Residential Water Use, Rate, Revenue, and Nonprice Conservation Program Database


Book Description

This report describes and contains the information and database developed for the research study Effectiveness of Residential Water Conservation Price and Nonprice Programs (Michelsen, McGuckin and Stumpf 1998). The water demand, price and conservation program information documented in this report is the result of research and data collection efforts and utility cooperation initiated in 1991 by William Bruvold and continued by the researchers of this report through a consortium of universities. The study encompasses seven water utilities in three western states- California, Colorado and New Mexico. The information gathered, developed and refined for this study was digitized and a database created in spreadsheet format for analysis. Database structure, variable names, definitions, computational adjustments and study area characteristics are described in this report. Water demand model descriptions and analysis results of this research are presented in another publication of the AWWA Research Foundation by Michelsen, McGuckin and Stumpf (1998) entitled Effectiveness of Residential Water Conservation Price and Nonprice Programs.




Annual Report


Book Description




Water Code


Book Description




Costing Improved Water Supply Systems for Low-income Communities


Book Description

This manual and the free downloadable costing tool is the outcome of a project identified by the Water, Sanitation and Health Programme (WSH) of the World Health Organization (WHO) faced with the challenge of costing options for improved access, both to safe drinking water and to adequate sanitation. Although limited in scope to the process of costing safe water supply technologies, a proper use of this material lies within a larger setting considering the cultural, environmental, institutional, political and social conditions that should be used by policy decision makers in developing countries to promote sustainable development strategies. Costing Improved Water Supply Systems for Low-income Communities provides practical guidance to facilitate and standardize the implementation of social life-cycle costing to “improved” drinking-water supply technologies. These technologies have been defined by the WHO/UNICEF Joint Monitoring Programme for Water Supply and Sanitation, as those that, by the nature of its construction, adequately protect the source of water from outside contamination, in particular with faecal matter. The conceptual framework used has also been conceived to be applied to costing improved sanitation options. To facilitate the application of the costing method to actual projects, a basic tool was developed using Microsoft Excel, which is called a water supply costing processor. It enables a user-friendly implementation of all the tasks involved in a social life-cycle costing process and provides both the detailed and the consolidated cost figures that are needed by decision-makers. The scope and the limits of the costing method in a real setting was assessed through field tests designed and performed by local practitioners in selected countries. These tests were carried out in Peru and in six countries in the WHO regions of South-East Asia and the Western Pacific. They identified practical issues in using the manual and the water supply costing processor and provided practical recommendations. References and Glossary Author(s): Fabrizio Carlevaro, Geneva School of Economics and Management, Switzerland and Cristian Gonzalez, International Road Federation, Geneva, Switzerland







Non-revenue water


Book Description

Non-revenue water (NRW) includes physical losses (pipe leaks) and commercial losses (illegal connections, unmetered public use, meter error, unbilled metered water, and water for which payment is not collected). NRW levels are high in many developing countries, and they can be expensive to reduce. Members of the International Water Association (IWA) Water Loss Task Force developed the Economic Level of Leakage (ELL), which outlines the optimal level of physical losses based on engineering inputs. However, the ELL approach is less useful in developing countries than in developed countries, as it ignores commercial losses, the annualized cost of water supply capacity expansion, and situations in which production capacity does not meet demand. This report presents a financial model that addresses the limitations noted above and provides acceptably accurate values of optimal, steady-state NRW without the need for large data collection efforts. The model uses an NRW framework adapted from the IWA Water Balance and the Burst and Background Estimates (BABE) and Econoleak methodologies. The report presents specific results for 59 utilities in 27 countries in Asia, Africa, and Eastern Europe; these include optimal NRW, optimal physical losses, optimal commercial losses, optimal meter replacement frequencies, optimal leak detection survey frequencies, actual losses, and impacts on utility revenue and water supply coverage. This model allows utility managers and regulators to establish NRW targets and to optimally allocate resources to NRW management. Ultimately, use of the model will help save water, increase utility revenues, expand coverage, and reduce health and economic impacts.