ENGINEERING – ENVIRONMENTAL & WATEWATER ENGINEERING CALCULATOR
Do Deficit Stream
A precise tool.
What is the Do Deficit Stream & How does it work?
The StreeterβPhelps model describes how biochemical oxygen demand (BOD) and reaeration interact to create a dissolvedβoxygen (DO) deficit downstream of a pollutant source. As organic matter decays, it consumes oxygen at a rate governed by the deβoxygenation constant (k_1), while atmospheric reaeration restores oxygen at a rate governed by (k_2). The balance of these two processes determines the shape of the DO sag curve.
Mathematically, the deficit (D(x)) at a downstream distance (x) (or travel time (t)) is expressed by the StreeterβPhelps equation. The equation combines an exponential decay of the remaining BOD with an exponential recovery of DO due to reaeration, and it is referenced to the saturation concentration (D_{sat}) of oxygen in the water.
Engineers use this model to predict the critical point where the DO deficit is greatest, to size treatment facilities, and to assess compliance with waterβquality standards. By inputting siteβspecific parametersβupstream DO, ultimate BOD, rate constants, flow velocity, and depthβone can estimate the magnitude and location of the oxygenβdeficit peak.
D(x) = frac{k_1 L_0}{k_2 – k_1}left(e^{-k_1 t} – e^{-k_2 t}right) + (D_0 – D_{sat}) e^{-k_2 t}
D(x) = dissolvedβoxygen deficit at distance x (mg/L)
L_0 = ultimate BOD concentration (mg/L)
k_1 = deβoxygenation rate constant (1/d)
k_2 = reaeration rate constant (1/d)
D_0 = upstream dissolvedβoxygen concentration (mg/L)
D_{sat} = saturation DO (mg/L)
t = travel time = x / U (days)
L_0 = ultimate BOD concentration (mg/L)
k_1 = deβoxygenation rate constant (1/d)
k_2 = reaeration rate constant (1/d)
D_0 = upstream dissolvedβoxygen concentration (mg/L)
D_{sat} = saturation DO (mg/L)
t = travel time = x / U (days)
Parameters
Result
β
Frequently Asked Questions
What is the Streeter-Phelps model used for?
The Streeter-Phelps model is used to predict the dissolved oxygen (DO) levels in water bodies downstream of a pollutant source, considering both deoxygenation and reaeration processes.
How do I calculate the DO deficit using this model?
To calculate the DO deficit, input the initial BOD, deoxygenation constant (k1), reaeration constant (k2), and downstream distance into the calculator. The model will then compute the DO deficit at that point.
What do k1 and k2 represent in the Streeter-Phelps model?
k1 represents the deoxygenation rate constant, which is how quickly organic matter consumes oxygen. k2 represents the reaeration rate constant, which is how quickly atmospheric oxygen replenishes the water.
How does atmospheric reaeration affect the DO levels?
Atmospheric reaeration increases the dissolved oxygen levels in the water by transferring oxygen from the air into the water, helping to mitigate the effects of deoxygenation caused by pollutants.
What is a DO sag curve?
A DO sag curve is a graphical representation of how dissolved oxygen levels decrease downstream of a pollutant source and then gradually increase as reaeration occurs. The shape of this curve depends on the balance between deoxygenation and reaeration.
Can this model be used for any water body?
While the Streeter-Phelps model is widely applicable, its accuracy can vary depending on local conditions such as temperature, flow rate, and specific pollutant characteristics. It works best in well-mixed, flowing waters.
What are some practical applications of this calculator?
This calculator can be used by environmental engineers, water treatment plant operators, and researchers to assess the impact of pollutants on downstream water quality and to design effective reaeration systems.
Results are for informational purposes only and do not constitute professional advice.