A study has discovered a new method for providing drinking water that uses only half the energy of traditional approaches.
A new prototype water harvester could offer a simpler and more efficient way to extract drinking water from the air compared to traditional devices, according to a recent study. Made with temperature-sensitive materials, this nickel-titanium-based dehumidifier can collect more water from the atmosphere within 30 minutes than conventional systems, while using roughly half the energy.
As more than 2 billion people around the world are estimated to lack access to clean drinking water, improving conventional ways to collect such a valuable resource would make it significantly more attainable for water-scarce regions, said John LaRocco, lead author of the study and a research scientist in psychiatry at The Ohio State University College of Medicine.
“You can survive three minutes without air, three weeks without food, but only three days without water,” said LaRocco. “But with it, you can begin to solve a lot of problems, like national security, mental health, or sanitation, just by improving the accessibility of clean drinking water.”
Innovative Cooling Technology and Portability
Whereas many existing water harvesting technologies are large, energy-intensive, and slow, this team’s device is unique due to elastocaloric cooling, which uses materials that can reduce energy use, size, and complexity. This design is what also allowed their prototype to become portable enough to fit inside a backpack, said LaRocco.
Researchers compared their creation with a dehumidifier that operates using desiccant wheels, rotating cylinders lined with hydrophilic materials that work to trap and remove humidity from the surrounding airflow. They tested the performance of each device in sessions of 30 minutes each, evaluating their energy consumption, heat generation, and water-harvesting efficiency.
The study was recently published in the journal Technologies.
The trial’s results revealed significant differences in power consumption and highlighted what conditions their prototype might be best suited for. For example, said John Simon is, co-author of the study and an undergraduate student in electrical and computer engineering, the humidity level of the region where their device is used could influence the effectiveness of its water collection capabilities.
“Compared to the traditional desiccant wheel system, our system has the ability to scale more dynamically to fit the needs of the environment,” said Simonis. “Because our device is more modular, there’s room for a lot of adaptability.”
The authors noted that places like the Philippines, Indonesia, Haiti, and even Ohio are a few of the places where the standard humidity would fall just right enough for their prototype to achieve maximum efficiency.
Safe Water Production and Material Considerations
The water produced from their device is readily drinkable, said Simonis, but because their device is also made with 3D printed materials that can degrade over time, must be heavily filtered to limit the amount of microplastics someone could ingest if they drank it immediately.
According to statistics provided by the United Nations, only about 0.5% of Earth’s water is freshwater and safe for human consumption. Environmental changes caused by war, pollution, and climate change also remain risk factors for an ongoing global water crisis.
Because natural disasters and international emergencies will continue to exacerbate these issues, it’s imperative to find ways to creatively harvest water to support marginalized populations, said Qudsia Tahmina, co-author of the study and associate professor of practice in electrical and computer engineering.
That said, being able to ensure consistency of devices that can harvest a renewable resource out of thin air will help make the process both more economical and more feasible, the study notes. It’s a goal that if achieved, will impact every facet of life on Earth, said LaRocco.
“We’re hoping that clean water for the rest of the world isn’t just a pipe dream,” he said.
Using the team’s models, it is possible for the public to experiment with creating a dehumidifier of their own. But while their prototype is as of now meant for individual use, in the future, it could be easily optimized to care for the needs of a household or larger community, said Simonis.
“It is possible to develop an incredibly large version of our prototype,” he said. “It could extract as much water in a limited amount of time and get the same energy efficiency as somebody who may have a smaller device who’s running theirs continuously.”
Reference: “Comparing Elastocaloric Cooling and Desiccant Wheel Dehumidifiers for Atmospheric Water Harvesting” by John LaRocco, Qudsia Tahmina, John Simonis and Vidhaath Vedati, 29 September 2024, Technologies.
DOI: 10.3390/technologies12100178
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2 Comments
Bummer. Nickel and titanium equals expensive and environmentally problematic. I’m anticipating with bated breath the development of tech that harnesses cooling effects, such as moving magnets in magnetic fields, or moving the magnetic fields over the magnets, or whatever, that the Japanese have observed, which would probably involve expensive rare earths, so back to square one. Then there is the twist and spin quantum effect thing, probably requiring expensive 2D materials. The whole thing is a conundrum. I imagine a material made of a thin piece of thermo-absorbant material facing the interior of confinement fused to a thermo-radiant material forming the exterior of the confinement.
This kind of tech always makes me think that it’s removing the moisture from the air. There is surely a better solution than that.