Patent Grant
8272360
The present invention relates to a diagnostic device for the starter of a combustion engine.
The starting of combustion engines, whether they have applied spark ignition, direct injection or self-ignition, depends on the availability of the starter. The performance of the starter is a function of the size of the vehicle's battery, among other things. The thermal stress of the parts having current flowing through them, and the mechanical load of the parts transmitting the torque, increase with growing battery size. Although the starter is provided for only brief operating periods, one has to expect long cranking times of the combustion engines, especially at lower outside temperatures, and with that, a high thermal stress of the starter.
A starting device for internal combustion engines is described in published German patent document DE 198 10 954. The starting device for internal combustion engines includes a starter motor whose starter pinion is initially engaged with the ring gear of the internal combustion engine via a starter solenoid. After that, the starter motor is operated at maximum torque. Initially, the starter motor drives the pinion at reduced torque via a series resistor. At the same time, the starter solenoid for the starter pinion is pre-engaged at reduced engaging force, e.g., in a clocked manner, with the ring gear and engaged with it when this is indicated. After that, full power is supplied to the starter solenoid, so that the pinion is fully pressed into the ring gear and at the same time a switching contact of a relay, e.g., of the starter solenoid, bridges the series resistor of the starter motor. Now the starter motor is able to crank through the internal combustion engine at full torque.
Published German patent document DE 103 46 857 relates to a device for the protection of a starter line or a starter and generator line in a motor vehicle. The device includes a starter battery, a starter and a starter and generator line or a starter line connecting the starter to the starter battery, a battery disconnect switch being provided in the starter and generator line to which a switch control signal is supplied by a control and regulating unit. The control and regulating unit determines a switch control signal that opens the battery disconnect switch by the evaluation of the measured battery current. In the control and regulating unit, the evaluation of the measured battery current is undertaken while taking into consideration a stored protection characteristics line for the battery current. The stored protection characteristics line includes information about the response of further protection elements of the electrical system of a motor vehicle.
Battery state detection devices are known, within the scope of a motor vehicle electrical system monitoring, in which a metrological recording of electrical quantities and temperatures takes place, using subsequent evaluation by appropriate algorithms for the battery state detection device. Conventional starters of combustion engines are generally designed as DC motors, which are interconnected to the battery via a relay.
Using the software integration proposed according to the present invention for a supplementary starter detection in an engine control unit that is already present, or in a vehicle electrical system state detection device, a sensor system that is already assigned to a motor vehicle battery may be utilized, on the one hand, and on the other hand, the functionality of the control unit that is already present or the vehicle electrical system state detection device that is present is able to be broadened to a considerable degree for a starter diagnosis. As a component subject to wear, the starter is very important with regard to starting reliability, and with that, with regard to the vehicle's availability. Instead of assigning the extended functionality to the starter, one may integrate the starter diagnosis directly into a vehicle electrical system state detection device, which makes it possible to utilize the components that are already present there for the starter diagnosis, so as to avoid a costly and thereby a cost-intensive redundancy.
Because of a starter diagnosis that is integrated into the vehicle electrical system state detection device or that is to be integrated into an engine control unit that is already present, the starter operation may be monitored at each application, and impending malfunctions, e.g., because of excessively long cranking phases, excessively great temperature stress or component wear, may be detected at an early time. Within the scope of currently usual fault storage readout measures within the framework of vehicle inspections, the data that are read out are able to be read out with respect to the mechanical wear of the starter components as well as its temperature stress, as seen over the operating time of the starter, and preventive maintenance measures may be undertaken on the starter of the combustion engine, so that one may guard against failure of this absolutely essential electrical component in vehicles for starting a combustion engine, in a farsighted manner.
Within the starter diagnosis provided according to the present invention, the starting current of the starter is monitored as the meaningful input variable that can be derived from the battery current of the motor vehicle's battery. The voltage of the motor vehicle's battery may be used as additional information. In the vehicle electrical system state detection devices that are already used these days, the battery current during the starting procedure of a combustion engine is already ascertained at a resolution in the millisecond range, so that the corresponding information may also be drawn upon within the scope of a starter diagnosis.
In the illustration shown
Reference numeral 11 designates a load distributor for the electric loads respectively present in the vehicle electrical system; Vi symbolizes, in a representative way, a plurality of electrical users in the vehicle electrical system, such as windshield wiper motors, electrical window lifters, electrical seat adjustment drives and the like.
Vehicle electrical system state detection device 10 includes a plurality of hardware components identified by reference numeral 12 and software 13. In addition, an electrical energy management 14 is integrated into vehicle electrical system state detection device 10, which controls load distributor 11 with regard to a respective current maximum load of the vehicle electrical system of a motor vehicle. In vehicle electrical system state detection device 10 according to the illustration in
In the illustration according to
In battery state detection device 16, which may be part of a vehicle electrical system state detection device 10, the value of the respective current 21 deliverable by vehicle battery 7 is ascertained within a current/voltage measurement. Battery state detection device 16 moreover includes algorithms, with the aid of which battery voltage 23 can be ascertained from battery current 21. Both value 21 for the battery current and value 23 for the respective battery voltage may be supplied to a starter diagnosis 15, which is able to be implemented as an additional functionality within the scope of a vehicle electrical system state detection device 10.
In the illustration according to
The individual steps shown in
An additional starting current comparison 33 for a second starting current threshold value (such as, for instance, approximately 1000 A) is post-connected to starting current comparison 30 for the first starting current threshold value of, for instance, 300 A. Within additional starting current comparison 33, the starting current of starter 5 is checked to see whether it exceeds a second threshold value, such as 1000 A. If this is detected to be so within the scope of the comparison carried out in additional starting current comparison 33, a corresponding fault flag 34 (battery too big, applied ignition start) is set, and the initiation of a second measure 35 is indicated. Second measure 35 may be constituted as switching off or making a maintenance recommendation. If starter 5 exceeds the second threshold value of, for instance, 1000 A, this may indicate that starter 5 is being operated using too great a voltage or batteries that are too big. There exists the danger of considerable consequential damage, for instance, by too great a starter rotary speed, for which starter 5 is not designed. Therefore, switching off starter 5 is appropriate. A reaction running in two stages is also possible, in which first a maintenance warning (check battery size) is set in response to the exceeding of a low threshold, for example, the named second threshold of 1000 A, and the switching off of the starter takes place in response to the exceeding of a higher threshold, such as 1200 A. In this case, starting the combustion engine using starter 5 is not possible.
Within the scope of starter diagnosis 15, a continuation is made from additional starting current comparison 33 to a frequency check of the starting current of starter 5. Within the scope of frequency check 36, the starting current of starter 5 is investigated to see whether it has high frequency components. In the positive case, a fault flag 37 is set, which points to the reaching of a wear boundary of starter 5. Powerful noise components in the frequency spectrum of starter 5, for example, point to excessive wear in the commutator system of starter 5.
A maintenance request (cf. reference numeral 38) may be set via a fault storage that can be read out during vehicle maintenance, and can be read out within the scope of an inspection by connecting a diagnostic plug of an engine control unit.
In a short circuit check 39 that is post-connected to frequency check 36 of the starting current of starter 5, the starting current of starter 5 is checked for the repeated occurrence of short circuit current peaks. In case those have occurred, a corresponding fault flag 40 (strongly low voltage in the vehicle electrical system of the motor vehicle or great overtemperature in the relay or even too high supply line resistances in the relay supply line or relay activation faults) is set. Repeated relay closing is taking place, which in the long run can lead to the occurrence of a short circuit; accordingly, switching off starter 5 is indicated for this fault case. The high currents occurring in response to short circuits go along with a high thermal stress of the components of starter 5. These are able to reduce the service life of starter 5 in a not inconsiderable manner; accordingly, the introduction of a fourth measure 41 is undertaken, i.e., switching off starter 5 or a maintenance recommendation is indicated.
In a checking step 42, that is post-connected to the short circuit check, for the current amplitude of the starting current of starter 5, the current amplitude of the starting current of starter 5 is determined. If it turns out within the scope of this check that the current amplitude of the starting current is decreasing, a fault flag 43 is set (misuse, fleeing vehicle driving). The starter current is checked whether it is constantly above a certain, fourth threshold value of, for instance, 500 A, which indicates that, for instance, starter 5 is being operated with a gear engaged. This takes place, for example, during improper use of the motor vehicle. As a rule, after a certain time, the starter has to be shut off as a function of the current level of the starter current, in order to avoid inadmissible overheating and thus an inadmissible thermal overstressing of the starter components. After the setting of corresponding fault flag 43, a shutting off is also undertaken or a maintenance recommendation 44 is output.
After running through the checking of the starting current of starter 5, within the scope of starting current comparison 30, of additional starting current comparison 33, of frequency check 36 of the starting current, of short circuit check 39 of the starting current, as well as of the checking of the current amplitude of the starting current of starter 5, if a start 50 of combustion engine 1 has taken place, the run-out current of starter 5 is checked. This takes place within the scope of a threshold value comparison 51 of the run-out current of starter 5 for falling below a third threshold value (for instance, 100 A).
If the third threshold value (for instance, 100 A) for the run-out current of starter 5 is exceeded, a fault flag 52 indicating sluggishness of the starter is set, which points to sluggishness of the mechanical components, such as, for instance, shafts that have run dry, defective bearings and additional faults, which are able to result in sluggishness of starter 5. In this case, a sixth measure 53 is recommended which is transmitted to vehicle electrical system state detection device 10 or an engine control unit of combustion engine 1, and which is able to be read out within the scope of an inspection of the motor vehicle by connecting the diagnostic plug from the engine control unit.
Threshold value comparison 51 for the run-out current of starter 5 is followed by an additional run-out current comparison 54 having a fourth threshold-value for the run-out current of starter 5. If the run-out current of starter 5 remains below the fourth threshold value of, for instance, 0 to 10 A, the system concludes that there is a freewheeling defect and a corresponding fault flag 55 is set. In this case, the conclusion is that there is a defect of the freewheeling situated between the starter shaft and the starter pinion. The carrying out of an appropriate seventh measure 56 is reported to vehicle electrical system state detection device 10, which is able to be read out within the scope of a following inspection of the motor vehicle. The garage personnel is given information-on an impending defect of starter 5, in the area of its freewheeling, by the setting of fault flag 55, so that they may intervene in a targeted manner.
The shutoff current (starter 5 in the switched off state) of starter 5 is investigated, within the scope of a shutoff current comparison 57, as to whether it exceeds a fifth threshold value (0 Ampere). In this case, a fault flag 58 may be set which points to sticking relay contacts. In this case, battery disconnect switch 9, that is reflected in the representation according to
The threshold value checked within the scope of starting current comparison 30 is of an order of magnitude of 300 A, whereas the second threshold value of the starter current is selected, for instance, in a range of 1000 A. The third threshold value for the run-out current of starter 5 may be picked to be at 100 A, for example, while the fourth threshold value for the starter current may be fixed at a value between 0 A and 10 A. The fifth threshold value that is used for checking the shutoff current may be at 0 A, for example.
When we speak above of switching off starter 5, what is understood by this is the interruption of the starting process of the combustion engine. This is indicated when either no starting process is possible or when heavy damage is to be expected if the starting process is nevertheless carried out under the detected states that were described above in detail.
Within the scope of the starter functionality, one investigates both for sluggishness 52 of the mechanical components of starter 5 and for a fault in freewheeling, which is detected by fault flag 55 for “freewheeling defect”. The results of the sluggishness indicated by fault flag 52 and the freewheeling defect indicated by fault flag 55 differ substantially from each other with regard to direction and effects. The direction and the action of the faults are opposite to each other, and accordingly they are recorded separately in the above-described starter functionality of the on-board diagnosis.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2004 031 306 | Jun 2004 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP2005/052093 | 5/10/2005 | WO | 00 | 5/7/2009 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2006/000496 | 1/5/2006 | WO | A |
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|---|---|---|---|
| 5512883 | Lane, Jr. | Apr 1996 | A |
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| 7312968 | Kahara et al. | Dec 2007 | B2 |
| 7774110 | Sago | Aug 2010 | B2 |
| 7791310 | Luz et al. | Sep 2010 | B2 |
| 20010038274 | Peter | Nov 2001 | A1 |
| 20040124870 | Raichle | Jul 2004 | A1 |
| Number | Date | Country |
|---|---|---|
| 41 32 533 | Apr 1993 | DE |
| 43 26 527 | Feb 1995 | DE |
| 198 10 954 | Sep 1999 | DE |
| 199 58 098 | Jun 2001 | DE |
| 103 46 857 | May 2005 | DE |
| 1 103 427 | May 2001 | EP |
| Number | Date | Country | |
|---|---|---|---|
| 20090217897 A1 | Sep 2009 | US |
