Involving people who will directly benefit from technology research is critical to sustainable development, as researchers have experienced by working with chili farmers in India for more than four years.
A team led by Stanford University developed a solar-powered technology to improve the quality and quantity of dried agricultural produce and potentially increase incomes of smallholder farmers in India, which average around $5 per day. Due to better quality, chilies dried by the equipment were sold at 14 percent to 22 percent higher prices than chilies dried traditionally in the open air, according to a recent study in Energy for Sustainable Development. Depending on the farmer’s underlying costs such a revenue boost could double profits, but the cost of buying the equipment, learning how to use it and uncertainty of financial outcomes are barriers to adoption.
The operational and technical design are not trivial. For example, the pilot greenhouse has demanding technical requirements, like reaching temperatures up to 140 degrees Fahrenheit for drying and staying below 89 degrees for growing seedlings. In addition, the study explores how third-party organizations or companies could buy the equipment and provide the seedling growth and drying for a fee to farmers, who would avoid upfront equipment costs while seeing the financial benefits of equipment usage.
The research suggests that credit-worthy entities, such as farmer collective groups, traders or exporters, should be the investors in the greenhouse. With government subsidies and private loans for the equipment purchase, the owning entity could collect fees for two services from multiple farms over seven months of the year. In this scenario, the study finds that the cost of equipment would be recuperated in just one year, instead of the 6.5 years for a single farm using the equipment for drying only.
“Most of the projects [at Deshpande Foundation] are based on the demand and need from the community,” explained Khan. “Because we know this issue well, we got started with Michael and Andrey, co-creating this technology to address the dried chilies problem.”
Back at Stanford, the Suryodaya project – named after the Hindi word for “sunrise” – navigated technical challenges with help from undergraduate seniors majoring in mechanical engineering in the capstone course Mechanical Engineering Design: Integrating Context with Engineering. Every year since 2018, students in the course have helped solve key design challenges.
To address these issues, the study also examines alternative financing available to the farmers and potential additional benefits, like avoiding the common waste of at least 10 percent of a crop from rains in open-air sun drying and using the equipment to grow seedlings when not drying. While still in development, the technology could improve the livelihood for many millions of farmers globally who grow and dry produce, such as grapes, spices, and beans.
“Technological energy innovation is only a part of the answer to reducing poverty in agriculture. Systems-level understanding and approaches are required to ensure that we adequately and ethically meet the needs of farmers while also designing for scalability,” said co-author Sally Benson, senior author of the study and a professor in Stanford’s Department of Energy Resources Engineering.
Following a presentation at Stanford by the Deshpande Foundation in 2017, lead author and postdoctoral scholar Michael Machala, PhD ’17, and co-author Andrey Poletayev, PhD ’20, went to Karnataka, India to meet with Innus Khan, the foundation’s senior director of agricultural initiatives and co-author of the study. The organization, based in the United States and India, develops sustainable and scalable enterprises that have significant social and economic impacts.
Chili farmers told the researchers in field visits that traditional open-air drying can take weeks to complete and cause degradation or total spoilage from sun bleaching, pests, rain and fungus. The Deshpande Foundation was working with more than 2,000 chili farmers at the time, Khan said. The team found that damages from open-air sun drying of chili on Indian farms slashed revenue by one-third on average.
The team thought sustainable social entrepreneurship might unlock scalable solutions for India’s 125 million smallholder family farms, one-quarter of the world’s total. India is a world leader in dried chili production at 1.7 million tons per year, and many of the country’s other products are also open-air dried.
Switching from open-air sun drying to drying in greenhouses is not a new idea, but previous research rarely looked at adoption. “People focused on technical questions, but they missed the user-facing questions that really determine whether a solution gets implemented or not,” said Poletayev.
The team found that using the equipment only for drying produce was a huge barrier to adoption of improved drying technology. The farmers, who have little disposable income, would take three to seven years to pay off the equipment purchase from their increased profits, according to the new study.
“Because solar dryers sit unused much of the year, we adapted the design of our system to meet another farming need of growing seedlings, which are more robust and productive when starting out in a greenhouse,” said Machala. “Farmers report that seedlings grown initially in our greenhouse and then transplanted to a field produce up to twice as many chilis as those sown in the field.”
“Over seventy students across six departments and three schools have contributed to this project. It’s truly been a transdisciplinary effort,” Benson shared.
One such student, Frederick Tan, B.S. ’18, visited India to learn more about his student team’s design challenge and eventually joined the research team full-time. “This project bridges academia to real-world problems. We got to tap into the resources that we’re so lucky to have at Stanford to help other people around the world,” said Tan, now a master’s degree student in the Department of Civil and Environmental Engineering.
To date, the international research team has begun piloting the published concept, working with smallholder farmers to dry 24,000 kilograms of red chili and grow 160,000 seedlings of chili, tomato, and eggplant. They hope to run a trial study on the fully implemented and financed system. And the team has begun growing and testing other dried products like turmeric, onion, mung beans, grapes and figs. Complementary produce seasons could raise the equipment utilization from seven months of the year to 12.
“We have a lot of promising results, but more R and D is needed to prepare for confirmation and adoption toward impact at scale,” said Machala.
This work was funded by Stanford’s Precourt Institute for Energy, Woods Institute for the Environment, TomKat Center for Sustainable Energy and Haas Center for Public Service, and by the Deshpande Foundation. For more information on the Suryodaya project, contact Michael Machala at mmachala at stanford dot edu.
Research Report:Overcoming barriers to solar dryer adoption and the promise of multi-seasonal use in India
All About Solar Energy at SolarDaily.com
We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain.
With the rise of Ad Blockers, and Facebook – our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don’t have a paywall – with those annoying usernames and passwords.
Our news coverage takes time and effort to publish 365 days a year.
If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
$5 Billed Once
credit card or paypal
SpaceDaily Monthly Supporter
$5 Billed Monthly
New-generation solar cells raise efficiency
Cologne, Germany (SPX) Apr 14, 2022
A German research team has developed a tandem solar cell that reaches 24 per cent efficiency – measured according to the fraction of photons converted into electricity (i.e. electrons). This sets a new world record as the highest efficiency achieved so far with this combination of organic and perovskite-based absorbers.
The solar cell was developed by Professor Dr Thomas Riedl’s group at the University of Wuppertal together with researchers from the Institute of Physical Chemistry at the Universit … read more