Design and Manufacturing of High Surface Area 3D-Printed Media for Moving Bed Bioreactors for Wastewater Treatment

Authors

Olivia Elliott, Auburn UniversityFollow
Stephanie Gray, Auburn UniversityFollow
Michael McClay, Auburn UniversityFollow
Bakr Nassief, Auburn UniversityFollow
Ann Nunnelley, Auburn UniversityFollow
Eric Vogt, Auburn University
Joseph Ekong, Auburn UniversityFollow
Kamran Kardel, Georgia Southern UniversityFollow
Ali Khoshkhoo, Auburn UniversityFollow
Gabriel Proaño, Auburn UniversityFollow
David M. Blersch, Auburn UniversityFollow
Andres L. Carrano, Georgia Southern UniversityFollow

Document Type

Article

Publication Date

4-2017

Publication Title

Journal of Contemporary Water Research & Education

DOI

10.1111/j.1936-704X.2017.03246.x

ISSN

1936-704X

Abstract

The specific surface area and topology of a biofilter media carrier is one of the most important parameters that determines the performance and efficiency of the system. In this work, mathematical models and 3D printing technologies were used to design and fabricate complex media designs that provide high specific surface area and refugia to protect biofilm from premature sloughing. Several gyroid based designs were proposed with specific surface area well beyond 2300 m²/m³. However, wall thicknesses and pore sizes that are prone to clogging determined a design that yields 1168 m²/m³ (133% larger than the baseline commercial K1 Kaldnes). Several moving bed bioreactors were constructed for laboratory testing with inoculation provided by wastewater from a fisheries operation. Preliminary results indicate that the 3D printed media can withstand the prevalent conditions in moving bed bioreactors, and that the NH₃ removal rate of gyroid media is comparable to that of K1 Kaldnes. This work establishes the feasibility of using 3D printing for bioreactor media fabrication and allows for future topology optimization for enhanced operation. Future work is needed to investigate how these complex media designs might stimulate novel microbial assemblages and community metabolism that translate into yield efficiency gains in reactor performance.

Recommended Citation

Elliott, Olivia, Stephanie Gray, Michael McClay, Bakr Nassief, Ann Nunnelley, Eric Vogt, Joseph Ekong, Kamran Kardel, Ali Khoshkhoo, Gabriel Proaño, David M. Blersch, Andres L. Carrano. 2017. "Design and Manufacturing of High Surface Area 3D-Printed Media for Moving Bed Bioreactors for Wastewater Treatment." Journal of Contemporary Water Research & Education, 160 (1): 144-156: Wiley Online Library. doi: 10.1111/j.1936-704X.2017.03246.x source: https://onlinelibrary.wiley.com/doi/full/10.1111/j.1936-704X.2017.03246.x
https://digitalcommons.georgiasouthern.edu/manufact-eng-facpubs/9

Copyright

Wiley Rights &