EPA 600/S-23/151 | October 2023 | www.epa.gov/research

Real Time Storm Sewer Monitoring

Joshua A. Steenbock
U.S. Environmental Protection Agency
Cincinnati, OH 45268

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Disclaimer

The U.S. Environmental Protection Agency (EPA) through its Office of Research and Development
funded and managed the research described herein under Task order 68HERC19D0009 Aptim Federal
Services. It has been subjected to the Agency's review and has been approved for publication. Note that
approval does not signify that the contents necessarily reflect the views of the Agency. Any mention of
trade names, products, or services does not imply an endorsement by the U.S. Government or EPA. The
EPA does not endorse any commercial products, services, or enterprises.

Joshua Steenbock, M.S.

U.S. Environmental Protection Agency
Office of Research and Development

Center for Environmental Solutions and Emergency Response
26 Martin Luther King Dr W
Cincinnati, OH 45220
Phone 513.569.7204

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Foreword

The U.S. Environmental Protection Agency (EPA) is charged by Congress with protecting the Nation's
land, air, and water resources. Under a mandate of national environmental laws, the Agency strives to
formulate and implement actions leading to a compatible balance between human activities and the ability
of natural systems to support and nurture life. To meet this mandate, EPA's research program is providing
data and technical support for solving environmental problems today and building a science knowledge
base necessary to manage our ecological resources wisely, understand how pollutants affect our health,
and prevent or reduce environmental risks in the future.

The Center for Environmental Solutions and Emergency Response (CESER) within the Office of
Research and Development (ORD) conducts applied, stakeholder-driven research and provides responsive
technical support to help solve the Nation's environmental challenges. The Center's research focuses on
innovative approaches to address environmental challenges associated with the built environment. We
develop technologies and decision-support tools to help safeguard public water systems and groundwater,
guide sustainable materials management, remediate sites from traditional contamination sources and
emerging environmental stressors, and address potential threats from terrorism and natural
disasters. CESER collaborates with both public and private sector partners to foster technologies that
improve the effectiveness and reduce the cost of compliance, while anticipating emerging problems. We
provide technical support to EPA regions and programs, states, tribal nations, and federal partners, and
serve as the interagency liaison for EPA in homeland security research and technology. The Center is a
leader in providing scientific solutions to protect human health and the environment.

Stormwater control has long been an area of concern, especially in areas that contain aging infrastructure
and combined sewer systems. This report tested a novel biological water quality monitoring system in a
stormwater sewer system located in Cincinnati, OH. Results were compared to data obtained via
traditional grab sampling. The biological monitoring system was able to record and present data on
microbial levels on a minute-to-minute basis from a website hosted by the manufacturer.

Gregory Sayles, Director

Center for Environmental Solutions and Emergency Response

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Table of Contents

Disclaimer	1

Foreword	2

Abbreviations and Acronyms	4

List of Figures and Tables	4

Acknowledgments	5

Executive Summary	6

1.0 Background	7

Bechtold Park and Cooper Creek	7

2.0 SENTRY Biomonitoring System and VEGAPULS C 21 Level Sensor	8

3.0 QA/QC	9

4.0 Results	10

5.0 Discussion and Conclusions	12

6.0 References	14

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Abbreviations and Acronyms

CCR

Carbon-Consumption Rate

CESER

Center for Environmental Solutions and Emergency Response

CFU

Colony Forming Unit(s)

CSO

Combined Sewer Overflow

CSS

Combined Sewer System

EPA

U.S. Environmental Protection Agency

IoT

Internet of Things

m

Meter

mg/L

milligram(s) per Liter

mm

Millimeter

NTU

Nephelometric Turbidity Unit

ORD

Office of Research and Development

TN

Total Nitrogen

TP

Total phosphorus

TSS

Total Suspended Solids

TDS

Total Dissolved Solids

I ist of Figures and Tables

Figure 1. Water Basin of Bechtold Park Test Site StreamStats 2023	7

Figure 2. FABCO Stormwater Diversion Device	8

Figure 3. Upstream and Downstream Locations of the SENTRY System Sensors	9

Figure 4. Bechtold Park Water Levels	10

Figure 5. CCR results from SENTRY Biomonitoring device	11

Figure 6 Representative example of the relationship between water level and CCR	11

Table 1 Laboratory Analytical Techniques	10

Table 2 Influent and Effluent Sampling Results	12

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Acknowledgments

Thank you to Jeff Szabo and Jim Goodrich for serving as reviewers for this Report. Thank you to Adam
Lehman and the Hamilton County Conservation district for all the insight and help facilitating this
project.

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Executive Summary

This report summarizes efforts to detect contamination from rainfall events using online water quality
sensors. Stormwater has long been an area of concern when it comes to contaminant monitoring and
potential remediation. Combined Sewer Overflow (CSO) systems can collect rainwater and sanitary
sewage, but heavy rainfall can overwhelm the treatment system and allow untreated stormwater and
wastewater back into local streams and waterways, in the form of a CSO. Using online water quality
sensors can allow researchers and water treatment officials to observe local waterways for potential CSOs
in real time and provide warnings to the local population or install mitigation technology at the area of
concern.

This project took place at Cooper Creek in Bechtold Park located in Cincinnati, OH. The park is
characterized by a mix of residential and commercial areas. Within the project site, a stormwater retrofit
device was installed and packed with various media to test the efficacy of the water treatment materials.
Bacteria levels were measured using a SENTRY real-time bacterial monitoring sensor (SENTRY™
Water Technologies, Inc., 65 Watts Avenue, Charlottetown, PE C1E 2B7, Canada). Flow levels were
recorded via a VEGAPULS C 21 (VEGA AMERICAS, Inc., 3877 Mason Research Pkwy., Mason, OH
45036 U.S.). The VEGAPULS is a noncontact level sensor with a measuring range of up to 15 m (meters)
and is accurate to within ±2 mm (millimeters).

The biological monitoring system was able to record and present data on microbial levels on a minute-to-
minute basis from a website hosted by the manufacturer. When comparing bacterial spikes to water levels
recorded via the level sensor, the data suggest that stormwater discharges are not the sole contributor to
higher coliform counts. The SENTRY system demonstrated its ability to monitor data remotely and
remain functional while being submerged within a stream for an extended period.

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1.0 Background

Stormwater control has long been an area of concern, especially in areas that contain aging infrastructure
and combined sewer systems. As a part of current research efforts, novel water quality sensors are being
tested to see how they might assist researchers in identifying and mitigating potential contamination from
stormwater. Nearly 80% of pollutants, biological or chemical, are found within the first flush of
stormwater following precipitation events (Jean-Luc Bertrand-Krajewski, 1998) (Szabo, Buchberger, &
Bishop, 2005). Finding a way to measure contamination from stormwater is an important first step in
mitigating its effects.

Bechtold Park and Cooper Creek

Bechtold Park is located within Cincinnati, OH, and is used for a variety of recreational purposes. Cooper
Creek is approximately 4 miles long and flows into Mill Creek, which connects to the Ohio River. The
Cooper Creek watershed is 0.24 sq mi and characterized as a highly urbanized area (50% impervious)
with commercial and industrial land use in the northeast corner and residential land use everywhere else
(Fig. 1) Through a partnership with the Hamilton County Soil & Water Conservation District and the
Cooper Creek Collaborative, it has been the site of several EPA projects. Various stormwater controls
have been installed in Cooper Creek, and this same site served as the project location for this study. The
Cooper Creek Collaborative has confirmed two CSOs near Cooper Creek, represented by red circles on
Figure 1. One CSO is near the watershed's outlet and the other is just downstream of the confluence with
Mill Creek

Figure 1. Water Basin of Bechtold Park Test Site StreamStats 2023

On August 2019, the FABCO passive flow management device (FABCO Industries, 24 Central Drive,
Farmingdale, NY 11735) was installed along Cooper Creek, represented by a black star on Figure I., The
FABCO device is a water diversion structure that allowed for different contaminant-absorbing media to

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be installed (Fig. 2). Along with the FABCO, a dam was installed to limit the flow of water and ensure
that any water passed through the media FABCO Fabguard, a proprietary stormwater media, was installed
inside the FABCO device to serve as a filter media to reduce colifonn numbers. Although reducing the
colifonn counts is not the focus of this report, it does serve to help quantify the health of the stream (EPA,
2023).

Figure 2. FABCO Stormwater Diversion Device

2.0 SENTRY Biomonitoring System and VEGAPULS C 21 Level
Sensor

As a part of an overarching goal to monitor and treat urban/residential contamination within stormwater, a
novel water quality sensor containing IoT (Internet of Tilings) technology was installed within the
Bechtold Park project site. The SENTRY system works by using a bioelectrode to measure the Carbon-
Consumption Rate (CCR) of the microbes in the water source. Biofilm is grown on the surface of the
sensor to which a constant voltage is applied. As the biofilm oxidizes the organic matter and uses energy,
the induced current will change (Sentry Water Tech - Clean Water Applications). This current is
measured and converted into a CCR measurement that is ultimately reported back to a real time graph that
is displayed via the SENTRY Biomonitoring website.

As a part of the installation at Bechtold Park, two CCR sensors and a data management panel were
installed alongside the FABCO unit on June 24, 2020, and remained in place until October 24, 2021.
Sensor EPA01 was installed upstream of the FABCO dam and Sensor EPA02 was installed downstream
of the dam (Fig. 3). Both EPA01 and EPA02 are distinct sensor units that report back to one SENTRY
unit. The sensors' positions were switched on August 12, 2021, to rule out any biases that the individual
sensors may have been exhibiting. Readings were taken every minute during the deployment.

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Figure 3. Upstream and Downstream Locations of the SENTRY System Sensors

The VEGAPULS C 21 radar sensor (VEGA) was installed behind the diversion device in August 2019.
The VEGA is a noncontact level sensor with well documented ability to measure flow in open-channel
waterways. Data from this device were collected via the NEXSENS data collection system (NexSens
Technology, Inc., Fairborn, OH 45324) and displayed via iChart. Level data was compared to microbial
readings to determine if there was a correlation between increased rainfall and higher CCR levels.

3.0 QA/QC

The objective of this report is to compare measurements obtained by novel IoT water quality technology
to measurements obtained via traditional industry standard technology. CCR data obtained from the
SENTR Y system were compared to a grab sample obtained from both upstream and downstream of the
FABCO unit on 7/27/2021. Grab samples were obtained by hand and were refrigerated until analysis
could be performed. Protocols for analyses done on grab samples are outlined in the table below.

Parameter

Instrument or Procedure

Analytical Method

Total Nitrogen (TN)

Spectrophotometer
(Hach DR6000, Loveland, CO)

Hach Method 10208

Total Phosphorus (TP)

Spectrophotometer
(Hach DR6000, Loveland, CO)

Hach Method 10210

Total Suspended Solids (TSS)

Dry/Weigh

Standard Methods for the
Examination of Water and
Wastewater-2540 SOLIDS

Total Dissolved Solids (TDS)

F i Iter/'Dry/'Weigh

Standard Methods for the
Examination of Water and
Wastewater-2540 SOLIDS

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E. coli

IDEXX
(Westbrook, ME)

Standard Methods for the
Examination of Water and
Wastewater-9223 ENZYME
SUBSTRATE COLIFORM
TEST

Turbidity

Turbidimeter
(Hach 2100, Loveland, CO)

Standard Methods for the
Examination of Water and
Wastewater - 2130
TURBIDITY

Table 1 Laboratory Analytical Techniques

The IoT devices installed at the project site were able to upload data to an external cloud that could be
accessed by EPA researchers in real time. Comparing data obtained via the SENTRY system to grab
samples collected and tested via traditional means can identify potential connections between E. coli
levels and CCR readings.

4.0 Results

Both the VEGA level sensor and SENTRY system performed with minimal interruptions for the duration
of the study. The battery on the SENTRY died 7/25/21 but was replaced the next day, and no performance
issues were observed. No other maintenance was needed for either device.

Water levels increased at the Bechtold park site during local precipitation events except for four events
that showed an increase in water level with no corresponding precipitation event (see arrows below in
Fig. 4).

NEXSENS

tech notogy

Data Graph

Bechtold Park Water Level Data

7/22/21	8/21/21	9/20/21	10/20/21

00:00	00:00	00:00	00:00

Date

Water level, ft

Figure 4. Bechtold Park Water Levels

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SENTRY data show an increase in CCR corresponding to increases in water levels, meaning there are
elevated bacteria levels every time there is a discharge into the creek, whether it be from stormwater or
another source. The CCR was higher on the upstream portion of the dam starting approximately July 20,
running contrary to expected results of lower microbial activity from the FABCO water diversion device.
On August 12 (green arrow), the probes were switched to rule out any potential bias or malfunctioning.
The results remained the same with the upstream sensor, CCR EPA02, reading higher than the
downstream sensor (Fig. 5).

EPA01 upstream
EPA02 downstream

12 Aug. Probes
were swapped

A

EPAQ1 downstream
EPA02 upstream

-CCR EPA02
-CCREPA01

t- - nM 1 ^	, .<*¦ -

Figure 5. CCR Results from SENTRY Biomonitoring Device. Probes Were Switched on Aug. 12, Indicated with a Green Arrow

Figure 6 plots both the CCR levels from sensor EPA01 and the water levels from a representative rain
event on 6/30/2021. As the water level increased throughout the beginning of the rain event, CCR
increased as well until the initial microbial load had passed the sensor.

CCR and Water Level

180
160
140
120

oe 100

u

u 80

60
40
20

3.5

3

2.5
2

1.5
1

0.5

0	0

6/30/2021 16:486/30/2021 18:006/30/2021 19:126/30/2021 20:246/30/2021 21:366/30/2021 22:48 7/1/2021 0:00 7/1/2021 1:12

Axis Title

CCR

•Water Level

Figure 6 Representative Example of the Relationship Between Water Level and CCR

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A grab sample was taken on 7/27/2021 on either side of the FABCO dam, obtaining both influent and
effluent water quality from the FABCO (Table 1). While the E. coli data cannot be compared directly
with CCR data, it is a good indication of the number of bacteria on either side. E. coli levels were 5.49 x
104 CFU/100 mL on the upstream/influent side of the dam, and at the time of sampling the SENTRY
reported a CCR level of 73.55. On the downstream/effluent side of the dam, the E. coli levels were 2.13 x
104 CFU/100 mL, and during sampling the SENTRY reported a CCR reading of 33.67.

Sample Date

7/27/2021

ANALYSIS

UNITS

9:15

9:18

Turbidity

NTU

4.33

4.05

Escherichia coli (E. coli)

CFU/100 mL

5.49 x 104

2.13 x 104

Total Suspended Solids (TSS)

mg/L

4

4

Total Dissolved Solids (TDS)

mg/L

666

567

Total Nitrogen (TN)

mg/L

8.16

6.09

Total Phosphorus (TP) (PO43)

mg/L

0.845

0.693

Orthophosphate (PO43 P)

mg/L

0.276

0.226









Table 2 Influent and Effluent Sampling Results

5.0 Discussion and Conclusions

The SENTRY System was generally helpful in monitoring the microbial activity in Cooper Creek. The
sensor remained functional throughout the life of the study and transmitted data with no mechanical
errors. The only interruption was a result of human error: not replacing a dying battery in time. Data show
that CCR levels were higher on the sensor upstream of the FABCO stormwater diversion device for
multiple data points, but this may be due to the location of the sensor rather than the efficacy of the
FABCO. In Figure 3, sensor EPA02 was placed directly on the downstream side of the dam rather than at
the end of the outflow pipe, which could have resulted in water backflowing and sitting stagnant, allowing
bacteria levels to build back up.

When comparing the CCR data to data obtained via a grab sample, there are higher CCR values and E.
coli concentrations upstream than downstream. The microbial activity associated with CCR cannot be
explicitly explained by E. coli levels, but the potential for a correlation exists. However, more samples
would need to be taken to establish such a relationship. These data help support the efficacy of the
SENTRY system.

Most of the observed water level increases correspond to rainfall events in the area. However, there are
several instances that the water levels increased during dry periods and may indicate unregulated releases
into Cooper Creek. On September 13, water levels rose while the CCR levels dropped to zero and
remained there for several days, pointing to some sort of discharge that inhibited microbial growth into
the stream. The increase in discharge may be due to effluent from a local swimming pool. At the end of
the season, the pool filters were backwashed, and the effluent discharged into Cooper Creek that morning.

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Future research could include new sites, potentially in unmodified waterways, and more consistent
collection of grab samples so that the SENTRY results can be better compared to more traditional
methods of water quality analysis. The methods established here can be reproduced in any watershed
potentially allowing for real time monitoring and control for elicit discharges during dry weather and
CSOs during wet weather. Understanding microbial activity in real time can better inform operation and
maintenance of storm water facilities.

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6.0 References

EPA. (2023). Revised Total Coliform Rule. Retrieved from epa.gov:

https://www.epa.gov/dwreginfo/revised-total-coliform-rule-and-total-coliform-rule

Jean-Luc Bertrand-Krajewski, G. C. (1998). Distribution of pollutant mass vs volume in stormwater
discharges and the first flush phenomenon. Water Research, 2341-2356.

Performance of Wet Weather Treatment Facility for Control of Combined Sewer Overflows: Case Study
in Cincinnati, Ohio. (n.d.).

Sentry Water Tech - Clean Water Applications. (2023, March 1). Retrieved from Sentry Water Tech:

https://www.sentrvwatertech.com/energy-optimization/clean-water-applications

Szabo, J., Buchberger, S., & Bishop, P. (2005). Performance of Wet Weather Treatment Facility for

Control of Combined Sewer Overflows: Case Study in Cincinnati, Ohio. Journal of Environmental
Engineering, 131.

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