Wastewater Treatment Plant

At Peacehaven Treatment plant near Brighton, new technologies are used to create a sustainable system of recycling wastewater.

This story was created for the Google Expeditions project by Twig World, now available on Google Arts & Culture

Faucet (1902)Museu de les Aigües

The process of cleaning our wastewater ensures that we have a fresh supply of safe water in the future, and minimises our impact on the environment by decontaminating our waste and turning it into a valuable resource.

Tap to explore

First Stop: Sewer

After we use water, we rarely consider its onward journey. 

Tap to explore

Well Connected

Almost all homes and business are connected to a grid of sewers to collect household wastewater. Storm drains on streets are also connected to this network. These run beneath our feet for hundreds of miles.

Tap to explore

Different Sources

Pipes that come from domestic houses contain all types of water waste, from toilets and sinks to washing machines and bathwater. Industrial sources might contain organic waste or chemicals from factories.

Tap to explore

Ancient Pipes

These Victorian sewers are 150 years old and are built from red brick, by hand. Before the widespread building of sewers in the 1800s, waste overflowed in streets. This led to diseases like cholera becoming rampant, causing many deaths. 

Tap to explore

Inflow

This wastewater treatment plant is able to serve 270,000 homes and is fed by many pipes from neighbouring towns and villages. After the branches of the different sources connect, the waste is pumped along a pipe up to 2.4m in diameter – large enough for a horse to walk through.

Tap to explore

Raising the Water Level

Once the water reaches the plant, it must be raised to the same level as the processing equipment. This means that the water is raised a total distance of 22m to the treatment area from the tunnel below.

Tap to explore

Working With Water

This is Richie. He is one of 5 staff members at the plant. Staff take it in turns to be on call at night – this means they have to react if an alarm is triggered in the plant.

Tap to explore

Water Source

At full capacity, the plant can process 3 tonnes of wastewater. It needs to be able to adapt to large volumes of waste quickly, as sewers can be in danger of overflowing during a heavy storm.

Tap to explore

Screening Process

The raw waste first goes through a filtration system, where it enters a chamber of screens. Here, 6mm holes separate larger particles – usually stray bits of plastic or other material that should never have ended up in the waste.

Tap to explore

The water then flows to the fat, oil grit and grease channels (FOGG), where air is injected into the liquid mix. This air forces the grease to the top of the mixture, and grit to the bottom. Here, grit is being collected, and will later be disposed of.

Tap to explore

Onward Journey

After the grit and grease is removed, the wastewater can move on to the next stage of decontamination. The grease and oil is converted into a biogas, which is then used as a fuel source.

Tap to explore

Grit Separation

Motors pump small particles of grit through these red pipes. Grit and grease are common byproducts of this process. Grit can come from rocks and sand that gets washed down drains, and grease can come from fast food restaurants.

Tap to explore

Safety Checks

Staff members have to carry out regular checks on their equipment. If the machines have a fault, it could trigger an alarm that stops the plant from working and cause a backlog of waste.

Tap to explore

Sludge Conversion

Sludge is the solid product that is removed at each stage of the treatment process. Chemicals are added to force large sludge particles to bind together so they can be removed easily.

Tap to explore

These larger particles are fed into anaerobic digesters – tanks where microbes feed on the bacteria present in sludge – and produce biogas, which can be used as a fuel source.

Tap to explore

Safety Wear

Safety precautions must be taken when working in an environment where bacteria might be present. If a machine is broken and needs internal repairs, staff must ensure their skin is covered before reaching into sludge tanks.

Tap to explore

Filtering Sludge

These paddles keep the sludge moving around a belt in this tank. This helps the larger particles bind together to be digested. After the biogas has been produced, the remaining sludge can be reused as farm fertiliser.

Tap to explore

The Right Consistency

Ferric chloride is added to bind the particles together, which then form flocs. Flocs are clumps of small particles, which in this case help to allow the larger particles to be removed from the mixture.

Tap to explore

Updating Results

In this laboratory space, staff must regularly take samples of sludge to ensure it is the correct consistency for being fed to the digester unit. This involves an in-depth knowledge of the science behind wastewater treatment.

Tap to explore

Richie has checked a sample from the sludge tank and is awaiting the result.

Tap to explore

Sample

Each of these bottles has a different sample taken from the sludge. This one is too watery and the one on the left is too lumpy – sludge that is ready to be digested will be somewhere in the middle.

Tap to explore

Testing Equipment

This machine tests the amount of moisture present in the sludge samples. If they are too watery, chemicals can be added to make them bind together to the right consistency.

Tap to explore

Odour Control

This shield funnels the smell from these samples towards a fan and away from the tester. The whole plant traps the air in every stage of the process and chemically scrubs it to neutralise odour.

Tap to explore

Aerated Filters

Lamella filters provide the second-last stage of the process. Hexagonal grids trap any remaining grime before the water flows through to the final treatment area. 

Tap to explore

Filtered through biological aeration filter funnels (BAFFs), wastewater is forced upwards by compressed air through several metres of floating polystyrene beads. Microorganisms that grow on the beads feed on nutrients and oxygen, provided by the wastewater and air. 

Tap to explore

The water is then released from the plant to the outflow tunnel.

Tap to explore

Water Difference

Staff work hard to ensure that water leaving the plant is safe to re-enter the environment. It is easy to see the difference the process has made. The outlet water is now clear of debris and sludge has been removed.

Tap to explore

Polystyrene Beads

Inside this pipe, water is forced upwards through the balls, as in this model. It then exits through a concrete filter, which allows water through, but prevents the balls from escaping into the outflow.

Tap to explore

Out in the Open

The final, safe water product travels 1.4km to the sea, where it joins a 2.5km outflow pipe. This pipe allows the treated water to be mixed with the seawater to begin the water cycle again.

Credits: All media
The story featured may in some cases have been created by an independent third party and may not always represent the views of the institutions, listed below, who have supplied the content.
Explore more

Interested in Science?

Get updates with your personalized Culture Weekly

You are all set!

Your first Culture Weekly will arrive this week.

Home
Discover
Play
Nearby
Favorites