The Perfect Fit
(May 2006, Alan E. Rimer for WE&T)
This practical decision matrix can help any utility create a viable water reuse
program
As concerns about water shortages grow, many municipalities have begun exploring
water reuse programs. Some states now require municipalities to consider water reuse
before building a new water or wastewater treatment plant or upgrading an existing
one. Reusing water can keep water tables from dropping, lakes from shrinking, and
wetlands from disappearing. In effect, the reused water becomes a new resource.
Urban areas have many potential uses for reclaimed water, including manufacturing
and cooling processes, toilet flushing, dual-system utility supplies, recreational
lake supplementation, and irrigation of golf courses, parks, cemeteries, and large
landscaped areas. The challenge is determining whether potential industrial, commercial,
and residential customers would be best served by a centralized or a decentralized
water reuse system.
Early water reuse programs were centralized. They typically involved upgrades to
an existing wastewater treatment plant and elaborate storage and distribution systems,
which often made them difficult to justify economically. So, design engineers began
considering satellite water reclamation facilities - compact systems built near
potential customers and major sewer trunk lines. This decentralized option can be
more cost-effective if the customer base isn't too diffuse.
To determine whether a centralized or a decentralized water reuse system would best
suit their needs, municipalities will need to answer the questions outlined below.
What are our long-term needs and goals?
When deciding whether to base a reuse program on an existing treatment plant or
on satellite water reclamation facilities, a municipality should begin with its
wastewater master plan. This comprehensive plan should include:
- existing and projected wastewater flows,
- a map of the existing collection and treatment system,
- a description of the system's current condition and the specific improvements needed,
and
- a capital improvement program for meeting future wastewater collection and treatment
needs.
Where are our reuse customers?
The municipality then should conduct a market study to identify potential uses for
reclaimed water, potential customers, and the volume of water these customers would
need. The potential customers should be pinpointed on a collection system map to
determine whether they are clustered in specific parts of the service area.
Table 1. Alternative Screening Matrix
|
Rating criteria (1=unfavorable, 5=favorable) |
Weight factor |
SWRF alternative/score |
Regional plant alternative/score |
|
Ease of operation |
15 |
3 |
4 |
|
Operational complexity |
|
45 |
60 |
|
Control requirements |
|
|
|
|
System Reliablity |
25 |
4.5 |
4 |
|
Equipment |
|
112.5 |
100 |
|
Title 22 |
|
|
|
|
Ease of implementation |
15 |
3.5 |
4.5 |
|
Design |
|
52.5 |
67.5 |
|
Construction |
|
|
|
|
Permits |
|
|
|
|
Aesthetics |
5 |
4.5 |
22.5 |
5 |
25 |
|
Capital Costs |
20 |
5 |
100 |
4 |
80 |
|
O&M costs |
20 |
5 |
100 |
3 |
60 |
|
Total |
100 |
432.5 |
392.5 |
|
Rank |
|
1 |
2 |
Source: Rimer et al., 2003
Should we decentralize?
Then, the municipality should decide whether to produce reuse-quality water at the
existing wastewater treatment plant (upgrading it, if necessary) or build satellite
facilities at strategic points throughout the service area. Before comparing alternatives,
however, the municipality should develop appropriate evaluation criteria and assign
each a "weight" based on the community's priorities (see Table 1, above). The total
sum of the weights should equal 100.
When evaluating an alternative, the municipality should rate each criterion from
1 (unfavorable) to 5 (favorable), multiply each score by the criterion's weight,
and add all the weighted scores together to get a total score. Then, a simple comparison
of totals will reveal the best option.
Cost obviously matters, and municipalities should not forget distribution piping
and pumping costs when evaluating alternatives. Annual pumping energy costs, for
example, may make the centralized option surprisingly more expensive than building,
operating, and maintaining three new satellite facilities (see Table 2, below).
Table 2. Summary of Total Present Worth
|
Capital cost |
SWRF alternative |
Regional plant expansion alternative |
|
SWRF-1 |
$6,300,000 |
|
|
SWRF-2 |
$1,100,00 |
|
|
SWRF-3 |
$2,600,000 |
|
|
Regional expansion alternative |
|
$3,035,000 |
|
Pipelines |
$2,203,000 |
$8,696,000 |
|
Resevoir and pump station |
|
$1,310,000 |
|
Total capital cost |
$12,203,000 |
$13,041,000 |
|
O&M cost |
|
|
|
Annual O&M cost |
$432,000 |
$572,000* |
|
Present worth O&M cost |
$4,955,000 |
$6,561,000 |
|
Total present worth cost |
$17,158,000 |
$19,602,000 |
* *About $100,000 of the total annual O&M cost is the additional cost for boosting
flow back into the reclaimed water distribution system.
Source: Rimer et al., 2003
Which treatment technologies should we consider?
Generally, advanced treatment technologies with small footprints, such as biological
aerated filters, integrated fixed-film activated sludge systems, membrane bioreactors
(MBRs), and moving-bed biofilm reactors, are appropriate for an existing treatment
plant or satellite facility intended for a water reuse program. All require fine
screening of the influent, but the degree of screening varies with the technology.
MBRs require the most stringent screening (a 1- to 3-mm mesh screen, depending on
the membrane manufacturer).
Alternatively, a conventional activated sludge facility could be retrofitted with
shallow- or deep-bed tertiary filters to produce reuse-quality water.
Afterward, the treated water can be disinfected via ultraviolet irradiation or hypochlorite,
depending on whether it is more important to have a compact footprint or a chlorine
residual in the distribution system.
Which technology is best for our project?
The choice of treatment technology should be based on such issues as aesthetics,
effluent quality, footprint, life-cycle costs, odors, and operations and maintenance
(O&M) requirements - as well as the life-cycle costs of the related reclaimed water
distribution system.
Aesthetics. An enclosable system that can be designed to "blend in" with the surrounding
neighborhood is important if public exposure is high.
Effluent quality. The treatment system must meet local water quality requirements.
Currently, most compact advanced processes meet California Title 22 water reuse
standards.
Footprint. Satellite facilities generally have limited space, so the smaller the
system, the better.
Life-cycle costs. When comparing life-cycle costs of the centralized and decentralized
water reclamation options, municipalities shouldn't forget the related distribution
system costs.
Odors. Many compact advanced technologies do not require primary or secondary clarifiers,
so odor emissions are minimal compared to a conventional wastewater treatment plant
with large, open basins.
O&M requirements. Ideally, a satellite facility should be automated and require
minimal staff attention.
Is this a good satellite facility design?
Most water management professionals know that a wastewater treatment facility should
be built in the lower reaches of a watershed, but where should satellite water reclamation
facilities be built? The optimum location is where demand is greatest, sewer trunk
lines are close, and sufficient wastewater flow is available (see Table 3, below).
One important construction goal is to minimize both the suction line from the sewer
and the distribution lines to customers.
When analyzing plans for satellite facilities, municipalities should evaluate them
based on several economic and noneconomic factors, including aesthetics, reliability,
capital costs, O&M costs, ease of implementation (how easily it can be designed,
constructed, and permitted), and ease of O&M.
Oak lsland's Experience
Oak Island, N.C., is a rapidly growing beach resort. The town currently has about
7200 full-time and 32,000 summer residents. Within 20 years, it expects to have
nearly 18,700 full-time and 42,000 summer residents.
The Oak Island wastewater treatment plant, which is on the mainland, currently serves
about 10% of the area's existing homes. The collection system includes about 24
km (15 mi) of sewers, 13 lift stations, and about 900 connections.
Table 3. Satellite Water Reclamation Facility Design Flows
|
Satellite water reclamation facility |
Tributary trunkline sewage flow (gal/d) |
Recycled water demand (gal/d) |
SWRF capacity (mgd) |
Identified user |
|
SWRF-1 |
650,000 |
625,000 |
0.63 |
Community college |
|
SWRF-2 |
450,000 |
115,000 |
0.11 |
Industry - process |
|
SWRF-n |
|
|
|
|
|
SWRF-n+1 |
500,000 |
260,000 |
0.26 |
Industry - cooling |
|
Total |
1.6 million |
1 million |
1.0 |
|
SWRF = satellite water reclamation facility
Source: Rimer et al., 2003
While this table only identifies point-of-sale customers, it also could apply to
dispersed irrigation or other customers near the satellite facility
The rest of the homes on the island are served by septic tanks, which have begun
discharging untreated wastewater to the surrounding Intracoastal Waterway. Given
expected growth, increasingly stressed groundwater supplies, and persistent septic
tank failures, the town needed to expand its wastewater utility to reduce fecal
coliform contamination and restore dissolved-oxygen levels in the waterway. Also,
Oak Island already produces reclaimed water in its mainland portion and considers
development of more reclaimed water capacity to be a prudent use of available resources.
After answering the questions listed above, the project team determined that the
most cost-effective option would be an island-wide vacuum collection system and
a new 1500-m3/d (400,000-gal/d) satellite facility that could produce reusable water
for irrigation and cooling towers. The existing treatment plant already produces
reclaimed water, but building a distribution system back across the lntracoastal
Waterway would have cost nearly $4 million. And according to the market study, there
are enough customers on the mainland to use all of the plant's reclaimed water.
The satellite facility, which will be in a park next to Town Hall, will use an MBR
to treat wastewater so it can be reused by island residents. The project team also
intends to build about 3000 m (10,000 ft) of distribution mains to various reuse
customers. At press time, construction was expected to begin in June or July.
This facility - the first in North Carolina to use an engineered MBR - and a small
portion of the reuse distribution system are estimated to cost about $2.6 million.
The project was not eligible for funding through the North Carolina Clean Water
Revolving Loan Fund, so the team applied for and received a grant from the North
Carolina Clean Water Management Trust Fund to design and construct the project.
The project met a number of the trust fund's goals, including reducing pollution
of state waters by eliminating failing septic tanks.
Bangkok's Experience
Samut Prakarn province south of Bangkok, Thailand, has a 526-000-m3/d (139-mgd)
wastewater treatment plant and hundreds of kilometers of collection lines, but none
of this system has been placed into service.
The extended aeration plant has a large pretreatment system that includes four 12.5-mm
bar screens, four vortex grit collectors with agitators, and three 336-m x 157-m
x 3.84-m pretreatment basins. This system is expected to achieve 60% solids removal
and 50% biochemical oxygen demand (BOD) removal. The plant also includes eight 55-m-diameter
secondary clarifiers that function at overflow rates up to 2.2 m/h and solids loadings
up to 10 kg/hom3.
Sludge handling is limited to temporary storage while disposal options are developed.
Theoretically, the primary storage ponds can hold about 2 years' worth of sludge,
while the secondary lagoons can hold the equivalent of 1 year's worth of sludge.
The related odor issues have not been addressed.
Overall, the treatment plant is designed to produce effluent with 20 mg/L of BOD,
50 mg/L of total suspended solids, and less than 5 mg/L of ammonia-nitrogen. It
was planned to discharge to the Gulf of Thailand. However, concerns about the ecologically
sensitive gulf, which is home to green mussels and other commercially valuable aquatic
life, prompted the government to "mothball" the wastewater utility while it evaluated
other uses for the reclaimed water.
Initial market studies suggested that a water reuse program might be effective.
A detailed market evaluation revealed four possible options: industry, agriculture,
aquaculture, and groundwater recharge.
Samut Prakarn has nearly 6000 factories, which collectively use about 165,000 m3/d
of water. At the moment, however, many are reluctant to use reclaimed water for
product manufacturing because of concerns about variability in water quality, related
regulatory and export limitations, and customer acceptance. Nevertheless, the project
team believes that industrial reuse will become a viable option during the next
30 years, because groundwater use will be tightly controlled or eliminated in the
future, and water will be scarce in the dry season.
The province also has large agricultural and aquacultural areas in the east and
near the existing treatment plant. The project team estimated that local farms will
need 265,500 m3/d and local fish farms will need 149,900 m3/d during the 6-month
dry season.
Meanwhile, overpumping has been depleting local aquifers, and the government wants
groundwater withdrawals to cease within the next 5 years. To supplement and rebuild
these aquifers, the project team recommended starting by building 10 recharge wells,
which would add 30,000 m3/d of reclaimed water to groundwater supplies.
To ensure that the reclaimed water would be suitable for agriculture, aquaculture,
or groundwater recharge, the project team considered several treatment and distribution
options and determined that adding disk filters to the existing treatment plant
would be the most cost-effective alternative.
This option isn't the best choice for industrial reuse, however, because too much
pumping would be required. Instead, the team recommended that several satellite
water reclamation facilities be constructed to serve these customers, beginning
with a 10,000-m3/d demonstration facility. This facility, which would use an MBR,
would promote public acceptance and build industry confidence by showing that reclaimed
water can be a high-quality, reliable source of water.
These case studies illustrate the many decisions that any community faces as it
begins to evaluate using reclaimed water on a communitywide basis. A structured
approach to decision-making that involves all aspects (from aesthetics to financing)
provides the best opportunity to make the right decisions.
Alan E. Rimer is practice leader for water reuse in the Cary, N.C., office of Black
& Veatch (Kansas City, Mo.).
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