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by Dale E. Tompkins,
glass industry application
engineer — Kirk & Blum
Ineffective cullet dust
collection can drag down
a glass plant's performance
and productivity. If not
properly handled, cullet
dust (or "sugar cullet")
developed from crushing
operations can drift and
settle on finished product,
scratching surfaces and
profits. Large central
cullet dust collection
systems — traditionally
designed around one or
two large baghouse units — were
a high-maintenance, high-cost
necessary evil used to
control the nuisance dust.
Usually located outside
a plant and fed by massive
trunklines, these energy-draining
collectors require up to
200-hp fans running continuously
regardless of air supply
requirements. Maintenance
on baghouses is cumbersome
and time consuming, and
requires the entire dust
collection system to be
shut down while work is
done. Inherently inflexible,
central collection systems
also hamper future expansion,
can be cost-prohibitive
to expand and often require
costly, major reworking
to accommodate inevitable
process changes.
Drawbacks
such as these are driving
the trend toward modular,
multi-collector system
designs using numerous
small collectors located
close to dust pickup
points. Multi-collector
systems, using maintenance-friendly
cartridge-style collectors instead of traditional
baghouse collectors, provide:
- greatly decreased
energy cost due to
lower horsepower requirements;
- reduced
system maintenance
downtime;
- smaller duct length
and diameter;
- flexibility for
future system expansion;
and
- better overall dust
control.
On a recent rebuild
for a large building products
manufacturer in Laurinburg,
NC, Kirk & Blum,
designer, fabricator and
installer of process ventilation
systems, engineered a modular
dust collection system
for the flat glass producer
to handle increased dust
collection requirements
which would have overloaded the existing large baghouses.
Since completion, the amount of fugitive sugar cullet
has been negligible, the plant is getting effective
dust collection even while system maintenance is
performed, and plant is realizing $71,855 annual
energy savings.
Case in Point: New crushers,
more dust, modular systems
cuts fan hp 38%
In response
to costly and time consuming
cullet conveyor system
breakdowns, the glass plant
installed a new-technology
glass crushing system. Cullet, developed by crushing
flawed as well as thickness- and color-transition
sheet, falls onto conveyors located in a pit below
the main floor for recycling back to the furnace.
With the manufacturer's old cullet conveying system,
pieces of glass simply fell through hoppers, crushing
hoppers, edge trim hoppers or mechanical crushing
hoppers directly onto the conveyor's rubber belts.
Large falling cullet caused belt damage and occasional
hopper back-up, leading to costly and time-consuming
maintenance shutdowns.
To remedy this situation,
the manufacturer purchased
new technology crushers, crusher hoppers and vibratory
pan crushing conveyors to reduce the size of cullet
falling on the conveyors.
The new system produces
smaller-sized
pieces of glass, reducing conveyor belt damage, but
also creating a greater amount of sugar cullet. An
unwanted ingredient composed of sand, soda ash, limestone,
gypsum and other ingredients, sugar cullet poses
no environmental or OSHA problem, but is considered
a nuisance dust. It clings to conveyor belts, causes
dust piles and clouds at belt wipe brushes and beater
bars, and can scratch finished product if allowed
to escape out of the pit and drift onto the plant's
main floor.
Modular System Design
Deviating from traditional
central-collector system design, K&B engineered
a modular dust collection system around six small
cartridge-style collectors placed in the plant
close to dust pickup points, and one large unit
located outside the plant because of floor layout
restrictions. Placing collectors close to pickup
points decreased duct diameter and length as well
as horsepower requirements for the fans. In most
cases, fans on the small collectors were placed
on the collector roof or sidewall to save floor
space. Total horsepower requirement for the seven
motors used for this rebuild was 325hp — 200hp
less than if all collectors would have been located
outside. This provides the plant with an annual
energy cost savings of $71,885, covering the dust
collection system cost in eight years, and realizing
money-in-pocket savings from that point on.
Unlike
airhandling systems for woodworking or mist removal
applications,
thick-gage duct was used because of the abrasive
nature of cullet particles and
dust. Many sheet metal contractors shy away from
heavy gages to keep bids
low or because they simply cannot handle the
thicker sheetmetal. However, skimping on duct
gage to initially save a few pennies ends up
costing more in
the long run with repeated duct removal-and-replacement
maintenance operations. Sufficient abrasion resistance — especially
for elbows — is critical for long-lived
system performance for glass industry dust handling
applications. Typical duct thicknesses for this
project were:
- 14 gage-minimum straight
sections;
- small elbows of
1/4" abrasion
resistant plate;
- large elbows of 10
ga. abrasion resistant
plate.
Cartridge Convenience
Cartridge-style
collectors were chosen
by K&B
because of their reduced size, ease of maintenance
and lower overall cost versus large bags. Cartridge
filters have a protective metal wrap which shields
against pieces of cullet that may be picked up by
the system. The filter element is further protected
by a metal baffle located above each row of cartridges
within the collector, which deflects incoming cullet
away from the cartridges.
Smaller cartridge-style
collectors are more accessible
and easier to work on than large baghouses. For example,
horizontally mounted cartridges in the largest collector
in this system (96 cartridges) can be changed by
one person in one or two hours, with small four and
eight-cartridge collectors taking one person only
five minutes to change. Bag replacement in a baghouse
requires two or more workers at least one full day,
leading to increased maintenance costs and prolonged
system downtime. Individual collectors in modular
systems can be shut down and repaired while the other
collectors remain online, providing constant dust
handling.
Cartridge change is also
a much cleaner operation.
In the event material (More)
discharge points are not
emptied on schedule, cartridge
collector hoppers —
being smaller — are easier to clean out, and
cartridges are also less likely to be damaged by
such neglect. To remove dust collected on the outside
of the cartridge while the collector is online, each
cartridge row is alternately pulsed with compressed
air, saving on compressor usage versus some baghouses
which continuously send air through bags to remove
material coating the bags.
Modular Benefits
Modular
collector systems are
ideal where dust collection
is not always needed for
pick up points far down
the line or crushers that
do not run constantly.
Multiple unit collectors
can be tied into conveyors
and run only when needed,
resulting in additional
energy savings. For situations
where glass can travel
down multiple legs but
not down two adjacent legs
at the same time, diverter
valves or butterfly dampers
isolate the leg needing
air, thus lowering the
overall system air volume
requirements.
In nearly
every case, dust collection
needs will change with
future system expansion.
With large-collector
systems, it is likely that
the entire system will
need extensive reworking.
With smaller modular systems,
fans and collectors can
be easily added or relocated.
And if duct is to be scrapped,
it is more cost-effective to throw away smaller
diameters as opposed to massive sections of
trunkline. Smaller-diameter
duct is also more apt to
be reused for other applications.
Cost/Value
Price is often
the driving factor behind
such systems. Typically,
sheet
metal work is thrown into
a mechanical package that
includes civil, electrical and piping work. It is
most often considered a
minor item to be handled
by the
lowest bidding sub-contractor regardless of experience
or engineering capabilities. In this case, the glass
manufacturer had the foresight to focus not
only on initial costs, but on the total cost savings
it would realize having a system engineered by K&B
to provide years of low-maintenance service, be more
conducive to future growth and expansion, and require
less energy to run.
Cartridge
Versus Bag Replacement Bag
change in a typical baghouse
is a time-consuming and
messy operation, often
taking a two-person team
an entire day to complete. First the bag and its
support cage are removed and taken outside the collector.
The bag — in lengths to 12' and completely
coated in sugar cullet — is ripped off the
cage and disposed of, and a new bag installed over
the cage. The bag is then brought back into the baghouse
and reinstalled. Cartridge replacement
is much easier and cleaner.
The cartridges are mounted
horizontally, two-deep
in tubes within the compact
collector. Unscrewing a
large wingnut allows the
tube cap and cartridges
to be removed. Cartridges literally slide out thanks
to the collector design in which tubes are angled
upward in the back. Installing cartridges, cap
and wingnut completes the
job. The largest collector
for this rebuild has 96 cartridges, and takes one
person one to two hours to change cartridges. Small
four- and eight-cartridge collectors take one person
a mere five minutes for changeout. |
