Merit Partnership Pollution Prevention Project for Metal Finishers
& Modifying Tank Layouts
To Improve Process Efficiency
The Merit Partnership is a joint venture between U.S.
Environmental Protection Agency (EPA) Region 9, state and
local regulatory agencies, private sector industries, and
community representatives that was created to promote
pollution prevention (P2), identify P2 technology needs, and
accelerate P2 technology transfer within various industries in
southern California. One of these industries is metal finishing,
which is represented in the Merit Partnership by the Metal
Finishing Association of Southern California (MFASC).
Together, MFASC, EPA Region 9, and the California
Manufacturing Technology Center (CMTC) established the
Merit Partnership P2 Project for Metal Finishers. This project
involves implementing P2 techniques and technologies at metal
finishing facilities in southern California and documenting
and sharing results. Technical support for this project was
provided by PRC Environmental Management, Inc. The project
is funded by the Environmental Technology Initiative and
EPA Region 9, and is implemented, in part, through the
National Institute of Standards and Technology with CMTC.
INTRODUCTION
The layout of metal finishing process tanks and rinse tanks
plays an important role in overall process efficiency as well as
in waste generation. At most metal finishing facilities, process
lines evolve as tanks are added, removed, or become obsolete
because of production demands and development of new
process chemistries. Over time, process changes can result in
inefficient tank layouts, which often limit or complicate many
P2 opportunities, particularly closed-loop recycling
technologies.
This case study illustrates the benefits of evaluating conditions
at your facility and considering tank layout changes before
pursuing other P2 opportunities. Modifying tank layouts can
significantly improve production efficiency in terms of raw
material use, water use, and throughput; reduce waste
generation; and facilitate application of chemical recovery
technologies.
ALL METALS PROCESSING COMPANY
All Metals Processing Company (All Metals) is a small job
shop in Burbanlc, California, that performs cadmium, bronze,
and zinc electroplating and black oxide coating for aerospace
and other industrial customers. All Metals employs 15 workers,
and its facility has about 8,000 square feet of space for plating
operations.
All Metals uses about 7,800 gallons of water per day, most of
which is used for rinsing operations. Wastewater containing
metals and cyanide flows from rinse tanks to the on-site
wastewater treatment system (WWTS). In addition, dragout
and water from rinse tanks that spill onto the floor drain to a
sump from which they are pumped to the WWTS. The WWTS
currently generates about 680 pounds of filter cake per month,
which is disposed of in an off-site hazardous waste landfill.
Treated wastewater is discharged to the publicly owned
treatment works (POTW). At the beginning of the project, All
Metals indicated that its goals were to reduce water use and
eliminate wastewater discharges by installing chemical
recovery systems. In cooperation with the Merit Partnership,
All Metals agreed to evaluate its process tank layout in order
to reduce the contaminant load and wastewater flow from rinse
operations before consulting with technology vendors.
"Bottom Line" Impacts of Dragout
High process solution losses through dragout will:
X Increase the quantities of plating chemicals used
X Increase rinse water use or decrease rinsing quality
X Increase wastewater generation
X Increase the quantities of WWTS treatment chemicals
used
X Increase the quantity of filter cake generated
X Potentially increase the metal concentration in the
WWTS discharge
These process inefficiencies increase shop operating costs
and decrease profits!
California Manufacturing Technology Center
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CADMIUM
CYANIDE
PLATING
CADMIUM
CYANIDE
PLATING
(not in use)
SPRAY
RINSE
(not in use)
COPPER/
BRONZE
STRIP
CADMIUM
STRIP
RINSE
Figure 1. Original Tank Layout with Work Flow Indicated by Arrows
CADMIUM ELECTROPLATING LINE:
ORIGINAL LAYOUT
All Metals selected the cadmium electroplating line for a tank
layout evaluation because it is the most frequently used process
line and because dragout from this line contributes the largest
quantity of metals to the wastewater. The original cadmium
electroplating line layout and work flow are shown in Figure 1.
After alkaline soak cleaning and acid etching, the cadmium
electroplating line consists of the following three processes:
(1) cadmium cyanide electroplating, (2) bright dip (chromic
acid-based), and (3) chromate conversion. Each process bath
is followed by one or more rinses.
Based on its evaluation, the Merit Partnership determined that
the original tank layout resulted in the following:
High Dragout Losses: Only one dragout tank and no spray
rinses were used in the original tank layout to recover process
solution dragout. Consequently, dragout was lost to single-
stage rinses that discharged to the WWTS. Dragout was also
lost to the floor because of large spaces between tanks.
High Rinse Water Use: The single-stage rinses required a
high rinse water flow rate to maintain adequate rinse quality.
Inefficient Work Flow: Work flow overlap and backtracking
increased worker fatigue, decreased process throughput, and
contributed to dragout loss to the floor.
Process Solution Mixing in a Shared Rinse Tank A shared
rinse tank resulted in process solutions from two operations
mixing in the rinse tank, which negatively impacted rinse quality
and prohibited potential recovery and recycling of the process
solutions.
CADMIUM ELECTROPLATING LINE:
MODIFIED LAYOUT
The Merit Partnership used a computer program called Perfect
Rinsing to (1) model the effects of adding tanks to the cadmium
electroplating line and changing tank configurations,
(2) estimate the benefits of these changes, and (3) determine
the preferred tank layout. Perfect Rinsing, which is produced by
Finishing Technology of Kennelon, New Jersey, is designed to
simulate metal finishing rinsing operations. Specifically, the
program computes key rinsing parameters, including
Features of the Modified Cadmium Electroplating Line
• A spray rinse tank after the cadmium plating tank
• A spray rinse tank after the chromate conversion tank
• Two-stage counterflow rinse tanks in place of single-stage
rinse tanks
• A counterflow rinse tank after the bright dip tank
• Straight line process flow for plating and rinsing operations
• No unused tanks
CADMIUM
CYANIDE
PLATING
CADMIUM
BARREL
PLATING
SPRAY
RINSE
Figure 2. Modified Tank Layout with Work Flow Indicated by Arrows
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concentrations of process chemicals in the rinse tank and the
process chemical discharge rate, based on input parameters
such as the dragout rate, process bath chemical concentration
and evaporation rate, rinse water flow rate, and number and
configuration of rinse tanks. The Merit Partnership determined
the dragout rate on the cadmium electroplating line by
measuring the increases in the metal concentrations in the
rinse tank for each rack of parts plated. Perfect Rinsing assumes
complete mixing and steady-state conditions of water in the
rinse tank.
ESTIMATED IMPACT OF TANK LAYOUT
MODIFICATIONS
The modified tank layout allows All Metals to (1) recover and
reuse process solution dragout, (2) reduce rinse water flow, (3)
improve rinsing, (4) implement more efficient work flow, and
(5) lower concentrations of metals being discharged to the
POTW. Perfect Rinsing results for the original and modified
layouts are shown in Figures 3 and 4 for cadmium plating and
chromate conversion, respectively, and are discussed below.
The Merit Partnership modeled several alternative rinse tank
configurations for the cadmium electroplating line by changing
the type and number of rinse tanks used and the rinse water
flow rates. Comparisons were then made of the total rinse
water flow rates, the total dragout losses, and the rinse quality
in the rinse tanks of the original and alternate configurations.
With allowance for the physical constraints at All Metals, such
as available floor space, and the nature of the production
processes on the cadmium electroplating line, the preferred
tank layout was selected, and tank layout modifications were
made (see Figure 2).
Recovery and Reuse of Process Solution Dragout: The spray
and dragout rinse tanks collect concentrated solutions that are
used to replenish process baths. The spray rinse tanks added
after the cadmium cyanide plating and chromate conversion
tank are expected to reduce process solution losses 50 percent
by (1) removing dragout left on parts before they reach the
running rinses and (2) using the dragout to replenish the process
baths. Process solution recovery will also be improved because
less dragout is lost to the floor between tanks. The reduction
of process solution dragout is expected to result in a 50 percent
decrease in the quantity of WWTS filter cake generated by
treating wastewater from the cadmium electroplating line.
Figure 3. Perfect Rinsing Results:
Cadmium Plating
Original
Cadmium Cyanide Plating Rinse Tank Layout
Rinse Water
\
0.005 gpm
J
~r
1.5 gpm
I
"
Cadmium
Cyanide
[Cd] = 13,803 ppm
¦*-l
0.32^)ph
Dragout
Rinse
[Cd] = 3,286 ppm
Rinse
[Cd] = 3.6 ppm
~VWVTS
Wastewater
Total flow = 1.5 gpm
Total Cd discharge = 0.04 oz/hr
Modified
Cadmium Cyanide Plating Rinse Tank Layout
Rinse Water
r
T
O.OO^gpm 0.00^ gpm
~r
0.5 gpm
Cadmium
Spray
Dragout
Cyanide
0.32 gph
Rinse
Rinse
[Cd] = 13,803 ppm
Jr-
[Cd] = 3,731 ppm
[Cd] = 1,865 ppm
r
Counterflow
Rinse |
[Cd] = 6.2 ppm
[Cd] = 0.02 pprr
~ WWTS
Wastewater
Total flow = 0.5 gpm
Total Cd discharge = 0.02 oz/hr
Figure 4. Perfect Rinsing Results:
Chromate Conversion
Original
Chromate Conversion Rinse Tank Layout
Rinse Water
I
0.75 gpm 0.75 gpm
I J
Chromate
Conversion
[Cr] = 13,406 ppm
Rinse
[Cr] = 205 ppm
Rinse
[Cr] = 3.1 ppm
Stagnant
Rinse
[Cr] = 0.7 ppm
r
~WWTS
Wastewater
Total flow = 1.5 gpm
Total Cr discharge = 1.25 oz/hr
Modified
Chromate Conversion Rinse Tank Layout
Rinse Water
Chromate
Conversion
[Cr] = 13,406 ppm
1
T
Counterflow
Rinse |
1
[Cr] = 155 ppm
[Cr] = 3.5 ppm
Wastewater
Total flow = 0.5 gpm
Total Cr discharge = 0.62 oz/hr
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Tank Layout Modification Results
Before After Cost
Modification Modification Savings
Cadmium
Cyanide Dragout 18 gal/mo 9 gal/mo* $400/yr
Chromate
Conversion Dragout 123 gal/mo 62 gal/mo* $180/yr
Rinse Water 31,700 gal/mo 15,800 gal/mo $360/yr
Sewer Fee 31,700 gal/mo 15,800 gal/mo $l,440/yr
WWTS Chemicals Not Quantified
WWTS Filter Cake 200 lb/mo 100 lb/mo* $240/yr
Total Cost Savings = $2,620/yr
Total Cost = $4,520
Payback Period = 1.73 years
* Estimated from Perfect Rinsing results
Reduced Rinse Water Flow: All Metals significantly reduced
rinse water flow by installing counterflow rinse tanks. Two-
stage counterflow rinses theoretically require 97 percent less
water than single-stage rinses to achieve comparable rinse
quality. Spray rinses and dragout tanks also reduce the total
rinse water flow required for effective rinsing. Although Perfect
Rinsing results indicated that flow rates of less than 0.25 gallon
per minute (gpm) could be used for the counterflow rinses,
All Metals conservatively installed 0.5-gpm flow restrictors on
its three rinse tanks in place of the 1.5-gpm flow restrictors
originally used on the two rinse tanks of the original layout.
The combined reduction in dragout and rinse water flow results
in a reduction of the quantities of wastewater treatment
chemicals used.
"Since implementing the tank layout
changes, our wastewater treatment chemical
use has declined by 60 percent."
Tim Roach
Manager, All Metals
Improved Rinsing: As shown in Figure 3, the concentration
of cadmium in the last cadmium cyanide rinse tank is estimated
to have decreased by 99 percent, which results in a dramatic
increase in rinsing quality. Such a change improves overall
process efficiency, reduces the numbers of reject parts, and
reduces dragin to other process baths.
More Efficient Work Flow: Repositioning the tanks decreased
the amount of worker time and effort required to move parts
through the cadmium electroplating line. As a result, All Metals
has the capacity for increased process throughput.
Number of Footsteps Needed
for Cadmium Line Electroplating
Before Modification:
After Modification:
58
21
Lower Concentrations of Metals in WWTS Discharge: The
concentrations of cadmium and chromium discharged from
the WWTS to the POTW are expected to decrease as a result of
dragout reduction and process chemical recovery. This will
help All Metals consistently meet its cadmium and chromium
discharge limits, which will result in a cost savings by reducing
paperwork and fines paid for permit violations.
COSTS
The capital costs for the tank layout modifications included
$2,000 for two used counterflow rinse tanks and $600 for two
new spray rinse tanks. Costs for ancillary materials such as
plumbing hardware were not recorded; however, these costs
were not significant. Therefore, the total capital cost for the
tank layout modification was $2,600. Modifications were
performed by three shop workers in about 8 days and the total
labor cost for modifying the tank layout was $1,920. No
operation and maintenance (O&M) activities are needed for
the modified tank layout beyond those required for the original
layout. Therefore, no additional O&M costs are being incurred
as a result of the tank layout modifications.
THE NEXT STEP:
CHEMICAL RECOVERY TECHNOLOGIES
By reducing dragout and rinse water flow rates through tank
layout modifications, metal finishing facilities can more cost-
effectively apply chemical recovery technologies. By modifying
its tank layout for the cadmium electroplating line, All Metals
reduced dragout and rinse water use at the point of generation,
segregated rinses, and maximized production efficiency. All
Metals is now evaluating technologies to recover process
chemicals from wastewater for reuse in the process tanks. In
addition, these technologies also usually generate clean water
that can be recycled into the rinse tank for reuse. Potential
chemical recovery technologies include reverse osmosis, ion
exchange, vacuum evaporation, and electrowinning.
Chemical Recovery System Design Parameters
Cadmium Loading
Chromium Loading
Wastewater Flow Rate
Before
Modification
0.04 oz/hr
1.25 oz/hr
3.0 gpm
After
Modification
0.02 oz/hr
0.62 oz/hr
1.0 gpm
Dragout and wastewater flow reductions resulting from tank
layout modifications will enable All Metals to purchase a smaller
chemical recovery system, which will require less capital costs.
For more information on this case study or the Merit
Partnership, contact the following individuals:
Laura Bloch (EPA Region 9) at (415) 744-2279
John Siemalc (CMTC) at (310) 263-3097
Dan Cunningham (MFASC) at (818) 986-8393
Tim Roach (All Metals) at (818) 846-8844
Assistance for this fact sheet was provided by
PRC Environmental Management, Inc.
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