Tate Rogers (in rear, with white mask) works with a local pit-emptying team in South Africa to field test the Excrevator. Credit: Tate Rogers

In 2011, an engineering student came up with an idea to help people in the developing world deal with raw sewage. His goal was to use technology to help save lives by limiting people's exposure to the pathogens in human waste. Four years and several countries later, he's still working on it – and the technology is beginning to come into focus.

Here's the basic problem: in many parts of the , people don't use toilets. Instead, they use pit latrines, which quickly fill up with and have to be emptied by hand. Emptying those pit latrines means coming into contact with – and whoever has to empty those pits runs the risk of contracting a disease.

NC State engineering professor Bob Borden presented an undergraduate class with this problem in 2011, and a student named Tate Rogers had a possible solution. Rogers proposed the development of a hand-held tool that used a gasoline-powered auger (like a giant corkscrew) to pump the waste out of the pits into portable containers. The twisting of the auger would act like an Archimedes' screw to move the waste.

A lot has happened since Rogers brought his idea to Borden. The two of them brought together a larger team of researchers, including Francis de los Reyes (who has given a TED Talk on sanitation as a human right) and Tarek Aziz, to work on the project. In 2012, they received a $100,000 grant from the Gates Foundation to work on the prototype and test it in South Africa. In 2013 they got a second grant from the Gates Foundation to work on the technology that they now called the "Excrevator."

That second grant allowed Rogers to do additional field testing in India, South Africa and Malawi. And he learned a lot.

Rogers, (in rear, holding the equipment) field-tested the Excrevator with collaborators in Malawi. Credit: Tate Rogers

"The Excrevator works well with waste," Rogers says. "But there is an issue when it comes to dealing with garbage."

The problem is that human waste isn't the only thing that ends up in pit latrines. As Rogers puts it, "If you can imagine it being in a pit latrine, we've found it."

Stones and solid objects don't pose much of a problem. But plastic bags and clothing can get pulled into the auger, clogging it completely. To address this problem, Rogers and the rest of the Excrevator team have had to develop a variety of solutions.

"One way to deal with the debris is to fish it out, so we've developed tools to make that safer and easier," Rogers says. For example, they developed a strong, retractable claw at the end of a pole that can be used to snag and pull out Excrevator-clogging fabric or plastic.

They're also developing a powered "macerator" that can grind or chop up any debris, so that it can pass through the auger. Tracey Sisco, a civil engineering master's student at NC State, has been completing laboratory testing on different mechanisms for handling trash.

Pit latrines can be filled with solid trash (like this one in South Africa), which can clog the Excrevator. Credit: Tate Rogers

"Every pit latrine is different, so we are developing a suite of tools that can be used to deal with whatever obstacles you run into at any given pit," Rogers says. "And all of the tools – the Excrevator, the macerator, and a related vacuum system – can be run by one power source, called a Powercube."

Rogers is now a research associate at NC State, and works part-time on waste management research at RTI International, but he's still working on the Excrevator – and he has high hopes that it can make a meaningful difference in the near future.

The Excrevator team is now applying for a new grant, which would allow them to continue testing and fine-tuning the technology.

"Based on our fieldwork, we have a really good understanding of the challenges surrounding waste handling in the developing world," Rogers says. "And we're optimistic that we'll have reached a point in the next couple of years where we can move from prototype development to begin scaling up manufacturing for widespread use."