Water Resource Recovery Treatment Process

Providing clean, safe water to drink and use is only one side of the journey for this essential resource. Treating the wastewater that flows out of our homes and businesses is just as important and has one goal: release water to our waterways that is safe for public health and the environment.  

Wastewater comes from many sources including showers, sinks, dishwashers, laundries, toilets, car washes, hospitals, and more. According to the U.S. Environmental Protection Agency (EPA), the average American can produce up to 100 gallons of wastewater each day, or about 1600 glasses of water! 

Over 99.9% of wastewater is water, and the remaining less than 0.1% consists of solids, chemicals, nutrients, fats, and other pollutants. Water Resource Recovery Facilities (WRRF) work continuously 24 hours a day, 365 days a year to remove these pollutants down to the tiniest parts per million and discharge cleaned water back to waterways.

The process begins with the flow down a drain into a network of below ground pipes which are connected and combine the wastewater from other area homes and businesses. Most of these pipe systems operate by flowing “downhill” towards the water resource recovery facility, but sometimes the flows have to be pumped using lift stations.  

Once it arrives at the facility, the wastewater goes through a series of steps that mimics the process occurring naturally in streams and lakes. All water bodies have natural bacteria and other small organisms that feed on and eliminate waste. Water resource recovery facilities use bacteria and other organisms in a similar way to consume waste, but the process occurs much more quickly in a  tightly controlled process that is highly regulated. The typical time it takes to treat a drop of water is less than ten hours.

Preliminary Treatment

The wastewater that first enters the facility is called “influent.” The influent enters at an area called “headworks,” where it passes through large screens. The screens are designed to trap large objects such as sticks, rags, leaves, plastics, sanitary products, rocks, toys, trash and more. Once removed, these larger solids are hauled in covered trucks to the landfill for disposal. After screening, it enters a grit chamber to remove smaller solids such as rocks, sand, gravel, and other materials. Grit chambers are large tanks that slow down the wastewater just long enough for these solids to fall to the bottom. These materials are also collected and sent to the landfill.

Preliminary treatment screens for wastewater

Primary Treatment

The wastewater then flows to sedimentation tanks or primary clarifiers. These tanks hold it for several hours, allowing lighter materials, like fats, oils, and grease, to float to the top, where they can be skimmed off. Other heavier particles and suspended solids sink to the bottom as primary sludge which is collected by large mechanical scrapers and pumped out of the bottom of the tank. 

Both the skimmed material and primary sludge are sent to solids processing for treatment and disposal.  At this point, over 50% of the suspended solids have been removed by these physical processes. Next, the clarified water flows into the secondary treatment which uses biological processes to further clean the water. 

primary clarifier for wastewater treatment

Secondary Treatment

The wastewater that flows into this next phase of treatment still contains some solid materials. If this were a stream or lake, the natural microorganisms present would consume these materials as food. Water resource recovery facilities use the same biological method to remove dissolved and fine organic particles not removed during primary treatment. At this stage, it flows into large aeration tanks where bubbling air provides the microorganisms with an optimal, controlled environment to thrive and consume the organic matter, breaking down the waste materials into carbon dioxide and clean water.  

The final phase of this process involves additional settling called secondary clarification where the solid particles, including the microorganisms, settle and are sent for solids processing or are recycled. Chemicals, such as ferric sulfate, may be added to reduce unwanted nutrients like phosphates by forcing more particles to settle.  

secondary treatment basin for wastewater treatment

Tertiary (Advanced) Treatment

At this point, the water is now mostly clean. The next phase improves the water quality even further. The water is sent through a filtration system, such as sand or a cloth media, to remove the remaining fine particles.  After the water passes through the filter material, it is ready for the final stage before being released back into the environment.

tertiary advanced filtration wastewater treatment

Disinfection

By the time the water reaches this phase it has been screened, clarified, aerated, clarified again and filtered. It is still important to disinfect the water to treat for any remaining bacteria or viruses to protect public health.

The most common form of disinfection is to add a chlorine solution to the water. Another disinfection method used is ultraviolet (UV) light. For UV disinfection, the water is sent through a chamber or series of basins and flows over submerged light bulbs that generate UV light. In both disinfection methods, the water is moved through the process allowing enough time for the either the chlorine solution or UV light to eliminate microorganisms that remain.

Once it has completed the disinfection process, the water is safe to be released back into the environment. Upon leaving a water resource recovery facility, the water is often cleaner than the streams and lakes it flows into.

ultraviolet light disinfection wastewater treatment

Solids Processing

The solids collected from the primary and secondary treatment units are about 100 times more concentrated than when first entering the plant. The final step for managing these remaining solids is to send them through a dewatering process, where gravity and physical barriers further remove excess water using a belt filter press or centrifuge. After additional water has been removed, these concentrated solids are transferred into large containers. The containers are lined with plastic bags which are sealed. The solids are then hauled in covered trucks to a landfill for disposal.



solids-process-truck

Odor Control

At NTMWD, odor control is a primary design and operation consideration for all treatment facilities. There are various odor control technologies available. NTMWD evaluates odor sources and selects the most appropriate technology to ensure odors are contained and treated effectively within the proximity of the plant. Technologies include chemical injection, chemical scrubbers, carbon absorption and biological treatment. 

Sampling and Laboratory Testing

We ensure that the water discharged from our Water Resource Recovery Facilities (WRRF) into rivers, lakes and waterways is safe for human health and the environment, and meets or surpasses all regulatory requirements. The TCEQ permit for each WRRF sets pollution limits and reporting requirements all aimed at preserving water quality. At our WRRF, certified operators continuously perform process monitoring, laboratory, and field sampling of multiple water quality parameters to optimize the process.

Our laboratories and field personnel perform thousands of analyses per year from the time the flow enters the treatment facility until the cleaned water is discharged to the receiving waters.