How Wastewater Treatment Actually Works: From Sewage to Safe Discharge

Every day, millions of cubic meters of wastewater flow into treatment plants worldwide. What happens between the moment it enters and the moment clean water is discharged?

Most people see wastewater treatment as a mystery — dirty water goes in, clean water comes out. But behind this transformation is a carefully orchestrated sequence of physical, biological, and chemical processes.

Understanding this process is critical if you are designing, upgrading, or operating a wastewater treatment facility. Each stage has specific challenges, equipment requirements, and failure points that can derail the entire system.

This article walks through the complete wastewater treatment journey — from inlet screening to final discharge — explaining what happens at each stage, why it matters, and what equipment makes it work.

Stage 1: Preliminary Treatment — Removing the Big Stuff

The Challenge

Raw wastewater contains everything that goes down drains and toilets: plastic wrappers, rags, branches, stones, grease, sand, and organic solids. If these materials reach pumps or biological treatment systems, they cause blockages, wear, and process failures.

What Happens Here

Coarse Screening (10-40 mm openings)

The first barrier. Bar screens or coarse mechanical screens remove large debris:

Plastic bottles and bags
Rags and textiles
Sticks and branches
Other gross solids

Fine Screening (1-6 mm openings)

Captures smaller materials that pass through coarse screens:

Hair and fibers
Small plastics
Food particles
Cigarette butts

Grit Removal

Separates heavy inorganic particles (sand, gravel, glass) that would otherwise:

Abrade pump impellers and pipelines
Accumulate in tanks, reducing effective volume
Interfere with biological treatment

Grit chambers use gravity settling or vortex separation to remove these materials while keeping organic solids in suspension.

Grease and Oil Separation

For industrial or food service wastewater, grease traps or dissolved air flotation (DAF) systems remove fats, oils, and greases (FOG) that would:

Clog pipes and pumps
Coat biological treatment tanks
Inhibit oxygen transfer in aeration systems

Key Equipment

Bar screens and mechanical screens (step screens, drum screens)
Grit chambers (aerated or vortex type)
Grease separators and DAF systems
Screenings compactors and grit classifiers (for handling removed solids)

Why This Stage Matters

Preliminary treatment protects downstream equipment and processes. Plants that skimp here spend far more on pump repairs, tank cleaning, and process disruptions.

At G-LINK, we help clients select screening and grit removal systems matched to their influent characteristics — whether municipal wastewater with high grit loads or industrial streams with challenging FOG content.

Stage 2: Primary Treatment — Settling Out Suspended Solids

The Challenge

After removing large debris and grit, wastewater still contains:

Suspended organic solids
Colloidal particles
Some dissolved organic matter

Primary treatment removes 50-70% of suspended solids and 25-40% of BOD through physical settling.

What Happens Here

Primary Clarifiers (Sedimentation Tanks)

Wastewater flows slowly through large tanks (typically 2-4 hours retention time). Heavier solids settle to the bottom as primary sludge, while lighter materials (grease, oils) float to the surface as scum.

Bottom scraper mechanisms collect settled sludge and pump it to sludge treatment
Surface skimmers remove floating scum
Clarified water overflows to secondary (biological) treatment

Chemical Enhancement (Optional)

Some plants add coagulants (ferric chloride, alum, or polymers) to improve settling:

Destabilizes fine particles
Forms larger, faster-settling flocs
Can boost solids removal to 70-80%

Chemically enhanced primary treatment (CEPT) is common in plants with capacity constraints or high influent loads.

Key Equipment

Primary clarifiers (circular or rectangular)
Sludge scrapers and collection mechanisms
Scum removal systems
Chemical dosing systems (if using CEPT)

Why This Stage Matters

Primary treatment reduces the organic load on biological treatment by 30-40%. This means:

Smaller aeration tanks
Lower energy costs
Less excess sludge production

Plants without primary treatment must over-size biological systems, increasing both CAPEX and OPEX.

At G-LINK, we evaluate whether primary clarifiers make sense for your project or if direct-to-biological treatment (with enhanced screening) is more cost-effective.

Stage 3: Secondary (Biological) Treatment — Where Microbes Do the Heavy Lifting

The Challenge

Primary treatment removes solids you can see. But wastewater still contains dissolved organic pollutants — proteins, carbohydrates, fats — measured as BOD (Biochemical Oxygen Demand) and COD (Chemical Oxygen Demand).

These pollutants must be removed before discharge, and the most efficient way is biological treatment: using microorganisms to consume organic matter.

What Happens Here

Activated Sludge Process (Most Common)

Wastewater enters aeration tanks where it mixes with a high concentration of bacteria and other microorganisms (the “activated sludge”).

Step 1: Aeration

Air or oxygen is supplied through blowers and diffusers
Microorganisms consume dissolved organics as food
BOD/COD is converted to biomass (new bacteria) + CO₂ + water

Step 2: Secondary Clarification

Mixed liquor flows to secondary clarifiers
Microorganisms settle to the bottom as “sludge”
Return Activated Sludge (RAS) is pumped back to aeration tanks to maintain biomass concentration
Excess sludge (WAS) is removed to sludge treatment
Clarified effluent proceeds to tertiary treatment or discharge

Typical Performance:

BOD removal: 85-95%
TSS removal: 85-95%
Effluent BOD: 10-30 mg/L (without tertiary treatment)

Nutrient Removal: Nitrogen and Phosphorus

Many discharge permits require nutrient removal to prevent eutrophication in receiving waters.

Nitrogen Removal (Nitrification-Denitrification)

Nitrification (aerobic):

Ammonia (NH₃) is oxidized to nitrate (NO₃⁻)
Requires oxygen and longer sludge retention time

Denitrification (anoxic):

Nitrate is converted to nitrogen gas (N₂)
Requires an oxygen-free zone with carbon source
Nitrogen gas escapes to atmosphere

Phosphorus Removal

Biological: Enhanced Biological Phosphorus Removal (EBPR)

Specific bacteria accumulate phosphorus in their cells
Removed with excess sludge

Chemical: Precipitation with metal salts

Ferric chloride, alum, or lime added to precipitate phosphorus
Forms insoluble compounds that settle out

Alternative Biological Treatment Technologies

Membrane Bioreactor (MBR)

Replaces secondary clarifiers with membrane filtration
Produces ultra-clear effluent (<1 mg/L TSS)
Ideal for tight discharge limits or water reuse

Moving Bed Biofilm Reactor (MBBR)

Microorganisms grow on plastic carrier media suspended in the tank
More compact than conventional activated sludge
Good for upgrading existing plants

Sequencing Batch Reactor (SBR)

All processes (aeration, settling, decanting) occur in a single tank in timed sequences
Flexible operation, good for variable flows

Key Equipment

Aeration tanks and reactors
Blowers and air diffusers
Secondary clarifiers
RAS and WAS pumps
DO (dissolved oxygen) monitoring and control systems

Why This Stage Matters

Biological treatment is the heart of any wastewater plant. If it fails, nothing else works. Common failure modes:

Bulking sludge (poor settling due to filamentous bacteria)
Foaming (excessive surfactants or grease)
Nitrification failure (insufficient aeration or temperature drops)
Toxicity events (industrial discharge shocks)

Proper design, operation, and monitoring are critical.

At G-LINK, we help clients select the right biological treatment technology — conventional activated sludge, MBR, MBBR, or SBR — based on discharge limits, footprint constraints, and operational capabilities. We also support optimization of existing systems struggling with performance issues.

Stage 4: Tertiary Treatment — Polishing for Strict Discharge or Reuse

The Challenge

Secondary treatment typically produces effluent with:

BOD: 10-30 mg/L
TSS: 10-30 mg/L
Nutrients: Variable (depending on removal systems)

For many applications, this is acceptable. But strict discharge permits or water reuse requirements demand further treatment.

What Happens Here

Filtration

Removes residual suspended solids:

Sand filters (gravity or pressure)
Cloth disk filters
Membrane filtration (microfiltration or ultrafiltration)

Typical effluent after filtration: <5 mg/L TSS

Disinfection

Kills pathogenic bacteria and viruses before discharge or reuse:

Chlorination:

Sodium hypochlorite or chlorine gas added
Effective and low-cost
Requires dechlorination before discharge (to avoid harming aquatic life)

UV Disinfection:

Ultraviolet light damages microbial DNA
No chemical residual
Requires clear water (turbidity <5 NTU) for effectiveness

Ozonation (less common):

Powerful oxidant that kills pathogens and breaks down micropollutants
Expensive, used mainly for high-value reuse applications

Advanced Nutrient Polishing

If biological nutrient removal is insufficient:

Chemical phosphorus removal (adding metal salts)
Ion exchange for ammonia removal
Denitrification filters (biological filters using carbon source)

Advanced Oxidation (For Reuse or Micropollutant Removal)

Ozone + UV or hydrogen peroxide: Breaks down pharmaceuticals, pesticides, endocrine disruptors
Used in indirect potable reuse or sensitive discharge locations

Key Equipment

Sand filters, disk filters, or membrane systems
UV reactors or chlorination systems
Dechlorination systems (if using chlorine)
Advanced oxidation units (for reuse applications)

Why This Stage Matters

Tertiary treatment is often the difference between meeting discharge limits and facing fines or shutdowns.

Water reuse applications (irrigation, industrial cooling, indirect potable reuse) require tertiary treatment to ensure safety and public acceptance.

At G-LINK, we help clients design fit-for-purpose tertiary treatment — not over-engineering for unnecessary quality, but ensuring compliance and reliability.

Stage 5: Sludge Treatment — Handling the Byproduct

The Challenge

Wastewater treatment does not make pollutants disappear — it concentrates them into sludge (also called biosolids).

Where sludge comes from:

Primary sludge: Settled solids from primary clarifiers (~3-6% solids)
Secondary sludge (WAS): Excess biomass from biological treatment (~0.5-1.5% solids)

A typical plant processing 10,000 m³/day of wastewater produces 15-25 tonnes of dry solids daily.

Sludge handling costs often represent 30-50% of total plant operating costs.

What Happens Here

Thickening

Concentrating dilute sludge to reduce volume:

Gravity thickeners (for primary sludge)
Dissolved air flotation (DAF) (for WAS)
Centrifuges or belt thickeners

Typical output: 4-8% solids

Stabilization

Reducing pathogens and odor potential:

Anaerobic Digestion:

Sludge is heated to 35-55°C in sealed tanks
Bacteria break down organics without oxygen
Produces biogas (60-70% methane) that can generate heat or electricity
Reduces sludge volume by 40-60%
Typical retention: 15-30 days

Aerobic Digestion:

Sludge is aerated to allow bacteria to consume organics
Simpler than anaerobic, but no biogas production
Higher energy cost

Chemical Stabilization (Lime):

Lime added to raise pH >12, killing pathogens
Used when digestion is not feasible

Dewatering

Removing water to produce a solid cake suitable for disposal:

Belt presses (older technology, higher polymer use)
Centrifuges (high capacity, high energy)
Screw presses (low energy, low polymer, increasingly popular)
Filter presses (batch operation, very dry cake)

Typical cake solids:

Belt press: 18-25%
Centrifuge: 20-30%
Screw press: 15-22%
Filter press: 30-40%

Disposal or Beneficial Use

Final destination for treated sludge:

Landfill disposal (simplest, but increasingly expensive and regulated)
Land application (biosolids used as fertilizer, requires pathogen/metal limits compliance)
Incineration (volume reduction, energy recovery, but high CAPEX)
Composting (produces marketable soil amendment)

Key Equipment

Thickeners (gravity, DAF, centrifuge)
Anaerobic or aerobic digesters
Dewatering equipment (screw press, centrifuge, belt press, filter press)
Biogas handling systems (storage, flares, CHP units)
Polymer dosing systems (for dewatering)

Why This Stage Matters

Poor sludge handling leads to:

High disposal costs
Odor complaints
Regulatory violations
Lost energy recovery opportunities

Well-designed sludge treatment can turn a cost center into an energy producer (via biogas) or revenue generator (via compost sales).

At G-LINK, we provide complete sludge management solutions — from thickening and digestion to dewatering and disposal. We help clients model lifecycle costs and identify opportunities for energy recovery or beneficial reuse.

How It All Fits Together: The Integrated Treatment System

Wastewater treatment is not a collection of standalone equipment — it is an integrated system where each stage affects the others.

Upstream decisions impact downstream performance:

Poor screening → pump failures and biological treatment upsets
Undersized primary clarifiers → overloaded aeration systems and high energy costs
Inadequate nutrient removal → discharge violations
Poor sludge thickening → oversized dewatering equipment and high polymer costs

Successful plants are designed holistically:

Process steps are sized to work together, not independently
Equipment selections consider operational complexity and local support
Automation and monitoring provide early warning of problems
Operators are trained on the entire process, not just individual units

How G-LINK Supports Complete Wastewater Treatment Projects

We do not sell individual pieces of equipment. We help you design, source, and implement complete treatment systems that work reliably over 15-20 years.

Our Approach:

1. Process Design and Optimization

We start by understanding your full picture:

What is your influent flow and characteristics?
What are your discharge limits or reuse requirements?
What is your site footprint and civil construction budget?
What is your team’s operational experience and capabilities?

Based on this, we recommend a treatment train that balances performance, cost, and operational simplicity.

2. Equipment Selection Across Multiple Stages

Instead of sourcing screens from one supplier, clarifiers from another, and biological systems from a third, we coordinate the entire procurement:

Preliminary treatment: Screens, grit removal, FOG separation
Primary treatment: Clarifiers, chemical dosing (if needed)
Biological treatment: Aeration systems, clarifiers, or MBR membranes
Tertiary treatment: Filters, UV or chlorination systems
Sludge handling: Thickeners, digesters, dewatering equipment

All components are sized to work together, with matched flow rates, hydraulic profiles, and control integration.

3. Supplier Vetting and Quality Assurance

We compare offerings from multiple Chinese manufacturers:

Technical design and materials quality
Manufacturing capabilities and track record
Local service and spare parts availability
Lifecycle costs (not just equipment prices)

We coordinate factory inspections and pre-shipment testing to ensure equipment meets specifications.

4. System Integration and Installation Support

Wastewater treatment equipment must integrate with civil structures, electrical systems, and control architecture.

We ensure:

Equipment dimensions and connections match civil drawings
Electrical specifications are compatible with site power
Control systems can integrate with your SCADA or PLC platform
Installation manuals and as-built drawings are provided

5. Commissioning and Performance Verification

Startup is where design meets reality. We provide:

Technical guidance on startup sequences and optimization
Remote support for troubleshooting early-stage issues
Coordination with suppliers for warranty support if needed

6. Long-Term Technical Support

Once your plant is running:

Spare parts sourcing and supply chain management
Troubleshooting assistance for process or equipment issues
Recommendations for capacity expansion or technology upgrades

The goal: You get a complete, reliable treatment system — not a collection of equipment from different vendors pointing fingers when something does not work.

Final Thoughts

Wastewater treatment is a complex, multi-stage process. Success requires understanding how each stage works, how they interact, and what equipment delivers reliable performance over decades.

The plants that operate smoothly and cost-effectively are not necessarily the ones with the most advanced technology. They are the ones where:

Process design is matched to actual site conditions and influent characteristics
Equipment is selected for lifecycle reliability, not lowest price
All components are properly integrated and commissioned
Operators understand the system and can respond to upsets

If you are planning a new wastewater treatment plant, upgrading an existing facility, or struggling with performance issues, the most important step is ensuring your treatment train is designed as a complete system — not a collection of individual pieces.

Planning a wastewater treatment project or need help with an existing system? Contact us to discuss your requirements, or explore our complete wastewater treatment solutions.

Related resources:

Wastewater Treatment Plant Design: What to Specify and What to Avoid (coming soon)
Common Wastewater Treatment Failures and How to Prevent Them (coming soon)
Sludge Management Economics: From Cost Center to Value Generator (coming soon)