaynakça

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  • Aboelnga, H., Saidan, M., Al-Weshah, R., Sturm, M., Ribbe, L., Frechen, F. (2018). Component analysis for optimal leakage management in Madaba, Jordan. J. Water Supply Res. Technol. Aqua. 67, 384-396.
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  • Al-Saidi, M., Elagib, N.A. (2017). Towards understanding the integrative approach of the water, energy and food nexus. Sci. Total Environ. 574, 1131-1139. Arcadis. (2015). Sustainable Cities Water Index: Which Cities Are the Best Placed to Harness Water for Future Success? Arcadis: Amsterdam, The Netherlands.
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  • Bakker, K. (2012). Water security: Research challenges and opportunities. Science, 337, 914–915.
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  • Berg, S., Marques, R.C. (2011). Quantitative studies of water and sanitation utilities: A benchmarking literature survey. Water Policy, 13, 591–606.
  • Biswas, A.K. (2004). Integrated water resources management: A reassessment. Water Int. 29, 248-256.
  • Brown, R.R., Keath, N., Wong, T.H.F. (2009). Urban water management in cities: Historical, current and future regimes. Water Sci. Technol. 59, 847–855.
  • Cairns, R., Krzywoszynska, A. (2016). Anatomy of a buzzword: The emergence of ‘the water-energy-food nexus’ in UK natural resource debates. Environ. Sci. Policy, 64, 164-170.
  • Chad, S., Christopher, A.S. (2018). Putting water security to work: Addressing global challenges. Water Int. 43, 1017–1025.
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A Study on Evaluation Method and Urban Water Security, Integrated Urban Water Management

Yıl 2022, , 282 - 295, 31.08.2022
https://doi.org/10.31590/ejosat.1104414

Öz

Today, many cities are faced with significant difficulties in terms of water supply and management. Integrated Urban Water Management requires addressing together urban development and watershed management in order to achieve sustainable economic, social and environmental objectives. All of the water supply, sanitation, rainwater and wastewater management issues should be considered as a whole with land use planning and economic development. The purpose of an Integrated Urban Water Management approach is to integrate with other urban sectors such as land, housing, energy and transport with planning water sector in order to avoid fragmentation or recurrence in the process of policy making and decision making. In many countries, it is very difficult to ensure urban water security. While few studies have assessed water security at the regional level, many have highlighted the lack of assessment of water security and implementation of measures in order to be successful at the urban level. Studies focused on measuring urban water security are not holistic, and there is still no consensus on how to define and use an assessment framework to measure the current state and dynamics of water security. Currently, there is no clearly defined and widely approved definition of urban water security. this study, aiming to cope with this challenge, will provide an assessment framework applicable to urban settlement and urban areas, and a systematic work description to better understand urban water security. The proposed work description of urban water security is based on the United Nations' sustainable development goal regarding water and sanitation, and human rights. The assessment framework used to ensure urban water security is based on drinking water and people, ecosystem, climate change and water-related hazards and socio-economic factors. Implementing this framework will help governments, politicians and water stakeholders target at scarce resources more effectively and sustainably.

Kaynakça

  • Aboelnga, H., Khalifa, M., McNamara, I., Ribbe, L., Sycz, J. (2018). The Water-Energy-Food Security Nexus: A Review of Nexus Literature and Ongoing Nexus Initiative for Policymakers; Nexus Regional Dialogue Programme (NRD): Bonn, Germany, pp. 25–30.
  • Aboelnga, H., Saidan, M., Al-Weshah, R., Sturm, M., Ribbe, L., Frechen, F. (2018). Component analysis for optimal leakage management in Madaba, Jordan. J. Water Supply Res. Technol. Aqua. 67, 384-396.
  • Aboelnga, H., Ribbe, L., Frechen, F., Saghir, J. (2019). Urban Water Security: Definition and Assessment Framework. Resources, 8, 178, 1-19
  • ADB (Asian Development Bank) (2011). Rapid Urbanization and the Growing Demand for Ur¬ban Infrastructure in Africa. African Development Bank Market Brief. Vol. 1, Issue 1, pp. 1-12.
  • ADB (Asian Development Bank) (2013). Asia Water Development Outlook 2013; ADB: Manila, Philippines.
  • ADB (Asian Development Bank). (2016). Asian Water Development Outlook 2016: Strengthening Water Security in Asia and the Pacific; Asian Development Bank: Mandaluyong City, Philippines.
  • Allan, J.V., Kenway, S.J., Head, B.W. (2018). Urban water security-what does it mean? Urban Water J. 2018, 15, 899-910.
  • Al-Saidi, M., Elagib, N.A. (2017). Towards understanding the integrative approach of the water, energy and food nexus. Sci. Total Environ. 574, 1131-1139. Arcadis. (2015). Sustainable Cities Water Index: Which Cities Are the Best Placed to Harness Water for Future Success? Arcadis: Amsterdam, The Netherlands.
  • Arfanuzzaman, M., Rahman, A.A. (2017). Sustainable water demand management in the face of rapid urbanization and ground water depletion for social–ecological resilience building. Glob. Ecol. Conserv. 10, 9–22.
  • Artioli, F., Acuto, M., McArthur, J. (2017). The water-energy-food nexus: An integration agenda and implications for urban governance. Polit. Geogr. 61, 215–223.
  • Assefa, Y., Babel, M., Sušnik, J., Shinde, V. (2018). Development of a generic domestic water security index, and its application in Addis Ababa, Ethiopia. Water, 11, 37.
  • Bakker, K. (2012). Water security: Research challenges and opportunities. Science, 337, 914–915.
  • Bates, P.D., Horritt, M.S and Fewtrell, T.J. (2010). A Simple International Formulation of the Shallow Water Equations for Efficient Two Dimensional Flood Inundation Modeling. Journal of Hydrology, 387: 33-45
  • Berg, S. (2000). Developments in best-practice regulation: Principles, processes, and performance. Electr. J. 13, 11-18.
  • Berg, S., Marques, R.C. (2011). Quantitative studies of water and sanitation utilities: A benchmarking literature survey. Water Policy, 13, 591–606.
  • Biswas, A.K. (2004). Integrated water resources management: A reassessment. Water Int. 29, 248-256.
  • Brown, R.R., Keath, N., Wong, T.H.F. (2009). Urban water management in cities: Historical, current and future regimes. Water Sci. Technol. 59, 847–855.
  • Cairns, R., Krzywoszynska, A. (2016). Anatomy of a buzzword: The emergence of ‘the water-energy-food nexus’ in UK natural resource debates. Environ. Sci. Policy, 64, 164-170.
  • Chad, S., Christopher, A.S. (2018). Putting water security to work: Addressing global challenges. Water Int. 43, 1017–1025.
  • Charalambous, B., Laspidou, C. (2017). Dealing with the Complex Interrelation of Intermittent Supply and Water Losses; IWA Publishing: London, UK. pp. 22-28.
  • Choe, K., Varley, R., Bilani, H. (1996). Coping with Intermittent Water Supply: Problems and Prospects, Environmental Health Project; Activity Report No. 26.; USAID:Washington, DC, USA.
  • Clement, F. (2013). From water productivity to water security: A paradigm shift. In Water Security Principles, Perspectives and Practices; Lankford, B.A., Ed.; Routledge: Abingdon, UK, pp. 148-165.
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  • Komnenic, V., Ahlers, R., Van Der Zaag, P. (2009). Assessing the usefulness of the water poverty index by applying it to a special case: Can one be water poor with high levels of access? Phys. Chem. Earth Parts A B C, 34, 219–224.
  • Koop, S.H., van Leeuwen, C.J. (2015). Application of the improved city blueprint framework in 45 municipalities and regions. Water Resour. Manag. 29, 4629-4647.
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  • Lawrence, P.R., Meigh, J., Sullivan, C. (2002). The Water Poverty Index: An International Comparison; Department of Economics, Keele University: Keele, UK.
  • LeChevallier, M., Gullick, R., Karim, M., Friedman, M., Funk, J. (2003). The potential for health risks from intrusion of contaminants into the distribution system from pressure transients. J.Water Health. 1, 3–14.
  • Maheshwari, B., Singh, V., Thoradeniya, B. (2016). Balanced Urban Development: Options and Strategies for Liveable Cities; Springer: Berlin, Germany.
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  • Mara, D., Kramer, A. (2006). The 2006 WHO Guidelines for Wastewater and Greywater Use in Agriculture: A Practical Interpretation; WHO: Geneva, Switzerland.
  • Mekonnen, M.M., Hoekstra, A.Y. (2016). Four billion people facing severe water scarcity. Sci. Adv. 2, e1500323.
  • Nazif, S., Karamouz, M., Yousefi, M., Zahmatkesh, Z. (2013). Increasing water security: An algorithm to improve water distribution performance. Water Resour. Manag. 27, 2903-2921.
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  • Vorosmarty, C.J., McIntyre, P.B., Gessner, M.O., Dudgeon, D., Prusevich, A., Green, P., Glidden, S., Bunn, S.E., Sullivan, C.A., Liermann, C.R., et al. (2010). Global threats to human water security and river biodiversity. Nature 2010, 467, 555–561.
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Toplam 103 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Cengiz Koç 0000-0001-7310-073X

Yayımlanma Tarihi 31 Ağustos 2022
Yayımlandığı Sayı Yıl 2022

Kaynak Göster

APA Koç, C. (2022). Entegre Kentsel Su Yönetimi, Kentsel Su Güvenliği ve Değerlendirme Yöntemi Üzerine Bir Çalışma. Avrupa Bilim Ve Teknoloji Dergisi(38), 282-295. https://doi.org/10.31590/ejosat.1104414