Case Study: Fluid bed dryer-screener system quadruples production of granular chemical
By KasonFeatures chemicals circular vibratory screener granular Kason separator Vibro-Bed Vibroscreen
A circular fluid bed dryer equipped with an integral circular vibratory screener quadrupled production of a proprietary granular chemical product, and improved quality by increasing the consistency of drying times.
Granules are Pre-Screened, Dried, Re-Screened
The product is comprised of a granular carrier material, a filler material, and an active ingredient. The Vibro-Bed circular fluid bed dryer reduces moisture content of the converted material to less than 1.0 percent at 49°C, after which it is discharged into an integral 48 in. (1220 mm) diameter, two-deck Vibroscreen separator that removes (oversize) agglomerates and (undersize) fines, and discharges into storage containers at a rate of 907 kg/h. Afterwards the filler material and active ingredients are added, and the batch undergoes a proprietary conversion process.
Rectangular Fluid Bed Dryers Considered
The company’s engineering manager says he considered a rectangular fluidized bed dryer but found it cumbersome and costly. Rectangular fluidized beds, he explains, “work fine but are twice as large as a circular unit, requiring massive infrastructure and ancillary equipment, and they require higher airflow, consuming more energy.
“We were impressed with the circulating unit’s small footprint, fluidizing action, speed of drying, and modularity — you can move it without difficulty. We also had operating experience and a comfort level with circular vibratory screeners that look and function like a circular fluidized bed dryer.”
Circular Fluid Bed Dryer/Screener Operation
Converted material from storage containers is fed into the top inlet of the dryer by a bucket elevator. In the fluid bed chamber, the material vibrates on a circular screen within a rising column of 49°C air created by an upstream heater/blower ducted into the bottom of the chamber.
The continuous airflow, and vibration induced by two vibratory motors and spring suspension, separate and fluidize individual particles, maximizing surface area and drying efficiency.
The vibratory action also causes material to travel from the centre of the screen to a discharge spout at the screen’s periphery in controlled spiral pathways on a first-in-first-out basis, ultimately discharging dried material into the top-centre inlet of the circular vibratory screener.
An imbalanced-weight gyratory motor positioned beneath the chamber of the screener vibrates two screening decks. Oversize particles travel in controlled spiral pathways from the centre of the screen to a spout at the screen’s periphery where they are discharged for reprocessing.
On-size and undersized particles pass rapidly through the top screen to a bowl-shaped feed tray that directs them to the centre of the second screen. On-size particles travel in controlled spiral pathways to a spout at the screen’s periphery where they are discharged, while undersize material passes through the screen onto an integral metal chute that discharges it through a third spout for reprocessing.
Analyze Separated Material
Since any increase in the ratio of active ingredient to carrier and filler increases the occurrence of agglomeration, the company monitors the ratio of agglomerates to on-size material to detect whether any process variation has affected distribution of the active ingredient.
Since the drying-screening portion of the overall process operates offline, it can also be utilized to dry raw materials containing excess moisture, or dry other bulk products manufactured by the company.
In anticipation of wide-ranging drying applications, the system was engineered to operate at temperatures higher than that required to dry the proprietary chemical.
Improved Labour Utilization
According to the engineering manager, operators previously moved back and forth between tasks while waiting for product to dry and were unable to focus adequate attention to either task, raising the chance for error. “Operators are now fully utilized in producing and drying the product, with significantly less error,” he says, and reports that the drying-screening system paid for itself in less than six months from combined productivity gains and labour savings.
This case study is courtesy Kason from the Kason Chemical & Plastics Sourcebook
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