Innovative methods for water disinfection

Title of the research project

Bubbles 4life: hydrodynamic cavitation for water disinfection in developing countries

Scientific area 

Hydraulics

Project coordinator

Costantino Manes

Abstract

Bubbles4life project aims at developing a low cost robust and reliable method for water disinfection that can be used in developing countries, using a physical process called “Hydrodynamic Cavitation”.

Description of the research project 

There are currently about 780 million people in the world who have no access to drinkable water sources. As a result of this, more than 3 million people die every year of sanitation and hygiene related issues and 99% of all deaths occur in developing countries. Such a water emergency is caused by several issues. Among these, the lack of appropriate water-treatment methods plays an important role. Technologies that are commonly and successfully used in the developed world cannot be used so easily in developing countries as they are associated with high costs of installation, maintenance and operation and they require the use of chemicals that are not easy to retrieve. This proposal intends to tackle this issue by further developing a promising technique called Hydrodynamic Cavitation (HC). This technique relies on the principle of forcing water to flow in constricted regions and hence to make it boiling as a consequence of the low pressure levels it experiences. When pressure is restored, water bubbles implode violently generating conditions that are lethal for any microorganisms. The current understanding of the physical processes governing water-treatment through HC is very poor. The general aim of Bubbles4life is to bridge this knowledge gap and design reliable and low-cost HC reactors. HC does not require chemicals and/or high tech components, which makes it a perfect candidate for applications in developing countries.

Impact on society 

Sustainable supply of clean water can lead to an enormous drop in sanitation-related illnesses currently affecting developing countries. The results from bubbles4Life can also find numerous applications in high-income countries. For example, HC reactors applied in the food industry may promote water re-use (e.g., vegetables washing) and the reduction of chemicals for sterilization purposes, which may alter the properties and taste of food and drink-products. HC is also known to promote mixing and hence highly efficient HC reactors can be used to optimise chemical reactions occurring in liquids, which are of interest for a plethora of applications within the chemical and pharmacological industry.

Short CV of project coordinator 

Costantino Manes graduated at the University of Ancona in 2002. PhD degree in Hydraulics in 2006 from the University of Aberdeen (Scotland, UK). Post doc in Switzerland at the institute for snow and avalanche research (2006-2008) and at the Polytechnic of Turin (2008-2011). Lecturer from 20011-2015 at the University of Southampton, UK. He has been Associate Professor of Hydraulics since 2015 at the Polytechnic of Turin. His main research interest spans from fundamental to applied Fluid Mechanics, with a clear focus on the study of turbulent flows. He is author and co-author of more than 40 publications in peer reviewed journals and proceedings of international conferences.

Working group@Polito

Luca Ridolfi, Full professor, DIATI

Riccardo Vesipa, DIATI

2  post Doc researchers

Partenariato

Academic Partner 

University of Southampton, United Kingdom

Non-academic Partner 

Società Metropolitana Acque Torino (SMAT)

  • Budget: 150.000 euro
  • Start date: 15/09/2017
  • End date: 14/09/2019
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