Abstract
A commercial SCR filter, deployed in the USA in 2015, was sectioned and examined using techniques including mercury porosimetry, electron microscopy, and micro-X-ray computed tomography. The catalyst washcoat was found to be consistent with Cu/SSZ-13, possibly including some zirconia and alumina. Three distinct regions were observed with respect to catalyst loading and location. A region at the inlet end of the filter, comprising 15 to 21% of the total effective filter length, was relatively lightly coated. Most of the catalyst present in this region was observed inside the porous filter walls, and the catalyst concentration was generally greater near the upstream filter wall surfaces. Moving axially down the monolith toward the outlet, a second region comprising 14 to 20% of the total effective filter length was more heavily coated, with catalyst present throughout the thickness of the porous filter walls, as well as coatings on both the upstream and downstream filter wall surfaces. The final region at the outlet end of the monolith, which accounted for 65 to 70% of the filter length, had an intermediate catalyst loading. Most of the catalyst here was again observed inside the porous filter wall. Concentrations in this region were higher near the downstream filter wall surfaces. Detailed models of multi-functional aftertreatment devices, such as the one examined here, have included representations of catalyst distribution within the filter bricks and indicate that catalyst distribution may have an impact on flow distribution, soot loading patterns, local concentrations, and ultimately conversion efficiency. Previous work has also shown that catalyst distribution across the thickness of an exhaust filter wall can have significant impacts on backpressure during soot loading.
Highlights
Diesel particulate filters (DPFs) play an important role in reducing harmful emissions from on-road vehicles
This work describes characterization of catalyst distribution throughout the volume of one commercially produced selective catalytic reduction (SCR)-filter brick using a combination of approaches including physical sectioning, optical examination, mercury porosimetry, microscopy, and X-ray computed tomography (CT)
A number of electron micrographs were taken of filter wall surfaces at various locations using a Phillips/FEI XL30 FEG environmental scanning electron microscope (ESEM) in the backscattered electron detector configuration
Summary
Diesel particulate filters (DPFs) play an important role in reducing harmful emissions from on-road vehicles. Catalyst coatings with oxidation functionality were applied successfully to DPFs early in their commercialization to assist in filter regeneration, to reduce hydrocarbon and carbon monoxide emissions, and to promote subsequent unit operations downstream, for example, by increasing the ratio of NO2 to NO. Adding other functionalities, such as three-way catalysts (TWC) [3] or ammonia selective catalytic reduction (SCR) [4], is more challenging, in part because of the volume of catalyst necessary to achieve desired conversions, as well as competition with soot oxidation reactions. This work describes characterization of catalyst distribution throughout the volume of one commercially produced SCR-filter brick using a combination of approaches including physical sectioning, optical examination, mercury porosimetry, microscopy, and X-ray computed tomography (CT)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
