Analyze removal rates, recovery, energy, and chemicals precisely. Built for operators, engineers, and performance reviews. Get dependable insights before optimizing treatment processes and costs.
| Item | Sample Input | Unit | Notes |
|---|---|---|---|
| Design Flow | 6000 | m³/day | Reference capacity for utilization checks. |
| Influent Flow | 5000 | m³/day | Incoming water to the process. |
| Effluent Flow | 4700 | m³/day | Final treated discharge or reuse flow. |
| Operating Hours | 22 | hours/day | Actual daily runtime. |
| Energy Use | 1550 | kWh/day | Total process energy. |
| Chemical Consumption | 68 | kg/day | Total chemical feed used. |
| Turbidity | 120 → 3.5 | NTU | Shows very strong clarification performance. |
| TSS | 210 → 12 | mg/L | Used for removal and mass reduction. |
| BOD | 180 → 18 | mg/L | Indicates organic load reduction. |
| COD | 320 → 42 | mg/L | Measures chemical oxygen demand reduction. |
Removal Efficiency (%) = ((Influent Concentration − Effluent Concentration) ÷ Influent Concentration) × 100
Water Recovery (%) = (Effluent Flow ÷ Influent Flow) × 100
Runtime Utilization (%) = (Operating Hours ÷ 24) × 100
Capacity Utilization (%) = (Influent Flow ÷ Design Flow) × 100
Mass Removed (kg/day) = ((Qin × Cin) − (Qout × Cout)) × 0.001
Energy Intensity (kWh/m³) = Energy Use ÷ Effluent Flow
Chemical Intensity (kg/m³) = Chemical Consumption ÷ Effluent Flow
Average Removal = Mean of turbidity, TSS, BOD, and COD removal efficiencies with available valid values.
It estimates treatment performance using contaminant removal, water recovery, runtime utilization, capacity loading, pollutant mass removed, energy intensity, and chemical intensity.
Using both values shows water recovery and supports better mass removal estimates. This is important when sludge losses, backwash losses, or evaporation change process volume.
Turbidity is an optical quality indicator, not a direct mass concentration. The calculator still computes turbidity removal percentage, but avoids reporting a misleading mass removal value.
That depends on process goals and regulations. Many plants aim for high removal on suspended solids and organics, often above 80% or 90% for strong performance.
Yes. The structure works for both, provided your chosen parameters and interpretation fit the treatment system. Always compare outputs with plant-specific operating and regulatory targets.
Energy intensity shows how much energy is needed per cubic meter treated. Lower values usually indicate better operational efficiency, assuming treatment quality remains acceptable.
The related removal value becomes negative, which signals process deterioration, measurement error, or contamination introduced during treatment. Review sampling points and operating conditions.
Yes. The CSV export works well for spreadsheets, while the PDF export is convenient for quick plant summaries, maintenance reviews, and operator performance documentation.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.