A Message from the Director

Last year we celebrated the 60th anniversary of the City’s Miramar Reservoir. It was an opportunity to reflect on our past, focus on our current operations and look forward to upcoming projects.

Not only is Miramar Reservoir an important part of our water supply system, but it has become a very popular recreational area for the public. And in the future, Miramar Reservoir will be a key part of the City’s Pure Water system that will provide more than 40% of our drinking water by 2035.

Two major steps forward that were taken in 2020 to begin construction on the Pure Water system included:

• Construction bids were advertised for the North City Pure Water Facility, Morena Northern Alignment and Tunnels, Morena Pump Station and expansions of the North City Water Reclamation Plant and North City Pure Water Pipeline, and
• A U.S. EPA loan was refinanced that will save taxpayers $293 million.

2020 was a difficult year for all of us, and 2021 has its challenges as well. But we are proud that we have been able to continue providing great water and wastewater service to the citizens of San Diego during this pandemic. We adapted in numerous ways by having many employees working from home, instituting new safety protocols at our facilities and in the field and providing more assistance to customers online.

In the coming years you’ll see progress as we build the Pure Water system, continue to upgrade our infrastructure, adapt to better assist the public and improve our water supply to make San Diego a more sustainable city.

Sincerely,

Shauna Lorance

Director of Public Utilities

City of San Diego

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Water Supply - What’s in Your Water

Before It’s Treated?

The sources of drinking water (both tap water and bottled water) include rivers, lakes, streams, ponds, reservoirs, springs and wells. As water travels over the surface of the land or through the ground, it dissolves naturally occurring minerals and, in some cases, radioactive material and can pick up substances resulting from the presence of animals or from human activity. Contaminants that may be present in source water include:

• Microbial contaminants, such as viruses and bacteria that may come from sewage treatment plants, septic systems, agricultural livestock operations and wildlife.
• Inorganic contaminants, such as salts and metals, that can be naturally occurring or result from urban storm water runoff, industrial or domestic wastewater discharges, oil and gas production, mining or farming.
• Pesticides and herbicides that may come from a variety of sources such as agriculture, urban storm water runoff and residential uses.
• Organic chemical contaminants, including synthetic and volatile organic chemicals that are byproducts of industrial processes and petroleum production and can also come from gas stations, urban storm water runoff, agricultural application and septic systems.
• Radioactive contaminants, that can be naturally occurring or be the result of oil and gas production and mining activities.

In order to ensure that tap water is safe to drink, the U.S. Environmental Protection Agency (EPA) and the State Water Resources Control Board (State Board) prescribe regulations that limit the amount of certain contaminants in water provided by public water systems. The U.S. Food and Drug Administration regulations and California law also establish limits for contaminants in bottled water that provide the same protection for public health. Drinking water, including bottled water, may reasonably be expected to contain at least small amounts of some contaminants. The presence of contaminants does not necessarily indicate that water poses a health risk.

Imported Water Supply and the Impact on Water Quality

The City of San Diego currently imports most of its water supply, the bulk of which is raw (untreated) water purchased from the San Diego County Water Authority. All raw water is treated before entering the City’s drinking water distribution system. Less than 10% of the imported water purchased from the County Water Authority is a blend of treated water from the Metropolitan Water District’s Skinner Water Treatment Plant, the County Water Authority’s Twin Oaks Valley Water Treatment Plant and the Carlsbad Desalination Plant.

Most of the imported water from the County Water Authority is a blend from the Colorado River and State Water Project (see map to the left). Throughout the year, the ratio of water from each source changes. The constituents that make up the City’s source water are influenced by the water source, climate, geology and the land activities that they flow through. The City continually monitors our source water and adjusts its treatment process to ensure that the water is always healthy and safe.

News on Rate

Increases

You will soon receive information in the mail with details about proposed rate increases for water and wastewater services.

For the first time in 10 years, the City of San Diego is planning to increase wastewater rates, by 5%, starting in January 2022. In addition, the City is proposing to pass through regional water cost increases to its customers.

For more information, visit

www.sandiego.gov/rate-increases

STAGES OF OUR WATER TREATMENT

Watershed protection: Protecting the watersheds prevents contamination

of our water supply and is the most cost-effective process in water treatment.

Extensive measures are taken to prevent contamination of our local and imported water. If you see “No Swimming” or “No Dumping” signs posted near water supplies, this is for the protection of your drinking water. The latest Watershed Sanitary Survey, which contains information on the City’s watersheds, including water quality and vulnerabilities, is available at: sandiego.gov/public-utilities/

water-quality/watersheds/sanitary-survey.

Coagulation: This is the chemical process of rapidly mixing coagulants into the water entering the water treatment plant. Many of the particles in the source water have negative charges, causing them to repel each other, much like two magnets when the negative ends are put together. Coagulation changes these negative charges to neutral.

Flocculation: Coagulated water is slowly mixed causing the neutral particles

to collide. When the collisions occur, the particles clump together forming floc. As the floc is formed, particles in the water are trapped within the floc. The floc now looks like snowflakes suspended in the water.

Sedimentation: The floc particles are heavier than water. Mixing is stopped and the water slowly flows through the sedimentation basins, during which the floc settles to the bottom and is removed. The clear water is collected from the

top of the sedimentation basins.

Disinfection, Primary: Drinking water is further treated to remove or inactivate viruses, bacteria and other pathogenic organisms. Disinfection is accomplished in a variety of methods. The Alvarado and Miramar water treatment plants use ozone as the primary disinfectant. The Otay Water Treatment Plant uses chlorine dioxide as the primary disinfectant. These are advanced disinfection processes and have the advantage of providing higher quality water with better taste.

Filtration: Water is passed through deep filtration beds to produce water

that is crystal clear. Extremely small particles are removed during this process. San Diego’s water treatment plants produce water with turbidity (cloudiness)

significantly better than drinking water standards, indicating a highly effective

treatment process and resulting in high-quality drinking water.

Disinfection, Secondary: Chloramines are created by adding chlorine and ammonia to the water. Chloramines help prevent microbial contamination from occurring in the water distribution system.

Corrosion Control: The corrosivity of the water is controlled by adjusting the pH.

Primary

Disinfection,

Chlorine Dioxide,

Otay WTP

Ferric Chloride

Polymer

Anthracite Coal

Silica Sand

Support Media

Sweep Up Around Your Yard: Sweep up dirt, debris and yard waste and dispose of them properly. Yard waste has the potential to carry hazardous landscaping chemicals such as pesticides and fertilizers into the storm drain system and generate large amounts of bacteria if left to decompose in gutters, drains and local waterways.

Eliminate Over-Irrigation: Prevent water from leaving your property so it won’t carry pollutants into our storm drains during dry weather. Sweep hard surfaces instead of hosing them off with water, adjust and maintain sprinklers so they don’t spray onto your driveway or sidewalk and fix leaks promptly.

When It Rains: During the rainy season, redirect rain gutter downspouts to landscaped areas where the water can be absorbed and replenish groundwater or connect your downspout to a rain barrel to store the water for later use.

From Your Car: Your car can be a source of automotive pollutants such as motor oil. It’s important to check your car regularly for fluid leaks.

From Curb to Ocean: The City of San Diego oversees the operation and maintenance of 48,000 storm drain structures, 1,148 miles of pipe and 15 pump stations designed to control flooding by moving rain water away from the public and property to transport it to local waterways.

Aging Infrastructure: Maintenance of our storm water system is partially funded by a small storm water fee included in your water bill and supplemented by other City funds. It’s estimated that almost $900 million are needed in the next five years to fully fund the repairs and improvements required for the maintenance of this infrastructure and protect the quality of our waterways.

Vital to San Diego: A fully functional and operational modern storm water system is important to the environmental and economic health of San Diego and is essential to our quality of life.

Think Blue appreciates everything you do to help protect our local waterways. Visit ThinkBlue.org for more information on how you can prevent pollution in our waterways.

DEFINITION OF TERMS

Action Level (AL): The concentration of a contaminant which, if exceeded, triggers treatment or other requirements that a water system must follow.

Location-based Running Annual Average (LRAA): The average of the most recent four quarters of monitoring performed at a distinct location in the distribution system. Location-based Running Annual Averages are calculated quarterly using 12 months of data and may include values obtained in 2018.

Maximum Contaminant Level (MCL): The highest level of a contaminant that is allowed in drinking water. Primary Maximum Contaminant Levels are set as close to the Public Health Goals or Maximum Contaminant Level Goals as is economically and technologically feasible. Secondary Maximum Contaminant Levels are set to protect the odor, taste and appearance of drinking water.

Maximum Contaminant Level Goal (MCLG): The level of a contaminant in drinking water below which there is no known or expected health risk. Maximum Contaminant Level Goals are set by the U.S. Environmental Protection Agency.

Maximum Residual Disinfectant Level (MRDL): The highest level of a disinfectant allowed in drinking water. There is convincing evidence that addition of a disinfectant is necessary for control of microbial contaminants.

Maximum Residual Disinfectant Level Goal (MRDLG): The level of a drinking water disinfectant below which there is no known or expected risk to health. Maximum Residual Disinfectant Level Goals do not reflect the benefits of the use of disinfectants to control microbial contaminants.

Notification Level (NL): Health-based advisory levels established by the Division of Drinking Water for chemicals in drinking water that lack Maximum Contaminant Levels. When chemicals are found at concentrations greater than their notification levels, certain requirements and recommendations apply.

Public Health Goal (PHG): The level of a contaminant in drinking water that does not pose a significant risk to health. Public Health Goals are not regulatory standards.

Primary Drinking Water Standard (PDWS): Maximum Contaminant Levels, Maximum Residual Disinfection Levels and treatment techniques for contaminants that affect health, along with their monitoring and reporting requirements.

Treatment Technique (TT): A required process intended to reduce the level of a contaminant in drinking water.

ABBREVIATIONS

1. absent

CA SMCL: California Secondary Maximum Contaminant Level

CU: color units

DLR: detection limit for reporting

gr/Gal: grains per gallon

MDL: City of San Diego Water Quality Laboratory Method Detection Limit –

the lowest quantifiable concentration of a measured parameter detectable by the laboratory.

mL: milliliter

n/a: not applicable

ND: not detected (less than DLR, where applicable)

NTU: nephelometric turbidity units

OU: odor units

pCi/L: picocuries per liter (a measure of radiation)

ppb: parts per billion or micrograms per liter (μg/L) – [1 ppb = 0.001 ppm]

ppm: parts per million or milligrams per liter (mg/L) – [1 ppm = 1,000 ppb]

μS/CM: micro-siemens/centimeter

• less than

• greater than

Primary standards (MCLs) are developed for the purpose of protecting the public from possible health risks associated with long-term exposure to contaminants. In this table there are five primary standards listed, which means that of the many primary standards set by DDW and the EPA, only these were detected at or above the DLR in San Diego’s drinking water. These results are significantly below their respective MCLs. In general, no health hazard is expected to exist when contaminant levels are below a Primary MCL. A list of the parameters which were analyzed for, but not detected, in San Diego’s drinking water is posted at sandiego. gov/public-utilities/water-quality/water-quality-reports.

California state law requires water agencies with more than 10,000 water service connections to supplement naturally-occurring fluoride in their drinking water. Our water system complies with this requirement to help prevent dental cavities in consumers. In 2020, the City of San Diego’s source waters contained naturally- occurring fluoride between 0.1 and 1.0 ppm. State regulations require water producers to supplement this naturally-occurring fluoride to an optimum dose of 0.7 ppm. In 2020 treated water had fluoride concentrations ranging from 0.1 to 0.9 ppm, with average values of 0.4 to 0.7 ppm. Information about fluoridation, oral health, and current issues is available at cdc.gov/fluoridation/index.html.

As water travels over the surface of the land or in underground aquifers, it dissolves naturally-occurring minerals and, in some cases, radioactive material. Radioactive materials can be naturally-occurring or a result of oil and gas mining activities. The results in the table above are presented in units of picocuries per

liter (pCi/L), a standard measurement that represents an amount of radiation per liter of water. San Diego’s drinking water is substantially lower than the MCL for all radioactive parameters.

*Based on Monthly Percentages of Positive Total Coliform samples

CITY OF SAN DIEGO DISTRIBUTION SYSTEM

MAJOR SOURCES IN

DRINKING WATER

Naturally present in the environment

We are required to monitor your drinking water for specific contaminants on a regular basis. Results of regular monitoring are an indicator of whether your drinking water meets health standards. During December 2019 through April 2020, 139 of the 2,706 required distribution system sample sites were not monitored for total coliform and E. coli for reasons outside of our control. Therefore, we cannot be sure of the quality of the drinking water in the associated pressure zones during the weeks these sites were not monitored. However, we have since taken the required samples and put in place policies and tools to safeguard against similar occurrences in the future. Coliforms are bacteria that are naturally present in the environment and are used as an indicator that other, potentially-harmful bacteria may be present in the water supply.

DDW regulations require the City to test a minimum of 85 samples per week throughout our distribution system for total coliform bacteria, and to report the results, including the percentage of total coliform positive samples in a given month. To meet this requirement, in 2020 the City of San Diego collected and analyzed 6,784 total

coliform samples from the distribution system, an average of 130 per week. The test also examines the presence of E. coli, which is a subgroup of total coliform. The MCL for total coliform is the presence of coliform in 5% or more of the samples analyzed in one month, meaning that if 100 samples are collected in March and five contain total coliform, a violation of the MCL has occurred. The regulations are written as a percentage of monthly samples because multiple variables can cause a positive result, including localized contamination at the tap. In 2020, the City did not exceed the monthly MCL for total coliform. In fact, this has never occurred in the City’s system since this rule was established in 1989. The maximum value recorded in 2020 was 0.74 percent of monthly samples. When any sample tests positive for total coliform, three additional samples associated with that site are collected and the cause of the positive result is investigated.

Total Coliform Rule testing also examines the presence of E. coli, which is a subgroup of Total Coliform. All samples obtained from our distribution system in 2020 were absent of E. coli.

MAJOR SOURCES IN DRINKING WATER

Soil runoff

Turbidity is a measure of the cloudiness of the water and is regulated as a Treatment Technique (TT) – an indicator of the effectiveness of our treatment. The City’s three water treatment plants (WTPs) monitor turbidity every 15 minutes to ensure consistent, high-quality drinking water production for our customers.

46. performance goals established by DDW state that all samples should have turbidity less than 1 NTU, and 95% of the samples should have turbidity less than 0.3 NTU. All three of our treatment plants had 100% of turbidity values less than 0.3 NTU; the maximum values measured in 2020 were 0.20 NTU for Alvarado WTP, 0.10 NTU for Miramar WTP and 0.08 for Otay WTP. These consistent and very low turbidity results have led

to our treatment plants receiving performance awards. For example:

• The Otay WTP has been awarded the Director’s Award from the American Water Works Association (AWWA) Partnership for Safe Water (PSW) Program for thirteen consecutive years.
• The Miramar WTP has received the Director’s Award for nine years and the President’s Award for eight consecutive years.
• Our award-winning Alvarado Treatment Plant participates in the PSW program, meeting all turbidity standards.

Lead and copper are at Non Detectable levels in the water produced at San Diego’s water treatment plants, but can enter drinking water through plumbing materials used in homes or businesses. Exposure to lead and copper may cause health problems ranging from stomach distress to brain damage. In 1991, the EPA published the Lead and Copper Rule (LCR) which, along with corrosion control and other treatment practices, requires monitoring of lead and copper at customer taps. The purpose of the LCR residential sampling is to assess the potential of lead and copper to leach into drinking water from the plumbing installed between the water meter and the tap in homes and businesses. If lead concentrations at customer taps exceed an Action Level (AL) of 15 ppb or copper concentrations exceed an AL of 1.3 ppm in more than 10% of taps sampled, we are required to inform the public and undertake a number of additional actions to ensure comprehensive corrosion control.

If present, elevated levels of lead can cause serious health problems, especially for pregnant women and young children. Lead in drinking water is primarily from materials and components associated with service lines and home plumbing. The City of San Diego is responsible for providing high quality drinking water, but cannot control the variety of materials used in plumbing components. When your water has been sitting for several hours, you can minimize the potential for lead exposure by flushing your tap for 30 seconds

to two minutes before using water for drinking or cooking. If you are concerned about lead in your water, you may wish to have your water tested. Information on lead in drinking water, testing methods, and steps you can take to minimize exposure is available from the Safe Drinking Water Hotline at 1-800-426-4791 or at https://www.epa.gov/lead.

Lead and Copper Rule monitoring must be conducted every three years. In 2020 54 customers provided samples from their taps to the City of San Diego for lead and copper analysis. None of the residences had a copper or lead result above the AL. Because less than 10% of our results were above the AL for both lead and copper, our water is considered non-corrosive, and no additional actions are required. Our next system-wide study will be conducted in the summer of 2023.

In 2017, DDW issued a Permit Amendment requiring water utilities to sample for lead in the drinking water of any school requesting testing. Additionally, Assembly Bill 746 was signed into law in October 2017, requiring California water providers to conduct lead testing at public K-12 schools within their service area to determine if lead is present in the school’s private plumbing or water fixtures. The table lists the total number of schools the Public Utilities Department has tested under these programs. To obtain testing results from individual schools, please contact the school directly or visit the district website.

Drinking water must be disinfected to ensure that any potentially harmful microbes are neutralized. There are a variety of disinfection strategies used throughout the United States. San Diego utilizes some of the more advanced disinfection technologies available. Our Alvarado and Miramar water treatment plants use ozone and chloramines for disinfection. Ozone produces fewer disinfection byproducts than chlorine or chloramines alone and is considered a superior disinfection method. However, all disinfectant strategies have the potential to create a byproduct. When ozone is used, bromate is monitored as a disinfection byproduct. The City’s Otay WTP uses chlorine dioxide and chloramines for disinfection. When chlorine dioxide is used, chlorite is monitored as a disinfection byproduct in the plant effluent and distribution system. All 2020 results for bromate and chlorite are below the MCLs. Total Organic Carbon (TOC) has no health effects. It is monitored and reported here because it provides an assessment of potential disinfection byproduct formation.

As drinking water travels from the City’s WTPs through the distribution system to homes and businesses, a disinfectant residual must be maintained in order to prevent growth of potentially harmful microbes.

In San Diego, chloramines are used for this purpose. The City performs frequent and comprehensive monitoring to ensure that disinfectant levels remain in the proper range throughout our large and complex distribution system. The Maximum Residual Disinfectant Level (MRDL) is 4.0 ppm. In 2020 the City analyzed 7751 samples for chloramines throughout the distribution system; the average residual was 2.0 ppm and the maximum was 3.8 ppm.

Another category of disinfection byproducts that the EPA and DDW regulate are Total Trihalomethanes (THMs) and Haloacetic Acids (HAA5). Compliance with EPA’s Stage 2 Disinfection ByProduct (DBP) rule is based on the running annual average at each location monitored in the distribution system. The MCL for THMs is an LRAA of 80 ppb, and the MCL for HAA5 is an LRAA of 60 ppb. The City has had no violations of the EPA Stage 1 and Stage 2 DBP MCLs since the program was formalized in 2002. In 2020, our highest LRAA for TTHM was 46 ppb, and individual measurements ranged from 8.8 to 65.6 ppb. For HAA5, our highest LRAA was 14 ppb, and individual measurements ranged from ND to 22 ppb.

Secondary standards (Secondary MCLs) are set to protect the odor, taste, and appearance of drinking water. If present at or above the Secondary MCL, these parameters may cause the water to appear cloudy or colored, or to have a different or unusual taste or odor. These parameters are not considered to present

a risk to human health at or above Secondary MCL levels. All measurements of Secondary Standards were at or below the Secondary MCL in 2020.

Water quality parameters that may be of interest to our consumers, but do not have MCLs or PHGs and are not considered to present a risk to human health, are included in the table above. Although sodium and hardness do not have MCLs, they are of interest to many consumers who are concerned about sodium intake and may believe that the hardness of the water could affect their health. Therefore, monitoring and

reporting are required by DDW. Sodium refers to the salt present in the water and is generally naturally occurring. Hardness is the sum of positively-charged mineral ions present in the water, essentially the sum of magnesium and calcium. These minerals are usually naturally occurring. Alkalinity and pH are included here because they have proven to be of interest to our customers.

The parameters listed in the Detected Unregulated Parameters section are not regulated by DDW or the EPA, and monitoring is not required. Unregulated contaminant monitoring helps U.S. EPA and the State Water Resources Control Board to determine where certain contaminants occur and whether the contaminants need to be regulated. Boron and N-Nitrosodimethylamine (NDMA) have been issued Notification Levels (NL) by DDW. If detected above the NL, customers must be notified of the presence of these parameters. The results presented here are significantly lower than the NL. Hexavalent Chromium (CrVI) was issued an MCL of 10 ppb and a DLR of 1 ppb by DDW in 2014. However, these were withdrawn in 2017. The values presented here are approximately 100 times less than 10 ppb.

As part of the 1996 Safe Drinking Water Act (SDWA) amendments, every five years EPA selects from the Contaminant Candidate List (CCL) up to 30 unregulated contaminants to be monitored by public water systems as part of the

Unregulated Contaminant Monitoring Rule (UCMR) program. The CCL is a list of contaminants that are not regulated but are known or anticipated to occur in public water systems, and may warrant future regulation under the Safe Drinking Water Act. The results of UCMR studies provide a basis for future regulatory actions to protect public health. The City of San Diego conducted UCMR4 sampling in 2018.

San Diego’s drinking water was tested by an EPA-approved contract laboratory in 2018 for 30 UCMR4 unregulated contaminants. This included 10 different cyanotoxins, none of which were detected. Twenty additional chemicals were monitored, including metals, pesticides, and alcohols. Of these 32 parameters, two were detected – manganese and HAA9. Additionally, two indicators of water quality were monitored in untreated water – bromide and Total Organic Carbon (TOC).

Public Utilities Department

9192 Topaz Way

San Diego, CA 92123

Quality | Value | Reliability | Customer Service

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SAN DIEGO, CA PERMIT 134

This report contains important information about your drinking water. Translate it, or speak with someone who understands it.

Spanish

Este informe contiene información muy importante sobre su agua potable.

Tradúzcalo o hable con alguien que lo entienda bien.

Arabic

Chinese (Traditional)

Chinese (Simplified)

Farsi

French

Cé rapport contient des information importantes concernant votre eau potable. Veuillez traduire, ou parlez avec quelqu’ un qui peut le comprendre.

Hmong

Daimntawv tshaj tawm no muaj lus tseemceeb txog koj cov dej haus.

Tshab txhais nws, los yog tham nrog tej tug neeg uas totaub txog nws.

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Swahili

Shauri hii niya kufahamisha uzuri wa maji ya kunyua.

Shauri nilazima egeuzwe kwa yoyote hajui Kiingereza.

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