DE102007019990B4 - Car generator with external regulator - Google Patents

Abstract

Vehicle generator (1) comprising a rotor (7) with a field winding (5) and a stator with a plurality of stator windings, wherein the vehicle generator (1) is designed for external control, in which an externally arranged regulator (3) by the Exciter winding (5) adjusts flowing current, wherein the generator (1) comprises means (16, 17) which ensure at least one emergency operation of the generator (1) in case of failure of the external regulator (3), wherein the excitation winding (5) is formed in several parts and at least two partial windings (5a, 5b), wherein the different partial windings (5a, 5b) have a different resistance and a different inductance.

Description

State of the art

The invention relates to a motor vehicle generator, in particular a self-excited generator, according to the preamble of patent claim 1.

Car generators are often realized as self-excited, multi-phase electric machines. Such generators comprise a rotor with a field winding, as well as a stator with several (usually three) stator windings in which a regenerative alternating voltage is induced. The excitation circuit with the regulator winding is connected to a generator regulator, which turns on and off the exciting current flowing through the exciter winding with a desired duty cycle (PWM signal) and thus regulates the generator output voltage.

1 shows a schematic diagram of a known from the prior art vehicle generator 1 with an internal regulator 3 . 4 ie the controller 3 . 4 is in the housing of the generator 1 structurally integrated. The generator 1 , which is realized here as a three-phase electric machine, comprises a rotor 7 with a field winding 5 , and a stator with three stator windings (not shown). The excitation winding 5 is over a transistor 4 connected to the positive battery terminal B +. The induced phase voltages are rectified by means of a rectifier 9 rectified.

During operation of the vehicle, the controller receives 3 current setpoints from a control unit 2 via a control line 11 , The regulator 3 then generates a corresponding PWM signal, with which the switching power amplifier 4 is controlled. The duration of the ON time at OFF time determines the magnitude of the excitation current. An advantage of this design is that the integrated regulator 3 in case of a defect of the control unit 2 or the control line 11 enters an emergency mode and continues to operate with preset parameters. The supply of the electrical system is thus ensured at least in principle. However, this design has the disadvantage that the logic of the regulator 3 after installation in the vehicle can not or only with difficulty be changed.

2 shows another type of vehicle generator 1 in which the regulator 3 outside the generator in a control unit 2 is arranged. The remaining construction of the generator 1 is otherwise unchanged 1 , The freewheeling diode 6 is in the control unit 2 integrated.

An advantage of this design is that the logic of the regulator 3 as software in the control unit 2 can be easily changed to suit different applications. However, the external design has the disadvantage that in case of a defect of the controller or the excitation line 11 the generator 1 de-energized. As a result, no electricity is generated and the electrical system is powered by the generator 1 no longer supplied.

DE 103 21 872 A1 discloses a control device for controlling the output voltage of a generator. Herein, to improve the reliability of the generator control proposed to perform the control in normal operation by means of a main controller, which is implemented as software in a control unit and to perform the control by means of an auxiliary controller in case of malfunction of the main controller.

DE 38 44 442 A1 discloses a battery charging system having a generator, a voltage regulator, a battery and consumer and a consequential damage protection device, with the help errors in the system can be displayed via a control element and which contains an additional voltage regulator, which can take over the voltage control in the event of an error until the error is fixed.

DE 198 25 126 A9 discloses an arrangement for adjusting the speed of a commutator motor with series or shunt excitation to different speed ranges of washing machines, especially at low washing and spin speeds and higher spin speeds, wherein the different speeds are achieved by two or more field windings are provided, the separated or together can be switched on and of which at least one field winding contains a field tapping.

US 2004/0155632 A1 discloses an H-bridge topology for bidirectional field excitation configured to neutralize the effect of a permanent magnet of a rotor.

US 2003/0201756 A1 discloses a generator comprising a rotor having a field winding and a stator having a plurality of stator windings, the generator being adapted for external control, in which an externally arranged regulator adjusts the current flowing through the field winding, the generator having an emergency device in case of failure of the external controller ensures at least one emergency operation of the generator.

Disclosure of the invention

It is therefore the object of the present invention to combine the advantages of the two designs together, ie on the one hand to ensure high availability of electrical system supply and on the other hand to allow easy adjustment of the controller.

This object is achieved according to the invention by the features specified in claim 1. Further embodiments of the invention are the subject of dependent claims.

An essential aspect of the invention is to provide a generator with external control, comprising means which ensure at least one emergency operation in case of failure of the external controller. This has the significant advantage that the availability of the generator can be significantly improved and at the same time the logic of the controller can be easily changed. The generator is protected against both a defect of the controller including controller and control line.

According to a first embodiment of the invention, the generator comprises 1 an additional supply path through which the excitation winding is still supplied with electrical power in case of failure of the controller. D. h., The exciter winding is connected in this case via a redundant supply path with a supply voltage, in particular the vehicle electrical system voltage. This has the significant advantage that at least one emergency supply is ensured if the regulator fails.

The field winding is preferably formed in several parts in this case and comprises at least two partial windings. A main terminal of the entire field winding is preferably connected to the supply potential and a center connection to the controller. The partial windings preferably have a different ohmic resistance. In the case of two partial windings, the ratio of the resistors is preferably 1: 3. The partial winding with the lower ohmic resistance is preferably connected to ground, and the other partial winding is connected to the supply potential.

Each partial winding is preferably associated with a freewheeling diode. The freewheeling diodes can z. B. be arranged on the stand or in the runner.

The switching output stage of the controller can be switched either against the reference potential (high-side) or against ground (low-side).

According to a second embodiment of the invention, the generator comprises a permanent magnet, which in emergency operation, i. H. in case of failure of the controller or controller, a predetermined magnetic field generated in the rotor. This ensures a minimum supply of electrical consumers in emergency mode. The excitation winding is preferably formed in one piece in this embodiment.

The generator in this case preferably comprises an additional inductance, which generates a counter-excitation in normal operation and attenuates the magnetic field of the permanent magnet. The additional inductance is preferably connected to the supply potential and prevents the mains voltage from rising too much during normal operation. In the supply path of the additional inductance, a Zener diode is preferably provided which becomes conductive in the reverse direction when the Z voltage (for example 15 V in a 12 V network) is exceeded. Then flows through the additional inductance, a current that leads to a counter-excitation and attenuates the magnetic field of the permanent magnet.

According to another embodiment of the invention, an additional inductance is also provided which generates a counter-excitation. In contrast to the embodiment described above, however, this inductance is preferably connected to the control unit and is controlled by this also in normal operation. In this case, the control unit contains a corresponding control or regulator circuit for operating the additional inductance. The exciter winding in this case preferably consists of several partial windings. A main terminal of the entire field winding is preferably connected to the reference potential. The generator controller is preferably connected to a center node. The additional inductance generates a magnetic opposing field during normal operation, which weakens the magnetic field of one of the partial windings.

According to a third embodiment of the invention, the generator comprises a one-piece excitation winding, which is connected on the one hand via the control line to the generator controller and also via a redundant supply path to the supply potential. The supply path preferably includes a resistor which is dimensioned such that a minimum excitation in the excitation winding is achieved in the event of failure of the generator regulator. The additional supply path is preferably guided via the ignition switch.

Regardless of the particular embodiment of the ground terminal of the field winding can either via one of the brushes directly to ground or z. B. be connected via the ball bearing of the rotor directly to the ground terminal of the rectifier. In the latter case, an additional ground connection can be saved.

Brief description of the drawings

The invention will now be described by way of example with reference to the accompanying drawings. Show it:

1 a schematic diagram of a known from the prior art generator with integrated controller;

2 a schematic diagram of a known from the prior art generator with external regulator;

3 a schematic diagram of an external regulator generator according to a first embodiment of the invention;

4 a schematic diagram of a generator according to the first embodiment, but with a different arrangement of freewheeling diodes;

5 a schematic diagram of a generator according to the first embodiment, but with a switched to ground regulator;

6 a schematic diagram of a generator according to a second embodiment of the invention;

7 a schematic diagram of a generator according to the second embodiment, but with different connection of an additional inductor;

8th a schematic diagram of a generator according to a third embodiment of the invention;

9 a schematic diagram of a generator according to a fourth embodiment of the invention; and

10 a schematic diagram of a generator according to the fourth embodiment, but with a different arrangement of the freewheeling diode.

Embodiments of the invention

Regarding the explanation of 1 and 2 Reference is made to the introduction to the description.

3 shows a schematic diagram of a motor vehicle generator according to a first embodiment of the invention. The generator is realized here as a self-excited, three-phase synchronous machine whose rotor two series-connected exciter windings 5a . 5b having. The winding 5b is against the supply potential B +, and the partial winding 5a switched to ground. Each partial winding is a freewheeling diode 6a . 6b assigned here in the brush holder 13 are arranged. The freewheeling diodes 6a . 6b are each parallel to the associated sub-excitation winding 5a . 5b connected.

In normal operation (ie, all components operate faultlessly), the entire field winding generates an excitation field which generates an alternating voltage in the stator windings. This is done by means of a rectifier 9 rectified. A ball bearing of the runner 7 is with the reference numeral 8th characterized.

The partial winding 5b is at the node 15 connected, via an additional supply path 16 and the ignition switch 14 connected to the mains voltage B +. The middle node between the two partial windings 5a . 5b is connected to a node DF at which the controller 3 or the switching output stage 4 of the controller is connected. The transistor 4 is switched here against the supply potential B + (high-side variant).

In normal operation, the controller generates 2 a DF signal with a predetermined duty cycle, by means of which the desired excitation current is set. In the event of a controller failure, for example due to a defect in the control unit or an interruption of the control line 11 , is from the generator 1 no DF signal received anymore. In this case, via the additional supply path 16 a minimum excitation of the excitation windings 5a . 5b ensured. The generator is thus not sufficient and can continue to supply the electrical system at least to a limited extent.

The minimum excitation is here by the total resistance of the two partial windings 5a . 5b certainly. The resistance of the partial winding 5b for example 6 ohms and that of the partial winding 5a 2 ohms.

This embodiment has the advantage that the generator 1 is not de-energized in case of failure of the controller and thus ensures at least a minimum supply of electrical consumers. On the other hand, an overvoltage in the electrical system is possible at higher speed or low load.

4 shows a schematic diagram of a motor vehicle according to 3 in contrast to 3 the freewheeling diodes 6a . 6b in the runner 7 are integrated. Incidentally, this generator is different 1 not from 3 so that reference is made to the above description.

5 shows a schematic diagram of a generator with two excitation windings 5a . 5b according to the embodiment of 3 , In contrast to 3 here is the transistor 4 of the generator controller switched to ground (low-side variant).

6 shows a schematic diagram of a generator 1 according to a second embodiment of the invention. The generator 1 includes a one-piece excitation winding 5 and a permanent magnet 17 that's the exciter winding 5 energized in normal operation. The excitation winding 5 is in turn via the node DF with the generator controller 3 . 4 connected. In case of a defect of the regulator 3 or the control line 11 becomes the excitation winding 5 from the permanent magnet 17 excited. To prevent overvoltage, here is an additional inductance 18 provided that generates an opposing field in the case of overvoltage, which is the magnetic field of the permanent magnet 17 weakens.

The additional inductance d 18 is via an additional supply path 16 connected to the supply voltage B +. In this supply path is also a Zener diode 19 provided which becomes conductive in the reverse direction when the mains voltage reaches a predetermined threshold, e.g. B. 15 V, exceeds. This threshold is determined by the Z voltage of the Zener diode 19 certainly. Overvoltages in the electrical system can thus be effectively prevented.

The ground node of the exciter winding 5 is about the ball bearing 8th with the ground node of the rectifier 9 connected and switched to ground. Overall, therefore, only a single ground connection is needed.

7 shows a schematic diagram of a motor vehicle generator 1 according to the embodiment of 6 , The generator 1 again comprises a permanent magnet 17 and an additional inductance 18 representing the magnetic field of the permanent magnet 17 weakens at overvoltage. In contrast to 6 here is the supply path 16 the inductance 18 not over the ignition switch 14 but directly to the output of the rectifier 9 connected. The ground terminal of the exciter winding 5 is about the ball bearing 8th led, as well as in 6 , Otherwise, a third slip ring would be necessary.

8th shows a schematic diagram of a motor vehicle generator 1 according to a third embodiment of the invention. The excitation winding 5 is here formed in two parts and includes the partial windings 5a and 5b , The partial winding 5b is at the terminal 15 connected via the ignition switch 14 is connected to the supply potential B +. The second part winding 5a is switched to ground. This arrangement corresponds to that of 4 , In contrast to 4 here is an additional inductance 18 provided by a supply path 20 with the control unit 2 connected is. The inductance 18 can by means of the power switch 19 be driven to generate an opposing field, the magnetic field of the field winding 5a . 5b weakens.

To avoid overvoltages in the electrical system is also a Zener diode 21 provided that exceed the Zener voltage of z. B. 15 V in the reverse direction is conductive and a current flow through the inductance 18 causes. The Zener diode 21 is between the supply path 16 the excitation winding and the supply path 20 the inductance 18 connected. In normal operation, the generator output voltage is through the controller 2 regulated, which generates a predetermined signal DF-p.

9 shows a schematic diagram of a motor vehicle generator 1 according to a fourth embodiment of the invention. In this case, the generator includes 1 a one-piece excitation winding 5 , which is connected to terminal DF at one terminal and to ground at the other terminal. The excitation winding 5 is additionally via a supply path 16 connected to the reference potential B +. The supply path 16 contains a resistor 22 who is here in the brush holder 13 is arranged. The freewheeling diode 6 the exciter winding is located in the external control unit 2 ,

In normal operation, the generator output voltage from the controller 2 regulated, which generates a corresponding DF signal. In case of failure of the controller 3 will be a minimum excitation via the supply path 16 ensured.

10 shows a schematic diagram of a motor vehicle generator 1 similar 9 , In contrast to 9 here is the freewheeling diode 6 integrated in the brush holder. Incidentally, the two circuits are identical.

Claims (16)

Vehicle generator ( 1 ), a runner ( 7 ) with a field winding ( 5 ) and a stator with a plurality of stator windings, wherein the vehicle generator ( 1 ) is designed for external control, in which an externally arranged controller ( 3 ) by the excitation winding ( 5 ) current flowing, the generator ( 1 ) Medium ( 16 . 17 ) in case of failure of the external controller ( 3 ) at least one emergency operation of the generator ( 1 ), the excitation winding ( 5 ) is formed in several parts and at least two partial windings ( 5a . 5b ) comprising the different partial windings ( 5a . 5b ) have a different resistance and a different inductance. Vehicle generator according to claim 1, characterized in that the generator ( 1 ) an additional supply path ( 16 ), over which the excitation winding ( 5 ) in case of failure of the external controller ( 3 ) continues to be supplied with electrical power. Vehicle generator according to claim 1, characterized in that a main connection ( 15 ) of the multipart exciter winding ( 5 ) with the supply potential (B +), and a center connection (DF) with the controller ( 3 ) connected is. Vehicle generator according to claim 3, characterized in that the controller ( 3 ) an output stage switch ( 4 ) connected either to ground or to the supply potential (B +). Vehicle generator according to claim 1, characterized in that each partial winding ( 5a . 5b ) a freewheeling diode ( 6a . 6b ) assigned. Vehicle generator according to claim 5, characterized in that the freewheeling diodes 6a . 6b in the brush holder ( 13 ) or in the runner ( 7 ) of the generator ( 1 ) are arranged. Vehicle generator according to claim 1 or 2, characterized in that the generator ( 1 ) a permanent magnet ( 17 ), which in case of failure of the controller ( 3 ) a predetermined magnetic field in the rotor ( 7 ) generated. Vehicle generator according to claim 7, characterized in that an inductance ( 18 ) is provided, which can generate a counter-excitation, the magnetic field of the permanent magnet ( 18 ) weakens. Vehicle generator according to claim 8, characterized in that the inductance ( 18 ) via an additional supply path ( 6 ) is connected to a supply potential (B +). Vehicle generator according to one of claims 7 to 9, characterized in that in the supply path ( 16 ) of inductance ( 18 ) a Zener diode ( 19 ) is provided. Vehicle generator according to claim 1 or 2, characterized in that the generator ( 1 ) an additional inductance ( 18 ) comprising the magnetic field of the excitation winding ( 5 ) weakens. Vehicle generator according to claim 11, characterized in that the inductance ( 18 ) via an additional connection (DFn) with a control unit ( 2 ) connected is. Automotive alternator according to claim 11 or 12, characterized in that the (by the inductance 18 ) flowing power from a controller ( 2 ) is controlled. Vehicle generator according to claim 2, characterized in that in the additional supply path ( 16 ) a resistor ( 22 ) is arranged. Vehicle generator according to claim 2, characterized in that the additional supply path ( 16 ) via the ignition lock ( 14 ) of the vehicle is guided. Vehicle generator according to one of the preceding claims, characterized in that the ground terminal of the excitation winding ( 5 ) via a ball bearing ( 8th ) with the ground connection of the rectifier ( 9 ) connected and connected to ground.

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