EP2249025A2 - Method for determining the heating characteristics and the type of a glow plug - Google Patents

Abstract

To determine the heating characteristics and type of a heater plug, for diesel motors, a pulse width modulated voltage pulse is applied to it. During the pulse, an electrical value is measured repeatedly and the difference between successive measurements is evaluated to give the heating characteristic. The difference is compared with stored parameters, to give the heater plug type.

Description

description

The invention relates to a method for determining the heating characteristic of a glow plug having the features specified in the preamble of claim 1. Such a method is from the DE 10 2006 010 194 A1 known.

For diesel engines, a variety of different glow plug types is currently known, each differing in their heating characteristics. The currently used glow plug types can be roughly divided into ceramic glow plugs and metallic glow plugs. However, there are not only significant differences between ceramic glow plugs and metallic glow plugs, but also, for example, between ceramic glow plugs of different manufacturers and even between different types, ie models, ceramic glow plugs from the same manufacturer.

However, for efficient glow plug control, the heating characteristics of the glow plug used must be known. It is therefore desirable to be able to automatically determine the type of glow plug used in order to be able to realize a glow plug operation optimally matched to the heating characteristics of the glow plug used.

From the DE 10 2006 010 194 A1 For example, a method of detecting the type of glow plug is known, in which electrical quantities, for example the resistance, the gradient of the resistance or the inductance, measured and determined by comparison with stored parameter sets, each representing a specific type of glow plug, the type of glow plug used.

Although it is possible with the known method to distinguish metallic and ceramic glow plugs from one another. However, to distinguish between ceramic glow plugs of different types, ie different models of the same or different manufacturers, the known method is not suitable.

Object of the present invention is therefore to show a way how the heating characteristics of a glow plug can be determined more precisely, so that ceramic glow plugs of different types can be distinguished from each other.

This object is achieved by a method having the features specified in claim 1. Advantageous developments of the inventions are the subject of dependent claims.

By several times, preferably at the beginning and end of the voltage pulse during a voltage pulse, an electrical variable, for example, the resistance is measured, the heating characteristic of a glow plug can be determined much more precise than this example by a simple gradient by means of the difference of successive measurement results of this size during the heating phase of the glow plug, as for example from the DE 10 2006 010 194 A1 is known, would be possible. In fact, a simple gradient formation assumes that the temperature rise of a glow plug is steady takes place and accordingly the gradient of a temperature-dependent electrical variable reflects the heating characteristics of a glow plug.

Surprisingly, much more precise results can be achieved by giving up this seemingly plausible assumption. In fact, glow plugs can cool noticeably between the individual voltage pulses. By measuring an electrical quantity several times, in particular at the beginning and at the end of a voltage pulse, and forming the difference between two successive measurement results of this size, a much more precise statement can be made and the type of candle can therefore be determined even if only between the candle types minor differences exist.

A measurement result can be determined from several individual measurements, for example 2 to 5, in rapid succession, which via a filter function such. B. averaging, are summarized. The time interval between the first and the last measurement of such a sequence should preferably not be more than 1/10, particularly preferably not more than 1/50 of the pulse duration or the time interval of the combined measurement results. This procedure can reduce the influence of random noise and thus increase the accuracy of the evaluation.

In the method according to the invention, the difference to be evaluated can be calculated in each case between a measurement result determined for the beginning of a voltage pulse and a measurement result determined for the end of the voltage pulse. In this way, the heating behavior of a glow plug can be determined precisely and the type of candle can be determined. Alternatively or additionally, it is also possible to calculate the difference between a measurement result determined for the end of a voltage pulse and a voltage result determined for the beginning of a subsequent voltage pulse. In this way, the cooling behavior of a glow plug, which is also characteristic of the type of glow plug and thus also for the heating behavior, can be reliably determined.

In principle, the heating characteristic of a glow plug can be determined by evaluating a single difference value. However, several difference values are preferred determined and evaluated. For example, the difference between a measurement result determined for the beginning of a voltage pulse and a voltage pulse determined at the end of the voltage pulse can be calculated for a plurality of pulses, and an arithmetic mean can be formed from these difference values and evaluated. In this way, the precision of the evaluation can be improved.

An advantageous development of the invention provides that, in the evaluation, the difference is divided by a quantity correlated with the energy input during a voltage pulse. In this way, the difference is thus divided by a quantity which correlates with the energy input between the relevant for the two measurement results times. The size correlated with the energy input can be, for example, the pulse duration, the current intensity or the vehicle electrical system voltage. It is also possible, in particular, to use functions correlated with the energy input, in particular products, of the aforementioned sizes. In particular, the size correlated with the energy input can also be the energy input itself. The greater the correlation between the magnitude correlated with the energy input during the voltage pulse and the energy input, the greater the increase in the accuracy of the evaluation achieved by the division.

The variable measured in a method according to the invention is preferably the electrical resistance of the glow plug. In principle, however, it is also possible to measure another temperature-dependent electrical variable at a glow plug, for example the inductance, capacitance or a resonance frequency.

Preferably, with a method according to the invention, the heating characteristic of a glow plug is determined by determining the type of glow plug. In general, it can be assumed that the heating characteristics of different glow plugs of the same type differ at best negligibly. In principle, however, a possible aging influence on the heating characteristic of a glow plug can also be determined by the method according to the invention, so that it is even possible to distinguish between new and old glow plugs of the same type.

In particular, a glow plug type identification can also take place in a glow plug type identification phase which is connected upstream of the normal annealing cycle. The precision The evaluation by means of the method described here can be further increased by such a phase by the phase is chosen such that the mutual influence of the Glühkerzenbestromung is reduced. This can be z. B. be achieved in that the glow plugs are operated with a fixed pulse duration and the pulse duration is chosen such that no other glow plugs on or off during a pulse of a glow plug.

The present invention further relates to a control device for glow plugs, which has a memory in which a program is stored, which executes a method according to any one of the preceding claims in operation. The memory of such a controller preferably includes parameter ranges which are typical for particular types of glow plugs. By comparing a parameter determined by a method according to the invention with the stored parameter ranges, a glow plug can thus be unambiguously assigned to a glow plug type and then driven with an optimum heating program for the particular type of candle.

Figur 1:

den Widerstandsverlauf zweier keramischer Glühkerzen unterschiedli- chen Typs bei einer Ausgangstemperatur von 25°C; und

Figur 2:

den Verlauf eines durch ein erfindungsgemäßes Verfahren gebildeten Parameters während der Aufheizphase für keramische Glühkerzen un- terschiedlichen Typs.

Further details and advantages of the invention will be explained with reference to an embodiment with reference to the accompanying drawings. Show it:

FIG. 1:

the resistance of two ceramic glow plugs of different types at an outlet temperature of 25 ° C; and

FIG. 2:

the course of a parameter formed by a method according to the invention during the heating phase for ceramic glow plugs of different types.

In FIG. 1 By way of example, the electrical resistance R in mΩ over the time t in milliseconds for two ceramic glow plugs type A and B during three voltage pulses of 12 V is given. The type A glow plug is a candle marketed by Bosch under the model designation GLP5, the type B glow plug is a candle sold by Beru under the model name CGP.

In FIG. 1 It can be seen that with the glow plugs of the two types A, B both the absolute values of the resistance and the increases of the resistance during a voltage pulse differ. On closer inspection, it can also be seen that the resistance value at the beginning of a pulse is slightly smaller than the resistance value at the end of the preceding pulse.

In order to be able to assign a given glow plug to a given glow plug type, at the beginning and at the end of at least one voltage pulse, an electrical variable, for example the resistance R, is measured and the difference of successive measurement results of this size is formed. In the simplest case, the electrical quantity is measured exactly twice during a voltage pulse. The knife values of the individual measurements are then the measurement results whose difference is formed. An increased accuracy can be achieved by several, for example 2 or 3, measurements being carried out shortly after one another at the beginning of a voltage pulse and a measurement result for the beginning of the voltage pulse being formed from the measured values thus obtained, for example by combining the individual measured values via a filter function such as z. B. averaging. In a corresponding manner, several measurements can be carried out shortly after one another at the end of a voltage pulse and a measurement result for the end of the voltage pulse can be formed from the measured values thus obtained

In FIG. 1 is the difference of the electrical resistance at the beginning and at the end of a voltage pulse marked as ΔR. To evaluate the difference, this is divided by the energy input made during the pulse. The energy input during a pulse is the product of pulse duration, current and voltage. However, for purposes of evaluation, the energy input can also be approximated, for example, by the product of pulse duration and current intensity, by assuming the voltage as approximately constant.

The energy input between two measurements can be done, for example, continuously by an integrator or by summation of individual time period. In particular, it is advantageous to calculate the energy from a linear interpolation of the voltage and current measured values at the measuring times.

FIG. 2 shows for various glow plugs of the types A and B the time course of the value of the thus formed quotient of the resistance change .DELTA.R during a pulse and during the pulse energy input E. The values of the individual glow plugs form clearly two distinct groups. A first group of values found on type A glow plugs is in the range of 1.5 and 2.5, a second group of values found on type B glow plugs is between about 5 and 7.5. The values of glow plugs of type A and B thus differ by about a factor of 3, which is significantly more than the dispersion of the values of individual glow plugs of the same type. FIG. 2 shows that the quotients described are characteristic of the glow plug types A and B, respectively, and thus can be used to assign a glow plug to a particular type. The method according to the invention thus makes it possible to reliably detect the type of glow plug.

Surprisingly, the time course of the values within the scope of the measurement accuracy is almost constant. Since the glow plugs heat up as the time progresses due to current pulses, the approximately constant course means that the value of the quotient is approximately temperature-independent. This is an important advantage since, in the application of the method, the initial temperature does not matter. The method can thus be used in a cold glow plug, which may have a temperature between -30 ° C and + 40 ° C, depending on the weather conditions, as well as a warm glow plug, which may have a temperature of several hundred degrees due to a previous engine operation become.

In principle, the type of a given glow plug can already be determined on a single value, which was determined for a single current pulse. However, the reliability of the assignment can be improved if the evaluation is based on several values. For example, a function may be calculated that depends on the differences between adjacent values of a series of measurement results of a variable measured at the beginning and end of a voltage pulse, respectively. In particular, the arithmetic mean of a sequence of parameters calculated by evaluating the difference between successive measurement results of an electrical quantity can be calculated.

For metrological reasons are in FIG. 2 no values are shown for the first two current pulses. Already from the third current pulse, a clear difference can be seen between the values of glow plugs of type A and type B, the value of the quotients being almost constant. As already mentioned, this means that, with the described method, glow plugs can be assigned to a specific type, regardless of their initial temperature. By such an assignment, the heating characteristics of a glow plug can be reliably determined. For example, heating characteristics of all common glow plug types can be stored in a memory of a control unit. In that a glow plug is assigned to a certain type of train, the control unit can control a glow plug after only a short time in an optimally matched to the heating behavior.

Advantageously, the method described can be determined by evaluating the difference between successive measurement results of an electrical variable, a parameter that is characteristic of the type of glow plug and in particular also allows the distinction between ceramic glow plugs of different types. By comparing the parameter to be determined with predetermined parameter ranges, therefore, the glow plug type of a given glow plug can be determined.

The duration of the current pulses is insignificant for the inventive method per se. In particular, the parameter determined according to the invention, which is used for the determination of the candle type, is largely independent of the pulse duration, so that the pulse duration can be changed during the determination of the candle type. Typically, the pulse duration is between 5 ms and 120 ms.

The described method can be carried out with a glow plug controller having a memory in which a program is stored which executes such a method in operation. Such a control device can be designed in terms of its hardware components as conventional control devices and are characterized only by its memory content. In addition to software implementing the above-described method of detecting a glow plug type, the memory preferably contains different parameter ranges with which a parameter determined by the method according to the invention is compared. The individual parameter ranges are each characteristic of certain glow plug types, so that a glow plug can be unambiguously assigned to a specific type by comparison with the parameter ranges.

In addition, various heating routines or control variables, for example a desired value for the effective voltage after reaching an optimum operating temperature, can be stored in the memory of the Glühsteuergeräts. In this way, after carrying out the method according to the invention, a glow plug can always be activated with an optimum program for the heating characteristic of the respective type of glow plug. Furthermore, a control routine or control variables which are used when the parameters determined for a glow plug do not permit assignment to a known type are also preferably stored in the memory. This case can occur, for example, when glow plug types come on the market, which were not yet known in the manufacture or programming of the controller.

Claims (13)

A method for determining the heating characteristics of a glow plug, wherein the glow plug pulse width modulated voltage pulses are applied, characterized in that during a voltage pulse several times measured an electrical variable and the evaluation of the difference of successive measurement results of this size, the heating characteristic of the glow plug is determined. A method according to claim 1, characterized in that the electrical quantity at the beginning and at the end of a voltage pulse is measured in order to determine two successive measurement results of the electrical quantity. Method according to one of the preceding claims, characterized in that in the evaluation, the difference is divided by a correlated with the energy input during a voltage pulse magnitude. A method according to claim 3, characterized in that the correlated with the energy input size is the pulse duration. A method according to claim 3, characterized in that the correlated with the energy input variable is the current intensity. A method according to claim 3, characterized in that the correlated with the energy input size is the vehicle electrical system voltage. Method according to one of claims 3 to 6, characterized in that the correlated with the energy input size of the energy input itself. Method according to one of the preceding claims, characterized in that the measured electrical magnitude is the electric resistance. Method according to one of the preceding claims, characterized in that the measurement results are determined in each case by a plurality of measurements. Method according to one of the preceding claims, characterized in that, in the case of a plurality of voltage pulses, respectively two measurement results of the electrical quantity are determined, a plurality of difference values between successive measurement results are formed and evaluated. A method according to claim 10, characterized in that an average of a plurality of difference values is evaluated. Method according to one of the preceding claims, characterized in that in the evaluation, the difference or a variable calculated therefrom with stored parameter values, each representing a particular Glühkerzentyp with a known heating characteristic compared, and thus the Glühkerzentyp and the heating characteristics of the glow plug are determined. Control unit for glow plugs, characterized in that the control device has a memory in which a program is stored, which executes a method according to any one of the preceding claims in operation.

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