Reinventing the Toilet

Around the world, some 2.4 billion people lack access to toilets or improved sanitation, and more than 1 billion people resort to open defecation—a practice that poses significant health and environmental risks. Even in urban areas, more than 2 billion people live without the services or infrastructure for the safe disposal of human waste, which can result in contaminated drinking water. Diarrhea caused by poor sanitation and unsafe water kills more than 300,000 children each year. Not having toilets in a private setting is not only a health risk, but a women's issue due to the high rates of sexual violence being forced to defecate in the open can bring.

Turning Human Waste into Fuel and Disinfected Water


Under grants from the Bill & Melinda Gates Foundation’s “Reinvent the Toilet” challenge, in 2012 we assembled a team of experts to develop a novel waste treatment system designed for use in the places where people need it most. This toilet operates as a closed loop, with technology to treat and reuse liquids and generate power via a chemical-free combustion process.

Our toilet is designed to operate off-grid—without piped-in water, a sewer connection, or outside electricity—and converts human waste into burnable fuel, stored energy, and disinfected, non-potable water, all for an operating cost of less than US $.05 per day. As it stands now, the system runs on the equivalent of two car batteries; in the future, a unit could be potentially powered by solar panels.

Testing the Toilet in Community Settings


In 2014, we demonstrated a prototype of our toilet in New Delhi, where the response was overwhelmingly positive. Users, researchers, and government officials liked how our toilet burns solid waste, harvests energy from feces, and uses electrochemical disinfection rather than chemicals or additives. Participants also saw tremendous value in the water savings achieved through low flush volume and the use of recycled and disinfected liquid for flush water, as well as our commitment to integrate menstrual hygiene management processes into the interface and process technology.

In September 2016, we began testing our first prototype toilet in Ahmedabad, India; this unit operates on a university campus and demonstrates a use case for an institutional setting. In 2017, our team deployed two additional prototypes in locations with different use profiles. In Durban, South Africa, we are partnering with a local government water utility to test a unit in a low-income urban community’s shared toilet, shower, and washing station, referred to as a community ablution block. And in Coimbatore, in the southern Indian state of Tamil Nadu, we are partnering with a private-sector company, a spinning mill, to test the toilet near a female workers’ dormitory. This will demonstrate the usability of our system in a shared toilet setting and facilitate efforts to incorporate women’s sanitation needs into the design.

Improving Public and Environmental Health and Quality of Life


Community toilet blocks and forward-operating bases only scratch the surface of our off-grid toilet system’s potential. This toilet could also be deployed in national disaster recovery programs, in refugee camps, or in remote locations off the electric grid. The TOWR configuration is ideal for construction sites in low-resource areas around the world, where migrant workers often stay for 18 to 24 months with only pit latrines, and the system is also suitable for festivals, tourist sites, and other large civic gatherings.

Ultimately, our aim is to perfect the development of a waste treatment system that can be integrated into poor rural and urban communities and has the potential to be adapted to other uses as well. We are working to ensure that our demonstration models align with cultural norms and will be accepted, and used, by the people who need them most. In so doing, we hope our technology will support significant improvements in public health, quality of life, and the environment in nations around the world.