The
city of Indian Harbour Beach is located on central Florida’s eastern barrier
island at the convergence of the Banana River and the Indian River Lagoon (IRL),
which are actually bays. The city abuts the Atlantic Ocean on the east and the
Banana River on the west. Essentially, the whole city is urbanized and
developed, with only a few vacant parcels of undeveloped lots. The population is
estimated to be over 1,800 people.
The
IRL was designated in 1991 as one of the first National Estuaries in the
country. The IRL—and, in particular, the subsection named the Banana River—is an
important economic resource for Indian Harbour Beach. Over the last 20 years,
the health of the river has markedly declined, with significant losses of
critical seagrasses and fisheries. The principal cause of degradation of the
Banana River has been polluted stormwater runoff.
To
address stormwater pollution problems in the IRL, the Florida Department of
Environmental Protection (FDEP) is implementing the total maximum daily load
(TMDL) program with the following goals:
- Evaluation of the health of
the Indian River Lagoon
Determination of the
pollutant loadings entering the water body- Estimation of the
assimilative capacity of the water body to receive pollutants without
degradation
- Calculation
of the reductions in pollutant levels necessary to avoid exceeding the
assimilative capacity of the water body
- Assigning pollutant load
allocations/reductions to communities and stakeholders within the
watershed
To
comply with proposed load allocations, communities will be required to undertake
several steps to reduce their stormwater pollutants. These steps include
retrofitting existing stormwater infrastructure to add stormwater treatment
facilities to the systems, launching public education programs, increasing
development regulations, and complying with National Pollutant Discharge
Elimination System (NPDES) permits.
FDEP’s
Verified List of Impaired Waters for the Banana River indicates that nutrients
(phosphorus and nitrogen) and mercury are the principal sources of impairment.
In April 2007, the EPA established TMDLs for the IRL and the Banana River. In
the Banana River adjacent to the city, the EPA’s TMDL is a 63% reduction of
total nitrogen (TN) and 67% reduction of total phosphorus (TP) mass annual
loadings from stormwater systems. There are no point-source discharges or septic
tanks in Indian Harbour Beach, meaning that the city’s load allocation
reductions must come entirely from its municipal separate storm sewer system
(MS4).
FDEP
is also in the process of establishing TMDLs for the IRL, which will probably
mirror EPA’s TMDLs. At this point, community compliance with the TMDL program is
voluntary, but FDEP plans enforcement of TMDLs by opening a community’s NPDES
Phase II permit and inserting TMDL allocation reductions into that
permit.
Recognizing
that FDEP would be developing TMDLs in the near future, the city undertook a
stormwater quality study with Allen Engineering and Stormwater Solutions Inc.
(SSI) to model and quantify stormwater pollutant loadings, compare the pollutant
loadings to TMDL allocations, and propose stormwater retrofit projects necessary
to comply with TMDL goals. The city was unusual in that it had virtually no
flooding problems due to its proximity to the beach and bay; this was strictly a
water-quality study.
Pollutant
Loading Assessment
Indian
Harbour Beach encompasses approximately 1,323 acres. The city has 98 stormwater
outfalls to the Banana River and is well blanketed with traditional stormdrain
pipes, ditches, curbs, and gutters. There are currently 19 outfalls that have
stormwater treatment systems, with the remaining 79 outfalls discharging
untreated stormwater to the Banana River.
The
city has predominantly residential properties, with a few commercial sites.
There are 22 existing stormwater treatment systems in the city, serving 483
acres with either wet detention or dry retention ponds.
The
EPA and FDEP used the Pollutant Load Assimilation (PLASM) spreadsheet model and
the Hydrologic Simulation Program–Fortran (HSPF) model for calculating pollutant
loadings for the TMDLs. These models were used on a region-wide basis, but were
not discrete enough to determine individual basin or citywide loadings. While
these are highly accurate models that are appropriate for establishing
scientifically defendable pollutant load allocations, the expense,
complexity,
and calibration effort of using these models was beyond the budget of a small
town that does not have a geographical information system (GIS)
database.
The
EPA’s TMDL allocation was for a percent removal of existing stormwater loadings,
rather than an effluent limitation or specific mass load. As such, an accurate
determination of existing loads and associated model calibration were not
necessary. Therefore, SSI recommended the use of a simplified spreadsheet model
similar to PLASM that could be used to calculate uncalibrated mass annual
loadings of TN, TP, and total suspended solids (TSS) from the city’s stormwater
system. A spreadsheet model also enabled easy calculation of load reductions
from proposed retrofit projects. Use of a relative spreadsheet model provided
the city with considerable savings in model
development that will be applied toward implementing proposed
projects.
FDEP
is in the process of refining Florida’s stormwater design criteria based on the
study “Evaluation of Current Stormwater Design Criteria within the State of
Florida” (Harper and Baker 2007). The methods used by Harper and Baker to
calculate pollutant loadings were used in this study to ensure that the modeling
methods would be similar to FDEP’s TMDL study.
Allen
Engineering delineated and mapped the city’s drainage basins. Within each
drainage basin, the land uses, soil types, C factor, soil curve number (CN), and
“Non Directly Connected Impervious Area” were determined. Potential pollutant
loads for TP, TN, and TSS for each of the 93 basins was calculated as shown in
Table 1, using the following formula:
PPL
parameter = Area × Loading
where
PPL
= potential pollutant load (kg/year) for each parameter
Area
= drainage basin area (acres)
Loading
= pollutant load (kg/acre/year) for each parameter
Localized
mass annual pollutant loading rates are critical factors for use of this type of
model. Harper’s report allows determination of pollutant loading rates based on
local rainfall records, soil types, and land uses for all parts of Florida.
Annual
runoff volume was calculated by multiplying the mean annual rainfall depth by
the area and runoff coefficient C.
Existing
stormwater treatment systems and their associated sub-basins were then
identified in each basin. FDEP has a BMP database showing event mean
concentration (EMC) removal efficiencies
based on years of monitoring data in Florida. BMPs in this database were
constructed to current design standards, as were the existing BMPs in the city.
Therefore, using FDEP’s BMP database provided reasonably accurate estimates for
removal efficiencies of the existing BMPs. Table 2 from the BMP database was
used to estimate pollutant removal effectiveness for each individual parameter
of concern for wet detention ponds.
Because
of the obvious difficulties in quantifying BMP effectiveness when there is no
effluent discharge, dry retention ponds are not listed in FDEP’s database. FDEP
recommends using Harper’s approach of assuming that 100% of all pollutants from
the design storm would be trapped and filtered into the ground. He performed a
statistical analysis of rainfall events for various regions of Florida to
determine the frequency of storms exceeding the design storm (generally 1 inch
of runoff), enabling an annual weighted mass calculation based on how much water
percolates into the ground with 100% treatment for small storms versus how much
runoff bypasses the system with no treatment in larger storms. Harper developed
a series of charts for a range of design storms from 0.25 inch to 4.0 inches of
runoff storage. The full report can be viewed at www.florida-stormwater.org.
For
analysis of existing dry retention ponds in this report, mean annual mass
removal efficiencies for 1.00 inch of retention (the normal design standard)
were used from Harper’s study. The removal efficiencies were a function of
meteorological zone, CN, Non Directly Connected Impervious Area CN value, and
Percent Directly Connected Impervious Area.
The
resultant existing pollutant loads per contributing
basin of each BMP were calculated
with the following equation to account for existing BMP pollutant
reductions:
EPL parameter = Σ
[Loading parameter × (1 - Removal
parameter)]
where
EPL
= existing annual pollutant load for each parameter
Loading
= potential pollutant load (kg/year) for each parameter
Removal
= removal efficiency for each BMP for each
parameter
Subtracting
the removed mass pollutant load from the potential pollutant load gives the
existing stormwater pollutant loads. A sample of those calculations is shown in
Table 3.
The
result of the calculations shows that there are 3,209 kg/year of TN, 536 kg/year
of TP, and 84,362 kg/year of TSS discharged into the Banana River from the
city’s stormwater system.
TMDL
Goals
Based
on the EPA’s load allocations, Indian Harbour Beach’s targeted pollutant
removals will be 2,022 kg/year for TN and 359 kg/year for TP, as shown in Table
4. It is significant to note that the TMDL reduction goals are citywide, meaning
that development with existing treatment facilities are not excluded from load
allocations. The burden of pollutant reductions is equally spread across all
land uses. If properties with existing stormwater systems are excluded from
retrofitting, then the remainder of the properties will shoulder additional
burdens to remove even more than 63% TN and 67% TP from their
runoff.
Proposed
Retrofit Projects
To
meet the large TMDL load reductions, it was obvious that significant levels of
stormwater retrofitting would be required. SSI evaluated existing groundwater
elevations, soils types, and land uses to generate a list of appropriate
structural BMPs for Indian Harbor Beach. Four types of BMPs were
recommended:
- Dry retention ponds/swales in areas with
Type A soils
- Wet detention ponds on deep major
outfalls
- Exfiltration trenches on streets with
Type A soils, low groundwater, and sidewalks
- Inlet traps on numerous small drainage
basins where other BMPs could not be installed
Every
outfall and drainage basin in the city was inspected to develop a list of
retrofit projects to reduce nutrients. All vacant properties were evaluated for
acquisition and potential pond construction. Projects were targeted on all city
and county properties. Every road with medians and type A soils was a potential
site for retention swales or exfiltration trenches. On streets with no sidewalks
and type A soils, curb cuts were proposed with retention swales to be cut behind
the curbs. A preliminary list of proposed retrofit projects was
generated.
Initial
pollutant load modeling showed that the proposed BMPs would not generate
targeted pollutant removals. To provide even more pollutant reductions,
treatment trains consisting of 15,806 linear feet of exfiltration trenches and
six dry retention projects were proposed for the upstream basins of the Gleason
Park wet detention pond. Those projects would reduce the volume of water
entering the Gleason Park pond, making it more effective in treating the runoff
that did make its way to the pond.
There
were numerous outfall pipes that had no economically feasible retrofit
opportunities. In those basins, inlet traps were specified to at least remove
gross solids of sediment and organic debris. A project list of 19 structural
BMPs plus 105 inlet traps was proposed.
Proposed
Pollutant Loads
The
determination of the pollutant loads, assuming
implementation of the proposed alternatives, started with the existing pollutant
loads. Because the city was fully built out, all land uses in the proposed
conditions were considered the same as in the existing conditions. Proposed
pollutant loadings after BMP implementation were calculated with the following
methodology.
Sub-basin
areas contributing to each of the proposed BMPs were determined. It was assumed
that the pollutant loads over the entire basin were homogeneous. Therefore, a
ratio of sub-basin size to basin size was used to calculate existing loadings
for the sub-basins. The formula shown below was used for calculating the
sub-basin loadings.
EPL
parameter = PB Loading per parameter × SB Area
/ PB Area
where
EPL
= existing sub-basin annual pollutant load for each
parameter
PB
loading = parent basin pollutant load (kg/acre/year) for each
parameter
SB
area = sub-basin area (acres)
PB
area = parent basin area (acres)
Proposed
BMP Effectiveness
Each
individual proposed dry retention pond and swale was modeled by calculating the
retention volume and by using the appropriate tables from Harper’s study as
discussed previously.
The
design principle for exfiltration trenches is the same as for dry retention
ponds: a designed volume of water is percolated into the ground, treating 100%
of all associated pollutants. Removal efficiencies for exfiltration trenches
were calculated in the same manner as for dry retention
ponds.
The
proposed wet ponds would not meet standard design criteria for 1 inch of
retention and therefore would not have the pollutant removal effectiveness shown
in the FDEP database. Hence, pollutant removals for the proposed projects were
calculated by using the methodology from Harper’s study, which indicates that a
wet pond’s effectiveness is more accurately related to the permanent pool
volume. FDEP recommends using the linear regression equations shown in Figures 1
and 2 for calculating wet detention pond removal efficiencies. These methods are
now promulgated by several of Florida’s water management districts for many
permitting conditions.
Inlet
traps remove organic debris and sediment from stormwater runoff, which are
different components of pollutants not normally measured in the water column
with autosamplers. Research for FDEP by Smith and England (2007) indicated that
in the Rockledge, FL, area, gross pollutants accounted for 22.7% of the TN and
16.8% of the TP mass annual loadings (including EMC loads) from a residential
drainage basin. In a study by England (2001), a grated inlet trap was shown to
remove 79.3% of grass and sediment loads. Pollutant removals for inlet traps
were calculated as:
RETN
= 0.793 × 22.7% = 18%
RETP
= 0.793 × 16.8% = 13.3%
RETSS
= 79.3%
where
RE
= removal efficiency for each
parameter
Using
the above methods showed each proposed BMP to have a unique, calculated removal
efficiency for each pollutant of concern, as shown in Table
5.
The
basic methodology for treatment train calculations was as
follows:
- Calculate the existing mass annual
pollutant load within a sub-basin for each parameter based on land use, soils
characteristics, and existing treatment systems as shown in Table
3.
- From Table 5, use the calculated
treatment efficiency for each parameter to determine the pollutant load moving
to the next downstream sub-basin.
- Calculate the pollutant loading for each
parameter for the next sub-basin downstream by adding the pollutant load leaving
the upstream basin to the downstream sub-basin load to give the total pollutant
load entering the next BMP.
- Using the BMP removal efficiency from
Table 5 for the second BMP, multiply the removal by the load calculated in step
3 to give the mass load removed in the second BMP.
- Continue this stepwise process for each
sequential BMP until the receiving water is reached.
Acknowledging
that the removal efficiency numbers used in this method may be controversial
when using vault boxes to treat TSS, it was felt that the method was sound when
using the selected BMPs for nutrient and sediment (not TSS) removals. Remember
that there are no TSS TMDLs for this region.
The
pollutant load removals for each BMP were summed to give a total pollutant load
removal for each basin. The total proposed pollutant removals for the entire
city are 996 kilograms per year for TN, 248 kilograms per year for TP, and
51,797 kilograms per year for TSS. This equates to a 31% removal for TN, 54%
removal for TP, and 59% removal for TSS, which is considerably less than the
TMDL allocations. See Table 6 for a sample of the proposed conditions pollutant
loading estimates.
Table
7 gives project specific costs and proposed pollutant removals for
implementation of this stormwater-quality master plan. It also shows a cost per
kilogram of pollutant removed for each project, which is important information
when prioritizing projects in a cost benefit analysis. A cost per kilogram of
pollutant removed should be an important selection criterion used for all BMP
selections.
Table
8 shows that although implementation of the proposed structural BMPs would
provide significant load reductions from the city’s stormwater system, these
improvements would still fall short of probable TMDL reduction goals. Further
pollutant load credits can be obtained from FDEP by implementing a combination
of so-called soft, or nonstructural, programs of ordinance revisions requiring
higher levels of BMP use for development activities, street sweeping, public
education, and enacting an ordinance to reduce the use of nitrogen bearing
fertilizers. The city is already pursuing some of these programs as part of its
NPDES Phase II permit.
These
types of soft BMPs are effective methods for source control that reduce the
pollutant loadings entering the city’s MS4. It is generally more cost-effective
to prevent pollutants from entering stormwater than to remove them from
stormwater once they are dissolved.
Indian
Harbour Beach has a stormwater utility with an equivalent residential unit rate
of $4.00 per month. Annual revenues generated are approximately $200,000. At the
current funding levels, it would take about 35 years to implement the proposed
projects in this study. To effectively implement TMDL-mandated improvements in a
reasonable time frame, the city should investigate additional sources of funding
for its stormwater program.
Conclusions
Recognizing
impending TMDL mandates, Indian Harbour Beach proactively engaged Allen
Engineering and Stormwater Solutions Inc. to develop a water-quality master plan
for the city’s stormwater system. Master planning for water quality, as opposed
to creating a flood control master plan, allowed Indian Harbour Beach to
specifically address TMDL concerns.
Because
of the nature of the TMDL being expressed as a percent reduction of TN and TP
loadings, SSI was able to develop a spreadsheet model of the city’s stormwater
discharges much more economically than using a full-blown hydrologic and
hydraulic (H&H) model. Even though this type of model is not calibrated, the
selection of proposed projects with relative removals will suffice for
TMDL-compliance purposes. H&H models are necessary for establishing TMDLs,
but may not be necessary for a city to demonstrate TMDL
compliance.
SSI
generated an existing conditions model of the city’s stormwater system, selected
20 potential retrofit projects, and modeled the resultant pollutant reductions.
A spreadsheet-based model showed that with the proposed BMPs, the city would
reduce the TP loads by 31% and TN loads by 54%. Costs for these projects were
estimated at $6,803,251. Through the use of spreadsheet data summaries,
individual project costs, pollutant removals by parameter, and costs per
kilogram of pollutant removed were developed to assist the city in prioritizing
project construction sequences.
Because
the use of a spreadsheet model is not calibrated to actual runoff
concentrations, actual pollutant loadings may be different from model
predictions. It is recommended that the city undertake a sampling program to
obtain actual runoff concentration data that could be used to calibrate the
model. Such a monitoring program for long-term pollutant sampling generally
takes several years of storm event (not background) sampling. To meet FDEP’s
request for a list of retrofit projects as part of the TMDL process, the
spreadsheet model allowed quick development of pollutant loadings and retrofit
projects that will take many years to implement. During the ensuing years,
collected sampling data can be used to refine the model, but the basic project
needs will not change much.
Even
though these removals would fall far short of the expected TMDL allocations,
further significant reductions through structural BMP implementation would not
be fiscally feasible. To achieve additional load reductions, it was also
recommended that the city undertake a series of nonstructural BMP initiatives
that would result in further reductions of nutrient loads through source control
programs.