Reduced Lundell Alternator

Reduced Lundell (claw-pole) alternator with an external voltage regulator

Libraries:
Powertrain Blockset / Energy Storage and Auxiliary Drive / Alternator

Description

The Reduced Lundell Alternator block implements a reduced Lundell (claw-pole) alternator with an external voltage regulator. The back-electromotive force (EMF) voltage is proportional to the input velocity and field current. The motor operates as a source torque to the internal combustion engine.

Use the Reduced Lundell Alternator block:

To model an automotive electrical system
In an engine model with a front-end accessory drive (FEAD)

The calculated motor shaft torque is in the opposite direction of the engine speed. You can:

Tune the external voltage regulator to a desired bandwidth. The stator current and two diode drops reduce the stator voltage.
Filter the load current to desired bandwidth. The load current has a lower saturation of 0 A.

The Reduced Lundell Alternator block implements equations for the electrical, control, and mechanical systems that use these variables.

Electrical

To calculate voltages, the block uses these equations.

Calculation	Equations
Alternator output voltage	$v_{s} = K_{v} i_{f} ω - R_{s} i_{s} - 2 V_{d}$
Field winding voltage	$v_{f} = R_{f} i_{f} + L_{f} \frac{d i_{f}}{d t}$

Control

The controller assumes no resistance or voltage drop.

Calculation	Equations
Field winding voltage transform	$V_{f} (s) = R_{f} I_{f} (s) + s L_{f} I_{f} (s)$
Field winding current transform	$I_{f} (s) = \frac{V_{f} (s)}{(R_{f} + s L_{f})}$
Open loop electrical transfer function	$G (s) = \frac{V_{s} (s)}{V_{f} (s)} = \frac{K_{v} ω}{(R_{f} + s L_{f})}$
Open loop voltage regulator transfer function	$G_{C} (s) = \frac{V_{f} (s)}{V r e f (s)}$
Closed loop transfer function	$T (s) = \frac{G (s) G c (s)}{1 + G (s) G c (s)}$
Closed loop controller design	$T (s) = \frac{1}{τ s + 1} \to G (s) G c (s) = \frac{1}{τ s}$ $G_{C} (s) = K_{g} (K_{p} + \frac{K_{i}}{s})$ $G (s) G_{C} (s) = \frac{K_{v} ω}{(R_{f} + s L_{f})} K_{g} (K_{p} + \frac{K_{i}}{s})$ $K_{p} = L_{f}, K_{i} = R_{f}, a n d K_{g} = \frac{2 π f}{K_{v} ω}$

Mechanical

To calculate torques, the block uses these equations.

Calculation	Equations
Electrical torque	$τ_{e l e c} = (K_{v} i_{f} ω) i_{l o a d}$
Frictional torque	$τ_{f r i c t i o n} = K_{b} ω$
Windage torque	$τ_{w i n d a g e} = K_{w} ω^{2}$
Torque at start	$τ_{s t a r t} = K_{c}$ when $ω = 0$
Motor shaft torque	$τ_{m e c h} = τ_{e l e c} + τ_{f r i c t i o n} + τ_{w i n d a g e} + τ_{s t a r t}$

Power Accounting

For the power accounting, the block implements these equations.

Bus Signal			Description	Variable	Equations
`PwrInfo`	`PwrTrnsfrd` — Power transferred between blocks Positive signals indicate flow into block Negative signals indicate flow out of block	`PwrMtr`	Mechanical power	P_mot	$P_{m o t} = ω τ_{m e c h}$
		`PwrBus`	Electrical power	P_bus	$P_{b u s} = - v_{s} i_{l o a d}$
	`PwrNotTrnsfrd` — Power crossing the block boundary, but not transferred Positive signals indicate an input Negative signals indicate a loss	`PwrLoss`	Motor power loss	P_loss	$P_{l o s s} = - (P_{m o t} + P_{b u s} - P_{i n d})$
	`PwrStored` — Stored energy rate of change Positive signals indicate an increase Negative signals indicate a decrease	`PwrInd`	Electrical winding loss	P_ind	$P_{i n d} = L_{f} i_{f} \frac{d i_{f}}{d t}$

The equations use these variables.

v_ref	Alternator output voltage command
v_f	Field winding voltage
i_f	Field winding current
i_s	Stator winding current
V_d	Diode voltage drop
R_f	Field winding resistance
R_s	Stator winding resistance
L_f	Field winding inductance
K_v	Voltage constant
F_v	Voltage regulator bandwidth
F_c	Input current filter bandwidth
V_fmax	Field control voltage upper saturation limit
V_fmin	Field control voltage lower saturation limit
K_c	Coulomb friction coefficient
K_b	Viscous friction coefficient
K_w	Windage coefficient
ω	Motor shaft angular speed
i_load	Alternator load current
v_s	Alternator output voltage
τ_mech, T_mech	Motor shaft torque

Examples

Build Conventional Vehicle Model

Build a vehicle with an internal combustion engine using the conventional vehicle reference application.

Ports

Inputs

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RefVolt — Alternator output voltage command
`scalar`

Alternator output voltage command, in V.

AltSpd — Angular speed
`scalar`

Motor shaft input angular speed, in rad/s.

LdCurr — Alternator load current
`scalar`

Alternator load current, in A.

Do not connect the port to the alternator rated current, which is a constant value. The block uses the alternator load current as the stator winding current, i_s, to determine the alternator voltage and motor torque. If you connect the port to the rated alternator current, the block does not model the dynamic effect of load current changes on the voltage and motor torque.

Output

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Info — Bus signal
bus

Bus signal containing these block calculations.

Signal			Description	Units
`FldVolt`			Field winding voltage	A
`FldFlux`			Field flux	Wb
`PwrInfo`	`PwrTrnsfrd`	`PwrMtr`	Mechanical power	W
	`PwrTrnsfrd`	`PwrBus`	Electrical power	W
	`PwrNotTrnsfrd`	`PwrLoss`	Motor power loss	W
	`PwrStored`	`PwrInd`	Electrical winding loss	W

AltVolt — Alternator output voltage
`scalar`

Alternator output voltage, in V.

LdTrq — Motor shaft torque
`scalar`

Motor shaft torque, in N·m.

Parameters

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Machine Configuration

Voltage constant, Kv — Constant
`.1` (default) | `scalar`

Voltage constant, in V/rad/s.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Kv`
Values:	`.1` (default) \| `scalar`
Data Types:	`double`

Field winding resistance, Rf — Resistance
`0.2` (default) | `scalar`

Field winding resistance, in ohm.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Rf`
Values:	`0.2` (default) \| `scalar`
Data Types:	`double`

Field winding inductance, Lf — Inductance
`0.002` (default) | `scalar`

Field winding inductance, in H.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Lf`
Values:	`0.002` (default) \| `scalar`
Data Types:	`double`

Stator winding resistance, Rs — Resistance
`0.01` (default) | `scalar`

Stator winding resistance, in ohm.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Rs`
Values:	`0.01` (default) \| `scalar`
Data Types:	`double`

Diode voltage drop, Vd — Voltage
`0.7` (default) | `scalar`

Diode voltage drop, in V.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Vd`
Values:	`0.7` (default) \| `scalar`
Data Types:	`double`

Voltage Regulator

Regulator bandwidth, Fv — Bandwidth
`2000` (default) | `scalar`

The regulator bandwidth, in Hz.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Fv`
Values:	`2000` (default) \| `scalar`
Data Types:	`double`

Current filter bandwidth, Fc — Bandwidth
`1000` (default) | `scalar`

The current filter bandwidth, in Hz.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Fc`
Values:	`1000` (default) \| `scalar`
Data Types:	`double`

Field voltage max, Vfmax — Maximum field voltage
`100` (default) | `scalar`

The maximum field voltage, in V.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Vfmax`
Values:	`100` (default) \| `scalar`
Data Types:	`double`

Field voltage min, Vfmin — Minimum field voltage
`-100` (default) | `scalar`

The minimum field voltage, in V.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Vfmin`
Values:	`-100` (default) \| `scalar`
Data Types:	`double`

Mechanical Losses

Coulomb friction, Kc — Friction
`0` (default) | `scalar`

Coulomb friction, in N·m.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Kc`
Values:	`0` (default) \| `scalar`
Data Types:	`double`

Viscous friction, Kb — Friction
`0` (default) | `scalar`

Viscous friction, in N·m/rad/s.

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Kb`
Values:	`0` (default) \| `scalar`
Data Types:	`double`

Windage, Kw — Windage
`0` (default) | `scalar`

Windage, in N·m/rad²/s².

Programmatic Use

To set the block parameter value programmatically, use the set_param function.

To get the block parameter value programmatically, use the get_param function.

Parameter:	`Kw`
Values:	`0` (default) \| `scalar`
Data Types:	`double`

References

[1] Krause, P. C. Analysis of Electric Machinery. New York: McGraw-Hill, 1994.

Reduced Lundell Alternator

Description

Electrical

Control

Mechanical

Power Accounting

Examples

Build Conventional Vehicle Model

Ports

Inputs

RefVolt — Alternator output voltage command scalar

AltSpd — Angular speed scalar

LdCurr — Alternator load current scalar

Output

Info — Bus signal bus

AltVolt — Alternator output voltage scalar

LdTrq — Motor shaft torque scalar

Parameters

Machine Configuration

Voltage constant, Kv — Constant .1 (default) | scalar

Programmatic Use

Field winding resistance, Rf — Resistance 0.2 (default) | scalar

Programmatic Use

Field winding inductance, Lf — Inductance 0.002 (default) | scalar

Programmatic Use

Stator winding resistance, Rs — Resistance 0.01 (default) | scalar

Programmatic Use

Diode voltage drop, Vd — Voltage 0.7 (default) | scalar

Programmatic Use

Voltage Regulator

Regulator bandwidth, Fv — Bandwidth 2000 (default) | scalar

Programmatic Use

Current filter bandwidth, Fc — Bandwidth 1000 (default) | scalar

Programmatic Use

Field voltage max, Vfmax — Maximum field voltage 100 (default) | scalar

Programmatic Use

Field voltage min, Vfmin — Minimum field voltage -100 (default) | scalar

Programmatic Use

Mechanical Losses

Coulomb friction, Kc — Friction 0 (default) | scalar

Programmatic Use

Viscous friction, Kb — Friction 0 (default) | scalar

Programmatic Use

Windage, Kw — Windage 0 (default) | scalar

Programmatic Use

References

Extended Capabilities

C/C++ Code Generation Generate C and C++ code using Simulink® Coder™.

Version History

See Also

RefVolt — Alternator output voltage command
`scalar`

AltSpd — Angular speed
`scalar`

LdCurr — Alternator load current
`scalar`

Info — Bus signal
bus

AltVolt — Alternator output voltage
`scalar`

LdTrq — Motor shaft torque
`scalar`

Voltage constant, Kv — Constant
`.1` (default) | `scalar`

Field winding resistance, Rf — Resistance
`0.2` (default) | `scalar`

Field winding inductance, Lf — Inductance
`0.002` (default) | `scalar`

Stator winding resistance, Rs — Resistance
`0.01` (default) | `scalar`

Diode voltage drop, Vd — Voltage
`0.7` (default) | `scalar`

Regulator bandwidth, Fv — Bandwidth
`2000` (default) | `scalar`

Current filter bandwidth, Fc — Bandwidth
`1000` (default) | `scalar`

Field voltage max, Vfmax — Maximum field voltage
`100` (default) | `scalar`

Field voltage min, Vfmin — Minimum field voltage
`-100` (default) | `scalar`

Coulomb friction, Kc — Friction
`0` (default) | `scalar`

Viscous friction, Kb — Friction
`0` (default) | `scalar`

Windage, Kw — Windage
`0` (default) | `scalar`

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.