Asymmetric Static Generator

Note

Static generators should always have a positive p_mw value, since all power values are given in the generator convention. If you want to model constant power consumption, it is recommended to use a load element instead of a static generator with negative active power value.

See also

Unit Systems and Conventions

Create Function

Input Parameters

net.asymmetric_sgen

Parameter

Datatype

Value Range

Explanation

name

string

name of the static generator

type

string
naming conventions:
“PV” - photovoltaic system
“WP” - wind power system
“CHP” - combined heating and power system

type of generator

bus*

integer

index of connected bus

p_a_mw*

float

\(\leq\) 0

active power of the static generator : Phase A[MW]

q_a_mvar*

float

reactive power of the static generator : Phase A [MVar]

p_b_mw*

float

\(\leq\) 0

active power of the static generator : Phase B[MW]

q_b_mvar*

float

reactive power of the static generator : Phase B [MVar]

p_c_mw*

float

\(\leq\) 0

active power of the static generator : Phase C[MW]

q_c_mvar*

float

reactive power of the static generator : Phase C [MVar]

sn_mva

float

\(>\) 0

rated power ot the static generator [MVA]

scaling*

float

\(\geq\) 0

scaling factor for the active and reactive power

in_service*

boolean

True / False

specifies if the generator is in service.

*necessary for executing a power flow calculation
**optimal power flow parameter

Electric Model

Static Generators are modelled as PQ-buses in the power flow calculation:

alternate Text

The PQ-Values are calculated from the parameter table values as:

\begin{align*} P_{sgen} &= p\_mw \cdot scaling \\ Q_{sgen} &= q\_mvar \cdot scaling \\ \end{align*}

Note

The apparent power value sn_mva is provided as additional information for usage in controller or other applications based on panadapower. It is not considered in the power flow!

Result Parameters

net.asymmetric_sgen

Parameter

Datatype

Explanation

p_a_mw

float

resulting active power demand after scaling : Phase A [MW]

q_a_mvar

float

resulting reactive power demand after scaling : Phase A [MVar]

p_b_mw

float

resulting active power demand after scaling : Phase B [MW]

q_b_mvar

float

resulting reactive power demand after scaling : Phase B [MVar]

p_c_mw

float

resulting active power demand after scaling : Phase C [MW]

q_c_mvar

float

resulting reactive power demand after scaling : Phase C [MVar]

The power values in the net.res_sgen table are equivalent to \(P_{sgen}\) and \(Q_{sgen}\).