Grain, feed, and seed facilities are often faced with a dirty situation when designing dust collection for rail car and truck dump pits.
Designing a dump pit with good dust collection in mind not only addresses the dirty situation but can save operational time and money.
Traditional dust collectors for these applications include local hoods that capture nuisance dust using large volumes of air that are then transferred to a remote baghouse dust collector. With an integrated point-of-use dust collector, nuisance dust from the grain or seed is still captured at the pit, but it can remain with the primary grain in the pit, eliminating any need for a duct system to a large remote baghouse dust collector.
Designed correctly, integrated dust collection can save potentially 25 per cent to 50 per cent of installed cost compared to traditional, remote baghouse dust collection.
In facilities that utilise several dump pits, a centralised system pulls air from all dump pits, even if only a few are active. With a-point-of-use system, air extraction (and the energy costs for operating fans) is only performed for the active pits. Inactive pits are left idle, rather than adding unnecessary air volume to the centralised dust system capacity.
Integrated point-of-use dust collection uses the same slotted baffles as traditional dump pit systems to control airflow at the dump pit opening. While grain is loaded into the pit, baffles swing open to allow grain to enter while leaving much of the unused pit area closed. After loading is completed, the baffles return to a close position to restrict nuisance dust from exiting the pit.
Point-of-use collectors stationed on either side of the pit create a slight negative pressure in the pit to capture nuisance dust. Dust pulsed from the filters during operation returns back into the pit and exits with the process grain stream.
Grain pulled into the waste stream of a conventional baghouse dust collection is often lost. It can sometimes be introduced back into a process stream with bucket elevators or conveyors, but these represent added capital and operational costs.
Also, if more than one type of commodity is processed at a facility, the mixture from a traditional baghouse collector may complicate return to the process stream. Point-of-use collectors eliminate this complication as they keep grain and dust within the original process stream.
Besides saving product otherwise destined to become part of a waste stream, point-of-use collectors can save both capital and installation expenses, while having a positive impact on operational costs.
As point-of-use collectors only see short duration surges of loading, a few smaller collectors replace the traditional large baghouse. Shipping costs for smaller point-of-use collectors are often much less, and eliminating ductwork lowers installation costs substantially compared to traditional remote dust collection. In addition, the reduction in ducts will reduce fan static requirements, allowing the selection of smaller, less expensive fans and controls leading to potential energy cost savings.
With all the potential costs in a dump pit process, yearly energy consumption offers the most notable cost advantages when considering point-of-use dust collection.
As a final consideration, look at the downtime consequences on a facility when filters need to be serviced or replaced. A traditional baghouse requires several workers for filter replacement. By contrast, filters in point-of-use collectors are typically changed with relative ease from outside the collector, typically only requiring a single worker. The units in our earlier example could be fully serviced in just a couple of hours.