WO2009010482A1 - Device for controlling a generator of a motor vehicle - Google Patents

Abstract

The invention relates to a device for controlling a generator of a motor vehicle, comprising a generator controller and a generator, wherein the generator controller comprises a governor controller having an operating voltage connection and being grounded via a ground connection. The generator further comprises an excitation coil having a first and a second connection. The first connection of the excitation coil is connected to the operating voltage connection via the governor controller. The second connection of the excitation coil is connected to the ground via the governor controller.

Description

Device for controlling a motor vehicle generator

The invention relates to a device for controlling a motor vehicle generator

State of the art

It is already known to regulate the output voltage of a generator by means of a generator regulator. The output voltage of a generator depends on several influencing factors, which include the speed, the electrical load in the vehicle electrical system, the state of charge of the starter battery and the temperature. In order to generate a constant voltage in the electrical system, the generator controller regulates the output voltage of the generator within predefined limits. This regulation takes place via an adaptation of the exciter current flowing through the field winding of the generator. To adjust the excitation current, a change of the duty cycle of a PWM drive signal is performed.

When using a high-side transistor as a switching transistor of the generator regulator of the excitation current is removed from a DC voltage supply terminal B + and passed through the transistor to the field winding. The second terminal of the excitation winding is connected to ground.

From DE 101 50 380 Al a proposed for a motor vehicle electrical system power supply is known, which has a battery, a generator and a controller. Several consumers are connected to the battery. The generator is used to charge the battery. The controller is intended to control the generator voltage. The regulator includes a controller, a controlled by the controller first switch for controlling the generator voltage in normal operation and a controllable by the controller second switch for controlling the generator voltage in case of malfunction of the first switch. The first switch is arranged between a supply voltage connection terminal and a connection of the exciter winding of the generator. The second switch is provided between the other terminal of the field winding and ground. The controller has its own ground connection. Due to the redundant design of the controller, its reliability is increased.

Advantages of the invention

A device for controlling a motor vehicle generator with the features specified in claim 1 has the advantage that in the case of any interruption of the supply of the regulator control of the generator regulator, in particular an ASIC of the generator regulator, and the exciter circuit is interrupted. This prevents the occurrence of overvoltages in the electrical system. Such overvoltages in the vehicle electrical system could lead to vehicle electrical system states with serious effects, for example a shutdown or overloading up to a failure of components that are required for the driving of the motor vehicle. This advantage is essentially achieved in that the excitation winding is applied to the regulator controller in both poles and is preferably connected in both poles to the ASIC of the generator regulator.

Further advantageous features of the invention will become apparent from the exemplification thereof with reference to the drawing. Drawing

FIG. 1 shows a block diagram of a first device for controlling a motor vehicle generator. FIG. 2 shows a block diagram of a second device for controlling a motor vehicle generator.

description

The device shown in FIG. 1 has a generator controller 1, a generator unit 28 with a generator 2 and a rectifier arrangement 11, a battery 12, loads 13, an inductive load 14, the terminal 15 and a control unit 16.

The generator regulator 1 contains a regulator controller 7a implemented as an integrated circuit and customer-specific connections such as the connection LIN shown in FIG. 1 and connections B +, DF +, DF- and X to the generator 2. The connection LIN is connected via a capacitor 18 Mass connected. The task of the capacitor 18 is to filter the signals provided at the LIN terminal.

The integrated circuit 7a has a non-illustrated control unit, an ohmic resistor 20, a switching transistor 21, a diode 23 and a switching transistor 6a.

Furthermore, the integrated circuit 7a has connections 8, 9, 24, 25 and 26 as well as a detection input 10. The terminal 8 of the integrated circuit 7a is connected via the terminal DF of the generator regulator 1 to the second terminal 5b of the exciter winding 5 of the generator 2. The terminal 9 of the integrated circuit is connected via a ground connection 3 to ground 4. The connection 25 of the integrated circuit is connected via the terminal DF + of the generator controller 1 with the first End 5a of the field winding 5 of the generator 2 connected. The detection input 10 of the integrated circuit 7a is connected via the terminal X of the generator controller 1 with the phase voltage terminal W of the generator in connection düng. The connection 26 of the integrated circuit 7a is connected to the external control unit 16 via the connection LIN of the generator controller 1.

Between the terminals 24 and 25 of the integrated circuit 7a is within the integrated circuit of the

Switching transistor 6a connected such that the first terminal 5a of the field winding 5 is connected via the switching transistor 6a of the integrated circuit to the operating voltage connection B +.

The terminal 24 of the integrated circuit 7a is connected via the generator unit 28, to which the generator 2 and the rectifier arrangement 11 belong, to the vehicle electrical system BN of the motor vehicle.

The generator 2 has, in addition to the already mentioned excitation winding 5 not shown phase windings, which are connected to phase voltage terminals U, V, W of the generator 2. The phase voltages generated at the phase voltage connections are rectified by the rectifier arrangement 11 and then forwarded to the on-board network BN. Furthermore, the rectifier arrangement 11 has a ground connection IIa via which it is connected to ground 4.

To the electrical system BN, the battery 12, the consumer 13, the inductive load 14 and the terminal 15 are connected.

During operation of the device shown, it may be the case that the earth connection 3 of the regulator control 7a is interrupted. As a result, the controller controller 7a loses its intended reference potential. It turns via the regulator controller 7a a random voltage, whose height depends on the external circuit of the integrated circuit and parasitic connections. Typically, this random voltage is less than the actual voltage at the generator regulator terminals. For this reason, the control unit of the integrated circuit 7a tries to increase the voltages at the terminals of the integrated circuit. The control unit of the integrated circuit 7a can not recognize that an error has occurred.

In order to prevent the generator controller 1 from increasing the output voltage of the generator 2 by corresponding activation of the excitation winding to such an extent that overvoltages occur in the electrical system which could lead to the destruction of onboard power supply components, the second connection is in the present invention 5b of the field winding 5 via the terminal DF and the terminals 8 and 9 of the integrated circuit 7a and the ground connection 3 of the integrated circuit 7a connected to ground 4.

This has the consequence that in the case of an interruption of this ground connection 3 not only the regulator control 7a is disconnected from its reference potential, but also the exciter circuit of the generator and thus the current flow through the exciter winding 5 is interrupted.

In the apparatus described above, after all of this occurs when an interruption of the ground connection 3 of the controller controller 7a of the generator 2 is deliberately de-energized. As a result, in the electrical system no surges can occur that could lead to the destruction of electrical system components.

FIG. 2 shows a block diagram of a second device for controlling a motor vehicle generator. This device also has a generator controller 1, a generator neratoreinheit 28 with a generator 2 and a rectifier assembly 11, a battery 12, consumer 13, an inductive load 14, the terminal 15 and a control unit 16 on.

The generator controller 1 contains as controller control an integrated circuit 7b and customer-specific connections such as the terminal LIN shown in Figure 2 and terminals B +, DF +, DF- and X to the generator 2. The terminal LIN is connected via a capacitor 18 to ground. The task of the capacitor 18 is to filter the signals provided at the LIN terminal.

The integrated circuit 7b has a non-illustrated control unit, an ohmic resistor 20, a

Switching transistor 21, a diode 23 and a switching transistor 6b.

The integrated circuit 7b differs from the integrated circuit 7a shown in FIG. 1 in that the terminals 24 and 25 of the integrated circuit 7b are directly connected to each other within this integrated circuit via a line and the switching transistor 6b is connected between the terminal 8 and the Terminal 9 of the integrated circuit is provided within this integrated circuit 7b. Consequently, in this embodiment, the first terminal 5a of the field winding 5 is connected directly to the operating voltage terminal B + via the integrated circuit 7b, while the second terminal 5b of the field winding 5 is connected via the switching transistor 6b to the terminal 9 and via this and the ground connection 3 of the integrated circuit 7b is connected to ground 4.

Occurs in this embodiment, between the terminals 24 and 25 of the integrated circuit 7b on an interruption, as indicated in Figure 2, then this interruption is also the field circuit of the generator 2 interrupted. This has the consequence that no unwanted overvoltages occur in the electrical system.

After all, it is advantageously achieved in the present invention that, in the event of an interruption in the supply of the regulator controller, which is preferably realized as an ASIC, the exciter circuit of the generator is also interrupted so that no undesired overvoltages occur in the vehicle electrical system. This is essentially achieved in that both terminals of the field winding are connected to the controller control of the generator controller or its ASIC and are thus integrated into the supply path of the controller control.

Claims

claims

1. A device for controlling a motor vehicle generator, which has a generator controller (1) and a generator (2), wherein the generator controller (1) a controller llersteuerung (7a, 7b), which has an operating voltage connection (B +) and via a ground connection (3) is connected to ground (4), and wherein the generator (2) has a first (5a) and a second (5b) terminal having exciter winding (5), characterized in that the first terminal (5a) the exciter winding (5) via the regulator controller (7a, 7b) to the operating voltage terminal (B +) is connected and the second terminal (5b) of the exciter winding (5) via the regulator control (7a, 7b) is connected to ground.

2. Device according to claim 1, characterized in that the first terminal (5a) of the excitation winding (5) via a switch (6a) of the controller control

(7a, 7b) is connected to the operating voltage terminal (B +).

3. Device according to claim 1, characterized in that the second terminal (5b) of the excitation winding (5) via a switch (6b) of the controller controller (7a, 7b) is connected to ground.

4. Device according to one of the preceding claims, characterized in that the controller controller (7a, 7b) is an integrated circuit, a connection (8) of the integrated circuit with the second

Terminal (5b) of the field winding (5) is connected and another terminal (9) of the integrated circuit is connected via a ground connection (3) to ground (4).

5. Device according to one of claims 2-4, dadur ch ge kenn z e i chne t that the switch (6a, 6b) a

Switching transistor is.

6. Device according to claim 5, characterized in that the switching transistor (6a, 6b) is a component of the integrated circuit (7a, 7b).

7. Device according to one of claims 4 - 6, characterized in that the integrated circuit ei ^¬ NEN detection input (10) which is connected to a phase voltage terminal (W) of the generator (2).

8. The device according to claim 7, characterized in that the integrated circuit for the evaluation of a at the detection input (10) of the integrated

Circuit present signal is provided and outputs an error signal when detecting an excitation interruption.