Catalytic Denitrification in a Trickle Bed Reactor: Ion Exchange Waste Brine Treatment

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Abstract

Catalytic reduction of nitrate in ion exchange (IX) waste brine for reuse is a promising option for reducing IX costs and environmental impacts. A recycling trickle bed reactor (TBR) was designed and optimized using 0.5 percent by weight (wt%) palladium–0.05 wt% indium catalysts supported on US mesh size 12 × 14 or 12 × 30 activated carbon particles. Various liquid superficial velocities (Ur) and hydrogen gas superficial velocities (Ug‐H2) were evaluated to assess performance in different flow regimes; catalyst activity increased with Ug‐H2 at all Ur for both catalysts and was greatest for the 12 × 30 catalyst at the lowest Ur (8.9 m/h). The 12 × 30 catalyst demonstrated up to 100% higher catalytic activity and 280% higher mass transfer rate compared with the 12 × 14 catalyst. Optimal TBR performance was achieved with both catalysts in the trickle flow regime. The results indicate that the TBR is a promising step forward, and continued improvements are possible to overcome remaining mass transfer limitations.

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Author and article information

Contributors

Allison M. Bergquist:

Bio :

Allison M. Bergquist is an environmental engineer for ExxonMobil Research & Engineering Company. She earned her PhD in civil and environmental engineering from the University of Illinois at Urbana‐Champaign in 2016. Her dissertation research was focused on the development of a hybrid ion exchange‐catalyst technology to treat ion exchange waste brine. In 2015 she was awarded the AWWA American Water Scholarship. Madison Bertoch is a research assistant at the University of Texas at Austin. Gary Gildert is general manager at Vanguard Catalyst LLC in Alvin, Tex. Timothy J. Strathmann is a professor at the Colorado School of Mines in Golden, Colo. Charles J. Werth (to whom correspondence may be addressed) is a professor and the Bettie Margaret Smith Chair in Environmental Health Engineering at the University of Texas at Austin, 301 E. Dean Keeton St., Austin, TX 78712 USA; werth@utexas.edu.

Journal

Journal ID (doi): 10.1002/(ISSN)1551-8833

Title: Journal ‐ American Water Works Association

Abbreviated Title: Journal ‐ American Water Works Association

ISSN (Print): 0003-150X

ISSN (Electronic): 1551-8833

Publication date (Electronic): 01 May 2017

Affiliations

Urbana; Ill.USUniversity of Illinois at Urbana‐Champaign

Austin; Tex.USUniversity of Texas at Austin

Houston; Tex.USJohnson Matthey Inc.

Golden; Colo.USColorado School of Mines

Article

DOI: 10.5942/jawwa.2017.109.0055

SO-VID: f61fd545-6a20-42d2-8ef5-5f2d25394cd5

History

Funding

Funded by: US Environmental Protection Agency (USEPA)

Award ID: RD‐83517401

ScienceOpen disciplines: Earth & Environmental sciences,General environmental science,Environmental engineering

Keywords: Ion Exchange,Velocity,drinking water treatment,ion exchange,palladium‐indium,trickle bed reactor,Mass Transfer,Reactors,Brines,Denitrification,Reuse,Activated Carbon Treatment,activated carbon,brine reuse,catalysis

Data availability:

ScienceOpen disciplines: Earth & Environmental sciences, General environmental science, Environmental engineering

Keywords: Ion Exchange, Velocity, drinking water treatment, ion exchange, palladium‐indium, trickle bed reactor, Mass Transfer, Reactors, Brines, Denitrification, Reuse, Activated Carbon Treatment, activated carbon, brine reuse, catalysis

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