DE4404684C1 - IC engine ignition testing - Google Patents

Abstract

A test procedure for examining an ignition system of an IC engine in which to indicate correct functioning of the ignition unit, a conversion element for converting electrical energy into light is used and in which the electrical energy of the ignition system is tapped off in a contactless manner. Using quick and simple information indicates whether or not the ignition unit is operating correctly, and at least one (first) semiconductor light-emitting diode (LED) (14) is used as the energy conversion element, with a search coil (10) shunting the LED (14) as a contactless energy supply device.

Description

The invention relates to a method with the features of the preamble of claim 1 and a device for Execution of the procedure.

DE 28 08 468 A1 describes a generic method known after the proper high voltage supplier Ignition system of an internal combustion engine without strangers gie can be checked by fixing a test electrode on an externally insulated ignition current capacitively connect the test electrode to the ignition current conductor is coupled, and over at least one diode path capacitive at the test electrode due to ignition voltage carried ignition test charge in a functioning as an integrator Capacitor stored and one of the storage capacitor parallel gas discharge lamp is supplied, so that the gas discharge lamp in rhythm with the high voltage pulses with a brightness proportional to the ignition voltage flashes. Accordingly, the test is disclosed there advises to set up.

However, the aforementioned method or test device has several  Disadvantage. For one thing, a test electrode must be on a high voltage cables can be fixed as the Hellig gas discharge not only from the amount of high voltage depends, but also on the feasible Kopp capacity. On the one hand, this measure is time-consuming dig. On the other hand, it carries along with modern vehicles shielded ignition power cables not to the target because of their Shielding coat lies on ground. The same limitation but is also effective with unshielded ignition cables, if this z. B. are very dirty and damp and a conductive moisture film on the outer jacket of the Ignition cable the required electrostatic field training dung disturbs. The ignition voltage is also the gas discharge lamp higher than its operating voltage, so that it even if the test elec trode on the ignition cable a pronounced "dead area" for gives the ignition voltage in which no information is obtained can be. Finally, at high engine revs regular flashing ability may be restricted, if e.g. B. the capacitor is no longer open or is unloadable. In this regard, one is playing reproducible way of attaching the test electrode to the Cable in accordance with the capacity of the storage con a crucial role. An information there over whether z. B. a suspected misfire by an ent speaking incorrect current supply to the primary winding of the ignition coil cannot be won.

Methods are also known according to which a probe, which is coupled to an ignition cable of a motor vehicle and - as soon as a high voltage pulse flows through the ignition cable - a measurement signal by either inductive or capacitive means is produced. The measurement signal is then from an im or test device located outside the vehicle  evaluates, as exemplified in DE 42 10 051 A1, the DE 23 56 440 A1 and US 3,828,256. To the above disadvantages mentioned here comes the further disadvantage of required use of external energy.

The invention has for its object a generic Propose a procedure that avoids the above Share it quickly and easily in the workshop Indicates whether the ignition system of an internal combustion engine is working properly works properly. In particular, it should be easily recognizable make misfires or combustion irregularities towards insufficient magnetization of the ignition coil are to be returned.

This task is accomplished by a generic method the characterizing features of claim 1 solved.

The method according to the invention provides that, per se, is unimportant wanted, but usually always a leak magnetic field of ignition coils as well as very low at low forward voltage to exploit the power requirements of semiconductor light-emitting diodes in order to such a light emitting diode by means of a stray field antenna acting search inductance from the leakage magnetic field of the Ignition coil on an inductive way with energy for light emission sion to supply.

On the one hand, this gives rise to magnetic leakage induction based test methods the above mentioned dirt and Moisture problems entirely eliminated. Because of the very quick response and lack of one of the ignition hysts rese of gas discharge lamps corresponding hysteresis of / at Light-emitting diodes, on the other hand, conduct every single magnetic reversal the ignition coil in a wide range of energization of the ignition coil for a safe response of the light emitting diode  dependent on speed or ignition sequence frequency. Irregularity or inadequacies in the magnetization of the ignition coil (Ultimately, the prerequisite for a proper ge Ignitable voltage is) are based on the corresponding Un regularity (non-periodicity) or atypical weakness of the The LED flashes quickly and reliably.

Finally, it is particularly advantageous that the method for checking ignition systems with ignition coils of any construction art (single spark, double spark ignition coils and single ignition coil with distributor) and that based on a appropriately designed device using this procedure rens also the measurement of the closing angle, burning time and Engine speed can be simplified.

Advantageous further developments of the method are based on teaching of dependent claims 2 to 14.

Another object of the invention is to provide a harsh workshop operation easy-to-use device to propose to carry out the procedure as pas sive diagnostic tool is small and robust.

This task is characterized by a device ning features of claim 15 solved. Advantageous te further development of this device are according to the teaching of dependent claims 16 to 22 given.

A device designed in this way impresses with simplicity their structure and their application as well as their costs Favorable manufacturability from a common standard component, such as an inductive speed or position giver. If the device is used properly, the workshop can time saved and also the appearance  ignition damage-related repair damage, such as damage Damage to the catalytic converter due to unburned emissions fuel, can be prevented.

Further details and advantages of the method and example more device go from the drawing and its itself here subsequent description; there is the description preceded the device. Show it

Fig. 1a to 1k several switching schemes Vorrich lines according to the invention;

Fig. 2 is a longitudinal sectional diagram of an exemplary rotationally symmetrical device with only one light-emitting diode and permanently integrated permanent magnet according to Fig. 1d;

Fig. 3 is a schematic representation of a Vorrich device in the test operation according to the method.

Without restricting generality, FIG. 1a illustrates the circuit diagram of the simplest embodiment of a device according to the invention, while FIGS . 1b to 1k relate to circuit diagrams of various advantageous further developments.

According to Fig. 1a, the device comprises at least one coil Induk tion with an open field guide. This can advantageously have a core 11 which supports the open field guidance and is made of magnetically conductive material. These parts can be part of a commonly used inductive sensor 20 'within the scope of the invention. This also applies to all the training shown in Fig. 1b to 1i. A semiconductor light-emitting diode is connected to the connections 13.1 and 13.2 of the induction coil - normally connected to contacting means in such an encoder.

The development according to FIG. 1b provides a current valve connected antiparallel to the light-emitting diode, for example in the form of a (non-illuminating) normal diode. This measure protects the light emitting diode under conditions that would result in high reverse voltage peaks on the light emitting diode, which could destroy the light emitting diode.

In Fig. 1c, the anti-parallel normal diode 15 is replaced by a second light emitting diode 14.2 , which is connected anti-parallel to a first light emitting diode. According to the invention, the two light-emitting diodes can generate light of the same color or of different colors when passing current.

Based on an approximately the same electro optical conversion efficiency can differ from different brightnesses rapid ge of the magnetic field during its assembly and disassembly be closed.

The training according to FIG. 1d further provides for a permanent magnet, such as that used for. B. in rotary position and speed sensors is already combined with an inductor so that it is acted upon by a magnetic quiescent flux which can be changed by a magnetic conductance change in the magnetic external field. For example, with this configuration, the switching off of the primary ignition coil current can be made optically recognizable by the lighting up of the light diode at a fixed location in an ignition coil.

With the same winding sense and the same permanent magnetic flow direction, the exemplary embodiment according to FIG. 1e differs from that according to FIG. 1d only by an opposite polarity of the light-emitting diode 14 . With the configuration so modified compared to FIG. 1d, the activation of the primary ignition coil current can be made optically recognizable by the lighting up of the light diode at the same fixed location.

In addition, permanent premagnetization of the magnetic route of the induction coil still other before parts offer as follows. Corresponding permanent advance Typically, encoders are not designed for applications thought, where they have an externally caused extra mag netfeld be exposed as in the present case, because the magnetic flux source is deliberately in the transmitter relocated outside of the same to the assembly, befe No need to fix and adjust magnetic sources that can.

Depending on the direction of flow of such an external additional field in relation to the permanent quiescent field, the magnetically conductive core 11 can be magnetized more or less close to its saturation under the influence of an external field. This in turn has the consequence that with the devices according to FIGS . 1d and 1e under the same test conditions under different brightnesses of the light emitting diodes can be reached, depending on how the external flux is directed in relation to the flux of the permanent magnet or depending on whether the rise or fall of the external river is faster than its fall or rise. Appropriate assessment can be very helpful in practice, especially with electronic ignition systems that are suspected of being faulty.

The exemplary embodiment according to FIG. 1f combines both of the above-mentioned forms, in that a first light-emitting diode 14.1 or a second light-emitting diode 14.2 of the induction coil 10, which is polarized in the opposite direction, can be connected in parallel via a changeover switch 18 . By this measure, for. B. one and the same device for the aforementioned tests can be left in a test position once found, whereby test blurring due to repositioning errors of two different devices with different polarity LEDs are avoided.

The embodiment of FIG. 1g avoids the order switch 18 in that a permanent magnet 12 'is hen vorgese, which is reversibly arranged with respect to its magnetic coils flooding, so that its north and south poles can each swap their position. If, for example, a conventional inductive sensor with a permanent magnet is used in the manufacture of such a device, then designs with magnets arranged laterally or parallel to the coil body in the axial direction of the coil, which can be movably or pivotally mounted thereon, are particularly suitable for this purpose.

The embodiment of FIG. 1h with permanent magnet 12 otherwise corresponds to that according to FIG. 1c without permanent magnet. In this embodiment and its application to different colored diodes can be particularly advantageous. The one luminous color then corresponds, for example, to the induction of switching on and the other luminous color to the induction of switching off of the primary ignition coil current.

The exemplary embodiments according to FIGS . 1i and 1k include, in addition to the protective diode 15 already known from FIG. 1b, resistors 15 and 16 in different branches which, with suitable dimensioning, increase the risk of destruction of the at least one light-emitting diode 14 even in the event of inadvertently excessive or exclude impermissibly high inductive disposition.

FIG. 2 uses a schematic section to illustrate the structure of a simple exemplary embodiment of the device.

It was produced from an inductive position transmitter that was originally approximately spark plug-shaped. In the housing 20, which is preferably made of plastic, a sleeve body 18 formed of insulating material is mounted, which is formed at one end as a receiving sleeve for a bar magnet 12 and at its other end as an insertion sleeve for a light-emitting diode 14 .

The magnet 12 is axially upstream of a soft magnetic coil core 11 in the tubular housing 20 , the latter of which carries a coil winding 10 surrounding it.

The coil core 11 either extends directly to the end face 20.1 of the tubular Ge housing 20 or passes through a corresponding bore in the end face 20.1 from the housing 20 , as exemplified here.

The magnet body 12 holding sleeve body 18 has axially extending bores or externally two axially extending de slots, in which the two ends 13 a and 13 b of the coil winding away from this and in the direction of extension of the magnet 12 are guided past this isolated. The insertion sleeve end, at the base of which the two Spulenan connections emerge from the aforementioned bores or slots, has here, for example, two diametrically opposite incisions 18.1 in the axial direction.

Through the slots formed in this way, the two ends of the coil winding are guided, for example, radially outward (or - as far as far into outside slots in the sleeve body 18 - inward), and in the same way the connections 14.1 and 14.2 of the light-emitting diode 14 are outward performed and, for example, within the slot solution each galvanically connected to one another, for example by welding, so that the light-emitting diode 14 is stored in the axial direction in the insertion sleeve as defined by the depth of the two cuts and remains in the last manufacturing step if the rubber-elastic insulating sleeve 19 with its one annular bulge 20.3 of the housing 20 engaging behind one end 19.1 and one of the light-emitting diodes 14 passing through or a possibility of viewing another end 19.2 via the light-emitting diode 14 and the part of the insulating body 18 projecting from the housing 20 onto the housing 20 postponed or - is pressed.

It goes without saying that in a similar "wiring technology" also other circuits according to Fig. 1b to 1k are feasible if more than two and different depth incisions in the sleeve end of the sleeve body 18 for storage and contacting corresponding components are seen before. In the case of two light-emitting diodes, these can also be arranged rotated by 90 ° for the purpose of radial radiation, so that they are e.g. B. can be observed through a side window in the spout 19 . The free space in this grommet can be sprayed with crystal-clear to translucent silicone rubber and any components embedded in it and (at least) the injection opening and / or the injection opening required by injection technology, in which the silicone rubber is then superficially exposed, can serve as a viewing window.

Fig. 3 illustrates a device 1 according to the invention when used according to the method in the vicinity of an ignition coil 2nd

The inventive method for checking the ignition system of an internal combustion engine provides that an induction coil - hereinafter also called a search coil - from which at least one semiconductor light-emitting diode can be supplied with electrical energy, with the internal combustion engine approaching the ignition coil and with a change in orientation 3 in the sense of the arrows in Fig. 3 around the ignition coil that in the case of the at least one light-emitting diode lighting up, the search coil is approximated and oriented to the ignition coil in such a way that it lights up in the ignition cycle in accordance with a relevant experience value for the brightness , and that from the light emission and its chronological sequence ge the absence of defects or deficiency of the ignition system is concluded.

If the at least one light-emitting diode ( 14 , 14.1 ) is not illuminated in any position of the search coil with respect to the ignition coil while the internal combustion engine is running, the method is terminated in this step.

For a first (rough) assessment, the placement and orientation of the search coil are made such that the (at least one) LED in the ignition cycle maxi lights up brightly.  

Then the distance can be scanned again such a degree that the brightness lighting up to what is necessary for recognizability Dimension is reduced so that a regular and constant light or irregular and / or differently hel The lighting of the LED (s) is particularly true becomes acceptable.

Part of the process is that the little Mostly a light emitting diode and the search coil on small Connected space and handled one body bar apply.

According to the method, the field sensitivity of the search coil 10 can also be increased in that it is equipped with a magnetic preferred path in the form of a magnetically conductive coil core 11 , which can also be permanently magnetized according to a further process development.

In a further refinement, the method provides that the polarization or intensity, or alternatively both, of the permanent magnetization of the coil core is / are changed and on the basis of the observable light emission of the at least with opposite polarization and / or differently strong magnetization of the coil core a light-emitting diode 14 or 14.1, the ignition system is assessed.

The nature of the coil core 11 can be matched to the nature of a permanent magnet 12 causing the premagnetization that the coil core 11 is magnetized under predetermined test conditions close to the ignition coil more or less strongly to saturation and on the basis of the observable light emission the at least one light-emitting diode 14 or 14.1 is an assessment of the ignition system.

The method according to the invention further comprises that a second light-emitting diode 14.2 with opposite polarity is either connected alternately with the first one to the search coil or else the first light-emitting diode 14.1 is connected in parallel at least indirectly in opposite poles and an assessment is made on the basis of the alternating light emission of the light-emitting diodes the ignition system. Under certain conditions, the relative increase or decrease in the ignition coil current can be inferred from corresponding brightness comparisons.

According to the method, light-emitting diodes 14.1 and 14.2 with different luminous colors can also be used, and the ignition system can be assessed on the basis of the different-colored light emissions of the light-emitting diodes.

Finally, the method also includes, for assessing the rise and fall of the magnetizing current of the ignition coil, two separate single-body devices, each comprising at least one search coil 10 and a light emitting diode 14 or 14.1 , which differ only in the polarity of the connection of the light emitting diode contained therein.

Finally, a corresponding one, through a magnet Premagnetized device according to the process without foreign This checks the energy requirement for proper function  that they are attached to a magnetizable material and subtracted again, depending on the polarity of the light diode (s) related to bias polarization the light-emitting diode (s) either when putting on or removing lights up / light up.

Claims (24)

1. A method for checking the ignition system of an internal combustion engine, in which an element converting electrical energy into light is used to display the proper functioning of the ignition system and wherein said electrical energy is removed from the ignition system without contact, characterized in that

• - That as electrical energy into light converting element at least one (first) semiconductor light-emitting diode ( 14 , 14.1 ) and as contactless energy supply means one of the at least one semiconductor light-emitting diode least least indirectly connected search coil ( 10 ) is used ver,
• - That the search coil is approached to the ignition coil while the internal combustion engine is running and is guided around the ignition coil while changing the orientation thereof,
• - That in the event that the at least one light-emitting diode ( 14 , 14.1 ) is not illuminated, the method is stopped in any position of the search coil;
• - That in the case of lighting up of the at least one light-emitting diode, the search coil is approximated and oriented to the ignition coil in such a way that the at least one light-emitting diode lights up in the ignition cycle in accordance with an experience value gained for the brightness, and
• - That from the light emission and their temporal sequence from the defectiveness or lack of defects of the ignition system is concluded.

2. The method according to claim 1, characterized in that

• - That (the at least one) light-emitting diode and the search coil are connected to each other in a small space and can be used easily.

3. The method according to claim 1, characterized in

• - That from the light emission and the requisite placement of the search coil in the vicinity of the ignition coil in particular on the defectiveness or lack of freedom of the ignition coil is concluded.

4. The method according to claim 1, characterized in

• - That for a first assessment the placement and orientation of the search coil is made such that the (at least one) light-emitting diode lights up brightly in the ignition cycle.

5. The method according to claim 4, characterized in

• - That the distance is then increased again to such a degree that the brightness of the lighting of the (at least one) light-emitting diode ( 14 , 14.1 ) is reduced to the extent necessary for recognizability, and at least one further assessment is then made.

6. The method according to claim 1, characterized in

• - That the search coil ( 10 ) supported by a magical preferred path in the form of a magnetically conductive coil core ( 11 ) is used.

7. The method according to claim 6, characterized in

• - That the magnetically conductive coil core ( 11 ) is permanently magnetized ( 12 ).

8. The method according to claim 7, characterized in that

• - That the polarization and / or intensity of the permanent bias of the coil core is / are changed and on the basis of the observable with opposite polarization and / or different degrees of bias of the coil core light emission of the at least one light-emitting diode ( 14 , 14.1 ), an assessment of the ignition system.

9. The method according to claim 8, characterized in

• - That the nature of the coil core ( 11 ) is matched to the nature of a permanent magnet causing the premagnetization ( 12 ) that the coil core under predetermined test conditions close to the ignition coil is more or less magnetizable to saturation and on the basis of what can be observed Light emission of the at least one light-emitting diode ( 14 , 14.1 ) takes place in the ignition system.

10. The method according to claim 1, characterized in

• - That a second light-emitting diode ( 14.2 ) with opposite polarity is alternately connected to the search coil and based on the alternating light emission of the two light-emitting diodes, the ignition system is assessed.

11. The method according to claim 1, characterized in

• - That a second light-emitting diode ( 14.2 ) with opposite polarity of the first light-emitting diode ( 14.1 ) is at least indirectly connected in parallel with the opposite polarity and an assessment of the ignition system takes place on the basis of the light emission of both light-emitting diodes.

12. The method according to any one of claims 7 to 11, characterized in that

• - That from corresponding brightness comparisons to the relative rise or fall of the ignition coil current is concluded.

13. The method according to any one of claims 10 and 11, characterized in

• - That light-emitting diodes ( 14.1 and 14.2 ) are used with different luminous colors and on the basis of the different colored lighting phenomena of the light-emitting diodes, the ignition system is assessed.

14. The method according to claim 2, characterized in that

• - That to assess the rise and fall of the magnetizing current of the ignition coil two single-body devices are used, which differ only in the connection polarity of the (at least one) light-emitting diode.

15. The method according to claim 7, characterized in

• - That for the purpose of checking the proper function of an external energy device to perform the method before seen the same device for the purpose of stimulating the light-emitting diode to a magnetizable material and is then pulled off again.

16. Device for carrying out the method according to claim 1, characterized in that

• - that it includes at least:
• - A search coil ( 10 ) protected by an outer sheath ( 20 ), which is at least part of a conventional inductive transmitter as is usual for position or speed measurements;
• - A semiconductor light-emitting diode ( 14 , 14.1 ) connected to the search coil;
• - Insulating cover means ( 19 ) that fix the light emitting de near the search coil ( 10 ) and thus both components of the device Be the form of an easily manageable piece.

17. The apparatus according to claim 16, characterized in

• - That the light emitting diode ( 14 ) at least one normal semiconductor diode ( 15 ) is connected antiparallel.

18. The apparatus according to claim 16, characterized in

• - That the light emitting diode ( 14.1 ) another light emitting diode ( 14.2 ) is connected antiparallel.

19. The apparatus according to claim 16, characterized in

• - That the search coil ( 10 ) has a magnetically conductive core ( 11 ).

20. The apparatus according to claim 19, characterized in

• - That it comprises a permanent magnet ( 12 ), which cher the magnetically conductive core ( 11 ) is pre-magnetized.

21. The apparatus according to claim 20, characterized in

• - That the permanent magnet ( 12 ) on / in the device with respect to its magnetic flow through the search coil ( 10 ) is variable, in particular reversible, displaceable or rotatably mounted.

22. The apparatus according to claim 16, characterized in

• - That it also comprises at least one resistor which is connected upstream of the at least one light-emitting diode ( 14 , 14.1 ).

23. The device according to claim 20, characterized in that

• - That it comprises an insulating sleeve body ( 18 ), in one end of which the permanent magnet ( 12 ) and in the other end the at least one light-emitting diode ( 14 ; 14.1 ) is supported GE.

24. The device according to claim 16, characterized in that

• - That cavities within the insulating cover are sprayed with a translucent silicone rubber which is exposed at least within a predetermined range for the purpose of light emission.