Passive DPFs

Passive regeneration refers to the process of cleaning a diesel particulate filter using the heat of the
exhaust gas alone. Diesel particulate matter will spontaneously combust when the temperature
exceeds about 550°C, but in most cases the exhaust gas of a diesel engine will never get that hot.
Fortunately, using catalytic technology, the combustion temperature can be reduced substantially,
and this facilitates passive regeneration within the range of exhaust gas temperatures which occur
regularly in many engines.
The temperature of the exhaust gas of a diesel engine varies according to the load placed on the
engine. To illustrate the point, here is a graph:
In order to work out whether a specific application is suitable for a passive DPF, the first question is
whether the engine load follows a predictable pattern. In some applications, such as a ferry on a
fixed route, a graph showing engine load against time will be very similar from one day to the next,
whereas in the case of a standby generator there may be no pattern at all. If there is a predictable
pattern, the next step is to install a datalogger and log the temperature over a period of typical use.
The data obtained from this exercise will enable an expert to predict whether passive regeneration is
a viable option, and if so, which version.
As mentioned above, catalytic technology is used to make passive regeneration practical. There are
four options as to how this technology is deployed, as follows:
1) A catalytic converter mounted upstream of the DPF oxidises nitrogen monoxide (NO) into
nitrogen dioxide (NO₂). The resulting NO₂, which is an oxidising agent, gives up its spare
oxygen atom to convert carbon in the diesel particulate matter into CO₂. This technology is
known as DOC+DPF (DOC refers to ‘Diesel Oxidation Catalyst’).
2) A catalytic coating is applied to the filter itself, known as CDPF (Coated Diesel Particulate
Filter).
3) A catalytic converter is installed upstream of a coated filter, referred to as DOC+CDPF.
4) A liquid known as a fuel-borne catalyst is mixed with the fuel, which results in small catalytic
particles being incorporated into the diesel particulate matter.
The advantages and disadvantages of these approaches are summarised here