Difference between revisions of "Resilient WASH systems in drought-prone areas"

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(Non-technical measures)
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[[Image:carelogo.png|thumb|right|150px|This section is based on a desk study written by Eric Fewster, commissioned by CARE Netherlands and the Netherlands Red Cross]]
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[[Image:carelogo.png|thumb|right|150px|This section is based on a desk study written by [http://www.linkedin.com/pub/eric-fewster/4/333/a90 Eric Fewster], commissioned by [http://www.carenederland.org/ CARE Netherlands] and the [http://www.rodekruis.nl/paginas/home.aspx Netherlands Red Cross]]]
  
 
Resilient WASH systems need to be able to cope with changes in the availability of water. This section explores which techniques can be used to improve water availability over space and time in areas not only prone to drought and changing climate variability, but also those areas with deteriorating water availability due to increasing water demands and human influences. The focus is on water supply and non-motorized irrigation in rural areas for populations of up to 5,000 people. Resilience is a concept used to describe how to make water systems more robust in terms of water availability, thereby reducing the vulnerability of people that rely on them.
 
Resilient WASH systems need to be able to cope with changes in the availability of water. This section explores which techniques can be used to improve water availability over space and time in areas not only prone to drought and changing climate variability, but also those areas with deteriorating water availability due to increasing water demands and human influences. The focus is on water supply and non-motorized irrigation in rural areas for populations of up to 5,000 people. Resilience is a concept used to describe how to make water systems more robust in terms of water availability, thereby reducing the vulnerability of people that rely on them.
  
====Primary focus====
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====Main content====
*[[Drought resilience - General issues|General issues]]
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*[[Impact of drought on WASH systems]] - Includes world maps on the locations of  water stress, scarcity, and historical drought.
*[[Drought resilience - Technical solutions|Technical solutions]]
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*[[Drought and links to other disasters]] - How drought is linked to other major disasters such as poverty, inequality, and conflict.
*[[Drought cycle management]]
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*[[Drought resilience - General issues|Drought resilience, non-technical solutions]] - Non-technical ways to make water systems more resilient, such as financial, institutional, environmental and social measures.
*[[Framework for evaluation of projects in drought-prone areas]]
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*[[Drought resilience - Technical solutions| Drought resilience, technical solutions]] - Technical solutions to make water systems more resilient.
 
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*[[Drought cycle management]] - Four stages of drought management: normal, alert, emergency, recovery.
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*[[Framework for evaluation of projects in drought-prone areas]] - a set of questions to help evaluate projects.
  
 
Both technical '''and''' non-technical components are important in discussing how to make water systems resilient. In many cases, it is not technical issues which cause projects to become unsustainable, but non-technical issues such as management, social relationships and community dynamics. A useful model to use is the [[FIETS sustainability principles| FIETS model]], which covers five dimensions of sustainability: Financial, Institutional, Environmental, Technical, and Social.
 
Both technical '''and''' non-technical components are important in discussing how to make water systems resilient. In many cases, it is not technical issues which cause projects to become unsustainable, but non-technical issues such as management, social relationships and community dynamics. A useful model to use is the [[FIETS sustainability principles| FIETS model]], which covers five dimensions of sustainability: Financial, Institutional, Environmental, Technical, and Social.
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* Environmental solutions - e.g. siting of seasonal water points in relation to pasture availability in pastoral areas
 
* Environmental solutions - e.g. siting of seasonal water points in relation to pasture availability in pastoral areas
 
* Social solutions - e.g. changing behavior in water use, use of communal sources, etc.
 
* Social solutions - e.g. changing behavior in water use, use of communal sources, etc.
 
 
'''More information about the effects of drought on water access and technologies''' (includes world maps on the locations of  water stress, scarcity, and historical drought): [[Impact of drought on WASH systems]]
 
 
'''How drought causes other major disasters such as poverty, inequality, and conflict:''' [[Drought and other disasters]]
 

Revision as of 09:54, 5 June 2012

This section is based on a desk study written by Eric Fewster, commissioned by CARE Netherlands and the Netherlands Red Cross

Resilient WASH systems need to be able to cope with changes in the availability of water. This section explores which techniques can be used to improve water availability over space and time in areas not only prone to drought and changing climate variability, but also those areas with deteriorating water availability due to increasing water demands and human influences. The focus is on water supply and non-motorized irrigation in rural areas for populations of up to 5,000 people. Resilience is a concept used to describe how to make water systems more robust in terms of water availability, thereby reducing the vulnerability of people that rely on them.

Main content

Both technical and non-technical components are important in discussing how to make water systems resilient. In many cases, it is not technical issues which cause projects to become unsustainable, but non-technical issues such as management, social relationships and community dynamics. A useful model to use is the FIETS model, which covers five dimensions of sustainability: Financial, Institutional, Environmental, Technical, and Social.

Technical measures

The technical measures to consider while planning a project can be divided into three types:

Non-technical measures

  • Financial & economic solutions - e.g. availability of micro-finance to users to replicate technology
  • Institutional solutions - e.g. establishment of effective water user associations to manage communal facilities
  • Environmental solutions - e.g. siting of seasonal water points in relation to pasture availability in pastoral areas
  • Social solutions - e.g. changing behavior in water use, use of communal sources, etc.