EPA-600/2-80-044
July 1980
WASTEWATER IN RECEIVING WATERS AT
WATER SUPPLY ABSTRACTION POINTS
by
Michael D. Swayne
Gregory H. Boone
David Bauer
John Scott Lee
SCS Engineers, Inc.
Redmond, Washington 98052
Contract No. 68-03-2592
Project Officer
John N. English
Wastewater Research Division
Municipal Environmental Research Laboratory
Cincinnati, Ohio 45268
MUNICIPAL ENVIRONMENTAL RESEARCH LABORATORY
OFFICE OF RESEARCH AND DEVELOPMENT
U.S. ENVIRONMENTAL PROTECTION AGENCY
CINCINNATI, OHIO 45268
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DISCLAIMER
This report has been reviewed by the Municipal Environmental
Research Laboratory, U.S. Environmental Protection Agency, and
approved for publication. Approval does not signify that the
contents necessarily reflect the views and policies of the U.S.
Environmental Protection Agency, nor does mention of trade names
or commercial products constitute endorsement or recommendation
for use.
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FOREWORD
The U.S Environmental Protection Agency was created because
of increasing public and government concern about the dangers of
pollution to the health and welfare of the American people.
Noxious air, foul water, and spoiled land are tragic testimonies
to the deterioration of our natural environment. The complexity
of that environment and the interplay of its components require
a concentrated and integrated attack on the problem,,
Research and development is that necessary first step in
problem solution; it involves defining the problem, measuring
its impact, and searching for solutions. The Municipal Environ-
mental Research Laboratory develops new and improved technology
and systems to prevent, treat, and manage wastewater and solid
and hazardous waste pollutant discharges from municipal and
community sources, to preserve and treat public drinking water
supplies, and to minimize the adverse economic, social, health,
and aesthetic effects of pollution. This publication is one of
the products of that research and provides a most vital communi-
cations link between the researcher and the user community.
This report describes the results of a study to determine
the present degree and extent to which surface waters used as
domestic supplies contain wastewaters from upstream sources. It
is hoped that these data will be helpful to those agencies con-
cerned with both water supply and wastewater management problems
Francis T. Mayo, Director
Municipal Environmental Research
Laboratory
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ABSTRACT
The indirect, unplanned reuse of wastewater for domestic
purposes is widespread. Wastewater sometimes represents a signi-
ficant portion of the total flow in many receiving waters. Since
the typical wastewater treatment plant does not remove all of the
contaminants from the wastewater, concern exists about the health
risk to downstream water supplies. Thus there is a need to know
the appropriate levels of municipal treatment to ensure the safety
of water supply intakes in the vicinity of the discharges. The
first step in better understanding the significance of this prob-
lem is to find out the present degree and extent to which surface
waters used as domestic supplies contain wastewaters from upstream
The purpose of this project was to determine how much wastewater
and wastewater-derived material from discharges is present in
the surface water supplies of U.S. cities with populations greater
than 25,000.
The study identifies 1246 municipal water supply utilities
using surface water from 194 basins serving 525 cities with popu-
lations greater than 25,000. The results are tabulated to show
for each utility the number of upstream wastewater dischargers
by type, an estimate of cumulated wastewater discharge flow, and
the ratio of wastewater flow to stream or river flow. The results
ranged from 142 utilities with no dischargers identified to many
utilities where the wastewater constituted a major portion of the
water supply. Several utilities were determined to be using water
from a source whose low flow was less than the combined upstream
discharge flows. Water supplies serving cities near the bottom
of large river basins were found to contain wastewater from sev-
eral thousand dischargers. However, those utilities with the
highest percentage of wastewater relative to supply flow were gen-
erally from small- to medium-sized creeks and rivers. Twenty
cities with a total population of more than 7 million were deter-
mined to have surface water supplies containing 2.3 to 16 percent
wastewater during average flow conditions and 8 to 350 percent
wastewater during low flow conditions.
Tnis Deport was submitted in fulfillment of Contract No. 68-
03-2592 by SCS Engineers under the sponsorship of the U.S Envi-
ronmental Protection Agency. This report covers the period August
15, 1977, to January 15, 1979, and work was completed as of Febru-
ary 16, 1979.
IV
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CONTENTS
Foreword -j j j
Abstract iv
Figures !vi
Tables vii
Abbreviations and Symbols ! !viii
Acknowledgements .' .' ! .ix
1. Introduction 1
2. Executive Summary 4
3. Recommendations 16
4. Approach *18
5. Results - Wastewater in Drinking Water Supplies . ! .*34
6. Results - Pollutant Loading in Drinking Water
Supplies 106
7. Projection of Wastewater Impacts on Water Supplies. 110
Appendices
A. Guide to City Index 114
B. Data Source Profiles 133
C. Wastewater in Drinking Water, by Percentage and
Type, for Utilities with Greatest Impacts. . . . 148
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FIGURES
Number n
— "age
1 Standard Federal administrative regions 9
2 Hydrologic link structure of upstream and downstream
utilities 21
3 WIRW logical file and record structure 27
4 Dual physical file structure 28
5 Data collection and assembly flow for WIRW 29
6 WIRW data entry form 30
7 Wastewater calculation worksheet-Harrisburg,
Pennsylvania 32
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TABLES
Numt
1
2
3
4
5
6
7
8
9
10
>er
Distribution of Population by Percent Municipal
Wastewater
Distribution of Numbers of Source Waters Impacted
by Region for Low Flow Conditions
Source Waters Impacted by Greatest Numbers of
Dischargers
Source Water Impact According to Average Flow Percent
Wastewater
Source Water Impact According to Population and
Percent Wastewater
SIC Code Groupings
Source Waters Impacted by Greatest Numbers of
Dischargers
Source Water Impact According to Average Flow
Percent Wastewater
Source Water Impact According to Population and
Percent Wastewater
Estimated Extent of Municipal and Industrial
Page
7
8
. 10
. 12
, 14
, 24
, 36
, 38
39
Discharges at Public Drinking Water Supply Intake
Points 41
11 Upstream/Downstream Indexing of Wastewater 95
12 Important Industrial Discharges to the Philadelphia
Schuykill Water Supply 105
13 Source Water Impact According to Estimated Degraded
Municipal Wastewater Load 108
14 Projected Population Growths for Each Study Area .... 112
15 Projected Source Water Impacts According to Percent
Degraded Wastewater 113
vi i
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ABBREVIATIONS
BOD
CMF
CM/m
IFD
IPWS
kkg/day
mg/1
MWFI
NAWDEX
NEEDS
NRDC
PCS
PUB
SIC
WIRW
USGS
MDSD
EGD
LIST OF ABBREVIATIONS AND SYMBOLS
-Biological oxygen demand
-City Master File
-Cubic meters per minute
-Industrial Facility Discharge File
-Inventory Public Water Supplies
-1000 kilograms/day - metric ton/day
•Milligrams per liter
•Municipal Waste Facilities Inventory
•National Water Data Exchange
•Survey of Needs for Municipal Water Treatment
Facilities (1976)
•Natural Resources Defense Council
•Permit Compliance System
•Public Utility Basin
•Standard Industrial Classification
•Wastewater in Receiving Water System
United States Geological Survey
Monitoring and Data Support Division
Effluent Guideline Division
vi i i
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ACKNOWLEDGEMENTS
This project was directed by Michael D. Swayne, Ph.D , and
managed by Gregory H. Boone with advice from Curtis J. Schmidt
Staff members who contributed to the project were: David Bauer-
environmental engineer, John Scott Lee - computer scientist
James Morgan and Peter M. Orser - environmental scientists, 'Paul
Robison - environmental researcher, and Deanna Sincovec and
Sharon Hinton - secretaries.
A number of other persons were helpful in accessing data
source files. William Milligan, EPA Office of Water Enforcement,
provided access to the Permit Compliance System which was used
to identify municipal and industrial dischargers. Patrick
Tobin, EPA Office of Drinking Water, provided access to the
Inventory of Public Water Supplies file which provided the list
of utilities and source waters. James P. Dawson, Oklahoma
Foundation for Research, Development, and Utilization, Inc.,
provided additional information on utilities and source waters
Melvin Edwards, Gayle Gillingham, and Donald Donalk, United
States Geologic Survey, provided information on stream flows.
Special appreciation is extended to EPA Project Officer,
John English, of the Municipal Environmental Research Laboratory
and Contract Officer Albert Ahlquist.
i x
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SECTION 1
INTRODUCTION
GOAL
The goal of this study was to determine the impact of up-
stream wastewater dischargers at the point of the water intake
Water SUPP^ utilities serving populations over
9nnnT
^b,uuu. This was to be accomplished using presently available
data and information contained in computer files, reports and
other documentation.
Objectives
The objectives of this study were to:
1. Identify all utilities supplying surface water to popula-
tions over 25,000.
2. Identify respective surface water names and intake points.
3. Identify all municipal and industrial dischargers upstream
from the utility intake points.
4. Determine respective municipal discharger categories (pri-
mary, secondary, tertiary), flow and BOD loads and industrial
categories (SIC codes).
5. Determine annual average and 7 day, 10 year low flows at
each intake point.
6. Determine ratio of the sum of municipal discharger flows to
water supply source flow (percent wastewater in drinking
water; . y
7. For selected sites, estimate BOD load caused by upstream
municipal dischargers at supply intake points.
Approach
The general approach to meeting these objectives can be
described as follows:
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1. Utilities serving over 25,000 persons and the names of their
respective source waters were located using the EPA Inventory
of Public Water Supplies (IPWS) File. This file yielded
1,246 source waters serving 540 utilities. Although the IPWS
file is not complete, it was considered to be the best source
available.
2. Identities of the surface source waters and the utilities'
water intake points were also determined using the IPWS file.
Unfortunately, the location (latitude and longitude) of the
intake points often was not available. For these cases,
it was assumed that the intake point was located at the
shortest distance between the city and the source water.
3. Identities of upstream dischargers were determined using the
Permit Compliance System (PCS). While this file provides
facility identities, it does not contain location data
more precise than city or county name, nor does it contain
discharge flow data or receiving water names. The procedure
used was to sort the PCS file by county and city names, and
make discharge assignments to the nearest surface water.
4. Flow and BOD loadings for municipal dischargers were ob-
tained from the Municipal Waste Facilities Inventory (MWFI)
File and the Survey of Needs for Municipal Water Treatment
Facilities (NEEDS) File. Unfortunately, the MWFI file
is generally out of date and contains limited flow data.
The NEEDS file contains good data on flow, but contains
only about 50 percent of the total number of municipal
dischargers. Locational data (latitude, longitude, or
receiving water name) were also generally lacking in these
files.
5. Source water supply flow data were also often difficult to
obtain. A search of United States Geologic Survey (USGS)
data files showed that out of 12,484 stations, less than
5,000 had sufficient data to compute an annual average flow
statistic, and less than 3,500 had sufficient data to com-
pute 7 day, 10 year low flow statistics. Gaugina stations
with data were often not close to intake points ;"therefore,
flows had to be approximated by extrapolation or, in some
cases, left blank.
6. A computerized data base was developed to store all the
relevant data on cities, utilities, source waters, and
dischargers. A combination of computer and manual proce-
dures were used to accumulate data on upstream dischargers
from each intake point.
7. Discharger location or river mile distances between dis-
chargers and the utility were generally not available.
Therefore, it was assumed that dischargers were concentrated
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at points midway between each adjacent upstream utility as a
means of providing necessary data for BOD fate models.
8. A detailed accounting of the types of industrial uses was
accomplished by examining the Standard Industrial Classifi-
cation (SIC) Code provided by the PCS file. Dischargers
?hIe<±Vlded,unt° ?2 ty?e?' Twenty-one types are essentially
the same as those identified as potential dischargers of
P^°/KmL?°llutants by the Natl'onal Resources Defense Coun-
SiLiaf? ' -?e^ De,cree- Data on industrial flows was not
generally available during this project.
Despite the deficiencies in the available data stored in
leS th reStS °f thl'S project are considered to
be nniir;eSH ? reStS °f thl'S project are considered to
be significant and extremely useful and timely for the following
i c ci o \j 1 1 o
1. Identifiable links have been established between wastewater
dischargers and major municipal water utilities.
2. Water utilities which may be impacted by potentially signi-
ficant amounts of pollutants have been identified and are
likely candidates for further study.
3. A Wastewater in Receiving Water (WIRW) data base system has
been developed which can be updated relatively easily as
more data become available and which can efficiently handle
data on about 30,000 dischargers and over 1 , 200 water
utilities.
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SECTION 2
EXECUTIVE SUMMARY
The completion of this study has provided a large amount
of data from which a number of interesting conclusions and
insights can be drawn. The data can also be used as the basis
for further analysis. However, before any additional analyses
are undertaken, it is important to understand the quality of
original data sources, assumptions made, and the limitations of
the data. The data accuracy and completeness will not ade-
quately support detailed or micro analysis at particular intakes
For example, it should not be used for estimating the concentra-
tion of certain pollutants at the water supply intake. However,
the data does provide an excellent national-1evel reference use-
ful for identifying those utilities which have a high probabil-
ity of being significantly impacted.
The Wastewater in Receiving Water (WIRW) data base is
considered to be a first step toward the development of a capa-
bility to quickly and efficiently estimate the impact of waste-
water dischargers on surface water supplies. Further work is
required in the areas of:
• Water supply intake locations - latitude/longitude
and/or river mile
t Water supply intake flows from each source by season
t Discharger location - latitude/longitude and/or
river mile
• Discharger activities and flows by season
0 Development of a hydrologic structure to "look" upstream
and downstream
• Presence and concentrations of pollutants in discharges
§ Fate of pollutants in the receiving waters.
Obvious comparisons can be made between levels of waste-
water impact for various cities within the WIRW data base
Interpretations of these comparisons may appear contradictory,
depending on how the analyst views the data. For example
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Philadelphia, Pennsylvania,draws drinking water from Neshaminy
Creek. About 3.8 percent of that water is wastewater during
average flow conditions, and that utility serves a population of
759,000 people. On the other hand, Columbia, South Carolina,
serves 228,000 people from the Saluda River which contains about
16 percent wastewater during average flow conditions. It might
be concluded that Columbia is more highly impacted because of
the higher percentage of wastewater. Others might see Phila-
delphia as more highly impacted because a greater population is
affected. Other criteria such as number of dischargers, river
flow, or location of intakes relative to dischargers can be used
to analyze the data. One of the major purposes of the study
was to develop, present and qualify data such that it could be
utilized by analysts with a variety of objectives.
Columbia, South Carolina,and a number of other cities
exhibit extreme low flow percent wastewater statistics. Colum-
bia shows a figure of 350 percent wastewater during low flow
conditions on the Saluda River. This implies that the city's
water supply is greatly impacted. However, this may be an
invalid conclusion. Unfortunately, the data source' (IPWS) file
did not identify seasonal changes in the water supply, or the
amount withdrawn from each source. For example, Columbia has
another water supply, the Broad River, which has a lower concen-
tration of wastewater. Because of possible seasonal changes in
point of withdrawal, the municipal supply may actually have a
much lower percent wastewater than the 350 percent indicated
However, the figures do indicate that water quality in the
Saluda River may be poor depending on the fate of the pollutants
or the assimilative capacity of the river.
t A percent wastewater figure greater than 100 percent may
be interpreted several ways. The data presented is simply the
total discharge flow estimate divided by the water supply source
flow estimate. A percentage greater than 100 percent may indi-
cate: water being used more than once, loss of water in the
river due to evaporation, loss to ground or consumptive with-
drawals, or inaccurate source data. It must also be understood
that the percent wastewater data presented reflects the waste-
water contributed only by municipal dischargers. Flow data
for industrial dischargers was not included because such data
was not available in source files during the course of this work
buch a file is now being developed by SCS Engineers for U.S
EPA, Monitoring and Data Support Division. This Industrial
ioon ieS Dischar9e fi]e (IFD) will be completed in early
1980 and will contain necessary point source flow and receiving
water location data for inclusion in the WIRW data base.
With these qualifications in mind, the following tables
present statistical summaries of the data base. Table 1 pre-
sents the distribution of population versus percent wastewater
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in water supply. Table 2 presents a spatial distribution by
federal regions of the number of water supplies containing var-
ious percentages of wastewater in water supplies. Tables 3 and
4 present cities whose water supplies appear to be impacted
significantly. Table 5 presents populations which appear to be
impacted the greatest. Figure 1 presents the standard federal
administrative regions.
Percent Municipal Wastewater by Population
Table 1 presents the population which utilizes surface
water supplies containing various percentages of municipal
wastewater. This table shows that of the persons utilizing
surface water (over 62 million) most are served by supplies
containing zero or low concentrations of wastewater during both
average and low flow conditions. About 15 million persons are
shown to be served by surface supplies containing at least 10
percent wastewater at low flow conditions and 4 million persons
use municipal supplies that contain 100 percent wastewater dur-
ing low flow conditions. However, as noted previously it is
unknown to what extent alternative water supplies are used dur-
ing low flow conditions or to what extent supplies are combined
iherefore, the data reflect the maximum estimated impact rather
than the actual estimated impact.
Percent Municipal Wastewater by Region
Table 2 presents the number of source waters in each
federal region containing various percentages of municipal
wastewater for average flow conditions. This table shows that
tor most regions, a high percentage of source waters contain
zero or a small percentage of wastewater.
tn h^n^J Region l> and the Northwest, Region X, appear
to have few surface water supplies containing wastewater. The
mn/laHnS area' Rugi°n VI1' has a greater number of wastewater
impacted sources than Regions I & X; however, there appear to
be a few extreme cases. The Southeast, Region IV, appears to
have the highest percentage of source waters with significant
percentages of wastewater, followed by the Middle Atlantic
Great Lakes, and South, Regions III and V and VI Mtlant1C'
Cities Impacted by Greatest Numbers of Dischargers
Table 3 presents a list of twenty cities which obtain
drinking water from water supplies impacted by the greatest
number of dischargers. The table is organized according to
the cumulative number of dischargers for each city. The cumu-
ative number includes all dischargers from the point of abstrac
tion to the head of the basin. Not surprisingly, this organiza
ba??n
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TABLE 1. DISTRIBUTION OF POPULATION BY PERCENT
PERCENT
WASTEWATER
0
.01-. 05
0.1-0.2
0.21-0.5
0.51-1.0
1.1-2.0
2.1-5.0
5.1-10
11-20
21-50
51-100
101-200
201-500
501-1000
— •- — .,— ^ - • i * i_ vi r i ^s i i_ n f~i
POPULATION DISTRIBUTION
LOW FLOW PERCENT
WASTEWATERxlOOO
32174
9144
34
1184
462
3751
4639
4429
9874
3137
2400
3967
1340
1 L. IN
POPULATION DISTRIBUTION
AVERAGE FLOW PERCENT
WASTEWATERxlOOO
32174
8833
6646
2542
7833
10216
10309
241
288
64
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greatest number of dischargers contributing to their water
supples. Since many of these dischargers are hundreds or even
aS ^±0? mleS awdy' the actual impact is not as significant
do it appears.
Since large river basins also tend to have large flow vol-
umes, the percent wastewater under average flow conditions is
n? J^96 T°r ^ny.°f ^he twenty cities ^'sted. The percentage
of wastewater during low flow conditions on the Ohio and upper
Mississippi and Missouri appears to be significant for cities
using these sources. However, this includes the flows from
^n £9^S ^^ .of m * ] e s away, and does not take into
fn£o L £• lnstream degradation of pollutants. There-
tore, these figures again represent maximum inputs,,
nnmhoH- Uste* "Next Adjacent" in Table 3 show the
number of dischargers between the abstraction point and the next
upstream utility For example, there are 26 dischargers between
Gretna and New Orleans water intakes, a distance of less than
Jn I! N5,' nh? number of next accent dischargers to Metairie
in the New Orleans area is 1,597. This indicates that 1,597
dischargers enter the Mississippi between Cape Girardeau and
.nHnn1^ i T^65 discharges on the Ohio below Paducah,
and on the lower Arkansas and lower Red rivers. Therefore the
?hP ML°L?1SChar9erS.wit?in a few hundred mi]es upstream from
arp n^H K 6a?S d^a 1S cl°ser to 2'000 and the other 18,000
are probably too far away to have much impact except for the
most conservative pollutants.
Cities Estimated to Have the Highest Percent of Municipal
wastewater ' -- - - ^ —
Table 4 presents 25 cities ranked according to percent
municipal wastewater under annual average source water flow con-
ditions Included in Table 4 for reference are degraded percent
wastewater estimates based on a simple nonconservatlve mod"
which was used to estimate the effect of stream purification
processes see Section 6), and estimates of the number of muni-
cipal and industrial dischargers. »u«iuer OT muni
,„*« Certa^n utilities with higher estimates of percent waste-
water such as Palm Springs and Monrovia, California, were
excluded from this summary because the resolution of the data
sources were not considered sufficient. The reason for exclud-
ing these utilities was usually based on the fact that they
anri "^"9 water from small basins with small source water flows
and, in this case, errors in wastewater flows or source water-
flows can cause significant variations in the percent waste-
These Cases need to be examined"" greater
11
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The degraded pollutant estimates show some decrease from
the conservative estimates. In one case--Alton, Illinois-it
appears that most of the wastewater is discharged some distance
upstream, since the nonconservati ve estimate ( 22%) Ts consider-
ably less than the conservative estimate (3.2%). consider
TahiJa hS recommended that the sources of water listed in
Table 4 be considered as a "shopping list" of supplies to be
investigated ,n more detail regarding the extent of wastewater
pollutants present rather than as a verified list of sources
based nn ?hp ^ was^ter impacts. This recommendation s
data anri Jh. ?9r*e,2f*data resoluti°"' lack of industrial flow
data and the fact that many of these cities use more than one
water source. For example, Columbia, SC, uses three water
sources in addition to the Saluda River, and Ypsi lantfuses
eight wells in addition to the Huron River. Ipslldntl uses
Cities Estimated to Have the Highest. Municipal Wastewater
Loading - - — c - <-c»va iei
loadinn°nfen "1?t||od °f Presenting impact is in terms of mass
i£p nnmn.V fantS 2" ?he P°Pulation served. Assuming that
averaae flnw nf ,6aCh Clty US6S Or is exP°sed to the "me
average flow of water per capita, then the mass loading of
pollutants on the population (based on the quality of the source
Hm« ?h lntake P°1nt) is P^Po^ional to the population
times the percent wastewater in the water supply.
whicfare^stim^pH^ V1St*2f twenty-f<»e population centers
wnicn are estimated to have the greatest loading or exoosurp
to municipal wastewater in drinking water supplies The cUies
erva^vl estimartpnnV° ^ Pr°dUC? °f Population and the cSn"
condit nn, Thf H S^""* wastewater at annual averaae flow
th^n thf degraded estimate averages 46 percent less
than the conservative estimates. It should be noted that thP
S?qn??1«n?a«??ptriatin?ht Var1eS at each site and Sould ha" a
Th?c **,.+ e^ °^ the ^aUty of water reaching the user
This fact was not addressed in preparing Table 5.
Summary
t™i u "astewater in Receiving Water (WIRW) data base is a
tool which can support many types of analysis. SevPra? of the
t H 6 *2enK1!!d1cated 1n this conclusion, others are pre-
" f HoweVer' U 1s ^ o'ta'nt to
t s
use even in this embryonic stage. Never before has so much da?I
on the relation between wastewater discharges !nd dr nkTna water
been assembled in such a comprehensive and useful form
'
ve an useu form rnllp
able ?aak°n H54° Utilities ac^ss the nation has eena'formd-
able task. However, now that the framewor -
framework has been established
13
-------�
•S
co •-« o «— i en vo CM
«~«ir>co
CM o\ oo co co CM co co o * o o * O oo o o •-• mo o «-•
U) 00 CO 00 00 to CO CM Cft CM CO CO CO 00 CO «T CM to CO > >> 3 I C 06 CL CX06
•06C CXOCOJiO -i- -r-
S- -C O oo oo (J
Q.
exec
tftO
i— 06
06 06 06 CX
^ o6oa ex t-
!-OS_(T3n3CoO>
<-*CM»— <^-i— <
0) >,
•— C E i—
loxcxq ^= -M s- u_
'SC-r-'Oi— SM-M4J p— U t- •<-> -r- OO -M '"
= •= M5 •-=«-*! 8- £* SL? c u
O 4J 3 O i— 10 O —«.»
a. oo a. « a.
14
-------�
building upon this data base and discovering new ways to use
roduct mat1°n Wl11 further accentuate the value of this final
15
-------�
SECTION 3
RECOMMENDATIONS
It is recommended that this study be updated in about a
year. At that time additional relevant data on municipal and
industrial discharges and stream flows currently being developed
will be available. The update will be relatively efficient
because of the availability of the WIRW system developed for
this project.
There are several ongoing EPA projects which will facili-
tate updating and expanding the files of data on the wastewater
discharges to water supplies. Some of the most important are:
1. EPA, Monitoring and Data Support Division - Industrial Fac-
ility Discharge File (IFD) - will provide data on municipal
and industrial discharge locations, flows and activities
(SIC codes). Complete by March 1980. Contract 68-01-4872.
Phillip Taylor, Project Officer.
2. EPA, Monitoring and Data Support Division - Hydrologic
Digital File (Reach File) project - will provide data on
hydrologic structure and stream flows. Complete November
1979. Contract 68-01-4679. Phillip Taylor, Project Officer.
3. EPA, Effluent Guidelines Division - Development of screen-
ing data on priority pollutants in municipal and industrial
effluents. Some data available on most discharger cate-
gories, will improve as more data collected. Washington,
D.C.
4. EPA, Enforcement Division - Permit Compliance System Modi-
fication - PCS file will be modified to include discharge
permit limitations for all major dischargers. Complete by
April 1980. Contract 68-03-2578. William Milligan,
Project Officer.
5. EPA, Monitoring and Data Support Division - Priority Pollu-
tant Fate - will provide data on physical properties of
priority pollutants to estimate degradation rates and fates
Complete November 1979. Michael Callihan, Project Officer."
6. EPA, Criteria and Standards Division - Proposed Ambient
Water Quality Criteria - will provide water quality criteria
16
-------�
heaitheffect,n b^ed.on a^ati' toxicity and human
health effects. Draft criteria available. Washington, D.C
An approach which could be used is as follows:
locations ^ fl
4. Operate the WIRW to produce estimates of mass loadings of
pol 1 utants . a u i
5. Modify mass loadings derived from step 4 by fate data to
estimate instream concentrations due to upstream discharges.
6. Compare instream concentrations to criteria established to
determine high impact areas.
7. Use WIRW system to determine causes of high impact.
mnnthr°^hnUirHS Wh1?!l can be eff^1ently started in about six
months, should provide more information on which to base deci-
systems^" relat1ons between dischargers and water supply
17
-------�
SECTION 4
APPROACH
A systems methodology was used to integrate and implement
the basic logical approach. The primary tool developed and used
was the Wastewater in Receiving Water (WIRW) system. The main
component of the WIRW system was the WIRW Data Base. A computer
data base was developed because of the considerable quantity of
data handling and analysis required. This approach allowed the
efficient use of existing data files in digital media and cen-
tralized all data to compute wastewater loadings and percent in
receiving waters. Building a data base also made it possible to
• Evaluate existing data and check for obvious errors
t Fill in gaps with manually retrieved data where necessary
t Allow for error correction by providing edit capability
t Allow for an automated data base update as better
information sources become available
t Allow for an automated data base update as changes
occur in the natural environment.
The latter two points are probably of the greatest significance.
Utten studies are done which require extensive data collection
and analysis, but which are done on an entirely manual basis
As better data becomes available, or when changes occur in the
natural environment due to increased numbers of dischargers
increases or decreases in discharge flows, changes in composi-
tion of industry groups, etc., each change or update would
attect several outputs and each would have to be dealt with
separately. On the other hand, a centralized data base with
update and retrieval software allows relatively quick recalcu-
lations using the new information. For example, frequently
during the course of the study, problems or gaps in the data
were discovered. Many of these were corrected or filled in
improving project results.
Identify Utilities and Source Waters
The primary data source was the Inventory of Public Water
18
-------�
Supplies file, which is a collection survey data gathered by the
of fJhP °%W%ter.SuPP^ (n°* the Office of Drinking Water SupplJ),
of the U.S. Environmental Protection Agency, on almost 47,000
public water utilities in the United States. Of these ut lities
540 were found which utilize surface water sources and serve a
population of 25,000 of more. The rest utilize ground or pur-
chased water sources or serve populations of less than 25,000.
These 540 utilities formed the nucleus of the WIRW System data
and ,U"f°rtunately, the IPWS file contains some inaccuracies
and data deficiencies. Among these are:
t Some source waters are incorrectly named or not
identified.
0 Some cities and/or utilities are not linked to a
source water.
t Many latitudes and longitudes for the abstraction
points were incorrect or unidentified.
t Source water types, either groundwater or surface
water, were sometimes not identified or labeled
i ncorrectly .
• Duplication of utilities and source waters for
some cities exists.
Some obvious IPWS deficiencies were corrected; however a
complete effort was not possible within project resources.
Although there are problems associated with the IPWS file it
is considered the most complete data base available^
thp S0/1011-^.!5"^*" water intal
-------�
Once the utilities and source waters were identified and
located, a schematic drawing was developed for each utility
basin (see Figure 2 for hypothetical basin).
Not only was a graphic representation helpful in illustrat-
ing the downstream progression of wastewater from utility to
utility, but a numerically coded representation was also used to
enable computer analysis. The computer cannot "see" that one
utility is downstream of another, but if each utility contains
pointer fields which identify the name of the upstream and down-
stream utility, then the computer can successively "find" these
utilities by accessing index lists which say where in the data
base they reside. The naming scheme utilized the IPWS identi-
fication code, a 14-digit number, to identify the name of each
utility.
This numerical linking of upstream and downstream utilities
was an extensive and critical task. It provides the spatial
hydrologic framework for the entire study. Not only was it
necessary to construct this hydrologic structure of public water
utilities, but it was also necessary to organize all the surface
water sources identified in this study within the United States
into hydrologic systems called Public Utility Basins (PUB).
Public Utility Basins were defined as the entire drainage
area upstream from a terminal point at an ocean or sink. The
purpose of this definition was to provide routing of wastewater
to a terminus. The Mississippi PUB therefore consisted of all
the area draining into the terminal point at the gulf.
A list of all PUBs defined for this study may be found
in Appendix A. The numbering of the PUBs is arbitrary and has
no inherent significance. PUB number 777 is reserved for source
waters which could not be found on any maps.
Identify Upstream Dischargers
Once the public water utilities and their source waters
were mapped and linked, assignment of waste dischargers was
made. The primary source of data for municipal and industrial
dischargers used is an EPA computer file called the Permit
^nS?l1?MC<;:.SySJ:eni (PCS)- This file contains about 60,000
NPDES (National Pollutant Discharge Elimination System) permits
and includes all known permitted dischargers in the U.S , as of
1977. Each wastewater discharger in this file is classified
according to SIC code, and approximate plant location (state,
city and county). Receiving water name or detailed discharge
location is not provided for on this file. The task of locating
the dischargers on the USGS hydrologic maps and linking them to
water supplies was time consuming, and the accuracy was
restricted by the lack of knowledge concerning exact discharge
20
-------�
Upstream
Utility Pointer
B
C
F
D
None
None
None
F
G
None
None
Source Water
Alpha River
Alpha River
Peach Creek
Alpha River
Second Creek
Third Creek
Fourth Creek
Beta River
Beta River
Peach Creek
Pear Creek
Utility Pointer
900
900
910
900
900
900
900
910
910
910
910
Figure 2. Hydrologic link structure of upstream and
downstream utilities.
21
-------�
locations. The approach used was as follows:
0 Determine the drainage basin of the source water
for the utility in question.
0 Identify dischargers from PCS file.
0 Sort dischargers by state and county and locate
manually on the same hydrologic maps used to
identify water utilities.
0 Verify that dischargers are upstream of water
supply.
There were a number of problems in determining the correct
structure relation between wastewater discharges and water
supplies due to the general lack of precise data on discharge
and intake location. Certain assumptions were often made to
resolve this problem as follows:
1. If the abstraction point for a city/utility is unknown,
then the abstraction point is generally assumed to be at
or near the upstream city limits.
2. If a reservoir appears on a map, in or near the city and is
on the city/utilities source water, and the abstraction
point is unknown, then the abstraction point is assumed to
be from the reservoir.
3. If the abstraction point for a city/utility is unknown,
and/or there are multiple intakes on the same source water,
then the intakes are treated as one.
4. Identified industrial and municipal dischargers within the
city limits are assumed to discharge downstream of the
water supply intake.
5. A city/utility which abstracts from a reservoir is assumed
to have its intake at the upstream city limits and conse-
quently is not affected by downstream discharges.
6. If receiving water for a discharger is unknown, then dis-
charge is assumed to be into the nearest body of water.
Discharger Flow and BOD Loadings
Data on municipal flows and treatment type were obtained
from the NEEDS and Municipal Waste Facilities Inventory
(MWFI) files. Flow data were not always available, but
were estimated from population for about 17 percent of the muni-
cipal dischargers. The estimate used for these cases was 100
22
-------�
gallons per day per person.
BOD loadings were assumed to be the same for facilities
with the same treatment (primary, secondary, tertiary) The
errors caused by making this assumption were not considered
serious since the wastewater in receiving water calculations
aggregate data from several upstream dischargers
Data on industrial discharge flows was not available dur-
ing this project. Therefore, industrial dischargers were
classified and aggregated by number according to SIC code.
Industrial dischargers were divided into 28 groups based
on the Standard Industrial Classification (SIC) code. Table 6
defines the SIC codes included in each of the 28 groups Those
?[OUS?nnmMnned with an asterisk include industries identified in
the EPA-NRDC consent decree. Thus, each group indicated by
asterisk contains an industry involved in the discharge of one
or more of the 129 priority pollutants defined by the consent
vi c \*» I c tr •
in r U S5?UId be n0tud that municipal dischargers are included
in Group 27 because they are included in SIC 4952 classifica-
tions. Therefore, tables in this report showing industrial dis-
charge totals represent totals for all dischargers, municipal
and industrial. Group 27 contains municipal dischargers (4952)
as well as others included in the Public Uti 1 i ti es (4941-4953)
classification. The total number of industrial dischargers
without municipals can be obtained by subtracting the number of
municipals which have been separated for more detailed analysis.
Source Water Flow Estimation
The USGS National Water Data Exchange (NAWDEX) system
?nt%re2 '% °Cate ?aU91'ng stati™s on the source waters of
interest. The resulting listings of Gauging stations for each
source water were then manually sortea to identify stations
with sufficient flow data which were considered to best repre-
sent the flow at each utility abstraction point.
The NAWDEX system is an index to water data which contains
reference to data from several hundred sources. ?he resources
n™ H,b 6 fhr th1s Pr°JeCt nec^^'tated the use of comp ?erized
flow data whenever possible. The USGS Water Storage and
Retrieval WATSTORE) system is the main source of computerized
W^TORP3 'V^ NAWDEX rdex' Thus> 9au9ing stations in ie
7 IITORE system were used to determine the annual average and
7-day, 10-year low flow for approximately 95 percent of all
abstraction points. Approximately 5 percent of the required
23
-------�
TABLE 6. SIC CODE GROUPINGS
(IN SEQUENTIAL SIC CODE ORDER)*
SIC Group
1 *
2 *
1
-
3
4
5
6
7
8
9 *
10 *
11
12 *
13 *
(12)*
(13)*
14
15 *
(14)
(15)*
(14)
(15)*
/ - • \
(14)
16 *
(14)*
17 *
(14)
(13)*
(14)*
18 *
(14)
/ i /-\ \ i
(18)*
(14)
19 *
(14)*
/ i *\ \ i
(13)*
SIC Codes
1000-1099
1100-1399
1400-1499
1500-2009
2010-2019
2020-2029
2030-2039
2040-2049
2050-2099
2100-2199
2200-2399
2400-2499
2500-2599
2600-2699
2700-2781
2782
2783-2799
2800-2811
2812-2813
2814-2815
2816
2817-2818
2819
2820
2821-2824
2825-2840
2841
2842-2850
2851
2852-2864
2865
2866-2868
2869
2870-2890
2891
2892
2893
SIC Group Description
Ore Mining and Dressing
Coal Mining, Oil & Gas Extraction
(Ore Mining)
No Group
Meat Processing
Dairy
Fruits and Vegetables
Grain Mills
Miscellaneous Foods
Tobacco
Textile Mills
Timber Products Processing
Furniture and Fixtures
Pulp and Paperboard Mills and
Converted Paper Products
Paint & Ink Formulation and Printing
(Pulp & Paper)
(Paint & Ink)
Miscellaneous Chemicals
Inorganic Chemicals Manufacturing
(Miscellaneous Chemicals)
(Inorganic Chemicals)
(Miscellaneous Chemicals)
(Inorganic Chemicals)
(Miscellaneous Chemicals)
Plastic & Synthetic Materials Mfg.
(Miscellaneous Chemicals)
Soap and Detergent Manufacturing
(Miscellaneous Chemicals)
(Paint & Ink)
(Miscellaneous Chemicals)
Organic Chemicals Manufacturing
(Miscellaneous Chemicals)
(Organic Chemicals)
(Miscellaneous Chemicals)
Rubber Processing
(Miscellaneous Chemicals)
(Paint & Ink)
(continued)
24
-------�
TABLE 6. (continued)
SIC Group
(14)*
-
20 *
-
21 *
-
(20)*
(19)*
22 *
23
-
24 *
-
24 *
-
25 *
-
(25)*
-
26 *
-
(26)*
-
(26)*
-
(25)*
-
(25)*
-
27 *
-
(27)
28 *
SIC Codes
2894-2899
2900-2910
2911
2912-2950
2951-2952
2953-2989
2990-2999
3000-3099
3100-3199
3200-3299
3300-3311
3312-3313
3314
3315-3317
3318-3320
3321-3322
3323
3324-3325
3326-3330
3331-3334
3335-3338
3339
3340
3341
3342-3350
3351
3352
3353-3999
4000-4940
4941
4942-4951
4952-4953
4954-9999
SIC Group Description
(Miscellaneous Chemicals)
No Group
Petroleum Refining
No Group
Paving and Roofing Materials
No Group
(Petroleum Refining)
(Rubber Processing)
Leather Tanning and Finishing
Glass, Stone and Clay
No Group
Iron and Steel Manufacturing
No Group
(Iron and Steel)
No Group
Machinery and Mechanical Products
No Group
(Machinery)
No Group
Non-Ferrous Metals Manufacturing
No Group
(Non-Ferrous Metals)
No Group
(Non-Ferrous Metals)
No Group
(Machinery)
No Group
(Machinery)
No Group
Public Utilities
No Group
(Public Utilities)
Other
NOTE: Items enclosed in parentheses are additional
occurrences of the same SIC group.
SIC codes in this group include those on priority
pollution list. J
25
-------�
flow data was obtained from the Army Corps of Engineers. This
data in published form is available for major rivers such as the
Ohio, Mississippi, etc., and was utilized when WATSTORE data
was unavailable.
Although WATSTORE provided the best available data, it also
had its limitations. Among these were:
• Occasionally, gauging stations did not have flow data
reported as being available.
0 Gauging stations did not always have a sufficient data
base to permit calculation of 7-day, 10-year low flow
values.
t Stations on rivers dividing states were at times
difficult to locate.
Lakes were assigned a flow by using a model that repre-
sents them as wide places in a river. An average flow through
the lake was then obtained by using available data on volumes
and retention times.
The Great Lakes basin was another special case. It was
considered that calculating the percent wastewater for an entire
Great Lake would be misleading and would not take into account
local mixing and current flow. Therefore, the dischargers
into the Great Lakes were not identified, since the resources
to do this would not result in a productive output at this time.
Develop Wastewater in Receiving Water System
The Wastewater in Receiving Water (WIRW) system consists
of two main parts: the data base and the data processor. The
system was developed in four stages. First, primary data exam-
ination programs were developed to examine and select data from
machine readable files of interest. This included the EPA IPWS,
PCS, NEEDS, MWFI and City Master files. Second, a skeleton
data base was created which defined the overall structure. A
hierarchical file and record structure was selected which simu-
lated the natural structure as shown by Figure 3. The data
base was initialized by entering from the IPWS file the universe
of service areas, utilities and source waters to be studied.
Third, a Data Input/Edit/Update subsystem was developed to allow
data entry from other files and from manual sources, as well as
correction or modification of previously entered data. Fourth,
data retrieval, analysis and report writing capabilities were
devel oped.
The WIRW system software consists of over 40 program
modules written in COBOL for an IBM 370 environment. File
26
-------�
organization is IBM Indexed Sequential utilizing both QISAM and
BISAM access methods. There are two physical ISAM files, as
shown by Figure 4 WIRW-DB is the master data base containing
SJ™ nnD°*-i' utllity ^cords, and source water records. The
WIRW-DDB file contains all the discharger records Keys in
the master WIRW-DB file for each source water record point to
the appropriate block or records in the WIRW-DDB file which are
all the next adjacent dischargers between that source water
intake point and any upstream utilities. Because the nature of
mnct ?,ni +?i dlsc^ar9er Jevel is most subject to change and the
most vo ati e, it was felt that by maintaining a separate
physical file, the change activity for the WIRW data base as a
whole^could be minimized. From a technical standpoint, it also
minimizes the disk storage space necessary and is particularly
fast at inquiries of selected portions of the data base. Most
inquiries of the entire data base can be accomplished by treat-
ing the files in a simple sequential access mode. It also
allows for simple analyses of discharger characteristics inde-
pendent of the complex data base structure as a whole, and
facilitates rapid updating of discharger data.
Figure 5 presents a flow diagram of how the primary data
sources relate to the data base. Data on stream flow, upstream
and downstream utilities and upstream next adjacent dischargers
were entered using a preprinted form (see Figure 6 for example)
^ Shkeleton data ba^. A data entry form wa< ™e-
25,000 people S°UrCe ""^ Supplyin9 a utility serving over
Water utility:
Service
Area
Source water
Source water:
Water utility:
Source water
Source water
Figure 3. WIRW logical file and record structure.
Discharge
Discharge
Discharge
Discharge
— Discharge
Discharge
Discharge
Discharge
27
-------�
WIRW-DB
1uVSKt-MO|
UTILITY^JECORDS
WIRW-DB RECORD KEYS
CR-SEQ-NO
UR-SEQ-NO
SR-SEQ-NO
WIRW-DOB RECORD KEY
DR-SEQ-NO
Figure 4. Dual physical file structure
28
-------�
Preprinted
Computer
Forms
USGS
15' Maps
and
1:250000
List of NPDES
Permit Holders
and Location
• Identification of
water utilities.
• Working list of surface
water sources.
• Used to find location of
water utility, it's point
of abstraction, and a USGS
gauging station.
• Used to provide higher
resolution on location
and identification of
source waters.
• Used to define the bound-
aries of a hydrologically
contiguous basin as well
as the structural linking
of upstream and downstream
public water utilities.
• Used to identify general
location of all contri-
buting effluent dischargers
• Used to provide effluent
discharge flows and para-
metric effluent data for
municipal dischargers.
Figure 5. Data collection and assembly flow for WIRW
29
-------�
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Three levels of data were preprinted, each corresponding
to a record type in the data base. At the top of each form is
a printout of the state, name of city and county (when avail-
able) that the public utility served. The. utility name, address
IPWS number or utility ID was printed at the second level. The
third level printed was the name of the source water utilized
by that utility and USGS river basin when available. The third
level data elements with underscores such as source water type
or USGS gauging station number used to derive stream flow were
filled in by data researchers directly on the forms. Any of
the preprinted data determined to be in error could be crossed
out and the correct data written in above it. In this way,
all data collected concerning closest USGS gauging station,
average and low stream flow, PUB identification, locations
of the source of the data found, upstream and downstream utility
identification pointers, and next adjacent discharger NPDES
numbers were entered onto one form and then keyed into machine
readable form and entered into the WIRW data base.
Wastewater In Drinking Water Calculations
Two basic tools were used to estimate the number of dis-
chargers and the percent municipal wastewater flow impacting
drinking water supplies. The first was an index for each utili-
ty basin (PUB) showing the hydrologic structure of all the
utility intakes, that is, the upstream/downstream order of the
intakes. The second was a computer generated worksheet which
accumulated the number and wastewater flow from municipal dis-
chargers and the number of industrial dischargers between a
utility and the next upstream utility (the next adjacent dis-
chargers). The overall totals were accumulated manually in
downstream order with the results being entered on the work-
sheets .
Figure 7 presents the worksheet for the city of Harrisburg,
Susquehanna River source as an example. All available informa-
tion in the data base on the city, utility and source water is
printed on the worksheet for information purposes. All avail-
able information in the data base on the next adjacent waste-
water flows and on the number of municipal dischargers is print-
ed inside the box on the top half of the sheet. Also, the num-
ber of next adjacent industrial dischargers organized by SIC
group is printed inside the box on the lower half of the sheet.
The cumulative municipal flow for this example is deter-
mined by adding the cumulative totals for each of the upstream
utilities listed at the bottom of the sheet by identification
number. For this case there were several adjacent upstream
utilities which needed to be examined. However, most of the
wastewater was being discharged between Harrisburg .and the next
upstream utilities since the total cumulative flow is 381 cfs
while the next adjacent flow is 321 cfs. In terms of the total
31
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number of dischargers about half of the total (371 out of 660)
were located between the Susquehanna intake and the next up-
stream utilities.
The percent municipal wastewater flow was then calculated
by dividing the total municipal flow by the average and low
stre?m flows'printed on the left Slde- For th1s case 381/34,418
and 381/2516 provided the percent municipal wastewater estimates
of 1.1 percent and 15.1 percent, respectively.
The results of these calculations were summarized and pre-
sented in the next section.
33
-------�
SECTION 5
RESULTS - WASTEWATER IN DRINKING WATER SUPPLIES
Efficient presentation of results developed from tens of
thousands of data points requires knowledge of the viewpoints
and objectives of the readers. Presentation of the "raw" data
provides the most information to the widest audience. However,
this requires more effort by each user to extract the particular
information of interest. The approach used in this study was to
provide a hierarchy of outputs as follows:
1. WIRW data base - data available on 540 utilities, 1,246
source waters and about 30,000 dischargers. The data is in
a digital media at the EPA Washington Computer Center (WCC).
This is the raw data output of the study. It has wide use
but requires knowledge of computer data processing to ob-
tain the information of interest.
2. Discharges to drinking water tables - data on the next
adjacent and cumulative flows and numbers of dischargers by
type contributing to source waters. This output consists of
worksheets as shown in Figure 6 for 588 source waters. The
worksheets are in paper media, hence easier for more users
to access and use.
3. Municipal wastewater in drinking water tables - summarizes
the cumulative number and flow of municipal wastewater dis-
chargers for each utility and source water. This output
consists of 55 pages of tables presented- in this section of
the report. Its use is oriented toward the user specifi-
cally interested in those drinking water supplies being im-
pacted by municipal dischargers.
4. Summary tables - presents those areas and cities which
appeared to have the greatest potential for wastewater im-
pact on drinking water. These tables are presented in the
Results and Executive Summary sections of this report for
easy access to a wide audience.
It can be seen that at each stage the information content
of the output was reduced by an order of magnitude, the trade-
off being information content versus ease of use and utility by
• 34
-------�
a particular user (in this case, one who is particularly in-
terested in the impact of municipal wastewater discharges on
water supply systems ) ,
SUMMARY RESULTS
Three summary tables are presented to indicate those cities
and drinking water sources which are estimated to be the most
highly impacted by wastewater dischargers according to available
data.
Cities Impacted by Greatest Numbers of Dischargers
Table 7 presents a list of twenty cities which obtain drink-
ing water from water supplies impacted by the greatest number of
dischargers. The table is organized according to the cumulative
number of dischargers for each city. The cumulative number in-
cludes all Dischargers from the point of abstraction to the head
ot the basin. Not surprisingly, this organization shows those
cities near the bottom of three large river basins, the
Mississippi, Ohio and Missouri, as having the greatest number of
dischargers contributing to their water supplies. However
since many of these dischargers are hundreds or even thousands
of miles away, the actual impact may not be as significant as
it appears.
Since large rivers also have large flows, the percent
wastewater under average flow conditions is relatively low for
most of the cities listed. Low flow conditions on the Ohio and
upper Mississippi and Missouri may be significant. However
this includes the flows from dischargers hundreds of miles away
and does not take into account the fate of instream degradation
of pollutants. Therefore, these figures represent maximum
impacts.
The Next Adjacent Columns in Table 7 show the number of
dischargers between the water supply abstraction point and the
next upstream utility. For example, there are 26 dischargers
between Gretna and New Orleans water intakes, a distance of less
them 10 miles. The number of next adjacent dischargers to
?e*a7i? ^ the New Orleans area is 1,597. This indicates that
in ?ho nh? K9?rS o^6r ?n the Miss1ssippi below Cape Girardeau,
on the Ohio below Paducah, on the lower Arkansas and lower Red
rivers Therefore, the number of dischargers within a few hun-
dred miles upstream from the New Orleans area is closer to
2,000 and the other 18,000 are probably too far away to have
much impact except for the most conservative pollutants or for
a large peak discharge caused by an upset condition or treat-
ment fai1ure.
35
-------�
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Cities Estimated to Have the Highest Percent of Municipal
Wastewater ~ - - -- K — -
Table 8 presents 25 cities ranked according to percent
municipal wastewater under average source water flow conditions
Included in Table 8 for reference are percent wastewater esti-
mates based on a simple nonconservati ve model (see Section 6)
and estimates of the number of municipal and industrial dis-
chargers .
Certain utilities with higher estimates of percent waste-
water were excluded from this summary because the resolution of
the data sources was not considered sufficient. These were
utilities using water *rom small basins with small source water
TIOWS. In this case, errors in wastewater flows or source water
n^m^fc Cdr^e S1'9nif1cant variations in the percent wastewater
estimates. These cases need to be examined in greater detail
before an accurate estimate of percent wastewater can be made.
The degraded pollutant estimates show some decrease from
the conservative estimates. In one case (Alton), it appears that
most of the wastewater is discharged some distance upstrelm,
since the nonconservati ve estimate (.22) is considerably less
than the conservative estimate (3.2).
It is recommended that the utilities listed in Table 8 be
considered as a "shopping list" of utilities to be investigated
^tn?rn detaiVegard!ng the potential human exposure to waste-
water pollutants, rather than as a list of the utilities with
the greatest impacts. One reason is because of data resolu-
manv n? tifc* °f , 1 ndus tri al f 1 ™ data, and the other is that
many of these cities use more than one water source For
example, Columbia, South Carol i na, uses three other sources in
ion to the6 ' "' YPS1'lant1 US6S elht
Cities Estimated to Have the Highest Municipal Wastewater
Loadi ng — ! - c -
Another method of presenting impact is in terms of mass
thf nn ? f P° ] ] " * a n * s p" the population served. Assuming that
avPr*Pnri±°n/0r,eaCh C1'ty US6S °r is exP°sed to the sime
average flow of water per capita, then the mass loading of
??mlc Jh °n th? P°Pulat1on ^ proportional to the population
times the percent wastewater in the water supply.
Table 9 presents a list of twenty-five population centers
which^are estimated to have the greatest loading or exposure to
municipal wastewater in drinking water supplies The cities
were ranked according to the product of population and the con-
nrr2nl^ «tlmate °f Pe!Tcent wastewater. The nonconservati ve
or degraded percent is also shown for reference.
37
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This analysis gives more weight to those utilities serving
larger populations. The large population centers such as Phila-
delphia and Dallas moved up in rank relative to Table 8. Also
other large centers appear such as St. Louis, New Orleans,
Cincinnati, Washington D.C., Louisville and Kansas City.
MUNICIPAL WASTEWATER IN DRINKING WATER RESULTS
The primary working level output with respect to the prin-
cipal objectives of this project is considered to be Table 10
presented on pages 41 through 94 of this section. This 55 page
table summarizes for each source water for each utility: the
population served by the utility, the cumulative number and flow
for each type of municipal discharger, the cumulative percent
municipal wastewater in drinking water and the total number of
municipal and industrial dischargers.
Each basin is listed in order by PUB number from 010-995,
except for those with zero dischargers and source waters which
could not be located. The cities within each basin are arranged
from upstream to downstream according to the source water that
serves it. Small source waters which could not be located were
given a 777 PUB code and basins with no dischargers were placed
at the end of the table.
To aid the user in reviewing the data in Table 10, an index
organized alphabetically by state and city was prepared to
facilitate accessing desired information. The City Name Index
located in Appendix A provides line numbers keyed to Table 10.
Each source water in Table 10 has a line number associated with
it in order from 1 - 804. The index can be used to locate a
city name of interest alphabetically, which then yields the
proper line number for Table 10. A few line numbers, such as
line 104, refer to nodes defined at strategic locations in
larger river basins, and used to. accumulate all upstream dis-
chargers for downstream routing.
Another significant output of this study is the routing of
wastewater downstream. No other available information shows the
relations between dischargers and utilities concatenated down-
stream or upstream. Table 11 on pages 95-103 presents an index
showing hydrologic relations between water supply utilities. It
provides a tracing of the utilities in each PUB that includes
the furthest downstream utility and each successive upstream
utility. This index was constructed using the data from the
upstream/downstream pointers of each utility, and was used to
trace the impact of wastewater to specific utilities.
Line numbers for Table 10 are provided in parenthesis next
to each utility name to aid in the use of Tables 10 and 11
simultaneously. This will allow the user to have a better idea
of the structural relation of the utilities and dischargers.
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for the yearly average and 7-day 10-year low flows. In addi-
tion, the total contribution of municipal wastewater is broken
down into the volumes originating from primary, secondary,
tertiary and unknown treatment. BOD loadings were not expli-
citly presented on the table. The loadings can be estimated if
desired by assuming typical BOD concentration for each type of
treatment. The BOD loading was calculated for those utilities
estimated to have the greatest wastewater impact. These results
are presented in Section 6. Space was allocated in the data
base system to accommodate data on BOD and other pollutants if
this becomes available.
Scanning the percent municipal wastewater and total num-
bers of dischargers columns will identify many potential "hot
spots" or areas of concern. It must be remembered while examin-
ing Table 10 that the percent wastewater values shown include
only municipal facilities for which flow data was provided or
could be estimated. The contribution to the total percent
wastewater values by each type of municipal treatment can be
determined by examining the primary, secondary, tertiary and
unknown effluent columns. These columns present the total num-
ber of dischargers identified by type (N), the total number with
flow data (n), and the total average known discharge rate in cfs.
For cases where the N/n ratio is much greater than unity
(few facilities with flow data), the percent wastewater esti-
mates will be low. Another estimate of the percent wastewater
may be obtained by increasing the discharge flow for each type
by the corresponding N/n ratio.
For example, referring to line 24, Lawrence, MA, the per-
cent wastewater estimates provided by Table 10 are 13 percent
and 1.0 percent for low flow and mean flow. However, it is
noted that only 13 of the 29 dischargers in the unknown efflu-
ent category have flow data available. Assuming that the 13
with flow data are a representative sample from the total popu-
lation of 29 dischargers, the discharge from the unknown cate-
gory for Lawrence increases from 64 cfs to 143 cfs. This in
turn increases the estimated percent wastewater values to 21
percent and 2.7 percent,respectively. This estimate may be too
high in some cases, since there is some reason to believe that
flow data were more often available for larger dischargers than
smaller dischargers.
DISCHARGES TO DRINKING WATER TABLES
Worksheets for those utilities identified in Tables 8 and
9 as having the highest estimated municipal wastewater impact
on drinking water supplies are presented in Appendix C for
reference. These worksheets present a more detailed breakdown
of municipal discharges to drinking water and also present the
industrial impact in terms of number of dischargers by SIC group.
104
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For example, one could determine for planning purposes which
downstream utilities would be affected by changes in upstream
dischargers-PUB 020 has two utilities which are affected
by discharges associated with upstream utilities. The
T k i i n \ • ''^""'''dinette K i v e r supply (Tins no. 13 on
Ihl. A- I ls affected by its next adjacent dischargers plus all
the dischargers associated with the city of Eugene-McKenzie
River supply (line no. 12). The wastewater routing in th f case
is very simple-discharges to the Eugene-McKenzie River supply
affect not only Eugene but also Corvallis downstream, since the
McKenzie is a tributary of the Willamette upstream of Cor"llis\
tho ?!her,Ca.SeS..are much more complicated. Take for example
the city of Ba timore in PUB 310. Baltimore (124) is affected
rh«?Lnn$9?djace?t dischargers plus all the dischargers to the
unester (Ltt) supply. The Chester (122) supply is affected bv
its next adjacent dischargers plus all the discharges to the
Lancaster-Susquehanna River (120) supply. The situation at this
point became more complex since the Lancaster-Susquehanna River
supply 1S affected by its next adjacent dischargers plus the
dischargers affecting five upstream utilities. Further, one of
Mn«? IcV6^ ? ^uy 5? Harrisburg-Susquehanna River supply,
U08) is affected by dischargers to several other upstream
ullll ?™'s,?n\0 Vt!eSe iS wilkesbarre, served by Penn Gas &
Water (74-85) which has eleven source waters.
It is obvious that the logic for large basins is complex-
however, the identification of this structure allows one to
look upstream or downstream. An upstream example is the case
hot^f a r^ter SUPP]VS Planned to be located on the Susquehanna
,^e^C ^^^nd..Uncaster. One needs only to determine
rP»m uMvr9e'Vr£ *et"een the "ater ^PPly and the next up-
stream utility, which is Lancaster, and then add the effects of
all the dischargers to the Lancaster plant. Another upstream
25 000) ?s %dPnti?aller Ut11^y (°ne SerVlng P°P«lati0n under
^5 000) 1S identified using the same source waters as a larger
tii lny 1n J111* report. 0"ce the adjacent dischargers are iden-
tified, up to the next major utility all the other upstream
dischargers affecting the small supply can be determined
th« ../}1?ownstream case is where a discharge is added to one of
afforJ u-?arKS water supplies. This discharge will not only
B»U?L~ S5rre 'I50 2arr1sbur9' Lancaster, Chester, and
Baltimore. Of course the effect decreases for certain pollu-
tants as one moves downstream. This is the subject of a more
detailed analysis taking into account fate models, travel times
etc.
Table 10 also provides a tool for identifying areas for
further investigation. This table presents the percent of
municipal wastewater discharges to most surface water supplies
serving 25,000 persons or more. The percentages are calculated
103
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SECTION 6
RESULTS - POLLUTANT LOADING IN DRINKING WATER SUPPLIES
The receiving water environment will alter the character-
istics of the wastewater discharges because of physical, chemi-
cal and biological mechanisms such as: oxidation, hydrolysis,
photolysis, volatilization, adsorption, biodegradation, bio-
transformation, and bioaccumulation. Models which can accurate-
ly estimate the fate of pollutants are quite complex and data
intensive. Also, the fate of many newly identified priority
pollutants cannot be determined due to the lack of basic data
on their properties.
Modeling the fate of biologically degradable organic pollu-
tants has a long history and has been practiced with some
success. Two simple assumptions commonly used in estimating
the fate of pollutants in rivers are to assume a first-order
decay rate and a plug flow. These were basic assumptions in
the development of the classic Streeter-Phelps equation. The
results of an application of this simple model are not consid-
ered to be very accurate. However, it can be used as a
"weighting factor" to deemphasize discharges as a function of
distance upstream.
FATE MODEL DEFINITION
The fate model selected for the analysis is based on simple
plug flow which assumes wastes are evenly distributed over the
cross section of the river, that no mixing occurs along the axis
of the river, and that the mass balance equation across a sec-
tion of the river approximates a first order decay rate and
that there are no other sources or sinks.
The steady state equation for this case can then be
written as:
C(x) = C(0)e-kx/v
where: C(x) is the pollutant load at a point x distance
from the source
C(0) is the load at the source
k is an organic degradation rate constant
x is the distance from source to point of interest
v is the average velocity of the river lflteresi;
106
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For example, the Philadelphia Schuylkill supply not only
contains significant wastewater from municipal discharges but
also contains wastewater from a considerable number of indus-
trial dischargers. The bottom half of Table 4 on page 12
shows that there are 240 total cumulative dischargers to the
Philadelphia Schuylkill supply. Subtracting the 65 municipal
dischargers leaves 175 industrial dischargers. The table also
shows that 43 industrial dischargers (62 total next adjacent -
19 municipal next adjacent) enter between the water supply in-
take and the next upstream utility, which in this case is
Norristown,about 15 miles upstream. The table shows that sev-
eral dischargers are in categories which may discharge priority
pollutants. The most significant are summarized in Table 12.
(See Table 6 for group definition by SIC code.)
TABLE 12. IMPORTANT INDUSTRIAL DISCHARGES TO THE PHILADELPHIA
SCHUYLKILL WATER SUPPLY
Group No.
1
12
15
19
20
24
25
26
*Within 15
Group Description
Ore Mining and Dressing
Pulp and Paper
Inorganic Chemicals
Rubber Processing
Petroleum Refining
Iron and Steel
Machinery and Mechanical
Products
Non-ferrous Metals
miles for this case
Cumulati ve
Dischargers
11
6
3
10
2
8
9
3
Next Adjacent
Di schargers*
3
4
1
2
1
2
9
0
Flow data for the industrial dischargers was not available
at this time. However, some estimate of industrial discharge
flow could be obtained by using the average water use in manu-
facturing data supplied by the U.S. Census or average flow data
from the EPA Effluent Guidelines Studies.
105
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Values for k range from about .1 to .5 day"1 and typical stream
velocities are 15 to 80 miles per day.
An arbitrary k/v value of .01 was selected for this
analysis. The weighting factor as a function of distance can
then be expressed as:
C(x) = C(0)e"'01x
where x is the distance in miles and C is a mass load moving
across a section per unit time.
Data on the river mile distance between dischargers and
water supply intakes were generally not available. Therefore,
the calculations were simplified by assuming that all next adja-
cent discharges entered the river at a point approximately
halfway between utilities or halfway between a utility intake
and the headwaters of the basin.
Approximate distances between utilities were determined
using 1:500,000 scale maps and dividers. The average distance
between utilities analyzed was about 35 miles. The typical root
mean square error which arises by making this assumption can be
determined from the relation Ax//TT7 where Ax is the distance
between utilities. This relation assumes that it is equally
probable that a discharger will be at any point along the river.
The typical error caused by assuming all dischargers were lo-
cated mid-point between utilities was therefore about ±10 miles.
Substituting this error into the degradation equation results
in an error of about 10 percent for each discharger. Since the
values of discharge flow and BOD concentrations are not known
with any greater accuracy than 10 percent, the addition of this
degradation error in the analysis is not considered significant.
Table 13 presents the results of applying this degradation
model to the utilities identified by Tables 8 and 9 in Section 5
as having the greater impacts of municipal wastewater on water
supply systems. The cities listed in Table 13 are ranked
according to percent wastewater after degradation at average
flow conditions. The non-degraded or conservative percent
wastewater loadings are also shown in the right hand columns for
comparison. The model for these cases results in biodegrada-
tions ranging from negligible to over a factor of two The
average degradation factor is about 30 percent.
The estimated degraded and conservative BOD loadings are
also presented in Table 13. The BOD loadings were estimated by
assuming that the typical concentrations for dischargers in
each category were as follows:
107
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SECTION 7
PROJECTION OF WASTEWATER IMPACTS ON WATER SUPPLIES
Factors which are considered to modify wastewater impacts on
water supplies as a function of time are:
1. Wastewater treatment regulations
2. Industrial change and growth
3. Population growth.
Treatment Regulations
Public law 92-500 is the basis for present and future regu-
lations to decrease municipal wastewater loads to receiving
waters. This law requires nationwide improvements in municipal
wastewater treatment and allows for more stringent local regula-
tions when considered necessary. The law also requires the de-
velopment of industrial waste pretreatment regulations which will
tend to decrease certain industrial components to municipal waste
streams.
Amendments enacted during 1977 to public law 92-500 will af-
fect the allowable concentration of non-conventional pollutants
in waste streams and provide for three strategies to be developed
to accomplish the control of potentially toxic pollutants These
are: industry by industry, area by area, and pollutant by pollu
tant. The extent of these changes is unknown since regulations
have not yet been developed. eyuiacions
Examination of the status of the various types of municipal
folding* ^atis'tics:' ^'^ '" ^ WI™ data *ase provldedlhe
Munici pal
Unknown
Pri mary
Secondary
T e r t i a ry
Treatment by Type
34.2%
9.4%
52.9%
3.5%
The Unknown category represents the municipal dischargers list
ed with no treatment or no treatment data available. This is a
reflection of data found in the source files used to build WTRW
" " '
110
-------�
Primary = 75 mg/1 based on raw influent of 150
mg/1 with 50% removal
Secondary = 30 mg/1 (typical permit value observed)
Tertiary = 5 mg/1
The estimated BOD concentrations in the water supply at the
points of abstraction due to upstream municipal wastewater dis-
chargers are also presented in Table 13. These were determined
by dividing* the estimated degraded BOD loads by the source water
supply flow. Typical concentrations of BOD in the water sup-
plies caused by upstream dischargers are estimated to range from
0.2 to 2 mg/1 for those cases which are impacted the greatest.
The estimated BOD loadings shown in Table 13 are based on
typical values and reasonable assumptions and are considered to
represent the order of magnitudes of wastewater and pollutants
which actually exist for the cases shown.
109
-------�
TABLE 14. PROJECTED POPULATION GROWTHS FOR EACH STUDY AREA
State
MI
SC
SC
CO
CO
NJ
NJ
NJ
PA
AL
TX
IN
CO
TX
PA
DE
CO
MI
AL
GA
OH
GA
TX
NJ
PA
City
Ypsilanti
Columbia
Greenwood
Pueblo
Thornton
Mil burn
Little Falls
Elizabeth
Bryn Mawr
Birmingham
Ingleside
Indianapolis
Westminster
Dallas
Philadelphia
Wilmington
Englewood
Oshkosh
Langdale
La Grange
Bowling Green
Columbus
Fort Worth
Elizabeth
Pittsburgh
Line
502
259
258
495
335
54
55
166
149
207
551
464
334
539
153
158
339
273
235
234
327
237
538
167
397
SMSA^
Ann Arbor
Columbia
Greenvi 1 le-Spartanburg
Pueblo
Denver-Boulder
Paterson-Passaic
Paterson-Passaic
Newark
Philadelphia
Birmingham
Corpus Christi
Indianapolis
Denver-Boulder
Dallas-Fort Worth
Philadelphia-Reading
Wilmington
Denver-Boulder
Appleton-Oshkosh
Atlanta
Atlanta
Toledo
Atlanta
Dallas-Fort Worth
Newark
Pittsburgh
Percent Popul
1970-1975^
9.5
14.8
11.2
6.1
13.3
-1.8
-1.8
-3.0
-.6
3.4
4.4
3.2
13.3
7.3
1.2
3.5
13.3
3.0
13.2
13.2
2.5
13.2
7.3
-3.0
-3.6
ation Change
1976-1984*3*
15
24
18
9.8
21
-2.9
-2.9
-4.8
-.96
5.4
7.0
5A
21
12
1.9
5.6
21
4.8
21
21
(- X
4
21
12
-4 8
~ • \J
-5.8
(1) Standard Metropolitan Statistical Areas (SMSA) where most dischargers
located
(2) Percent population changes from Bureau of Census County and City Data
Book 1977
(3) Projected population changes from 1976 to 1984 assuming constant growth rate
112
-------�
Primary plants will probably be converted to secondary or
tertiary plants at a rate depending on the availability of
construction funding. The number of secondary plants being
converted to tertiary plants could be significant because of the
recent emphasis on priority pollutants.
For the purpose of projection, it was assumed that all
primary and unknown plants would be converted to secondary
plants by 1984. No conversions from secondary to tertiary
plants were assumed, since there is no basis for a projection
and regulations affecting these changes are in a state of flux.
Growth
The volume of municipal wastewater discharges will tend to
increase because of industrial and population growth. However,
the industrial growth rate will probably be slowed by pretreat-
ment regulations and increased emphasis on inplant recycling.
Therefore, it was assumed that the major factor in increased
municipal discharges would be population growth. Table 14 pre-
sents the population growth rates for the most significantly
impacted cities shown previously in Tables 8 and 9 . A linear
relationship was assumed between wastewater generated and
population growth, and between percent degraded wastewater and
growth.
Results
Table 15 presents the results of projecting to 1984 the
percent wastewater and BOD loading based on the treatment-growth
assumptions discussed previously. By comparing the data in
Table 12 with the data in Table 15 it may be seen that the
cities influenced by high population growth rates and a higher
degree of present treatment increased in the percent wastewater
and BOD ranking. The source waters of certain cities are seen
to decrease in BOD loading due to projected changes in treatment
and growth. These include: Milburn and Little Falls, Bryn
Mawr, Indianapolis, Philadelphia, Oshkosh, Elizabeth and
Pittsburg.
Ill
-------�
APPENDIX A
GUIDE TO CITY INDEX
The City Index provides valuable information facilitating
the analytical use of Table 10 "Estimated Extent of Municipal
and Industrial Discharges at Public Drinking Water Supply Intake
Points." Each city identified in the WIRW Database is listed in
this index. Each state associated with those cities is also
listed. The state is listed first in alphabetical order, with
each city listed in alphabetical order within those states. If
a city has more than one source water, it is listed for each dif-
ferent source water. Source waters are given as a reference
guide. Table 10 Line Numbers are also given for easy cross-
reference. Each listing is also accompanied by a PUB Number, as
Table 10 is organized according to this code number. This number
represents the drainage basin of the source water in question
It is listed from least to largest. The code has no value except
as an identification number.
114
-------�
cc
LU
r-
«t
0
O
co-
O
c^>
o
o
a:
re 10
T3 S-
re oi
J_ en
CD S-
QJ re
t3 -C
o
QJ re
C CL
E i/> IB
^^ 3 QJ
QJ O) i/>
4->
•r- to
jo ro CD
= 23
°^^
I C "O
H- Q.Q
O o
•>-> L. QJ CO
OI >
!•- re -M QJ
•2 2^^
-M
c en o o
O) S- T-j-r-,
c 0) o o
— > s- s-
—I «t O. CL
113
-------�
LINE
STATE CITY NO
CA OAKLAND 584
CA OAKLAND 783
CA OAKLAND 784
CA OAKLAND 781
CA PALM SPRINGS 571
CA PALM SPRINGS 578
CA PETALUMA 796
CA REDLANDS 576
CA SACRAMENTO 580
CA SACRAMENTO 581
CA SAN DIEGO 782
CA SAN JOSE 785
CA SAN LUIS OBISPO 788
CA SAN LUIS OBISPO 790
CA SANTA BARBARA 794
CA SANTA BARBARA 795
CA SANTA CRUZ 575
CA SANTA CRUZ 574
CA VALLEJO 800
CA VALLEJO 587
CA VALLEJO 583
CA VENTURA 803
CA WATSONVILLE 798
CO ARAVADA 331
CO AURORA 338
CO BOULDER 330
CO BOULDER 329
CO COLO SPRINGS 494
CO COLO SPRINGS 563
CO DENVER 561
CO DENVER 562
CO DENVER 337
CO ENGLEWOOD 340
CO ENGLEWOOD 339
CO FORT COLLINS 341
CO FORT COLLINS 342
CO GREELEY 771
CO GREELEY 770
CO LAKEWOOD 333
CO LONGMONT 328
CO PUEBLO 495
CO THORNTON 335
CO WESTMINSTER 332
CO WESTMINSTER 334
PUB SOURCE WATER
990 PARDEE RESERVOIR
906 CHABOT RESERVOIR
906 UPPER SAN LEAND
904 SAN PABLO RE
912 SNOW & FALL CR
980 CHINO CREEK
949 LAWLER RESERVOIR
980 MILL CREEK
990 AMERICAN RIVER
990 SACRAMENTO R
905 OTAY RESERVOIR
915 BEAR GULCH RE
925 SANTA MARGARITA
935 WHALE ROCK RE
945 GIBRALTOR RE
945 CACHUMA RE
955 SAN LORENZO R
955 NEWELL CREEK
965 LAKE CURRY
995 PUTAH SOUTH CAN
990 CACHE SLOUGH
975 VENTURA RIVER
956 2 STREAMS IN BR
610 RALSTON RE
610 SOUTH PLATTE R
610 MIDDLE BOULDER
610 SILVER LAKE
610 PIKES PEAK WATE
910 DILLON RE
910 WILLIAMS FORK R
910 DILLON RE
610 SOUTH PLATTE R
610 BEAR CREEK
610 SOUTH PLATTE R
610 HORSETOOTH RE
610 CACHE LA POUDRE
810 BELLVIEW PLANT
810 BOYD LAKE
610 LENA GULCH MAPL
610 ST VRAIN RIVER
610 ARKANSAS RIVER
610 CLEAR CREEK
610 STANLEY LAKE
610 CLEAR CREEK
116
-------�
CITY INDEX LISTING
STATE CITY
AK ANCHORAGE
AL BIRMINGHAM
AL BIRMINGHAM
AL BIRMINGHAM
AL DECATUR
AL FLORENCE
AL GADSDEN
AL HUNTSVILLE
AL LANGDALE
AL MOBILE
AL MONTGOMERY
AL PHENIX CITY
AL PRICHARD
AL TUSCALOOSA
AR FAYETTEVILLE
AR FORT SMITH
AR HOT SPRINGS
AR LITTLE ROCK
AR LITTLE ROCK
AR LOWELL
AZ PHOENIX
AZ PHOENIX
AZ YUMA
AZ TEMPE
CA CORTE MADERA
CA CORTE MADERA
CA CORTE MADERA
CA CORTE MADERA
CA ESCONDIDO
CA FAIRFIELD
CA FAIRFIELD
CA FONTANA
CA FREMONT
CA HAYWARD
CA LOS ANGELES
CA LOS ANGELES
CA MILLBRAE
CA MILLBRAE
CA MILLBRAE
CA MONROVIA
CA MONTEREY
CA NAPA
CA NAPA
LINE
NO
001
206
207
208
489
490
204
488
235
761
205
236
762
203
513
511
521
512
515
514
570
568
567
569
797
791
792
793
804
582
588
577
586
585
566
780
789
786
787
579
799
801
802
PUB
010
410
410
410
610
610
410
610
430
420
410
430
421
410
610
610
610
610
610
610
910
910
910
910
950
940
940
940
985
990
995
980
990
990
910
902
930
920
920
980
960
970
970
SOURCE WATER
SHIP CREEK
SMITH LAKE
CABAHA RIVER
INLAND LAKE
TENNESSEE RIVER
CYPERSS CK
COOSA RIVER
TENNESSEE R
CHATTAHOOCHEE R
BIG CREEK
TALLAPOOSA R
CHATTAHOOCHEE R
EIGHT MILE CK
NORTH RIVER
WHITE RIVER
LAKE FT. SMITH
OUACHITA RIVER
MAUMELLE LAKE
LAKE WINONA
BEAVER RESERVOIR
SALT RIVER PROJ
SALT AND VERDE
AMERICAN CANAL
LAKE
NICASIO RE
KENT RESERVOIR
ALPINE RESERVOIR
BON TEMPE RE
LAKE HENSHAW
CACHE SLOUGH
PUTAH SOUTH CA
LYTLE CREEK
SOUTH BAY AQUED
SOUTH BAY
COLORADO RIVER
OWENS VALLEY AQ
CALAVERAS RE
CRYSTAL SPRINGS
SAN ANDREAS RES
MONROVIA AND SA
CARMEL RIVER
MILLIKEN RE
LAKE HENNESSEY
115
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
CT
CT
CT
CT
CT
CT
DE
DE
DE
DE
DE
FL
FL
FL
FL
FL
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
GA
HI
HI
HI
IA
IA
IA
IA
IA
IA
IA
WALLINGFORD
WALLINGFORD
WATERBURY
WATERBURY
WATERBURY
WATERBURY
CLAYMONT
CLAYMONT
CLAYMONT
WILMINGTON
WILMINGTON
BRADENTON
MELBOURNE
W PALM BEACH
W PALM BEACH
W PALM BEACH
ATHENS
ATHENS
ATLANTA
AUGUSTA
COLUMBUS
DALTON
DALTON
DECATUR
DOUGLASVILLE
EAST POINT
GAINESVILLE
GRIFFIN
GRIFFIN
LAGRANGE
LAWRENCEVILLE
MACON
MORROW
ROME
HILO
HILO
HILO
BURLINGTON
COUNCIL BLUFFS
DAVENPORT
DES MOINES
IOWA CITY
OTTUMA
SIOUX CITY
683 149 MACKENSIE RE
684 151 PISTAPAUG POND
685 152 WIGWAM RESERVOIR
687 154 E MOUNTAIN RE
686 153 MORRIS RESERVOIR
689 156 PROSPECT RES -
159 320 RED CLAY CREEK
160 320 CHRISTIANA CRK
161 320 WHITE CLAY CRK
157 320 HOOPES RE
158 320 BRANDYWINE CRK
767 495 'WARD LAKE
764 475 LAKE WASH ON TH
269 485 LAKE OKEECHOBEE
268 485 LAKE MANGONIA
270 485 CLEAR LAKE
243 440 NORTH OCONEE RI
242 440 SANDY CREEK
231 430 CHATTAHOOCHEE R
250 450 SAVANNAH RIVER
237 430 LAKE OLIVER ON
200 410 MILL CREEK
201 410 CONASAUGA RIVER
230 430 CHATTAHOOCHEE R
233 430 ANNEEWAKEE CRK
232 430 SWEET WATER C
228 430 LAKE SIDNEY LAN
238 430 HEADS CREEK RE
239 430 FLINT RIVER
234 430 CHATTAHOOCHEE R
229 430 CHATTAHOOCHEE R
245 440 OCMULGEE RIVER
244 440 LITTLE COTTON I
262 410 OOSTANAULA R
628 025 KAHOAMA STREAM
626 025 LAUOLI FALLS IN
627 025 PUKA MAUI INTAK
371 610 MISSISSIPPI R
351 610 MISSOURI RIVER
369 610 MISSISSIPPI R
372 610 RACOON RIVER
370 610 IOWA RIVER
373 610 DES MOINES R
349 610 MISSOURI RIVER
118
-------�
STATE
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CT
CITY
AN§ONIA
ANSONIA
ANSONIA
ANSONIA
BRIDGEPORT
BRIDGEPORT
BRIDGEPORT
BRIDGEPORT
BRISTOL
DANBURY
DANBURY
DANBURY
GREENWICH
GREENWICH
GROTON
GROTON
HARTFORD
HARTFORD
HARTFORD
MANCHESTER
MANCHESTER
MANCHESTER
MANCHESTER
MERIDEN
MERIDEN
MERIDEN
MERIDEN
NEW BRITAIN
BRITAIN
BRITAIN
HAVEN
HAVEN
HAVEN
HAVEN
LONDON
LONDON
LINE NO
PUB
NEW
NEW
NEW
NEW
NEW
NEW
NEW
NEW
NORWALK
NORWALK
NORWICH
NORWICH
NORWICH
SOUTHINGTON
STAMFORD
STAMFORD
638
637
640
639
643
642
645
644
646
647
649
648
651
650
653
652
656
654
657
658
660
659
661
662
664
663
666
667
669
668
673
672
671
670
675
674
676
677
688
679
678
680
681
682
102
101
104
103
107
106
109
108
111
112
114
113
116
115
118
117
121
119
122
123
125
124
126
127
129
128
131
132
134
133
138
137
136
135
141
139
142
143
155
145
144
146
147
148
SOURCE WATER
MIDDLE RESERVOIR
FOUNTAIN LAKE
QUILLINAN RE
BUNGAY RESERVOIR
HEMLOCKS RE
EASTON RESERVOIR
SHELTON RES #2
TRAP FALLS RE
BRISTOL RESERVOIR
MARGERIE RE
EAST LAKE RE
WEST LAKE
MIANUS MILL PON
PUTNAM RESERVOIR
POQUONNOCK RE
GROTON RESERVOIR
NEPAUG RESERVOIR
BARKHAMSTED RE
W HARTFORD RE
PORTER RESERVOIR
BUCKINGHAM RE
HOWARD RESERVOIR
GLOBE HOLLOW RE
BROAD BROOK RE
MERIMERE RE
ELMERE RESERVOIR
BRADLEY HUBBARD
SHUTTLE MEADOW
WHIGVILLE RE
WASEL RESERVOIR
MALTBY LAKES
LAKE WHITNEY
FARM RIVER DIVE
LAKE SALTONSTAL
BECKWITH POND
LAKE KONOMOC
ROCK LAKE
GRUPE RESERVOIR
DEEP RIVER RE
STONY BROOK RE
FAIRVIEW RE
RESERVOIR #1
NORTH STAMFORD
LAUREL RESERVOIR
117
-------�
STATE CITY
KS WICHITA
KY ASHLAND
KY BOWLING GREEN
KY FORT THOMAS
KY FORT THOMAS
KY FRANKFORT
KY FT KNOX
KY FT MITCHELL
KY GEORGETOWN
KY LEXINGTON
KY LEXINGTON
KY LOGICAL CITY #4
KY LOUISVILLE
KY PADUCAH
LA NEW ORLEANS
LA BOSSIER CITY
LA CHALMETTE
LA GRETNA
LA LOCKPORT
LA MARRERO
LA METAIRIE
LA MONROE
LA SHREVEPORT
MA AMHERST
MA AMHERST
MA BEVERLY
MA BEVERLY
MA BEVERLY
MA BRAINTREE
MA BRAINTREE
MA BROCKTON
MA BROCKTON
MA BROCKTON
MA BROCKTON
MA CHICOPEE
MA DANVERS
MA FALL RIVER
MA FITCHBURG
MA FITCHBURG
MA FITCHBURG
MA GLOUCESTER
MA GLOUCESTER
MA GLOUCESTER
MA HINGHAM
INE NO PUB SOURCE WATER
496 610 CHENEY RE
438 610 OHIO RIVER
469 610 BARREN RIVER
444 610 OHIO RIVER
445 610 OHIO RIVER
451 610 KENTUCKY RIVER
455 610 OTTER CREEK
448 610 LICKING RIVER
452 610 EAGLE CREEK
450 610 KY RIVER
449 610 HICKMAN CREEK R
468 610 OHIO RIVER
454 610 OHIO RIVER
492 610 OHIO RIVER
525 610 MISSISSIPPI R
520 610 RED RIVER
527 610 MISSISSIPPI R
526 610 MISSISSIPPI R
535 630 BAYOU LAFOURCHE
524 610 MISSISSIPPI R
523 610 MISSISSIPPI R
522 610 BAYOU DESIARD
518 610 CROSS LAKE
692 160 AMETHYST BROOK
701 205 ATKINS POND
033 215 IPSWICH RIVER
734 255 WENHAM LAKE
727 245 PUTNAMVILLE RE
749 275 BLUE HILL RIVER
742 265 GREAT POND
760 295 MONPONSETT POND
755 285 FURNACE & ONHAM
700 204 SILVER LAKE
699 202 AVON RE
693 160 QUABBIN RE
702 206 MIDDLETON POND
703 208 NORTH WATUPPA P
°29 181 WACHUSETT LAKE
030 180 MEETINGHOUSE P
S31 212 SCOTT RESERVOIR
709 222 WALLACE RE
707 218 HASKELL RE
706 216 BABSON RESERVOIR
7H 224 ACCORD POND
120
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
ID
ID
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IL
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
KS
KS
KS
KS
KS
POCATELLO
POCATELLO
ALTON
BLOOMINGTON
CARBONDALE
CHICAGO
DANVILLE
DECATUR
E ST LOUIS
EVANSTON
HIGHLAND PARK
KANKAKEE
MOLINE
NORTHBROOK
PEORIA
QUINCY
SPRINGFIELD
WAUKEGAN
WILMETTE
BLOOMINGTON
BLOOMINGTON
BLOOMINGTON
E CHICAGO
EVANSVILLE
FORT WAYNE
GARY
GARY
HAMMOND
HAMMOND
INDIANAPOLIS
INDIANAPOLIS
JEFFERSONVILLE
KOKOMO
MICH CITY
MUNCIE
MUNCIE
MUNCIE
RICHMOND
TERRE HAUTE
KANSAS CITY
LAWRENCE
LEAVENWORTH
MISSION
TOPEKA
009 020 MINK CREEK (WES
010 020 WHISKEY JACK CR
380 610 MISS RIVER
377 610 MONEY CREEK
384 610 CEDAR CK RE
288 500 LAKE MICHIGAN
457 610 NORTH FORK VERM
378 610 LAKE DECATUR
382 610 MISSISSIPPI R
287 500 LAKE MICHIGAN
284 500 LAKE MICHIGAN
375 610 KANKAKEE RIVER
368 610 MISSISSIPPI R
285 500 LAKE MICHIGAN
376 610 .ILL RIVER
374 610 MISSISSIPPI R
379 610 LAKE SPRINGFIELD
283 500 LAKE MICHIGAN
286 500 LAKE MICHIGAN
467 610 MONROE RESERVOIR
466 610 GRIFFEY CREEK
465 610 BEANBLOSSOM CR
291 500 LAKE MICHIGAN
456 610 OHIO RIVER SHAW
326 510 ST JOE RIVER
292 500 LAKE MICHIGAN
293 500 LAKE MICHIGAN
289 500 LAKE MICHIGAN
290 500 LAKE MICHIGAN
463 610 FALL CREEK
464 610 WHITE RIVER VIA
453 610 OHIO RIVER
458 610 WILDCAT CREEK
294 500 LAKE MICHIGAN
460 610 WHITE RIVER
462 610 BUCK CREEK
461 610 PRAIRIE CRK RE
446 610 WHITEWATER R
459 610 WABASH RIVER
358 610 MISSOURI RIVER
356 610 KANSAS RIVER
354 610 MISSOURI RIVER
357 610 KANSAS RIVER
355 610 KANSAS RIVER
119
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
MD
MD
MD
MD
ME
ME
ME
ME
ME
MI
MI
MI
MI
MI
MI
MI
MI
MI
MI
MI
MI
MN
MN
MN
MO
MO
MO
MO
MO
MO
MO
MO
MO
MO
MS
MS
MS
MS
MT
MT
MT
HAGERSTOWN
HYATTSVILLE
HYATTSVILLE
ODENTON
BANGOR
BIDDEFORD
LEWISTON
PORTLAND
WATERVILLE
BAY CITY
DETROIT
GRAND RAPIDS
HIGHLAND PARK
MIDLAND
MONROE
MUSKEGON
PORT HURON
SAGINAW
WYANDOTTE
WYOMING
YPSILANTI
DULUTH
MINNEAPOLIS HENNEPIN
MOORHEAD
ST CLOUD
ST PAUL
ST PAUL
CAPE GIRARDEAU
FT LEONARD WOOD
JEFFERSON CITY
JOPLIN
KANSAS CITY
KIRKWOOD
ST CHARLES
ST LOUIS
ST LOUIS
ST JOSEPH
COLUMBUS
JACKSON
MERIDIAN
MERIDIAN
BUTTE
BUTTE
BUTTE
174
169
178
170
636
019
665
020
655
298
303
295
301
297
305
296
300
299
304
302
323
275
365
556
364
366
367
385
361
360
502
359
383
363
362
381
353
271
766
765
343
003
002
350 POTOMAC RIVER
325 PATUXENT RIVER
350 POTOMAC RIVER
325 LITTLE PATUXENT
100 FLOODS POND
110 SACO RIVER
130 LAKE AUBURN
140 SEBAGO LAKE
120 CHINA LAKE
500 SAGINAW BAY LON
500 DETROIT RIVER
500 LK MICH FILTRAT
500 LAKE ST CLAIR
500 LAKE HURON
500 LAKE ERIE
500 LAKE MICHIGAN I
500 ST CLAIR RIVER
500 LAKE HURON
500 DETROIT RIVER
500 LAKE MICHIGAN
502 HURON RIVER
500 LAKE SUPERIOR
610 MISSISSIPPI R
840 RED RIVER
610 MISSISSIPPI R
610 MISSISSIPPI R
610 RICE CREEK CHAI
610 MISSISSIPPI R
610 BIG PINEY RIVER
610 MISSOURI RIVER
610 SHOAL CREEK
610 MISSOURI RIVER
610 MERAMEC RIVER
610 MISSOURI RIVER
610 MISSOURI RIVER
610 MISSISSIPPI R
610 MISSOURI RIVER
410 LUXAPALILA R
490 PEARL RIVER
480 LONG CREEK
480 BONITA
610 BIG HOLE RIVER
020 MOULTON RE
020 BASIN CREEK RE
122
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MA
MD
MD
MD
MD
MD
MD
MD
HINGHAM 710
HOLYOKE 721
LAWRENCE 024
LEOMINSTER 705
LEOMINSTER 725
LOWELL 023
LYNN 728
LYNN 726
LYNN 730
LYNN 729
NEW BEDFORD 731
NEW BEDFORD 732
NEW BEDFORD 733
PEABODY 735
PEABODY 736
PEABODY 032
PITTSFIELD 757
PITTSFIELD 758
PITTSFIELD 759
PLYMOUTH 738
PLYMOUTH 743
PLYMOUTH 739
RANDOLPH 740
SPRINGFIELD 744
SPRINGFIELD 748
SPRINGFIELD 747
WAKEFIELD 750
WEST SPRINGFIELD 691
WESTFIELD 751
WESTFIELD 690
WEYMOUTH 756
WEYMOUTH 741
WORCESTER 754
WORCESTER 025
WORCESTER 026
WORCESTER 027
WORCESTER 028
ANNAPOLIS 059
BALTIMORE 124
BALTIMORE 172
BALTIMORE 171
CUMBERLAND 173
FREDERICK 175
FREDERICK 176
224 ACCORD BROOK
236 WRIGHT & ASHLEY
180 MERRIMACK RIVER
214 WACHUSETT RE
242 FALL BROOK RE
180 MERRIMAC RIVER
246 HAWKES POND
244 WALDEN POND
252 BREEDS POND
248 BIRCH POND
254 GREAT QUITTICAS
254 LITTLE QUITTICA
254 ASSAWOMPSET PON
256 SPRING POND
258 SUNTAUG LAKE
215 IPSWICH RIVER-E
290 ASHLEY BROOK RE
290 ROARING BROOK
290 SACKETT BROOK R
262 LITTLE SOUTH PO
266 BOOT POND
264 GREAT SOUTH PON
265 GREAT POND
268 LITTLEVILLE RE
274 LUDLOW RESERVOIR
272 COBBLE MT RE
276 CRYSTAL LAKE
160 BEAR HOLE BROOK
278 TEKOA RESERVOIR
160 GRANVILLE RE
286 SWAMP RIVER DIV
265 GREAT POND
282 PINE HILL RE
180 KETTLE & LYNDE
180 KENDAIR
180 HOLDEN R
180 PINEHILL RE
305 BROAD CREEK
310 SUSQUEHANNA R
340 GUNPOWDER FLS P
330 N BRCH PATAPSCO
350 LAKE GORDON FLT
350 MONOCACY RIVER
350 LINGANORE CREEK
121
-------�
STATE CITY
NE OMAHA
NH CONCORD
NH MANCHESTER
NH NASHUA
NH PORTSMOUTH
NH SALEM
NJ ATLANTIC CITY
NJ ELIZABETH
NJ ELIZABETH
NJ ELIZABETH
NJ JERSEY CITY
NJ JERSEY CITY
NJ LITTLE FALLS
NJ MILLBURN
NJ MORRISTOWN
NJ NEW MILFORD
NJ NEWARK
NJ ORANGE
NJ PRINCETON
NJ SHREWSBURY
NJ SHREWSBURY
NJ SOMERVILLE
NJ TRENTON
NJ WOODBRIDGE
NJ WOODBRIDGE
NM ALAMOGORDO
NM SANTA FE
NV LAS VEGAS
NV NORTH LAS VEGAS
NV RENO
NV RENO
NY ALBANY
NY ALBANY
NY AMSTERDAM
NY AUBURN
NY BINGHAMPTON
NY BUFFALO
NY BUFFALO
NY BUFFALO
NY DUNKIRK
NY ELMIRA
NY ITHACA
NY ITHACA
NY KINGSTON
LINE
350
022
641
704
752
753
055
054
737
745
056
162
057
058
165
137
163
164
529
53°
565
564
5/3
572
045
046
040
034
060
319
318
317
316
0^1
036
035
044
PUB SOURCE WATER
610 MISSOURI RIVER
180 PENACOOK LAKE
17° MASSABESIC LAKE
180 PENNICHUCK BROOK
190 BELLAMAY RIVER
105 CANOBIE LAKE
210 DOUGHTY POND
320 DELAWARE-RARITA
320 RARITAN RIVER
320 RARITAN & MILLS
280 BOONTON RE
281 SPLIT ROCK RE
240 PASSAIC RIVER
240 PASSAIC RIVER
260 CLYDE POTTS RE
270 LAKE DEFOREST L
240 PEQUANNECK R
220 W BRANCH RAHWAY
320 DELAWARE RARATI
250 JUMPING BROOK
250 SWIMMING RIVER
320 RARITAN RIVER
320 DELAWARE RIVER
320 ROBINSON BR OF
320 DELAWARE RARITA
620 BONITO LAKE
620 SANTA FE RIVER
910 LAKE MEAD
910 LAKE MEAD
914 STEAMBOAT DTCH
914 TRUCKEE RIVER
230 HANNACROIX CREEK
230 BASIC CR RE
230 5 IMPOUNDING RE
226 OWASCO LAKE
310 SUSQUEHANNA R
500 LAKE ERIE
500 LAKE ERIE
500 LAKE ERIE
500 LAKE ERIE
310 CHEMUNG RIVER H
227 SIX MILE CREEK
227 FALL CREEK
230 MI^K HOLLOW BR
124
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
MT
MT
MT
MT
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
ND
ND
ND
ND
GREAT FALLS
HELENA
HELENA
MISSOULA
ASHEVILLE
BURLINGTON
BURLINGTON
CHAPEL HILL
CHAPEL HILL
CHAPEL HILL
CHARLOTTE
CONCORD
DURHAM
FAYETTEVILLE
GASTONIA
GASTONIA
GOLDSBORO
GREENSBORO
GREENSBORO
GREENSBORO
GREENVILLE
HENDERSONVILLE
HICKORY
HIGH POINT
LEXINGTON
LEXINGTON
RALEIGH
RALEIGH
RALEIGH
ROCKY MOUNT
SALISBURY
STATESVILLE
STATESVILLE
WILMINGTON
WILMINGTON
WILSON
WILSON
WILSON
WINSTON SALEM
WINSTON SALEM
BISMARCK
FARGO
FARGO
GRAND FORKS
346
345
344
004
480
214
213
216
215
217
263
198
220
218
264
265
227
212
210
211
241
481
262
209
195
196
221
222
223
240
197
192
191
219
763
226
224
225
194
193
347
558
557
559
610 MISSOURI RIVER
610 MISSOURI RIVER
610 TEN MILE
020 RATTLESNAKE
610 N FK SWANNANOA
415 STONEY CREEK
415 TOMS CREEK
415 PHILS CRK
415 PRICE CRK
415 MORGAN CRK
470 MT ISLAND LAKE
405 COLDWATER CRK
425 FLAT RIVER
415 CAPE FEAR RI
470 LONG CREEK
470 CATAWBA RIVER
425 LITTLE RI
415 LAKE BRANDT '
415 LAKE TOWNSEND
415 HORSE PEN CR
435 TAR RIVER
610 MILLS RI
470 CATAWBA RIVER
415 DEEP RI
405 YADKIN'RI
405 ABBOTTS CR
425 SWIFT CREEK
425 NEUSE RIVER
425 WALNUT CREEK
435 TAR RIVER
405 YADKIN RI
405 FOURTH CREEK
405 S YADKIN RIVER
415 CAPE FEAR RIVER
455 TOOMERS CREEK
425 CONTENTNEA CRK
425 SILVER LAKE
425 TOISNOT SWAMP
405 SALEM CR
405 YADKIN RI
610 MISSOURI RIVER
840 INTAKE #2 (SHEY
840 INTAKE #1 (RED
840 RED RIVER #1
123
-------�
STATE CITY
OH LORAIN
OH MANSFIELD
OH MARION
OH MARION
OH MASSILLON
OH MENTOR
OH PAINESVILLE
OH PORTSMOUTH
OH SANDUSKY
OH STEUBENVILLE
OH STRUTHERS
OH STRUTHERS
OH TOLEDO
OH WARREN
OK BARTLESVILLE
OK DEL CITY
OK LAWTON
OK LOGICAL CITY
OK LOGICAL CITY
OK MIDWEST CITY
OK MUSKOGEE
OK OKLAHOMA CITY
OK OKLAHOMA CITY
OK OKLAHOMA CITY
OK PONCA CITY
OK SHAWNEE
OK TULSA
OK TULSA
OK TULSA
OR COOS BAY
OR CORVALLIS
OR CORVALLIS
OR CORVALLIS
OR CORVALLIS
OR EUGENE
OR MEDFORD
OR PORTLAND
OR SALEM
PA ALLENTOWN
PA ALTOONA
PA ALTOONA
PA ALTOONA
PA ALTOONA
PA BEAVER FALLS
#1
#2
LINE NO PUB SOURCE WATER
308 500 LAKE ERIE
610 CLEAR FK CK RES
610 LITTLE SCIOTO
441 610 BIG SCIOTO
434 610 NEWMAN CREEK
3J2 500 LAKE ERIE INTAK
313 500 LAKE ERIE
439 610 OHIO RIVER
307 500 LAKE ERIE
430 610 OHIO RIVER
420 610 BURGESS LAKE IN
421 610 EVANS LAKE
306 500 LAKE ERIE
419 610 MOSQUITO CREEK
498 610 HULAH LAKE
J?05 610 LAKE THUNDERBIRD
516 610 LAKE LAWTONKA
510 610 ARKANSAS RIVER
504 610 ARKANSAS RIVER
5°7 610 LAKE THUNDERBIRD
503 610 FT GIBSON LAKE
509 610 LAKE OVERHOLSER
493 610 HEFNER LAKE
517 610 STANLEY DRAPER
497 610 LAKE PONCA
508 610 SHAWNEE LK
501 610 LAKE EUCHA
500 610 LAKE SPAVINAW
499 610 OOLAGAH LAKE
629 040 PONY CREEK
013 020 WILLAMETTE RIVER
014 020 ROCK CREEK-N F
015 020 ROCK CREEK-S F
016 020 GRIFFITH CREEK
12 020 MCKENZIE RIVER
18 030 ROGUE RIVER
11 020 BULL RUN RIVER
J7 020 NORTH SANTIAM R
131 320 LITTLE LEHIGH R
099 310 GLEN WHITE RUN
096 310 HOMERS GAP RUN
097 310 MILL RUN
096 310 KITTANING RUN
428 610 BEAVER RIVER NE
126
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
NY
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
OH
LOCKPORT
MAMRONECK
NEW YORK
NEW YORK
NEW YORK
NEWBURGH
NEWTONVILE
NEWTONVILE
NIAGARA FALLS
NORTH TONAWANDA
OSSINING
OSWEGO
PLATTSBURG
POUGHKEEPSIE
ROCHESTER
ROCHESTER
ROCHESTER
ROME
SPRING VALLEY
SYRACUSE '
SYRACUSE
TONAWANDA
TROY
UTICA
UTICA
WATERTOWN
WHITE PLAINS
YONKERS
AKRON
ALLIANCE
ASHTABULA
AVON LAKE
BARBERTON
BOWLING GREEN
CINCINNATI
CLEVELAND
CLEVELAND
COLUMBUS
COLUMBUS
EAST LIVERPOOL
ELYRIA
FINDLAY
GENEVA
LIMA
715
723
051
052
125
048
041
042
714
713
049
322
717
047
320
321
720
053
746
716
722
712
043
039
038
037
724
050
768
418
315
310
432
327
447
272
311
443
442
429
309
325
314
324
225 NIAGARA RIVER
238 MAMARONECK R
230 CROTON R SYSTEM
230 CATSKILL SYSTEM
320 DELAWARE R SYS
230 SILVER & PATTON
230 STONEY CREEK
230 MOHAWK RIVER
225 WEST BRANCH NIA
225 NIAGARA RIVER
230 INDIAN BROOK
500 LAKE ONTARIO
232 MEADE & WEST BR
230 HUDSON RIVER
500 LAKE ONTARIO
500 LAKE ONTARIO
234 HEMLOCK & CANAD
235 FISH CREEK
270. 2 DEFOREST LAKE
228 OTISCO LAKE
237 SKANEATELES LAKE
225 W B NIAGARA R
230 TOMHANNOCK RE
230 HINCKLEY RE
230 GRAY RE
229 BLACK RIVER
239 2 RESERVOIR
230 SAWMILL RE
501 CUYAHOGA R
610 DEER CREEK RE
500 LAKE ERIE
500 LAKE ERIE
610 BARBERTON RE
510 MAUMEE RIVER
610 OHIO RIVER
500 L ERIE CRIB 4
500 L ERIE CRIB 3
610 BIG WALNUT CREEK
610 SCIOTO RIVER
610 OHIO RIVER INTA
500 LAKE ERIE INTAK
510 BLANCHARD RIVER
500 LAKE ERIE INTAK
510 OTTAWA R
125
-------�
STATE CITY
PA JOHNSTOWN
PA JOHNSTOWN
PA JOHNSTOWN
PA JOHNSTOWN
PA JOHNSTOWN
PA LANCASTER
PA LANCASTER
PA LEBANON
PA LEBANON
PA LEBANON
PA LEMOYNE
PA LEMOYNE
PA LEVITTOWN
PA LEWISTOWN
PA LEWISTOWN
PA LEWISTOWN
PA LOGICAL CITY #3
PA MCKEESPORT
PA MCKEESPORT
PA MIDDLETOWN TWP
PA MILTON
PA MILTON
PA MILTON
PA NEW CASTUE
PA NEW KENSINGTON
PA NORRISTOWN BORO
PA NORTHAMPTON
PA NORTHAMPTON
PA PHILADELPHIA
PA PHILADELPHIA
PA PHILADELPHIA
PA PITTSBURGH
PA PITTSBURGH
PA POTTSTOWN
PA POTTSVILLE
PA POTTSVILLE
PA POTTSVILLE
PA POTTSVILLE
PA READING
PA READING
PA SCRANTON
PA SCRANTON
PA SCRANTON
PA SCRANTON
LINE NO
392
394
389
390
388
121
120
HI
112
113
HO
109
138
102
103
101
102
412
413
140
089
091
090
423
395
152
132
133
154
153
155
397
414
148
146
147
144
145
142
143
070
071
072
PUB SOURCE WATER
610 DALTON RUN RE
610 NORTH FORK RE
610 SALTLICK RE
610 TOYLLDAL DAM
610 SANDY RUN DAM
310 CONESTOGA CREEK
310 SUSQUEHANNA R
310 GOLD MINE CREEK
310 FISHING CREEK
310 SWATARA CREEK
310 YELLOW BREECHES
310 CONODOGUINET CR
320 DELAWARE RIVER
310 LAUREL RUN
310 WEST BROOK
310 TREASTER RUN
310 JUNIATA RIVER
610 YOUGHIOGHENY R
610 MONONGAHELA R
320 NESHAMINY CR
310 WEST BRANCH OF
310 SPRUCE RUN DAM
310 WHITE DEER CR
610 SHENANGO RIVER
610 ALLEGHENY RIVER
320 SCHUYLKILL R
320 LEHIGH RIVER
320 SPRING CREEK RE
320 DELAWARE RIVER
320 SCHUYLKILL R
320 SCHUYLKILL R
610 ALLEGHENY RIVER
610 MONONGAHELA R
320 SCHUYLKILL R
320 EISENHUTH RE
320 INDIAN RUN RE
320 WOLF CREEK RE
320 TAR RUN RE
320 ANTOETAM LAKE
320 LAKE ONTELAUNEE
310 ELMHURST DAM
310 OAK RUN DAM
310 LAKE HENRY
310 LEHIGH PUMP DAM
128
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
BENSALEM TWP
BETHLEHEM
BETHLEHEM
BETHLEHEM
BRISTOL
BRYN MAWR
BRYN MAWR
BRYN MAWR
BUTLER
BUTLER
-BUTLER
BUTLER
BUTLER
BUTLER
CANONSBURG
CANONSBURG
CANONSBURG
CHARLEROI
CHESTER
CHESTER
CONNELSVILLE
EASTON
FREDERICKTOWN
GERMAN TWP
GREENSBURG
GREENSBURG
GREENSBURG
HANOVER
HANOVER
HANOVER BORO
HARRISBURG
HARRISBURG
HARRISBURG
HARRISBURG
HARRISBURG
HAZLETON
HAZLETON
HAZLETON
HAZLETON
HUNTINGTON
JEFFERSON
JEFFERSON
JOHNSTOWN
JOHNSTOWN
141
136
135
134
139
151
149
150
387
426
386
425
424
427
416
415
417
405
122
123
411
126
404
401
409
410
408
118
115
116
105
108
114
106
107
130
127
128
129
100
402
403
393
391
320
320
320
320
320
320
320
320
610
610
610
610
610
610
610
610
610
610
310
310
610
320
610
610
610
610
610
310
310
310
310
310
310
310
310
320
320
320
320
310
610
610
610
610
DELAWARE RIVER
TUNK CR INTAKE
WILD CK PA FORS
WILD CREEK
DELAWARE RIVER
CRUM CREEK GEIS
NESHAMINY CREEK
PICKERING CREEK
ALLEGHENY RIVER
THORN RUN
ALLEGHENY RIVER
THORN RUN RE
ONEIDA-BOYDSTOW
CONNOQUENESSING
SPEERS RUN IMPO
JOHNSTONS RUN I
LITTLE CHARTIER
MONONGAHELA R
SUSQUEHANNA R
OCTARARO CREEK
YOUGHIOGHENY
DELAWARE RIVER
MONONGAHELA R
MONONGAHELA R
IMMEL RES STREA
INDIAN CREEK
BEAVER RUN RE
LONG ARM CREEK
LITTLE CONEWAGO
S BR CONWAGO CR
DEHART RESERVOIR
SUSQUEHANNA R
SWATARA CREEK
STONEY CREEK
BEAVER CREEK
MT PLEASANT
HARLEIGH
DRECK CREEK
BARNES RUN
STONE CREEK
S FORK TEN MILE
MONANGAHELA R
BEAR ROCK DAM
MILLCREEK RE
127
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
PA
RI
RI
RI
SC
SC
SC
SC
SC
SC
SC
SCRANTON
SCRANTON
SCRANTON
SCRANTON
SCRANTON
SCRANTON
SCRANTON
SCRANTON
SHAMOKIN
SHAMOKIN
SHAMOKIN
SHAMOKIN
SHARON
UNIONTOWN
UNIONTOWN
W CHESTER
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKES BARRE
WILKINSBURG
WILLIAMSPORT
WILLIAMSPORT
WILLIAMSPORT
YORK
YORK
BRISTOL
PROVIDENCE
WOONSOCKET
AIKEN
AIKEN
ANDERSON
CHARLESTON
CHARLESTON
COLUMBIA
COLUMBIA
062
063
064
065
066
067
068
069
092
094
093
095
422
406
407
156
084
085
075
082
077
078
076
079
081
083
074
080
396
086
087
088
119
117
694
695
696
252
251
249
253
255
261
259
310
310
310
310
310
310
310
310
310
310
310
310
610
610
610
320
310
310
310
310
310
310
310
310
310
310
310
310
610
310
310
310
310
310
161
162
162
460
460
450
460
465
470
470
SUMMIT LAKE
LK SCRANTON OVF
WILLIAMS BR RE
HAZARD POND
MARSHWOOD DAM
DUNMORE N03 DAM
DUNMORE N04 DAM
LAKE SCRANTON
BRUSH VALLEY RE
BEAR GAP #1 & #
TROUT RUN #4
#6 RESERVOIR
SHENANGO RIVER
RIVER STATION Y
YOUGHIOGHENY R
CHESTER CREEK
FOREST CITY-LAC
BRACE BROOK RE
WANAMIE RESERVOIR
PINE RUN
LAUREL RUN RE
OLYPHANT RE
WHITE OAK RE
CHENERY RE
RUSHBROOK RE
FALL BROOK RE
CRYSTAL LAKE RE
GRIFFIN LAKE
ALLEGHENY RIVER
HAGERMAN RUN
LYCOMING CREEK
MOSQUITO CREEK
YORK RE
SOUTH BRANCH CO
KICKAMUIT RE
PAWTUXET RIV SC
MILL RIVER
SHILOH SPRINGS
SHAWS CREEK
LAKE HARTWELL
EDISTO RIVER
GOOSE CREEK
BROAD RIVER
SALUDA RIVER
130
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
SC
SC
SC
SC
SC
SC
SC
SD
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TN
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
TX
GREENVILLE
GREENVILLE
GREENWOOD
LANCASTER
ORANGEBURG
ROCK HILL
SPARTANBURG
ABERDEEN
BRISTOL
CHATTANOOGA
CLARKSVILLE
CLARKSVILLE
CLEVELAND
COLUMBIA
JOHNSON CITY
JOHNSON CITY
KINGSPORT
KNOXVILLE
KNOXVILLE
KNOXVILLE
MARYVILLE
MORRISTOWN
MURFREESBORO
NASHVILLE
NASHVILLE
ABILENE
ABILENE
ABILENE
BROWNSVILLE
BRYAN
CORPUS CHRISTI
DALLAS
DALLAS
DALLAS
DALLAS
EL PASO
FORT WORTH
FORT WORTH
FORT WORTH
GARLAND
HARLINGEN
HOUSTON
INGLESIDE
LAREDO
257
256
258
267
254
266
260
348
475
487
473
474
486
491
476
477
478
485
484
482
483
479
470
471
472
544
545
546
534
549
550
542
539
540
541
531
537
538
536
543
533
528
551
532
470
470
470
470
460
470
470
610
610
610
610
610
610
610
610
610
610
610
610
610
610
610
610
610
610
650
650
650
620
650
660
640
640
640
640
620
640
640
640
640
620
615
660
620
TABLE ROCK COVE
N SALUDA RE
LAKE GREENWOOD
CATAWBA RIVER
N FORK
CATAWBA RIVER
SOUTH PACOLET R
ELM RIVER AND
SOUTH HOLSTON
TENN RIVER
CUMBERLAND R
BIG WEST FORK C
HIWASEE RIVER
DUCK RIVER
WATAGUA RIVER
PATRIC HENRY R
SOUTH HOLSTON R
MELTON HILL RE
BEAVER CREEK
TENNESSEE RIVER
LITTLE RIVER
CHEROKEE LAKE
STONES RIVER
CUMBERLAND R
CUMBERLAND R
LAKE FT PHANTO
LAKE KIRBY
LAKE ABILENE
RIO GRANDE R
BRAZOS RIVER
NUECES RIVER
TRINITY RIVER
LAKE RAY HUBBAR
GRAPEVINE RE
LITTLE ELM RE
RIO GRANDE R
CEDAR CREEK LAKE
BEN BROOK LAKE
EAGLE MT RE
LAKE LAVON
RIO GRANDE R
LAKE HOUSTON
NUECES RIVER
RIO GRANDE R
129
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
WA
WI
WI
WI
WI
WI
WI
WI
WI
WI
WV
WV
WV
WV
WV
WV
WV
WY
WY
WY
WY
YAKIMA
APPLETON
GREEN BAY
KENOSHA
MANITOWOC
MILWAUKEE
OSHKOSH
RACINE
SHEBOYGAN
SUPERIOR
BECKLEY
CHARLESTON
FAIRMONT
HUNTINGTON
MORGANTOWN
MORGANTOWN
WHEELING
CASPER
CHEYENNE
CHEYENNE
CHEYENNE
006
274
277
282
278
280
273
281
279
276
435
436
398
437
400
399
431
352
336
560
779
020
500
500
500
500
500
500
500
500
500
610
610
610
610
610
610
610
610
610
910
850
NACHES RIVER
LAKE WINNEBAGO
LAKE MICHIGAN
LAKE MICHIGAN
LAKE MICHIGAN
LAKE MICHIGAN
LAKE WINNEBAGO
LAKE MICHIGAN
LAKE MICHIGAN
LAKE SUPERIOR
GLADE CK IMPOUN
ELK RIVER
TYGART VALLEY R
OHIO RIVER
MONONGAHELA R
COBUN CREEK
OHIO RIVER
N PLATTE RIVER
DOUGLAS RE
LITTLE SNAKE 10
CRYSTAL LAKE
132
-------�
STATE
CITY
LINE NO
PUB
SOURCE WATER
TX
TX
TX
TX
TX
TX
TX
TX
TX
UT
UT
UT
UT
UT
UT
UT
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VA
VT
VT
WA
WA
WA
WA
WA
WA
WA
WA
WA
WA
LONGVIEW 769
LUBBOCK 506
NOLANVILLE 548
SAN ANGELO 552
SAN ANGELO 554
SAN ANGELO 553
TEMPLE 547
TEXARKANA 519
TYLER 555
OGDEN 774
OGDEN 773
OGDEN 772
SALT LAKE 776
SALT LAKE 778
SALT LAKE 775
SALT LAKE 777
ANNANDALE 190
CHARLOTTSVILLE . 185
CHARLOTTSVILLE 186
CHARLOTTSVILLE 187
CHESTERFIELD 189
CHESTERFIELD 179
CHESTERFIELD 180
DANVILLE 246
FAIRFAX 177
HOPEWELL 181
LYNCHBURG 184
LYNCHBURG 183
PETERSBURG 182
RICHMOND 188
ROANOKE 248
ROANOKE 247
BURLINGTON 719
SOUTH BURLINGTON 718
BELLINGHAM 634
BREMERTON 635
EVERETT 633
LONGVIEW 008
MOUNT VERNON 625
RICHLAND 005
SEATTLE 631
SEATTLE 632
TACOMA 630
WALLA WALLA 007
690 LAKE CHEROKEE
610 S CANADIAN R
650 LAKE BELTON
670 COLORADO RIVER
670 TWIN BUTES RE
670 NORTH CONCHO R
650 BELTON LK
610 WRIGHT PATTMAN
680 LAKE TYLER
820 WHEELER C
820 WEBER BASIN CON
820 PINE VIEW RE
830 CITY CREEK
830 BIG COTTONWOOD
830 PARLEYS CREEK
830 LITTLE COTTONWO
380 OCCOQUAN RIVER
370 RAGGED MOUNTAIN
370 SUGAR HOLLOW RE
370 S FORK RIVANNA
370 FALLING CREEK
360 APPOMATTOX RVR
360 SWIFT CREEK
445 DAN RIVER
350 GOOSE CREEK
360 APPOMATTOX R
370 JAMES RIVER
370 PEDLAR RESERVOIR
360 LAKE CHESDIN
370 JAMES RIVER
445 CARVINS COVE
445 FALLING CREEK RE
232 LAKE CHAMPLAIN
232 LAKE CHAMPLAIN
080 LAKE WHATCOM
090 UNION RIVER
070 SULTAN RIVER
020 COWLITZ RIVER
015 SKAGIT RIVER
020 COLUMBIA RIVER
060 CEDAR RIVER RE
070 TOLT RIVER
050 GREEN RIVER
020 MILL CREEK
131
-------�
INVENTORY OF MUNICIPAL WASTES FACILITIES AND FACILITY NEEDS
Record
Location
1-2
3-7
3-11
12
13
183-189
190-192
193
Field Size
in Bytes Unit Record Description
U-lS
ir-20
21-23
2«— 2S
27-30
31-32
33-52
53-72
73-92
93-94
55-S6
S7-10*
105
106-113
114-119
116-139
140-163
164-165
166-167
160-169
1TO
171
172-184
* 3
4
3
3
4
2
20
* ;o
20
2
t
e
\
a
2
24
24
2
2
2
1
I
* 13
STATE CODE - ALWAYS NUMERIC
COMMUNITY NUMBER - ALWAYS NUMERIC
FACILITY NUMBER - ALWAYS NUMERIC
DISCHARGE NUMBER - ALWAYS NUMERIC
MAY ALSC BE USED TO FURTHER IDENTIFY
A NEED PECCRC - POSITION 13 HOULO
ALSC BE NUMERIC
FACILITY NEED NUMBER - ALWAYS NUMERIC
IF >"!» RECORD IS A NEED RECORD ONLY
AND NOT AN EXISTING FACILITY RECORD
COUNTY NLMBER - ALWAYS NUMERIC
PRIORITY BASIN
IGNORE
fcATER QUALITY/EFFLUENT LIMITATIONS
* STANDARD METROPOLITAN STATISTICAL AREA
ISMSA CODE FBCM FIPS PUBLICATION!
NUMERIC
IGNORE
FACILITY NAME PART I - ALPHA
FACILITY NAME P«RT 2 - ALPHA
COUNTY NA«E - ALPHA
CLD FWCA REGION MJMOCR 101-09! - NUMERIC
* CONGRESSIONAL DISTRICT - NUMERIC
• CENSUS OF COMMUNITY - NUMERIC
CENSUS YEAR - NUMERIC «i = t9iO:7»19TQ I
ST/TE OISCMRGE PERMIT NUMBER - ALPHA
* MULTI/TYPE PCINT DISCHARGE - NUMERIC
(ll-l OF 1> I3»l OF 3! ETC.I
DISCHARGE CUTFALL NAME PART I - ALPHA
DISCHARGE CUTFALL NAME PART 2 - ALPHA
MAJOR BASIN NUMBER _ NUMERIC
• MINOR BASIN NUMBER - NUMERIC
• SUB BASIN NUMBER - NUMERIC
* INTER/1NTRA STATE STREAM - NUMERIC
I I - INTERSTATE! 0 .- 1NTRASTATE I
* OUTFALL TO LARGE OPEN WATER BODY
NUMERIC ( I * YES >
* LAT/LONG OF DISCHARGE POINT - NUMERIC
( POSITIONS 1-6 - LATITUDE »
I POSITIONS 7-13 - LONGITUDE I
* DISTANCE OUTFALL FROM SHORE OR BANK
I POSITIONS t-4 - DISTANCE;
POSITION 5""F"OR"M":
SEE INSTRUCTIONS " PART B " PAGE 6 I
* DEPTH OF OUTFALL SUBSURFACE - NUMERIC
» SEE INSTRUCTIONS " PART B " PAGE 7 I
* SERVES OTHER COMMUNITIES - NUMERIC
» I - YES )
• SERVED BY ANOTHER COMMUNITY - NUMERIC
( 1 • YES I
134
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APPENDIX B
DATA SOURCE PROFILES
Municipal Waste Facilities Inventory File
Survey of NEEDS for Municipal Water Treatment
Faci1ities
Permit Compliance System
Inventory of Public Water Supplies
National Water Data Exchange
City Master File
MUNICIPAL WASTE FACILITIES INVENTORY FILE
The Municipal Waste Facilities Inventory (MWFI) File con-
tains data on publicly owned wastewater treatment systems. The
file is maintained at the EPA Washington Computer Center in
Washington, D.C. System manager is Charles Conger (202/ 426-
7792) and data processing representative is Joyce Boyd. Data
sources are regional and state inventories of facilities. The
file contains data for about 24,000 plants; however, it has
been recently updated only for EPA Region IV.
The following table presents the list of MWFI data ele-
ments. Those which were used on input data to this project are
marked with an asterisk.
133
-------�
SURVEY OF NEEDS FOR MUNICIPAL WATER TREATMENT FACILITIES
The 1976 survey of NEEDS system provides data on publicly
owned treatment works in terms of location, treatment type, and
effluent flow. The file is maintained at the EPA Washington
Computer Center in Washington, D.C. System manager is James
Chamblee (202/ 426-4443). Data source was a 34-page question-
naire sent to 17,000 facilities. Most major facilities are in-
cluded.
A brief description of the data elements is presented below
with those used for this project marked with an asterisk.
NEEDS SURVEY NUMBER
This is a nine digit number. The first two digits are a
coded number from the Federal Information Processing Standard
for Designating States and Outlying Areas of the United States
UiHb-b), and designates a particular state. The next four
numbers are assigned sequentially by each state agency. The
last three numbers are assigned by the authority to the facil-
i ty.
FACILITY NAME
The official name of the facility which is legally used to
i d e n 11 f y i t.
AUTHORITY NAME
The official name of the authority which is legally used
toidentifyit.
*NPDES NUMBER
The National Pollutant Discharge Elimination System per-
mit number, assigned through the EPA permit program.
BASIN NUMBER
This four digit number shows the EPA major/minor basin
\* \J CJ c o •
136
-------�
195-202
20)
204-209
210-365
366
36T-374
3T5-3TT
IT8-3T9
160-381
182-383
184-385
186-389
190-396
197-403
(04-406
107-412
U3-418
il9-420
m-426
*27-432
O3-438
O9-441
142-444
8
1
6
* 1
1
* 8
* 3
2
2
2
2
4
7
* 7
* 3
6
* 6
6
* 6
6
6
3
3
445-468
469-492
24
24
493-516 24
S17-540 24
541-546 6
547-548 2
559-560 2
561-567 7
« CENSLS OF SERVING COMMUNITY - NUMERIC
YEAR Of CENSUS - NUMERIC 16 « 1960! 7 - 19TO I
DATE OF THIS REPORT - NUMERIC
( SEE INSTRUCTIONS " PART B " PAGE 4 I
CONSTRUCTION GRANTS NUMBERS AWARDED
( 26 I 6 - CHARACTER FIELDS
* POSITION 1-41 NUMERIC GRANT NUMBER
POSITION 5: WPC NUMBER
POSITION 6: SOURCE OF GRANT
SEE INSTRUCTIONS " PART B " PAGES 7 AND 8
• TYPE SEWER SYSTEM - NUMERIC
• ESTIMATED POPULATION SERVED - NUMERIC
I POSITION 1 • « * « IF FACILITY
IS BEING SERVED I
* DEGREE OF TREATMENT - ALPHANUMERIC
( POSITIONS i-2i NUMERIC
POSITION .3: ALPHA i
SEE REVISED INSTRUCTIONS " PART B "
IGNORE
* YEAR PLANT BEGAN OPERATION - NUMERIC
IGNORE
• YEAR MAJOR REVISION OF PLANT - NUMERIC
* ESTIMATED ANNUAL COST OF OCM - NUMERIC
( 999V9 )
* AVERAGE CILY FLOW ( DESIGN MGD I - NUMERIC
I 999SV999 I
* AVERAGE CAILY FLOW ( ACTUAL MGD I - NUMERIC
( 9999V999 I
* PERCENT INDUSTRIAL FLOW - NUMERIC
* PLANT DESIGN BCD LOAD MG/L - NUMERIC
» PLANT ACTUAL BOD LOAD MG/L - NUMERIC
* PERCENT INDUSTRIAL BOD LOAD - NUMERIC
* PERCENT TREATED EFFLUENT BOD MG/L - NUMERIC
* PERCENT SUSPENDED SOLIDS INFLUENT HG/L - NUMERIC
* PERCENT SUSPENDED SOLIDS EFFLUENT MG/L - NUMERIC
* PERCENT NITROGEN REMOVAL - NUMERIC
* PERCENT PHOSPHORUS REMOVAL - NUMERIC
ALPHA TREATMENT CCOES PART I - ALPHA
SEE INSTRUCTIONS " PART B " PAGE 12
SEE APPENDIX 8 FOR CODES USED
ALPHA TREATMENT COOES PART 2 - ALPHA
SEE INSTRUCTIONS " PART B " PAGE 12
SEE APPENDIX B FOR COOES USED
FACILITY REMARKS PART I - ALPHA
FACILITY REMARKS PART 2 - ALPHA
« IMPLEMENTATION REVIEW DATE - NUMERIC
( YRMOOAY I
* MULTI DATES FOR NEEDS - NUMERIC
( 11 - 1 OF l; 12 • 1 OF 2; ETC I
SEE INSTRUCTIONS " PART B H PAGE 12
* CONFORMANCE PLAN - NUMERIC
SEE INSTRUCTIONS " PART B M PAGE 13
FOR DESCRIPTION OF COOES
* TOTAL ESTIMATED COST ( $1000 I - NUMERIC
135
-------�
faci1ity.
Construction Grant Status
This one digit code shows if there is a construction
grant approved or pending, or if there are no applicable grants.
Projected Change
This one digit code shows projected physical changes for
the facility, i.e., if the facility will be enlarged, upgraded,
replaced, abandoned, etc.
*Abandonment Date
The appropriate date is filled in only if the facility will
be abandoned.
SUMMARY OF CATEGORY NEEDS
This section is used to record the costs for Categories
I-IVB. Column (a) is for the EPA assessment, column (b) is for
the state estimate, and column (c) is the portion required to
satisfy "backlog" facility requirements. "Backlog" refers to
facility requirements that are established on the basis of
current rather than 1990 population. The basis of estimate in
the last column is a one digit code which specifies the basis
of the cost estimation.
*FACILITY POPULATION
This section shows the population which receives treatment
and/or collection from the facility. Both are broken down by
present resident population, present non-resident population,
projected resident population, projected non-resident popula-
tion.
NEED FOR NEW COLLECTORS, INTERCEPTORS, FORCE MAINS, AND PUMPING
STATIONS
This section lists codes for new collectors, interceptors,
force mains and pumping stations, and their costs. The
diameter of pipe is in inches, the length in feet, and the ca-
pacity is in millions of gallons per day (MGD). These have been
converted in the technical summaries to metric units.
DISPOSAL OF LIQUID EFFLUENTS
"Disp," "use," and "chng" are all one digit codes indicat-
ing the type of disposal, whether the facility is now in use,
under construction, etc., and whether or not there will be a'
138
-------�
245 NUMBER
This thirteen digit number is the Municipal Waste Facility
Inventory number.
SAMPLE
If this box is checked, the facility was part of the sample
used by some states for communities of less than 10,000 popula-
tion outside Standard Metropolitan Statistical Areas (SMSA's).
FACILITY LOCATION
The state location is the same two digit FIPS-5 number used
in the authority number. The county location is based on the
FIPS-6 codes. The place location number is derived from the
"Geographic Identification Place Scheme" developed by the Cen-
sus Bureau, and is a four digit number.
CONGRESSIONAL DISTRICT
The number of the Congressional District in which the fa-
cility was located in 1976.
SUBMISSION CODE
This is a one digit number which indicates whether the fa-
cility needs have had no change since the 1974 Survey, were not
reported, or have been changed.
*CITY
The city in which the facility is located.
*COUNTY
The county in which the facility is located.
ZIP CODE
The official Post Office Zip Code of the facility.
*FACILITY STATUS
This shows by a one digit code whether the facility is
currently in operation or not in operation. Facilities not in
operation are usually either currently proposed or under con-
struction.
Nature of Faci1i ty
This is a one digit code which stands for the type of
137
-------�
bv Jul'veihe]q77 ?c* the di«harge will meet secondary treatment
oy July 1, 1977 is answered by a "yes" or "no".
IS REQUIRED TREATMENT LEVEL MORE STRINGENT THAN SECONDARY?
REASON
Whether or not the required treatment level is more strin-
9o6r 'no"" S^°ndar^ treatment standards is answered by a "yes"
or no . If yes, a one digit code- is entered under "REASON".
^TREATMENT AND SLUDGE HANDLING
There are three columns in this section. The first col
is for type of treatment and sludge handling (unU process)
hee USe> "nVthe ^i rd^^lu
umn
140
-------�
physical change, i.e., enlarge, upgrade, etc.
REQUIRED INFILTRATION/INFLOW CORRECTIVE ACTION
"Code" is a one digit number showing the type of corrective
action. "Basis" stands for the Basis of Estimate, referred to
previously.
This number is the total flow component (MGD) due to
i n f i 11 r a t i o n / i n f 1 o w.
MAJOR REHABILITATION/REPLACEMENT REQUIRED
"Code" is a one digit code standing for type of corrective
action. "Basis" is the Basis of Estimate.
DO WASTEWATERS ORIGINATE IN COMMUNITIES EXISTING BEFORE OCTOBER
18, 1972?
"no."
This is self-explanatory and is answered by a "yes" or
1972 COLLECTION POPULATION
This figure is the actual 1972 population requiring new
col 1ector sewers.
*FLOWS, CONCENTRATION, AND REMOVAL RATES
This section is for monthly average flow or concentration
figures in terms of the existing rate, the present design rate,
and projected design rate for the following categories:
1. total flow in million gallons per day (MGD)
2. total industrial flow in million gallons per day (MGD)
3. domestic flow per capita in gallons per capita per
day (gpcd)
Below these figures, influent and effluent concentrations
are shown for five-day Biological Oxygen Demand (milligrams per
liter), suspended solids (milligrams per liter), phosphorus
(milligrams per liter), total kjeldahl nitrogen (milligrams per
liter), total nitrogen (milligrams per liter), and any others.
DOES DISCHARGE MEET SECONDARY?
Whether or not the discharge currently meets secondary
treatment standards is answered by a "yes" or "no."
WILL DISCHARGE MEET SECONDARY BY JULY 1, 1977?
139
-------�
PCS DATA ELEMENT LIST
1 _ .
1 L c SYSTEM
|_ DATA ELEMENT
REGION CODE
* NPDES ID NUMBER
STATE CODE
DATA
TYPE
ABBR.
|
F
F
T*
i r
LOCATION, STATE-CITY CODE
*. SIC CODE (1972)
* MAJOR DISCHARGE INDICATOR
1 F
F
F
TYPE APPLICATION 1 F
TYPE OF OWNERSHIP j F
NAME OF FACILITY (SHORT)
NAME OF FACILITY (LONG)
I FIRST 30 DIGITS FACILITY NAME
SECOND 30 DIGITS FACILITY NAME
THIRD 30 DIGITS FACILITY NAME
FOURTH 30 DIGITS FACILITY NAME
LAST 5 DIGITS FACILITY NAME
* CITY NAME
1 F
F
1 F
F
F
F
* COUNTY CODE 1 c.
KC.UN
NPID
STTE
LCTN
SIC2
MAD I
TYPA
TYPO
FNMS
FNML
NAM]
NAM2
NAM3
NAM4
NAM5
CYN:I
_
1 F i r\TY
* COUNTY NAME F 1
RIVER BASIN CODE (2 DIGITS) MAJOR 1 F
RIVER BASIN CODE (4 DIGITS) MAJOR-MINOR 1 F
RIVER BASIN CODE (ALL DIGITS)
TYPE PERMIT ISSUED EPA/STATE
PERMIT ISSUE DATE
PERMIT EXPIRATION DATE
1 SUB-KhCiuN CODE
NEW .SOURCE CODE
INSPECTION DATE
INSPECTION TYPE
INSPECTOR CODE
FACILITY CODE
INSPECTION COMMENTS
COMPLIANCE SCHEDULE NUMBER
DATA SOURCE CODE
EVENT CODE
EVENT DESCRIPTION
COMPLIANCE COMMENTS
COMPLIANCE SCHEDULED DATE
COMPLIANCE ACTUAL DATE
DISCHARGE NUMBER
DMR REPORT DESIGNATOR
INITIAL REPORT DATE
REPORT UNIT
NO. OF UNITS IN REPORTING PERIOD
TOTAL NO. OF REPORTS DUE
INITIAL SUBMISSION DATE (EPA)
SUBMISSION UNIT (EPA)
NO. OF UNITS IN SUBMISSION PERIOD (EPA)
INITIAL SUBMISSION DATE (STATE)
SUBMISSION UNIT (STATE)
NO. OF UNITS IN SUBMISSION PERIOD (STATE)
FORECAST SUBMISSION DUE DATE (EPA) *
FORECAST SUBMISSION DUE DATE (STATE) **
* SE REPORT ONLY ** SS REPORT ONLY
L
F
F
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I iMi\ru
D I NORP
D STSU
D
D
D
D
D
D
SUUN
NSUN
STSS
suus
NSUS
SUDU*
SUDS**
NO. OF DIGITS
10/30
CARD
i ^ ~~~~ ~
40
CARD
2
9
5
10
21 r 1
7
i
X
2
£.
•J
J
30
120
30
30
30
30
5
20
20
2
4
*
2
1
1
?
}
!
121
31
31
31
31
6
2]
1
21
5
75
3
7
5
5
7
5 1
1 5 |
1
50
2
4
3
30
30
6
6
3
1
5 I
51 1
5 1
5 1
5 1
31 1
31 1
7
7
5
5
6 7 1
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35
35
6 7 1
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3
6
1
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6
6
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142
-------�
PERMIT COMPLIANCE SYSTEM
The Permit Compliance System (PCS) contains the universe
of facilities for which effluent discharge permits have been
issued. The system is maintained at the EPA Washington Computer
Center in Washington D.C. The system manager is William Milligan
(202/755-0994) and the data processing representative is
Carroll Barrett. The file contains data on about 60,000 indus-
trial and municipal facilities with respect to general location
and type of activity (SIC code).
The following table presents the list of PCS data elements.
Those which were used on imput data to this project are marked
with an asterisk.
141
-------�
IPWS DATA ELEMENTS
KR*S;J " This is the mailin9 address of the utility (this
treVt:eenYsarily have to be the ph^sicai '«•»*{;;
. of
the ut111tJ?E " ThlS 1S the ZiP C°de °f the maill'"9 address of
* MUNICIPAL^V, DISTRICT, INVESTOR
*9. WHAT IS THE CHARACTERISTIC(S) OF YOUR SERVICE AREA?
10. CAPACITIES - The most current information available.
*11. PRODUCTION - The most current information available.
12. DATE FORM COMPLETED
*13. REMARKS
15. INTAKE LOCATION - Latitude and Longitude of intake and
144
-------�
THE INVENTORY OF PUBLIC WATER SUPPLIES
The Inventory of Public Water Supplies (IPWS) contains
data on about 60,000 water supply systems. The file is main-
tained at the EPA Washington Computer Center in Washington D.C.
System Manager is Patrick Tobin. Data source was a questionnaire
which included: utility name, owner, characteristic of supply
and capacity and production, population served, source water and
type of treatment.
The following list presents the data elements included.
Those which were used as input data to this project are marked
with an asterisk.
143
-------�
NATIONAL WATER DATA EXCHANGE
-
water data available from a large number of organizations.
The NAWDEX system identifies domestic and foreiqn oraani
Mat.' i?. ra,2: K.':M!:S -.i'l;,:?;;: ' r "••
b,,,c,n, »h,t ,.o,r.pl,tc r,,10n th, .r,.n?z.{?" ;";tS;J »,t,r
»
CITY MASTER FILE
£PA
146
-------�
river basin.
*16. LABORATORY CONTROL - Place an X in the box for the type or
types of laboratory analyses made at the treatment facility.
Leave these blocks blank if no laboratory analyses are performed
145
-------�
APPENDIX C
WASTEWATER IN DRINKING WATER, BY PERCENTAGE AND
TYPE, FOR UTILITIES WITH GREATEST IMPACTS
This appendix presents an alphabetical listing of the
utilities in Tables 5 and 7 of the text.
148
-------�
EPA CITY MASTER FILE
Element #
* 1
* 2
* 3
*4
5
6
7
8
9
10
11
*12
*13
*14
15
*16
17
*18
*19
20
21
22
23
24
25
26
27
28
Posi tions
1-2
3-5
6-11
12-18
19-20
21-25
26-29
30
31-32
33-34
35-36
37-40
41-66
67-92
93-95
96-114
115
116-123
124-131
132
133
134-135
136
137
138-142
143-147
148
149-154
Length
2
3
6
7
2
5
4
1
2
2
2
4
26
26
3
19
1
8
8
1
1
2
1
1
5
5
1
6
Name
New state number
New county number
Latitude
Longi tude
Old state number
City number
Record number
Record code
EPA Major basin
EPA Minor basin
EPA Sub basin
SMSA
Community name - part 1
Community name - part 2
Old county number
County name
FWQA Population size group
1960 Census
1970 Census
Contract Awards PSG
Sanitary District code
Congressional District code
FWQA PSG (1970)
Contract Awards PSG (1970)
Study category
Computer category
Latitude/Longitude flag
Date of update
147
-------�
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TECHNICAL REPORT DATA
(Please read Instructions on the reverse before completing)
1. REPORT NO.
EPA-600/2-80-044
2.
3. RECIPIENT'S ACCESSION" NO.
4. TITLE AND SUBTITLE
WASTEWATER IN RECEIVING WATERS AT WATER SUPPLY
ABSTRACTION POINTS
5. REPORT DATE
July 1980 (Issuing Date)
6. PERFORMING ORGANIZATION CODE
7. AUTHOR(S)
Michael D. Swayne, Gregory H. Boone, David Bauer,
and John Scott Lee
8. PERFORMING ORGANIZATION REPORT NO.
9. PERFORMING ORGANIZATION NAME AND ADDRESS
SCS Engineers, Inc.
2875 152nd Avenue, NE
Redmond, Washington 98052
10. PROGRAM ELEMENT NO.
35B1C
11. CONTRACT
EPA 68-03-2592
63-03-2592
12. SPONSORING AGENCY NAME AND ADDRESS
13. TYPE OF REPORT AND PERIOD COVERED
Municipal Environmental Research Laboratory--Ci n. ,OH
Office of Research and Development
U. S. Environmental Protection Agency
Cincinnati, Ohio 45268
Final 8-77 to 1-79
14. SPONSORING AGENCY CODE
EPA/600/14
15. SUPPLEMENTARY NOTES
Project Officer: John N. English 513/684-7613
16. ABSTRACT
The purpose of this project was to determine how much wastewater and
wastewater-derived material from discharges is present in the surface water
supplies of U.S. cities of over 25,000 population. The study identifies 1246
municipal water supply utilities using surface water from 194 basins serving 525
cities with populations greater than 25,000. The results are tabulated to show for
each utility: the number of upstream wastewater dischargers by type, estimation of
cumulated wastewater discharge flow and the ratio of wastewater flow to stream or
river flow. The results ranged from 142 utilities with no dischargers identified
to many utilities where the wastewater constitutes a major portion of the water supply.
Several utilities were determined to be using water from a source whose low flow was
less than the combined upstream discharge flows. Water supplies serving cities near
the bottom of large river basins were found to contain wastewater from several thou-
sand dischargers. However, those utilities with the highest percentage of wastewater
relative to supply flow were generally from small-to medium-sized creeks and rivers.
Twenty cities with a total population of over seven million were determined to have
surface water supplies containing from 2.3 percent to 16 percent wastewater during
average flow conditions and from 8 percent to 350 percent wastewater during low flow
conditions.
17.
KEY WORDS AND DOCUMENT ANALYSIS
DESCRIPTORS
b.IDENTIFIERS/OPEN ENDED TERMS C. COS AT I Field/Group
Water Treatment
Water Reuse
Potable Water
Waste Treatment
Water Supply
Water Quality
Water Utilities
Stream Flow
Surface Water
Water Discharges
13B
18. DISTRIBUTION STATEMENT
Release to Public
19. SECURITY CLASS (This Report)
Unclassified
21. NO. OF PAGES
199
20. SECURITY CLASS (This page)
Unclassified
22. PRICE
EPA Form 2220-1 (9-73)
189
U.S. GOVERNMENT PRINTING OFFICE: 1980--657 - 165/0121
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