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Chemical Plant:
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Reprinted
from Chemical Processing
Evaporator Limits Boron
To 5 PPM At Award-Winning
Chemical Plant
Skimmer
holds oil to under 50 ppm;
pH equipment maintains range of 6.0-8.5
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Spray-film
evaporator reduces plant sewer discharge and fresh water requirements.
Ventron's sodium borohydride plant in Elma, Washington Oil skimmer
is operated continuously in both the discharge and stormwater
basins. Fiberglass reinforced plastic storage tanks are used
to store the evaporator concentrate PH controller is used to
monitor and control the addition of sulfuric acid or carbon
dioxide into the wastewater system. |
Problem:
the biggest challenge confronting Ventron Corporation in building
a wastewater plant for its chemical facility in Elma, Washington,
was meeting Washington State Dept. of Ecology limitations on boron
of 5 ppm. The Elma plant manufactures sodium borohydride, a versatile
chemical used in a variety of applications ranging from the generation
of sodium hydrosulfite for reductive bleaching of wood pulp, to
the purification of process chemicals. It is used as a pollution
control method, to remove heavy metals from wastewater.
Some limitations contained in the Dept. of Ecology Waste Discharge
Permit are routine, such as BOD, COD, suspended solids and total
oils, while others are specific to the Elma plant, such as boron,
zinc from cooling tower treatment and the ratio of the plant's flow
to the residential discharges. In addition, both the Washington
State Dept. of Ecology and EPA required the plant to submit an "Oil
Spill Prevention, control and Countermeasure Plan."
Solution: the first step in water pollution
control at the Elma plant is collecting and impounding all wastewater
from the plant. This is accomplished with three underground sewer
systems. The first of these sewers connects all chemical drains,
sending the discharge to a 15,000 gallon concrete basin. The second
of the underground sewers collects stormwater from all the padded
and diked areas of the plant and sends it to a second, 10,000 gallon
concrete basin. The third sewer is for sanitary wastewater only,
and flows directly to the municipal sewer. The contaminated wastewater
and stormwater are not suitable for discharge without further processing.
Oil
Removal
Oil
is removed with a Model 6V oil skimmer. The
skimmer is designed to be used in either basin and has operated
effectively with varying types of oil. The unit operates continuously,
skimming oil from the surface, as it enters the basin. There is
no chance for accidental discharge.
A closed loop of a specially formulated, flexible, hollow tube floats
on the water surface. Oil adheres to its surface but water is repelled.
The skimmer continuously draws the oil-covered tube through scrapers
and returns the clean tube to the water surface to gather more oil.
The skimmed oil flows by gravity through the mounting system or
a trough to the storage tank. The flexible, floating collector tube
is able to snake over and around floating debris to reach the floating
oil. It floats up and down with varying liquid levels. The flexible
tube flops so that it breaks up crusted oil or grease enabling it
to adhere to the tube. Six to fourteen feet of tubing floats in
the skimming area.
pH
control
The
original plant design called for pH adjustment with sulfuric acid.
A circulation system was installed to permit the addition of concentrated
acid to the recycle stream from the basin.
Shortly after plant startup, Ventron initiated a cost savings project
to use CO2 rather than sulfuric acid for neutralization. In addition,
the potential for over neutralization is reduced, as the minimum
possible pH using excess CO2 is about 6. The source for CO2 is a
waste gas stream from the hydrogen-generating unit, less than 100
ft. from the effluent basins. A sparge nozzle was installed at the
bottom of each of the basins to receive the waste gas stream which
is piped directly from the Hydrogen Plant.
The
system uses a flow through pH sensor and pH transmitter/analyzer
to control the amount of CO2 sparged. The pH sensor measures the
pH of the flowing aqueous fluid, and in this case, is installed
directly in the stream to the holding basins.
The
sensor consists of a flow chamber, glass and reference electrodes,
temperature compensator, and an ABS junction box containing a preamplifier.
These components are mounted on an ABS back-plate which is clamped
to a 2" pipe.
Since
the signal from the sensor is preamplified, the transmitter/analyzer
can be located as far as 3 miles away from the point of measurement.
Signal transmission requires only an ordinary four conductor shielded
cable.
Non-interacting
zero and span controls are used to adjust the output of the unit
to any desired range within 0 to 14 pH. This range may involve a
span as narrow as two pH units anywhere on the 0-14 pH range.
Evaporation
as final control
The
system requires evaporation as a final control step to meet the
5 ppm limit on boron in the effluent. Based on the operating economics,
Ventron chose a two-stage Spray-Film(r) vapor compression evaporator.
This unit concentrates both process and storm water to the 15-20%
total solids range.
This
type of evaporator has distinct advantages when handling low to
medium boiling point elevation solutions. Energy usage is exceptionally
low -- typically only 40 Btu per pound of water evaporated.
The
solution to be concentrated is sprayed over heated tube bundles
and is partially vaporized. The liquor that does not vaporize is
re-circulated for further concentration. The vapor is compressed
in a vapor compressor and returned to the evaporator module. Here
it condenses on the inside of the heating tube bundle, thus causing
vaporization of the recirculating solution.
Ventron
has been able to divert the evaporator distillate for use as a cooling
tower makeup water. This recycle serves a dual purpose, both reducing
the plant sewer discharge and the plant raw water requirement. With
this latest water conservation project to recycle the evaporator
distillate, the plant is one step closer to the zero-discharge level.
Presently, only the plant sanitary waste is sent to the municipal
sewer.
The
evaporator concentrate is collected in one of several fiberglass
reinforced plastic (FRP) storage tanks. The composition of the concentrate
is primarily sodium carbonate (sodium sulfate when acid neutralization
is used) and sodium borate. When sufficient quantity of concentrate
has been collected, it is trucked to one of two firms licensed for
waste disposal. It is interesting that one of these firms further
concentrates the sodium borate and sodium carbonate for use as an
additive in commercial fertilizer.Spill control measures
The
second area of pollution control involves the system of dikes and
curbs around storage tanks, process equipment, product loading area
and oil unloading area. All are designed to contain the contents
of the respective vessels in the event of a tank rupture or major
spill.
Results: Ventron used evaporation equipment
to meet the tight specifications on boron of 5 ppm or less in wastewater
effluent. Wastewater processing also includes oil removal to less
than 50 ppm and pH adjustment to the 6.0-8.5 range.
Since
use of heavy metal compounds in cooling water treatment was restricted,
Ventron substituted a phosphate-based corrosion inhibitor for the
commonly used zinc-based system. During the first two years of operation,
corrosion rates have been acceptable, ranging from 1 to 2 mils per
year.
Last
year The Pacific Northwest Pollution Control Association (PNPCA)
named Ventron Corporation as the recipient of its annual "Industrial
Pollution Control Award" for accomplishments in pollution control
at its new Elma, Washington facility. Mr. Richard Engelbrecht,
President of the Water Pollution Control Federation, presented the
award to Mr. John A. Durrell, Elma Plant Manager, at the 44th Annual
PNPCA Meeting held at the Hilton Hotel in Portland, Oregon on November
Third.
Ventron
Corporation was awarded one of six State Environmental Excellence
Awards for "innovative, state-of-the-art pollution controls"
at its Elma plant. The award was presented by Gov. Dixy Lee Ray
at a meeting of the Seattle Rotary Club. Winners were selected by
the Washington State Ecological Commission from a number of nominations.
Ventron was nominated for the award by Elma city
officials who pointed to Ventron's "cooperative, good neighbor
attitude" in making the nomination.
Ventron
Corporation, a subsidiary of Thiokol Corporation, actively sought
to achieve a high degree of pollution control in the planning stages
for the Elma plant. Although many of the accomplishments at Elma
were preceded at Ventron's plant in Danvers, Massachusetts, some
systems installed were totally innovative and required advancements
in state-of-the-art technology. Spill control measures at the plant
are exemplary and serve as a model for others in the industry. The
Washington for others in the industry. The Washington Department
of Ecology commended Ventron Corporation for having the most comprehensive
system in the area.
Automatic
Brill™ oil skimming system is described in Model 6V Brochure
from Oil Skimmers, Inc., P.O. Box 33092, Cleveland, OH 44133
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