The Water Treatment Process | Santa Clara Valley Water

Valley Water operates three drinking water treatment plants, Rinconada, Santa Teresa or Penitencia, to provide Silicon Valley with safe, clean, reliable water.

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Much of our water comes to us from the Sacramento-San Joaquin Delta and our local reservoirs.

The three water treatment plants transform the untreated source water into clean drinking water via a complex treatment process consisting of clarification, filtration, and disinfection steps.

Clarification
The first thing we do is remove the solid particles in the water -- mostly silt mixed in during the water's long journey from the Sierra-Nevada mountains to one of our water treatment plants.
 

As the silty water first enters our water treatment plants, we add chemicals like aluminum sulfate and polymers to the water. This process is called coagulation. As the water then travels through the plants, large mixers are used to blend the chemical and silt together to form heavy solid particles in the flocculation process. The particles then gradually sink to the bottom of the sedimentation basin, while the clarified water, free of solids, overflows and proceeds to the next treatment step. Rakes slowly rotate along the bottom of the sedimentation basin. They scrape the settled sludge at the bottom into a collection channel that removes the sludge out of the basin.

Ozone disinfection
Following major upgrades in , ozone was added at Penitencia and Santa Teresa Water Treatment Plants. Ozone is a powerful disinfectant that minimizes harmful disinfection byproducts and removes unpleasant tastes and odors.

The first step in ozone disinfection is to generate ozone gas. Liquid oxygen is transported to the plant and stored for use. It is then vaporized into oxygen gas. When electric currents are applied to a flow of oxygen gas, some oxygen molecules (O2) are split and bond to other oxygen molecules to form ozone molecules (O3).

Next, water that has completed the sedimentation process is conveyed into the ozone contactor basins. Ozone is bubbled up through the water. Typically, the water spends 15 minutes in this system, traveling up and down a series of reaction cells to maximize the contact with the ozone gas.

Ozonated water then moves on through the pipes to the next step, filtration.

Meanwhile, the ozone that was used in the process is converted back into harmless oxygen and released into the atmosphere.

Filtration
Next, the water is filtered to remove microscopic particles.

Rinconada and Penitencia Water Treatment Plants both use filters with anthracite coal and sand. Santa Teresa Water Treatment Plant uses filters with granular activated carbon and sand.  One of the advantages of granular activated carbon (GAC) is that aside from trapping tiny particles, it also removes chemical compounds that affect the water’s taste and odor.

 As the water seeps down the layers of sand and coal, tiny particles as small as one micron are removed from the water.

These filters are periodically washed to remove the microscopic particles adsorbed onto the filter media during normal operation. This involves taking the filter offline, draining, air scouring, and backwashing the filters. The wash uses air to agitate the filter beds and scour the trapped particles into the water and uses water to flush out the particles. After the filter has been cleaned, it is then refilled with water and put back on-line.

The backwash water flows into the recovery ponds where the solids in the washwater settle out and the water is pumped back to the beginning of the process to be treated again. At the Santa Teresa plant, the waste backwash water enters a mini-treatment plant to pre-clean it before it is pumped back to the starting point again. This will further reduce the possibility of parasites like giardia and cryptosporidium cycling back to the main treatment process.

 At the Rinconada plant, the waste backwash water is conveyed to the Washwater Recovery Facility for settling and decanting, with clarified washwater returned to the raw water inlet pipe. At the Penitencia plant, washwater is decanted in recovery ponds prior to returning to the main treatment process. A more robust facility for clarifying the washwater is currently in design and will be constructed in the future.

Final disinfection
The filtered water goes through one last step, secondary disinfection, to provide continuous disinfection when it is delivered to water users. Our treatment plants use chlorine and chloramine to kill any bacteria or viruses that may be present in the pipes from our plant to your tap. Chloramine is a combined chlorine and ammonia compound used to disinfect potable water.

Chlorine was first successfully used as a disinfectant for water in . Chlorine disinfection has just about eliminated water-borne diseases such as cholera and typhoid in the United States.  Advancements in water treatment science have reached a point where the detection and control of water contaminants have minimized health risks to almost negligible levels.

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What is wastewater, and why treat it?

We consider wastewater treatment as a water use because it is so interconnected with the other uses of water. Much of the water used by homes, industries, and businesses must be treated before it is released back to the environment.

If the term "wastewater treatment" is confusing to you, you might think of it as "sewage treatment." Nature has an amazing ability to cope with small amounts of water wastes and pollution, but it would be overwhelmed if we didn't treat the billions of gallons of wastewater and sewage produced every day before releasing it back to the environment. Treatment plants reduce pollutants in wastewater to a level nature can handle.

Wastewater also includes storm runoff. Although some people assume that the rain that runs down the street during a storm is fairly clean, it isn't. Harmful substances that wash off roads, parking lots, and rooftops can harm our rivers and lakes.

If you are looking for more details, kindly visit Water Treatmeant pipe.

Why Treat Wastewater?

It's a matter of caring for our environment and for our own health. There are a lot of good reasons why keeping our water clean is an important priority:

FISHERIES: Clean water is critical to plants and animals that live in water. This is important to the fishing industry, sport fishing enthusiasts, and future generations.

WILDLIFE HABITATS: Our rivers and ocean waters teem with life that depends on shoreline, beaches and marshes. They are critical habitats for hundreds of species of fish and other aquatic life. Migratory water birds use the areas for resting and feeding.

RECREATION AND QUALITY OF LIFE: Water is a great playground  for us all. The scenic and recreational values of our waters are reasons many people choose to live where they do. Visitors are drawn to water activities such as swimming, fishing, boating and picnicking.

HEALTH CONCERNS: If it is not properly cleaned, water can carry disease. Since we live, work and play so close to water, harmful bacteria have to be removed to make water safe.

Effects of wastewater pollutants

If wastewater is not properly treated, then the environment and human health can be negatively impacted. These impacts can include harm to fish and wildlife populations, oxygen depletion, beach closures and other restrictions on recreational water use, restrictions on fish and shellfish harvesting and contamination of drinking water. Environment Canada provides some examples of pollutants that can be found in wastewater and the potentially harmful effects these substances can have on ecosystems and human health:

• Decaying organic matter and debris can use up the dissolved oxygen in a lake so fish and other aquatic biota cannot survive;
• Excessive nutrients, such as phosphorus and nitrogen (including ammonia), can cause eutrophication, or over-fertilization of receiving waters, which can be toxic to aquatic organisms, promote excessive plant growth, reduce available oxygen, harm spawning grounds, alter habitat and lead to a decline in certain species;
• Chlorine compounds and inorganic chloramines can be toxic to aquatic invertebrates, algae and fish;
• Bacteria, viruses and disease-causing pathogens can pollute beaches and contaminate shellfish populations, leading to restrictions on human recreation, drinking water consumption and shellfish consumption;
• Metals, such as mercury, lead, cadmium, chromium and arsenic can have acute and chronic toxic effects on species.
• Other substances such as some pharmaceutical and personal care products, primarily entering the environment in wastewater effluents, may also pose threats to human health, aquatic life and wildlife.

Wastewater treatment

The major aim of wastewater treatment is to remove as much of the suspended solids as possible before the remaining water, called effluent, is discharged back to the environment. As solid material decays, it uses up oxygen, which is needed by the plants and animals living in the water.

"Primary treatment" removes about 60 percent of suspended solids from wastewater. This treatment also involves aerating (stirring up) the wastewater, to put oxygen back in. Secondary treatment removes more than 90 percent of suspended solids.

Learn more about the wastewater treatment process and the uses of reclaimed wastewater.

•  Water Science School HOME  •  Water Quality topics  •  Water Use topics  •

What is wastewater, and why treat it?

We consider wastewater treatment as a water use because it is so interconnected with the other uses of water. Much of the water used by homes, industries, and businesses must be treated before it is released back to the environment.

If the term "wastewater treatment" is confusing to you, you might think of it as "sewage treatment." Nature has an amazing ability to cope with small amounts of water wastes and pollution, but it would be overwhelmed if we didn't treat the billions of gallons of wastewater and sewage produced every day before releasing it back to the environment. Treatment plants reduce pollutants in wastewater to a level nature can handle.

Wastewater also includes storm runoff. Although some people assume that the rain that runs down the street during a storm is fairly clean, it isn't. Harmful substances that wash off roads, parking lots, and rooftops can harm our rivers and lakes.

Why Treat Wastewater?

It's a matter of caring for our environment and for our own health. There are a lot of good reasons why keeping our water clean is an important priority:

FISHERIES: Clean water is critical to plants and animals that live in water. This is important to the fishing industry, sport fishing enthusiasts, and future generations.

WILDLIFE HABITATS: Our rivers and ocean waters teem with life that depends on shoreline, beaches and marshes. They are critical habitats for hundreds of species of fish and other aquatic life. Migratory water birds use the areas for resting and feeding.

RECREATION AND QUALITY OF LIFE: Water is a great playground  for us all. The scenic and recreational values of our waters are reasons many people choose to live where they do. Visitors are drawn to water activities such as swimming, fishing, boating and picnicking.

HEALTH CONCERNS: If it is not properly cleaned, water can carry disease. Since we live, work and play so close to water, harmful bacteria have to be removed to make water safe.

Effects of wastewater pollutants

If wastewater is not properly treated, then the environment and human health can be negatively impacted. These impacts can include harm to fish and wildlife populations, oxygen depletion, beach closures and other restrictions on recreational water use, restrictions on fish and shellfish harvesting and contamination of drinking water. Environment Canada provides some examples of pollutants that can be found in wastewater and the potentially harmful effects these substances can have on ecosystems and human health:

• Decaying organic matter and debris can use up the dissolved oxygen in a lake so fish and other aquatic biota cannot survive;
• Excessive nutrients, such as phosphorus and nitrogen (including ammonia), can cause eutrophication, or over-fertilization of receiving waters, which can be toxic to aquatic organisms, promote excessive plant growth, reduce available oxygen, harm spawning grounds, alter habitat and lead to a decline in certain species;
• Chlorine compounds and inorganic chloramines can be toxic to aquatic invertebrates, algae and fish;
• Bacteria, viruses and disease-causing pathogens can pollute beaches and contaminate shellfish populations, leading to restrictions on human recreation, drinking water consumption and shellfish consumption;
• Metals, such as mercury, lead, cadmium, chromium and arsenic can have acute and chronic toxic effects on species.
• Other substances such as some pharmaceutical and personal care products, primarily entering the environment in wastewater effluents, may also pose threats to human health, aquatic life and wildlife.

Wastewater treatment

The major aim of wastewater treatment is to remove as much of the suspended solids as possible before the remaining water, called effluent, is discharged back to the environment. As solid material decays, it uses up oxygen, which is needed by the plants and animals living in the water.

"Primary treatment" removes about 60 percent of suspended solids from wastewater. This treatment also involves aerating (stirring up) the wastewater, to put oxygen back in. Secondary treatment removes more than 90 percent of suspended solids.

Learn more about the wastewater treatment process and the uses of reclaimed wastewater.

For more Comprehensive Sewerage Systemsinformation, please contact us. We will provide professional answers.