What is in this article?:
- Tapioca pearls ideal for removing water from ethanol
- 100 percent starch
- Researchers have found an alternative environmentally friendly and energy-efficient way to dry corn ethanol, and their proof is in the pudding. The shape and structure of tapioca pearls are ideal for removing water from ethanol.
Purdue University researchers have found an alternative environmentally friendly and energy-efficient way to dry corn ethanol, and their proof is in the pudding.
Michael Ladisch, a distinguished professor of agricultural and biological engineering; Youngmi Kim, a Purdue research scientist; and Ahmad Hilaly, director of process research at Archer Daniels Midland, found that the shape and structure of tapioca pearls are ideal for removing water from ethanol. Their findings were reported in the July issue of the journal Industrial & Engineering Chemistry Research.
After fermentation, ethanol contains between 6 percent and 12 percent water, which must be removed to make it fuel-grade. Many ethanol plants use corn grits, which absorb water, or molecular sieves, silica-based particles with tiny pores that only retain water molecules. Ladisch and Kim found that tapioca pearls work better than the conventional corn grit adsorbents.
"Any starch will absorb water. That's how you cook rice or pasta," Kim said. "The tapioca pearl is made of aggregated cassava starch granules that can adsorb more water."
Ladisch said tests found tapioca collected about 34 percent more water than corn. Molecular sieves, while effective, eventually wear out and create waste that must be disposed of. The tapioca can be dried and reused, and when they wear out, they can be used to make more ethanol.
"Tapioca is very efficient, and it's all-natural," Ladisch said. "There are no disposal issues. It's much more environmentally friendly."
Tapioca pearls, essentially spherical, are structured differently than corn grits, Ladisch said. While corn grits are solid, irregularly shaped particles, tapioca pearls contain a gelatin starch core upon which dry starch granules are aggregated, significantly increasing surface area.