Location: Bioproducts Research
Project Number: 2030-41000-056-09-R
Project Type: Reimbursable Cooperative Agreement
Start Date: Oct 1, 2011
End Date: Jun 30, 2014
Producers of apple juice, wine, olive oil, and tomato paste and juice in California generate hundreds of thousands of tons of pomace each year. Nut producers, specifically almond and walnut, also generate tons of hulls and shells. In the next decades, some specialty crop industries are expected to grow at a rapid pace, leading to generation of even more byproducts. For instance, the olive oil industry is expected to produce ten times more oil within the next decade. These byproducts are mostly converted to low-value compost or animal feed and have to be used quickly because they can be highly perishable. Consequently, growers have to find ways to transport or stabilize the byproducts and this can be costly. Torrefaction of pomace, hulls, and shells can provide added value by converting these byproducts to stable, high-energy density fuels. Torrefaction involves heating biomass under inert atmosphere between 200-300C. This removes most moisture and volatile components to produce a fuel comparable to low-rank coal. The torrefied material is hydrophobic and stable to biological activity and moisture. Torrefaction decreases mass of the material, resulting in reduced shipping costs. The objectives of this project are to 1) Optimize torrefaction conditions for apple, grape, olive, and tomato pomaces as well as almond and walnut hulls and shells, 2) Examine alternative methods for torrefaction, such as microwave heating, 3) Simulate the effects of torrefaction on material properties using modeling software, 4) Feed byproducts into continuous torrefaction reactor owned by a collaborator, Renewable Fuel Technologies (RFT), to determine their potential as biomass sources, and 5) Examine torrefied biomass as hydrophobic fillers, binders, and adhesives to produce polymer composites with superior material properties.
We first characterize physical properties of different pomaces and nut shells. We then optimize the torrefaction process in a muffle furnace by varying moisture contents of pomace and nut shells, treatment temperatures, and treatment times. We measure energy values of final products and examine effects of torrefaction on mass, moisture, lignocellulose, and ash contents. We examine sample stability by measuring moisture sorption at different relative humidity. Also, we use alternative heating methods for torrefaction, such as microwave heating. We then compare final properties of torrefied samples from the different heating methods. In addition, we use COMSOL Multiphysics software to model the torrefaction process. In this way, we determine the energy required to produce torrefied samples at different processing scales. We also incorporate torrefied biomass as fillers into polymers to produce composites with superior material properties.