Abstract
Climate change is regarded as the greatest threat to society in the coming years, and directly affects the water industry; with changes in temperature, rainfall intensities and sea levels resulting in increased treatment and subsequent energy costs. As one of the largest global consumers of energy, the water industry has the opportunity to significantly prevent climate change by reducing energy usage and subsequent carbon footprints. Wastewater treatment alone requires an estimated 1% - 3% of a country overall energy output while producing 1.6% of its global greenhouse gas emissions; over 75% of which can be due to the collection system. Gravity flows should therefore be incorporated where possible, reducing pumping requirements and therefore minimizing costs and subsequent carbon footprints. This study has assessed the operational energy usage of the alternative collection systems low pressure and vacuum, for use in situations in which a conventional gravity system is not practicable. This was carried out through hypothetical scenario testing using design parameters derived from literature, generating 60 hypothetical collection mains with variations in population, static head and main length. From this study, it was found that the energy demand of a low pressure system is 3.2 - 4.2 times greater than that of its equivalent vacuum system in the same scenario. Energy demand for both systems increases with population, static head and main length. However, population and therefore flow changes were found to have the greatest effect on the energy usage of both systems. Therefore, flow reduction measures should be adopted if the decarbonization of the water industry is to be achieved.
Highlights
The World Commission on Environment and Development (WCED) defines sustainability as “development which meets the needs of the present without compromising the ability of future generations to meet their needs” [1]
The water industry is critical in almost every aspect of society [4], and is directly affected by climate change, with changes in temperature, rainfall intensities and sea levels resulting in increased treatment and subsequence energy costs [5]
This study has aimed to compare low pressure and vacuum sewerage systems based on both price and carbon
Summary
The World Commission on Environment and Development (WCED) defines sustainability as “development which meets the needs of the present without compromising the ability of future generations to meet their needs” [1]. Gravity sewers are the most common form of wastewater collection system [14] and have been found to be an efficient system for areas with a high population density This system has been used for thousands of years; all other collection system options can be considered to be “alternative” systems [12] [15]. Vacuum sewer collection systems are considered to be an “eco-innovative” wastewater collection system, preventing the seepages and odors which can occur in a conventional gravity system [18] These systems have been found to be suitable in different situations including; areas with existing septic tanks; high water tables or nearby watercourses, flat ground topography or difficult ground conditions [19]. Vacuum collection systems are not viable in locations where the site topography requires wastewater to be transported up large elevations
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