ASM2d to ADM1 Translator

Introduction

A link is required to translate between biological based and physical or chemical mediated processes to develop plant-wide modeling of wastewater treatment. This model mediates the interaction between the Modified Activated Sludge Model 2d (ASM2d) and the Modified Anaerobic Digester Model 1 (ADM1).

The model relies on the following key assumptions:

  • supports only liquid phase

  • supports only Modified ASM2d to Modified ADM1 translations

Degrees of Freedom

The translator degrees of freedom are the inlet feed state variables:

  • temperature

  • pressure

  • volumetric flowrate

  • solute compositions

Ports

This model provides two ports:

  • inlet

  • outlet

Sets

Description

Symbol

Indices

Time

\(t\)

[0]

Inlet/outlet

\(x\)

[‘in’, ‘out’]

Phases

\(p\)

[‘Liq’]

Inlet Components

\(j_{in}\)

[‘H2O’, ‘S_A’, ‘S_F’, ‘S_I’, ‘S_N2’, ‘S_NH4’, ‘S_NO3’, ‘S_O2’, ‘S_PO4’, ‘S_K’, ‘S_Mg’, ‘S_IC’, ‘X_AUT’, ‘X_H’, ‘X_I’, ‘X_PAO’, ‘X_PHA’, ‘X_PP’, ‘X_S’]

Outlet Components

\(j_{out}\)

[‘H2O’, ‘S_su’, ‘S_aa’, ‘S_fa’, ‘S_va’, ‘S_bu’, ‘S_pro’, ‘S_ac’, ‘S_h2’, ‘S_ch4’, ‘S_IC’, ‘S_IN’, ‘S_IP’, ‘S_I’, ‘X_ch’, ‘X_pr’, ‘X_li’, ‘X_su’, ‘X_aa’, ‘X_fa’, ‘X_c4’, ‘X_pro’, ‘X_ac’, ‘X_h2’, ‘X_I’, ‘X_PHA’, ‘X_PP’, ‘X_PAO’, ‘S_K’, ‘S_Mg’]

Ion

\(j_{in}\)

[‘S_cat’, ‘S_an’] 1

Zero Flow Components

\(z\)

[‘S_fa’, ‘S_h2’, ‘S_ch4’, ‘X_su’, ‘X_aa’, ‘X_fa’, ‘X_c4’, ‘X_pro’, ‘X_ac’, ‘X_h2’]
Notes

1 “Ion” is a subset of “Outlet Components” and uses the same symbol j_in.

Parameters

Description

Symbol

Parameter Name

Value

Units

Soluble inerts from composites

\(f_{sI, xc}\)

f_sI_xc

1e-9

\(\text{dimensionless}\)

Particulate inerts from composites

\(f_{xI, xc}\)

f_xI_xc

0.1

\(\text{dimensionless}\)

Carbohydrates from composites

\(f_{ch, xc}\)

f_ch_xc

0.275

\(\text{dimensionless}\)

Proteins from composites

\(f_{pr, xc}\)

f_pr_xc

0.275

\(\text{dimensionless}\)

Lipids from composites

\(f_{li, xc}\)

f_li_xc

0.35

\(\text{dimensionless}\)

Valerate from polyhydroxyalkanoates

\(f_{XPHA, Sva}\)

f_XPHA_Sva

0.1

\(\text{dimensionless}\)

Butyrate from polyhydroxyalkanoates

\(f_{XPHA, Sbu}\)

f_XPHA_Sbu

0.1

\(\text{dimensionless}\)

Propionate from polyhydroxyalkanoates

\(f_{XPHA, Spro}\)

f_XPHA_Spro

0.4

\(\text{dimensionless}\)

Acetate from polyhydroxyalkanoates

\(f_{XPHA, Sac}\)

f_XPHA_Sac

0.4

\(\text{dimensionless}\)

Carbon content of polyhydroxyalkanoates

\(C_{PHA}\)

C_PHA

0.025

\(\text{dimensionless}\)

Equations and Relationships

Description

Equation

Volumetric flow equality

\(F_{out} = F_{in}\)

Temperature balance

\(T_{out} = T_{in}\)

Pressure balance

\(P_{out} = P_{in}\)

Zero-flow component conversions

\(C_{z, out} = 0\)

Anions balance

\(S_{an} = \frac{S_{IN, out}}{14}\)

Cations balance

\(S_{cat} = \frac{S_{IC, out}}{12}\)

COD demanding compounds in S_O2

\(COD_{SO2} = S_{O2, in} / \frac{1 - Y_{H}}{Y_{H}}\)

S_O2 concentration

\(S_{O2, 1} = S_{O2, in} - \frac{1 - Y_{H}}{Y_{H}} * COD_{SO2}\)

S_A concentration

\(S_{A, 1} = S_{A, in} - \frac{COD_{SO2}}{Y_{H}}\)

S_NH4 concentration

\(S_{NH4, 1} = S_{NH4, in} - (i_{NBM} * COD_{SO2})\)

S_PO4 concentration

\(S_{PO4, 1} = S_{PO4, in} - (i_{PBM} * COD_{SO2})\)

S_IC concentration

\(S_{IC, 1} = S_{IC, in} + \frac{COD_{SO2} * i_{CSA}}{Y_{H}} + (COD_{SO2} * i_{CXB})\)

X_H concentration

\(X_{H, 1} = X_{H, in} + COD_{SO2}\)

COD demanding compounds in S_NO3

\(COD_{SNO3} = S_{NO3, in} / \frac{1 - Y_{H}}{i_{NOx, N2} * Y_{H}}\)

S_A concentration

\(S_{A, 2} = S_{A, 1} - \frac{COD_{SNO3}}{Y_{H}}\)

S_NH4 concentration

\(S_{NH4, 2} = S_{NH4, 1} - (COD_{SNO3} * i_{NBM})\)

S_N2 concentration

\(S_{N2, 2} = S_{N2, in} + \frac{1 - Y_{H}}{i_{NOx, N2} * Y_{H}} * COD_{SNO3}\)

S_NO3 concentration

\(S_{NO3, 2} = S_{NO3, in} - \frac{1 - Y_{H}}{i_{NOx, N2} * Y_{H}} * COD_{SNO3}\)

S_PO4 concentration

\(S_{PO4, 2} = S_{PO4, 1} - (COD_{SNO3} * i_{PBM})\)

S_IC concentration

\(S_{IC, 2} = S_{IC, 1} + \frac{COD_{SNO3} * i_{CSA}}{Y_{H}} + (COD_{SNO3} * i_{CXB})\)

X_H concentration

\(X_{H, 2} = X_{H, 1} + COD_{SNO3}\)

Nitrogen demand for soluble inerts

\(S_{ND} = S_{F, in} * i_{NSF}\)

Phosphorus demand for soluble inerts

\(S_{PD} = S_{F, in} * i_{PSF}\)

Organic nitrogen from soluble inerts

\(SN_{org} = \frac{S_{ND}}{Ni[S_{aa}] * 14}\)

Monosaccharides mapping (if \(SN_{org} >= S_{F, in}\))

\(S_{su} = in\)

Monosaccharides mapping (if \(SN_{org} < S_{F, in}\))

\(S_{su} = \frac{S_{F, in} - SN_{org}}{1000}\)

Amino acids mapping (if \(SN_{org} >= S_{F, in}\))

\(S_{aa} = \frac{S_{F, in}}{1000}\)

Amino acids mapping (if \(SN_{org} < S_{F, in}\))

\(S_{aa} = \frac{SN_{org}}{1000}\)

S_F concentration

\(S_{F, 3} = S_{F, in} - (S_{su} * 1000) - (S_{aa} * 1000)\)

S_NH4 concentration

\(S_{NH4, 3} = S_{NH4, 2} + (S_{F, in} * i_{NSF}) - (S_{aa} * Ni[S_{aa}] * 1000 * 14)\)

S_PO4 concentration

\(S_{PO4, 3} = S_{PO4, 2} + (S_{F, in} * i_{PSF})\)

S_IC concentration

\(S_{IC, 3} = S_{IC, 2} + (S_{F, in} * i_{CSF}) - (S_{su} * Ci[S_{su}] * 1000 * 12) - (S_{aa} * Ci[S_{aa}] * 1000 * 12)\)

Equations and Relationships (with biological phosphorus removal)

Description

Equation

Biomass concentration

\(bio = X_{H, 2} + X_{PAO, in} + X_{AUT, in}\)

S_I concentration

\(S_{I, 4} = S_{I, in} + (bio * f_{sI, xc})\)

S_NH4 concentration

\(S_{NH4, 4} = S_{NH4, 3} + (bio * i_{NBM}) - (bio * f_{sI, xc} * i_{NSI}) - (bio * f_{xI, xc} * i_{NSI}) - (bio * f_{pr, xc} * Ni[X_{pr}] * 14)\)

S_PO4 concentration

\(S_{PO4, 4} = S_{PO4, 3} + (bio * i_{PBM}) - (bio * f_{sI, xc} * i_{PSI}) - (bio * f_{xI, xc} * i_{PXI}) - (bio * f_{ch, xc} * Pi[X_{ch}] * 31) - (bio * f_{li, xc} * Pi[X_{li}] * 31)\)

S_IC concentration

\(S_{IC, 4} = S_{IC, 3} + (bio * i_{CXB}) - (bio * f_{sI, xc} * i_{CSI}) - (bio * f_{xI, xc} * i_{CXI}) - (bio * f_{pr, xc} * Ci[X_{pr}] * 12) - (bio * f_{ch, xc} * Ci[X_{ch}] * 12) - (bio * f_{li, xc} * Ci[X_{li}] * 12)\)

X_I concentration

\(X_{I, 4} = X_{I, in} + (bio * f_{xI, xc})\)

X_H concentration

\(X_{H, 4} = 0\)

X_PAO concentration

\(X_{PAO, 4} = 0\)

X_AUT concentration

\(X_{AUT, 4} = 0\)

Nitrogen demand for particulate inerts

\(X_{ND} = X_{S, in} * i_{NXS}\)

Phosphorus demand for particulate inerts

\(X_{PD} = X_{S, in} * i_{PXS}\)

Organic nitrogen from particulate inerts

\(XN_{org} = \frac{X_{ND}}{Ni[X_{pr}] * 14}\)

Carbohydrates mapping (if \(XN_{org} >= X_{S, in}\))

\(X_{ch} = 0\)

Carbohydrates mapping (if \(XN_{org} < X_{S, in}\))

\(X_{ch} = \frac{(X_{S, in} - XN_{org}) * 0.4}{1000}\)

Protein mapping (if \(XN_{org} >= X_{S, in}\))

\(X_{pr} = \frac{S_{F, 3}}{1000}\)

Protein mapping (if \(XN_{org} < X_{S, in}\))

\(X_{pr} = \frac{XN_{org}}{1000}\)

Lipids mapping (if \(XN_{org} >= X_{S, in}\))

\(X_{li} = 0\)

Lipids mapping (if \(XN_{org} < X_{S, in}\))

\(X_{li} = \frac{(X_{S, in} - XN_{org}) * 0.6}{1000}\)

S_NH4 concentration

\(S_{NH4, 5} = S_{NH4, 4} + (X_{S, in} * i_{NXS}) - (X_{pr} * Ni[X_{pr}] * 1000 * 14)\)

S_PO4 concentration

\(S_{PO4, 5} = S_{PO4, 4} + (X_{S, in} * i_{PXS}) - (X_{ch} * Pi[X_{ch}] * 1000 * 31) - (X_{li} * Pi[X_{li}] * 1000 * 31)\)

S_IC concentration

\(S_{IC, 5} = S_{IC, 4} + (S_{F, in} * i_{CXS}) - (X_{ch} * Ci[X_{ch}] * 1000 * 12) - (X_{pr} * Ci[X_{pr}] * 1000 * 12) - (X_{li} * Ci[X_{li}] * 1000 * 12)\)

X_S concentration

\(X_{S, 5} = 0\)

X_PP concentration

\(X_{PP, 6} = 0\)

X_PHA concentration

\(X_{PHA, 6} = 0\)

S_va concentration

\(S_{va, 6} = \frac{X_{PHA, 6} * f_{XPHA, Sva}}{1000}\)

S_bu concentration

\(S_{bu, 6} = \frac{X_{PHA, 6} * f_{XPHA, Sbu}}{1000}\)

S_pro concentration

\(S_{pro, 6} = \frac{X_{PHA, 6} * f_{XPHA, Spro}}{1000}\)

S_ac concentration

\(S_{ac, 6} = \frac{X_{PHA, 6} * f_{XPHA, Sac}}{1000}\)

S_PO4 concentration

\(S_{PO4, 6} = S_{PO4, 5} + X_{PP, in}\)

S_IC concentration

\(S_{IC, 6} = S_{IC, 5} + (X_{PHA, in} * C_{PHA}) - (S_{va, 6} * Ci[S_{va}] * 1000 * 12) - (S_{bu, 6} * Ci[S_{bu}] * 1000 * 12) - (S_{pro, 6} * Ci[S_{pro}] * 1000 * 12) - (S_{ac, 6} * Ci[S_{ac}] * 1000 * 12)\)

S_K concentration

\(S_{K, 6} = S_{K, in} + (K_{XPP} * X_{PP, in})\)

S_Mg concentration

\(S_{Mg, 6} = S_{Mg, in} + (Mg_{XPP} * X_{PP, in})\)

Equations and Relationships (without biological phosphorus removal)

Description

Equation

Biomass concentration

\(bio = X_{H, 2} + X_{AUT, in}\)

S_I concentration

\(S_{I, 4} = S_{I, in} + (bio * f_{sI, xc})\)

S_NH4 concentration

\(S_{NH4, 4} = S_{NH4, 3} + (bio * i_{NBM}) - (bio * f_{sI, xc} * i_{NSI}) - (bio * f_{xI, xc} * i_{NSI}) - (bio * f_{pr, xc} * Ni[X_{pr}] * 14)\)

S_PO4 concentration

\(S_{PO4, 4} = S_{PO4, 3} + (bio * i_{PBM}) - (bio * f_{sI, xc} * i_{PSI}) - (bio * f_{xI, xc} * i_{PXI}) - (bio * f_{ch, xc} * Pi[X_{ch}] * 31) - (bio * f_{li, xc} * Pi[X_{li}] * 31)\)

S_IC concentration

\(S_{IC, 4} = S_{IC, 3} + (bio * i_{CXB}) - (bio * f_{sI, xc} * i_{CSI}) - (bio * f_{xI, xc} * i_{CXI}) - (bio * f_{pr, xc} * Ci[X_{pr}] * 12) - (bio * f_{ch, xc} * Ci[X_{ch}] * 12) - (bio * f_{li, xc} * Ci[X_{li}] * 12)\)

X_I concentration

\(X_{I, 4} = X_{I, in} + (bio * f_{xI, xc})\)

X_H concentration

\(X_{H, 4} = 0\)

X_PAO concentration

\(X_{PAO, 4} = X_{PAO, in}\)

X_PP concentration

\(X_{PP, 4} = X_{PP, in}\)

X_PHA concentration

\(X_{PHA, 4} = X_{PHA, in}\)

X_AUT concentration

\(X_{AUT, 4} = 0\)

Nitrogen demand for particulate inerts

\(X_{ND} = X_{S, in} * i_{NXS}\)

Phosphorus demand for particulate inerts

\(X_{PD} = X_{S, in} * i_{PXS}\)

Organic nitrogen from particulate inerts

\(XN_{org} = \frac{X_{ND}}{Ni[X_{pr}] * 14}\)

Carbohydrates mapping (if \(XN_{org} >= X_{S, in}\))

\(X_{ch} = 0\)

Carbohydrates mapping (if \(XN_{org} < X_{S, in}\))

\(X_{ch} = \frac{(X_{S, in} - XN_{org}) * 0.4}{1000}\)

Protein mapping (if \(XN_{org} >= X_{S, in}\))

\(X_{pr} = \frac{S_{F, 3}}{1000}\)

Protein mapping (if \(XN_{org} < X_{S, in}\))

\(X_{pr} = \frac{XN_{org}}{1000}\)

Lipids mapping (if \(XN_{org} >= X_{S, in}\))

\(X_{li} = 0\)

Lipids mapping (if \(XN_{org} < X_{S, in}\))

\(X_{li} = \frac{(X_{S, in} - XN_{org}) * 0.6}{1000}\)

S_NH4 concentration

\(S_{NH4, 5} = S_{NH4, 4} + (X_{S, in} * i_{NXS}) - (X_{pr} * Ni[X_{pr}] * 1000 * 14)\)

S_PO4 concentration

\(S_{PO4, 5} = S_{PO4, 4} + (X_{S, in} * i_{PXS}) - (X_{ch} * Pi[X_{ch}] * 1000 * 31) - (X_{li} * Pi[X_{li}] * 1000 * 31)\)

S_IC concentration

\(S_{IC, 5} = S_{IC, 4} + (S_{F, in} * i_{CXS}) - (X_{ch} * Ci[X_{ch}] * 1000 * 12) - (X_{pr} * Ci[X_{pr}] * 1000 * 12) - (X_{li} * Ci[X_{li}] * 1000 * 12)\)

X_S concentration

\(X_{S, 5} = 0\)

X_PAO concentration

\(X_{PAO, 5} = X_{PAO, in}\)

X_PP concentration

\(X_{PP, 5} = X_{PP, in}\)

X_PHA concentration

\(X_{PHA, 5} = X_{PHA, in}\)

S_va concentration

\(S_{va, 6} = 0\)

S_bu concentration

\(S_{bu, 6} = 0\)

S_pro concentration

\(S_{pro, 6} = 0\)

S_ac concentration

\(S_{ac, 6} = 0\)

X_PAO concentration

\(X_{PAO, 6} = X_{PAO, in}\)

X_PP concentration

\(X_{PP, 6} = X_{PP, in}\)

X_PHA concentration

\(X_{PHA, 6} = X_{PHA, in}\)

S_va concentration

\(S_{va, 6} = \frac{X_{PHA, 6} * f_{XPHA, Sva}}{1000}\)

S_bu concentration

\(S_{bu, 6} = \frac{X_{PHA, 6} * f_{XPHA, Sbu}}{1000}\)

S_pro concentration

\(S_{pro, 6} = \frac{X_{PHA, 6} * f_{XPHA, Spro}}{1000}\)

S_ac concentration

\(S_{ac, 6} = \frac{X_{PHA, 6} * f_{XPHA, Sac}}{1000}\)

S_PO4 concentration

\(S_{PO4, 6} = S_{PO4, 5} + X_{PP, in}\)

S_IC concentration

\(S_{IC, 6} = S_{IC, 5} + (X_{PHA, in} * C_{PHA}) - (S_{va, 6} * Ci[S_{va}] * 1000 * 12) - (S_{bu, 6} * Ci[S_{bu}] * 1000 * 12) - (S_{pro, 6} * Ci[S_{pro}] * 1000 * 12) - (S_{ac, 6} * Ci[S_{ac}] * 1000 * 12)\)

S_K concentration

\(S_{K, 6} = S_{K, in} + (K_{XPP} * X_{PP, in})\)

S_Mg concentration

\(S_{Mg, 6} = S_{Mg, in} + (Mg_{XPP} * X_{PP, in})\)

Classes

class watertap.unit_models.translators.translator_asm2d_adm1.TranslatorDataASM2dADM1(component)[source]

Translator block representing the ASM2d/ADM1 interface

build()[source]

Begin building model. :param None:

Returns:

None

initialize_build(state_args_in=None, state_args_out=None, outlvl=0, solver=None, optarg=None)[source]

This method calls the initialization method of the state blocks.

Keyword Arguments:

  • state_args_in – a dict of arguments to be passed to the inlet property package (to provide an initial state for initialization (see documentation of the specific property package) (default = None).

  • state_args_out – a dict of arguments to be passed to the outlet property package (to provide an initial state for initialization (see documentation of the specific property package) (default = None).

  • outlvl – sets output level of initialization routine

  • optarg – solver options dictionary object (default=None, use default solver options)

  • solver – str indicating which solver to use during initialization (default = None, use default solver)

Returns:

None

References

[1] Flores-Alsina, X., Solon, K., Mbamba, C.K., Tait, S., Gernaey, K.V., Jeppsson, U. and Batstone, D.J., 2016. Modelling phosphorus (P), sulfur (S) and iron (Fe) interactions for dynamic simulations of anaerobic digestion processes. Water Research, 95, pp.370-382. https://github.com/wwtmodels/Plant-Wide-Models