# Delta-Connected Load

Three-phase load wired in delta configuration

**Libraries:**

Simscape /
Electrical /
Passive /
RLC Assemblies

## Description

The Delta-Connected Load block models a three-phase load wired in a delta configuration. Each limb of the load can include any combination of a resistor (R), capacitor (C), and inductor (L), connected in series or in parallel.

You can specify values for the R, L, and C components directly in terms of resistance, inductance, and capacitance, or by rated powers at a rated voltage and frequency.

If you parameterize the block directly in terms or R, L, and C values, then for initialization, provide a three-element row vector of initial voltages for a capacitor and a three-element row vector of initial currents for an inductor.

If you parameterize the block in terms of rated powers, then specify initial conditions in terms of an initial voltage, initial voltage phase, and initial frequency. For example, if the load is connected directly to a three-phase voltage source, then the initial conditions are identical to the source values for RMS line voltage, frequency, and phase shift. To specify zero initial voltage magnitude, set the initial voltage to 0.

For certain combinations of R, L, and C, for some circuit topologies, you should specify parasitic resistance or conductance values that help the simulation to converge numerically. These parasitic terms help create a small parallel resistive path for an inductor and a small series resistance for a capacitor. When you parameterize the block in terms of rated powers, the rated power values do not account for these small parasitic terms. The rated powers represent only the R, L, and C values of the load itself.

### Block Parameterization

These tables list the block parameters for each value of the **Component
structure** parameter, based on the
**Parameterization** option you select:

`Specify by rated power and voltage`

`Specify component values directly`

**Specify by Rated Power and Voltage**

Component Structure | Main Parameters | Parasitics Parameters | Initial Conditions Parameters |
---|---|---|---|

| Rated voltage Real power | None | None |

| Rated voltage Rated electrical frequency Inductive reactive power | Parasitic parallel conductance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Capacitive reactive power | Parasitic series resistance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Real power Inductive reactive power | Parasitic parallel conductance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Real power Capacitive reactive power | None | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Inductive reactive power Capacitive reactive power | Parasitic parallel conductance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Real power Inductive reactive power Capacitive reactive power | Parasitic parallel conductance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Real power Inductive reactive power | None | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Real power Capacitive reactive power | Parasitic series resistance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Inductive reactive power Capacitive reactive power | Parasitic series resistance | Terminal voltage magnitude Terminal voltage angle Frequency |

| Rated voltage Rated electrical frequency Real power Inductive reactive power Capacitive reactive power | Parasitic series resistance | Terminal voltage magnitude Terminal voltage angle Frequency |

**Specify Component Values Directly**

Component Structure | Main Parameters | Parasitics Parameters | Initial Conditions Parameters |
---|---|---|---|

| Resistance | None | None |

| Inductance | Parasitic parallel conductance | Initial inductor current [ Ia Ib Ic ] |

| Capacitance | Parasitic series resistance | Initial capacitor voltage [ Va Vb Vc ] |

| Resistance Inductance | Parasitic parallel conductance | Initial inductor current [ Ia Ib Ic ] |

| Resistance Capacitance | None | Initial capacitor voltage [ Va Vb Vc ] |

| Inductance Capacitance | Parasitic parallel conductance | Initial inductor current [ Ia Ib Ic ] Initial capacitor voltage [ Va Vb Vc ] |

| Resistance Inductance Capacitance | Parasitic parallel conductance | Initial inductor current [ Ia Ib Ic ] Initial capacitor voltage [ Va Vb Vc ] |

| Resistance Inductance | None | Initial inductor current [ Ia Ib Ic ] |

| Resistance Capacitance | Parasitic series resistance | Initial capacitor voltage [ Va Vb Vc ] |

| Inductance Capacitance | Parasitic series resistance | Initial inductor current [ Ia Ib Ic ] Initial capacitor voltage [ Va Vb Vc ] |

| Resistance Inductance Capacitance | Parasitic series resistance | Initial inductor current [ Ia Ib Ic ] Initial capacitor voltage [ Va Vb Vc ] |

### Faults

*Since R2024b*

To model a fault in the Delta-Connected Load block, in the
**Faults** section, click the **Add fault** hyperlink next
to the fault that you want to model. In the Add Fault window, specify the fault properties. For
more information about fault modeling, see Fault Behavior Modeling and Fault Triggering.

The Delta-Connected Load block allows you to model these types of fault at the three-phase connection port:

Single-phase-to-ground fault (a-g, b-g, or c-g)

Two-phase fault (a-b, b-c, or c-a)

Two-phase-to-ground fault (a-b-g, b-c-g, or c-a-g)

Three-phase fault (a-b-c)

Three-phase-to-ground fault (a-b-c-g)

### Variables

To set the priority and initial target values for the block variables prior to
simulation, use the **Initial Targets** section in the block dialog
box or Property Inspector. For more information, see Set Priority and Initial Target for Block Variables.

Nominal values provide a way to specify the expected magnitude of a variable in a
model. Using system scaling based on nominal values increases the simulation
robustness. Nominal values can come from different sources, one of which is the
**Nominal Values** section in the block dialog box or Property
Inspector. For more information, see System Scaling by Nominal Values.

For this block, the **Initial Targets** and **Nominal
Values** settings are visible only if, in the **Main**
section, you set the **Parameterization** parameter to
`Specify component values directly`

and you do not set
the **Component structure** parameter to
`R`

.

## Examples

## Ports

### Conserving

## Parameters

## Extended Capabilities

## Version History

**Introduced in R2013b**