The need for a standard approach to assessing the functionality of rural community water supplies

Hydrogeology Journal, Jan 2018

The Sustainable Development Goals have set an agenda for transformational change in water access, aiming for secure household connections globally. Despite this goal, communal groundwater supplies are likely to remain the main source of improved water supplies for many rural areas in Africa and South Asia for decades to come. Understanding the poor functionality of existing communal supplies remains, therefore, a priority. A critical first step is to establish a sector-wide definition of borehole supply functionality and a standard method of its assessment.

A PDF file should load here. If you do not see its contents the file may be temporarily unavailable at the journal website or you do not have a PDF plug-in installed and enabled in your browser.

Alternatively, you can download the file locally and open with any standalone PDF reader:

https://link.springer.com/content/pdf/10.1007%2Fs10040-017-1711-0.pdf

The need for a standard approach to assessing the functionality of rural community water supplies

Hydrogeology Journal The need for a standard approach to assessing the functionality of rural community water supplies Helen Bonsor 0 1 2 3 Alan MacDonald 0 1 2 3 Vincent Casey 0 1 2 3 Richard Carter 0 1 2 3 Paul Wilson 0 1 2 3 0 Richard Carter and Associates Ltd , The Oxlip, Ampthill, Bedfordshire MK45 2EH , UK 1 WaterAid , 47-49 Durham Street, London SE11 5JD , UK 2 British Geological Survey, Lyell Centre , Research Avenue South, Riccarton, Edinburgh EH14 4AP , UK 3 British Geological Survey , Dundonald House, Upper Newtownards Road, Ballymiscaw, Belfast BT4 3SB , UK The Sustainable Development Goals have set an agenda for transformational change in water access, aiming for secure household connections globally. Despite this goal, communal groundwater supplies are likely to remain the main source of improved water supplies for many rural areas in Africa and South Asia for decades to come. Understanding the poor functionality of existing communal supplies remains, therefore, a priority. A critical first step is to establish a sector-wide definition of borehole supply functionality and a standard method of its assessment. Water supply functionality; Borehole; Groundwater development; Rural; Sustainable Development Goals (SDGs) - persisted since the 1970s, despite different approaches to introduction of services such as an increased emphasis on demand responsive approaches and community management (Cairncross et al. 1980; Arlosoroff et al. 1987; McPherson and McGarry 1987; Carter and Ross 2016; Whaley and Cleaver 2017) . As a result, the original investment and the intended benefits (improved health, nutrition, time-savings and education) are lost for the communities affected (Hunter et al. 2010; UN 2013) . Being able to understand the relative drivers of existing functionality of rural borehole supplies across different settings is essential for future investment and interventions to be able to deliver water supply services of increased sustainability and lasting benefit. However, in the absence of a sector-wide definition of borehole functionality, it is currently difficult to compare existing estimates of functionality accurately (Harvey and Reed 2006; Banks and Furey 2016) . There is now a growing research community focussed on this issue as well as efforts to standardise definitions led by the Sanitation and Water For All coalition (Wilson et al. 2016). This essay discusses the implications drawn from a review of this growing literature and suggests guidelines for defining and assessing functionality as a first step to being able to confidently compare studies and understand the relative drivers of poor functionality across different settings. Lack of a standard definition Currently, there is no single accepted definition of functionality, or what constitutes a functioning water point. This inhibits the ability of the research community, government, donors and practitioners alike to be able to understand the inter-related causes of water point failure. Consequently, solutions may be proposed and implemented that do not address the most significant drivers or deliver lasting benefit. A recent review of 111 studies from published and grey literature (for details see Wilson et al. 2016) found six main categories of how functionality is defined within studies (Table 1; Fig. 1). Within these categories, functionality is mostly measured using qualitative approaches and direct quantitative assessment measurements of functionality are rare. Thirty-four percent of the studies employ a simple binary approach to define water point functionality based on whether the source is ‘in use’ or ‘not in use’ at the time of the visit. A further 28% of the studies reviewed were found not to explicitly define functionality, but by default usually assume a simple binary working/not working definition. The limitation of a simple binary approach has led some to define multiple categories such as partially functioning but this in itself has made comparison of surveys more difficult. A tiered approach has been advocated by a few (4%) recent studies (Leclert 2012; Tincani et al. 2015; Carter and Ross 2016) in which several different levels of assessment and indicators are used to assess functionality. Fourteen percent consider functionality as a category within a much broader sustainability assessment of water service, but definitions used within this are often unclear. Three major projects (Triple 2009; Cross et al. 2013; Prat et al. 2015) have highlighted the need for clearer definitions of water point functionality in order to be able to understand, and move towards, improving service sustainability. These projects and related literature have drawn attention to the relationship between functionality and sustainability (Duti 2012; Moriarty et al. 2013; Prat et al. 2015) . Indeed, Lockwood and Smits (2011) observe that functionality (which they express as the percentage of water points working at any given time) often serves as a proxy for sustainability; however, it is important to recognise that the two are not synonymous, as noted by Carter and Ross (2016) . Water points can be non-functional at the moment they are inspected but, with an effective maintenance system may, over the course 1 - Not Defined 2 - Defined binary approach 3 - Mul -catagories 4 - Tiered defini on 5 - Sustainability assessment 6- Design Yield of a year, have limited downtime and deliver a sustainable supply of water. Equally, other water points which are found to be functioning at the time of inspection, may in reality experience significant downtime over a year, due to fundamental faults or issues, or less effective maintenance, and are less likely to deliver a sustainable supply (Carter and Ross 2016) . Guidelines for assessing functionality A major drawback of having such different definitions of functionality, and more worrying, no definition, is that it is difficult to compare studies. The term Bfunctionality^ is used by studies to represent both functionality at a point in time (‘snapshot’) and the performance of a water point, which includes a temporal/ reliability dimension. It is essential to differentiate between the two, and understand to which domain different functionality figures relate. Taking the findings from the literature review and Definition class Summary 1. Not defined 2. Defined binary approach 3. Multi-categories 4. Tiered definition 5. Sustainability assessment 6. Design yield Functionality not explicitly defined: by default, working or not working Defined to be ‘working’ or ‘not working’ based on whether the water point is working at the time of the visit: ‘in use’/‘not in use’ Different categories are used to capture the different levels of functionality status: functional, minimally functional, functioning through difficulties, broken, missing parts, seasonal Several different levels of assessment are used to assess functionality. As a minimum, functionality is assessed using a binary approach of ‘working’/‘not working’, but can be examined in greater detail using several levels of assessment A broader assessment approach which includes several factors indicating the reliability of the supply A water point is functional if it produces the design yield at the time of the visit & & & & developing thinking from an earlier paper (Carter and Ross 2016) , it is suggested here that the following guidelines should form core criteria for assessing functionality of water points: Functionality should be measured against an explicitly stated standard and population of water points. Functionality should be measured separately from the users’ experience of the service it provides. The assessments should be tiered, allowing for further information, but always being able to be reduced to a simple measure. A distinction can be made between surveying functionality as a snapshot (e.g. for national metrics) and monitoring individual water point performance and reliability (including a temporal aspect). These guidelines are applied in the following to develop a tiered approach for defining functionality of boreholes equipped with handpumps. The tiered approach enables functionality to be assessed in terms of the performance of that water point with an increasing level of detail: Binary: Is the water point physically working and producing some water at the time of the survey visit? (yes/no) Yield snapshot: Does the water point provide the sufficient minimum design yield (for example, 10 L/min)? Reliable yield: Does the water point provide a reliable yield (meeting criteria 1 and 2 above) year round (less than 30 days downtime in the previous 12 months)? Reliable yield including water quality: Does the water supply pass WHO inorganic and pathogen guidelines, as well as provide a reliable yield year-round? At the highest level, this approach assesses functionality based on a binary definition of ‘working’/ ‘not working’ at the time of a survey. The subsequent levels of assessment beneath this binary definition then move to provide a more detailed understanding of Fig. 2 An approach to assess the functionality of a water point according to the reliability of yield. This performance assessment includes a temporal dimension of the water point’s reliability the yield and reliability of supply. This enables a more refined assessment of functionality to be undertaken where possible, whilst acknowledging that such detailed assessments are not feasible or appropriate in all cases. The ‘binary’ and ‘yield snapshot’ assessments match the requirements of national survey assessments, whilst the more performance-focused definitions, which assess the reliability of the functionality, are more relevant to local or regional surveys looking to track the functionality of individual water points or programmes through time. Measuring functionality performance The set of aforementioned tiered assessment approaches require different quantities of data to be collected, and therefore increasing resources of time and cost. Importantly, the assessment criteria for the binary functionality definition at the highest level of the tiered approach is accessible to all survey types, and ensures a minimum level of functionality data can be compared between studies. The tiered approach also enables a clear distinction to be made between data collated to assess functionality at a point in time (tiers 1 and 2), and the data required to assess reliability of the water point functionality over time – i.e. reliability (tier 3). Figure 2 shows an assessment approach and the different levels of information which must be collated to assess the functionality of a water point according to different tiers in the approach. A tier 1 assessment could be undertaken by just answering the first question (Fig. 2), or a tier 2 assessment by answering the first two questions. All the questions need to be answered to complete a tier 3 assessment. Good statistical design can be used to gain maximum information for limited resources. A tier 1 assessment can be undertaken rapidly for an entire domain—for example a district, region, or even country. Good sampling design could then enable a smaller sample to be assessed within the domain at tiers 2, 3 or 4, and the result used to estimate results across the entire domain. Does the HPB provide water? no yes Was water flowing in past year? Is there sufficient quantity? no Has it had > 1 month downtime this year? yes no yes Has it had > 30 days downtime this year? no yes no yes Fully functional Partially functional – poor reliability Partially functional – low yield Poor yield and reliability Not functioning for test but has worked in last year Abandoned More than a definition: creating the necessary framework to understanding the underlying causes of community water supply failure Defining and measuring functionality is only a starting point. Water point failure and functionality is a multi-faceted, multilayered issue, with growing complexity emerging as one looks beyond the immediate causes of failure. If the SDGs are to be met, and water supply service across the world to become increasing sustainable and offer acceptable service levels (UNDP 2016) , the relative reasons for poor functionality in different environments and cultures need to be understood. Earlier work by the authors (Bonsor et al. 2015) identified a pathway for examining causes of poor functionality that includes: primary causes (e.g. mechanical failure, reduced yield, poor water quality); secondary causes (e.g. geology, poor siting, lack of spare parts, basic maintenance, local governance arrangements); the underlying conditions (including the institutional, financial and social factors that shape an environment in which failure is more or less likely); and long-term trends (e.g. changes in demand for water, evolution of governance arrangements, reduction in regional groundwater availability, climate change, deterioration of water quality). Given the scale of the problem, many are now working to understand poor functionality, and there are increasing efforts to standardise definitions and existing indicators. This provides an opportunity to reflect and consolidate approaches. By improving definitions, and the systematic collection of data pertaining to failure, efforts in the sector could be further focussed to better understand the primary drivers of functionality in different settings, and the specific interventions which will be able to deliver lasting benefit. Acknowledgements This work is part of the Hidden Crisis project within the UPGro research programme and is co-funded by Natural Environment Research Council (NERC), UK Department for International Development (DFID), and the Economic and Social Research Council (ESRC). The paper is published with the permission of the Executive Director of the British Geological Survey (NERC). Open Access This article is distributed under the terms of the Creative C o m m o n s A t t r i b u t i o n 4 . 0 I n t e r n a t i o n a l L i c e n s e ( h t t p : / / creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. Arlosoroff S , Tschannerl G , Grey D , Journey J , Karp A , Langenegger O , Roche R ( 1987 ) Community Water Supply: the handpump option . Rural Water Supply Handpumps Project , UNDP/World Bank, The World Bank, Washington, DC Banks B , Furey S ( 2016 ) What's working, where and for how long: a 2016 water point update . Poster, 7th RWSN forum, November 2016 , Abidjan, Côte d'Ivoire Bonsor HC , Oates N , Chilton PJ , Carter RC , Casey V , MacDonald AM , Calow R , Alowo R , Wilson P , Tumutungire M , Bennie M ( 2015 ) A hidden crisis: strengthening the evidence base on the sustainability of rural groundwater supplies-results from a pilot study in Uganda . OR/15/019, British Geological Survey, Nottingham, UK, 85 pp Cairncross S , Carruthers L , Curtis D , Feachem R , Bradley D , Baldwin G ( 1980 ) Evaluation for village water supply planning . International Reference Centre for Community Water Supply . Wiley, Chichester, UK, 179 pp Carter R , Ross I ( 2016 ) Beyond Bfunctionality^ of handpump-supplied rural water services in developing countries . Waterlines 35 ( 1 ): 94 - 110 Cross P , Frade J , James AJ , Trémolet S ( 2013 ) WASH cost end-of-project evaluation . IRC End-of-Project Evaluation Report , The Hague Duti VA ( 2012 ) Tracking functionality for sustainability . Conference proceedings paper, 2011 Annual Review Conference of the Community Water and Sanitation Agency , Kumasi, Ghana Harvey P , Reed R ( 2006 ) Community-managed water supplies in Africa: sustainable or dispensable? Commun Dev J 42 ( 3 ): 356 - 378 Howard G , Calow R , MacDonald A , Bartram J ( 2016 ) Climate change and water and sanitation: likely impacts and emerging trends for action . Ann Rev Environ Resour 41 : 253 - 276 Hunter PR , MacDonald AM , Carter RC ( 2010 ) Water supply and health . PLoS Med 7 ( 11 ) e1000361 , 9 pp. https://doi.org/10.1371/journal. pmed.1000361 JMP report ( 2014 ) : progress on drinking water and sanitation . World Health Organisation, Geneva. Joint Monitoring Programme (JMP) WHO/ UNICEF . Available at: http://www.who.int/water_sanitation_health/ publications/jmp-report-2014/en/. Accessed June 2017 Leclert L ( 2012 ) Status review of BSF's borehole drilling component in South Sudan ( 2006 - 2012 ). BMB/Euroconsult, Mott MacDonald report, MacDonald, Croyden, UK, 67 pp Lockwood H , Smits S ( 2011 ) Supporting rural water supply: moving towards a service delivery approach . IRC International Water and Sanitation Centre , The Hague, 187 pp MacDonald AM , Calow RC ( 2009 ) Developing groundwater for secure rural water supplies in Africa . Desalination 248 ( 1-3 ): 546 - 556 McPherson HJ , McGarry MG ( 1987 ) User participation and implementation strategies in water and sanitation projects . J Water Resour Dev 3 ( 1 ): 23 - 30 Moriarty P , Smits S , Butterworth J , Franceys R ( 2013 ) Trends in rural water supply: towards a service delivery approach . Water Alternatives 6 ( 3 ): 329 - 349 Prat M-A , Ross I , Kebebe S ( 2015 ) Value for money (VFM) and sustainability in WASH programmes: assessing the VFM of DFID's contribution to the water supply and sanitation programme (WSSP) in Ethiopia . Oxford Policy Management Report, OPM , Oxford, 82 pp Tincani L , Ross I , Zaman R , Burr P , Mujic , A , Evans B ( 2015 ) Regional assessment of the operational sustainability of water and sanitation services in Sub-Saharan Africa . Report by Value For Money, VFMWASH . http://vfm-wash. org/regional-assessment-of-theoperational-sustainability-of-water-and-sanitation-services-in-subsaharan-africa/ . Accessed December 2017 Triple S ( 2009 ) Providing reliable rural water services that last . Triple-S Briefing November 2009 , Triple S , San Juan, Puerto Rico, 5 pp UNDP ( 2016 ) Sustainable development goals: Goal 6-clean water and sanitation . UNDP, New York, 12 pp UN Water ( 2013 ) A post-2025 global goal on water: synthesis of finding and recommendations from UN-water . UN Water , New York, 41 pp Whaley L , Cleaver F ( 2017 ) Can 'functionality' save the community management model of rural water supply? Water Resour Rural Dev 9 : 56 - 66 Wilson P , Bonsor HC , MacDonald AM , Whaley L , Carter RC , Casey V ( 2016 ) UPGro Hidden Crisis Research consortium: unravelling past failures for future success in rural water supply-initial project approach for assessing rural water supply functionality and levels of performance . OR/16/044, British Geological Survey, Nottingham, UK, 35 pp


This is a preview of a remote PDF: https://link.springer.com/content/pdf/10.1007%2Fs10040-017-1711-0.pdf

Helen Bonsor, Alan MacDonald, Vincent Casey, Richard Carter, Paul Wilson. The need for a standard approach to assessing the functionality of rural community water supplies, Hydrogeology Journal, 2018, 367-370, DOI: 10.1007/s10040-017-1711-0