DE10156037A1 - Method for monitoring operation of heater element of motor vehicle interior heater based on comparing actual resistance of heater elements against known resistance temperature characteristic - Google Patents

Abstract

When in use the heater currents and voltage drops across a heater element or individual groups of elements are constantly measured. From the actual resistance (Raktuell) the heater controller derives the temperature (F1) from a known resistance/temperature characteristic. The controller identifies from the measurements during the warming up cycle whether the resistance value is on the falling (16) or rising (18) flanks of the characteristic. From a knowledge of typical values of the minimum resistance value (Rmin) the controller determines whether or not the heater is defective.

Description

The invention relates to a method for monitoring the function of a electric heating element of a motor vehicle auxiliary heater or an electric Heating element within a group of interconnected electrical Heating element of an additional vehicle heater. With the or each heating element it is in particular a PTC resistance element.

To increase the comfort of motor vehicles, their heating systems are in increasingly provided with additional electrical heaters, where as electrical heating elements, in particular PTC resistance elements (PTC modules) can be used. For reasons of operational reliability these modules are checked for their functionality. This includes checking the PTC components for defects or during operation Compliance with temperature.

Basically, one of the PTC modules or one are the measured variables Group of current flowing through interconnected PTC modules and the voltage drop across a PTC device or group of interconnected PTC blocks are available. From these measures the current resistance value can be determined and then from the Resistance characteristic (course of resistance over temperature) on the close current temperature. Because of their changeable Resistance of PTC modules is difficult to check in the temperature range; because the electronics that control the PTC modules have no specific ones Clues to the current temperature.

Depending on the temperature of the PTC module, the resistance can be up to 95% vary, which is why there is neither a defect in a PTC module nor its current temperature based on the current and / or voltage can be recorded.

The invention is based on the object of a method for Function monitoring of an electrical heating element to create, with which a not properly detected heating element.

• - während eines Aufheiz- oder eines Abkühlungsvorgangs der durch das Heizelement oder die Gruppe von Heizelementen fließende Strom und die über dem Heizelement oder der Gruppe von Heizelementen abfallende Spannung ermittelt wird,
• - aus den ermittelten Werten für den Strom und die Spannung der Widerstand ermittelt wird,
• - anhand dieser Widerstandswerte der relative Extremwert der Widerstandskennlinie ermittelt wird und
• - überprüft wird, ob der relative Extremwert innerhalb oder außerhalb eines vorgebbaren Widerstandsbereichs liegt.

To achieve this object, the invention proposes, according to a first variant, a method for monitoring the function of an electrical heating element, in which

• during a heating or cooling process, the current flowing through the heating element or the group of heating elements and the voltage falling across the heating element or the group of heating elements is determined,
• the resistance is determined from the determined values for the current and the voltage,
• - The relative extreme value of the resistance characteristic is determined on the basis of these resistance values and
• - It is checked whether the relative extreme value lies within or outside a predefinable resistance range.

In the invention, the knowledge that electrical Heating elements of one and the same type despite strongly varying with the temperature Resistance values are essentially the same characteristic Have resistance values, which are relative (and also absolute) extreme value of the resistance characteristic. Both sides of this relative and absolute extreme value (e.g. minimum of the resistance characteristic over the temperature), the characteristic curve has an incline different signs. In the case of a PTC module, e.g. B. has the Resistance characteristic curve at its minimum at approx. 60 ° C. To both smaller and too higher temperatures (starting from approx. 60 ° C) the electrical increases Resistance.

So when operating the auxiliary vehicle heater from low temperature values If the temperature is too high, the characteristic curve for each heating element or for each "Drive through" group of interconnected heating elements, see above can be continuous, quasi-continuous or at intervals the current and voltage values of the current one are queried Resistance value can be determined. But this can also be the characteristic relative extreme value of the resistance characteristic can be determined. If this is Extreme value within a specifiable range, then the heating element or the heating elements of a group of heating elements are OK. Otherwise a defect can be displayed.

The characteristic extreme value of the resistance characteristic can either when heating a heating element or group of heating elements, d. H. if the heating element or elements with an increasing current is energized, or when cooling, i.e. with a decreasing Current can be determined by measurement.

According to the same principle, namely the investigation of the Resistance characteristic, can also be the operating temperature of an electrical heating element be determined or checked, without an external or internal Temperature sensor.

• - während eines Aufheiz- oder eines Abkühlungsvorgangs der durch das Heizelement oder die Gruppe von Heizelementen fließende Strom und die über dem Heizelement oder der Gruppe von Heizelementen abfallende Spannung ermittelt wird,
• - aus den ermittelten Werten für den Strom und die Spannung der Widerstand ermittelt wird,
• - anhand dieser Widerstandswerte die Veränderung der Widerstandskennlinie ermittelt wird,
  anhand der Veränderung der Widerstandskennlinie ermittelt wird, innerhalb welches Bereichs de Widerstandskennlinie sich der Arbeitspunkt des Heizelements oder der Gruppe von Heizelementen befindet und
• - anhand des Widerstandswertes des Heizelements oder der Gruppe von Heizelementen im Arbeitspunkt und des ermittelten Bereichs der Widerstandskennlinie die Temperatur des Heizelements oder der Gruppe von Heizelementen ermittelt wird.

For this purpose, according to a second variant of the invention, which can also be combined with the previously explained first variant of the invention, a method is proposed in which

• during a heating or cooling process, the current flowing through the heating element or the group of heating elements and the voltage falling across the heating element or the group of heating elements is determined,
• the resistance is determined from the determined values for the current and the voltage,
• - the change in the resistance characteristic is determined on the basis of these resistance values,
  on the basis of the change in the resistance curve, it is determined within which area of the resistance curve the working point of the heating element or the group of heating elements is located and
• - The temperature of the heating element or the group of heating elements is determined on the basis of the resistance value of the heating element or the group of heating elements in the operating point and the determined range of the resistance characteristic.

In this second variant, the resistance characteristic curve is used determined in the operating point of the heating element or the heating element group, at what temperature or in what temperature range the heating element or the heating element group is currently being operated (namely above or below the characteristic value of the resistance characteristic corresponding temperature value. The resistance curve is above the Temperature stored in a memory or controller. So that can be checked whether the heating element or the heating element group with the intended temperature is operated.

Passing through the resistance characteristic curve during the operation of a Heating element or a group of heating elements by briefly Interruption of the power supply and restart after a certain time Time span take place, which is dimensioned such that the heating element or Heating element group to a value below the characteristic Extreme value of the temperature characteristic corresponding to the resistance characteristic has cooled down.

In order to be able to check on which branch of the resistance characteristic the current working point of the heating element or the heating element group is located, According to an advantageous development of the invention, it is sufficient if the characteristic extreme value of the Resistance characteristic has happened.

The invention is described below using the example of a PTC resistance elements as an electrical heating element with reference to the drawing explained in more detail. The individual shows:

Fig. 1 shows the characteristic resistance / temperature characteristic curve of a PTC resistive element,

Fig. 2 shows the characteristic current / temperature characteristic of a PTC resistance element and

Fig. 3 shows a measuring arrangement for monitoring the function of a PTC resistor element on the basis of the resistance characteristic curve on the basis of the PTC resistive element and the electric current flowing through drop across the PTC resistor element voltage.

Fig. 1 and 2 show the characteristic resistance and current characteristics of a PTC resistive element 10 (see Fig. 3) in function of temperature. It can be seen that the resistance characteristic according to FIG. 1 has its local or relative and absolute extreme value (minimum) at 60 ° C; at this temperature, the current characteristic curve has its maximum value (local or relative and absolute). The characteristic minimum resistance value is now used to monitor the PTC resistance element 10 with regard to its current temperature and for failure.

For this purpose, during a heating process of the PTC resistance element 10, the current flowing through it (e.g. as a voltage drop U _shunt over a temperature-invariant constant shunt resistor 12 or by using a transistor with current output - current sense output) and the Voltage drop U _PTC measured over the PTC resistance element 10 , namely continuously, quasi-continuously or in predefinable sampling intervals (see FIG. 3). The measured values are fed to a control and evaluation unit 14 , which controls the PTC heating element in accordance with a desired heating output. The respective resistance value is calculated in the control and evaluation unit 14 from the respectively current measured values. During the heating process, the course of the resistance values can be used to identify which branch, namely the falling branch 16 or the rising branch 18 , of the working point of the PTC resistance element. This makes it possible to assign the instantaneous operating temperature to one of the two temperature ranges 20 , 22 and, moreover, to determine the current temperature of the PTC resistance element, based on the resistance characteristic curve stored in the control and evaluation unit 14 .

This results in. For example, based on the measured values for the current through and the voltage drop across the PTC resistance element 10, a resistance value R _currently (see FIG. 1), no statement can be made as to whether the PTC resistance element 10 has the temperature T ₁ or T ₂ . Only by determining the branch 16 or 18 on which the current operating point of the PTC resistance element 10 is located can the current temperature be determined from the resistance value Raktuell using the stored resistance characteristic.

When passing the minimum resistance, its value can be determined. A defect (eg failure) of the PTC resistance element 10 can then be determined by comparison with an allowable value range for the minimum resistance stored in the control and evaluation unit. REFERENCE SIGN LIST 10 PTC resistance element
14 evaluation unit
16 falling branch
18 rising branch
20 temperature range
22 temperature range

Claims (9)

1. Method for monitoring the function of an electrical heating element or within a group of electrically connected electrical heating elements, the heating element or the group of heating elements having a resistance characteristic curve over temperature with a characteristic relative extreme value, and in the method
during a heating or cooling process, the current flowing through the heating element or the group of heating elements and the voltage falling across the heating element or the group of heating elements is determined,
the resistance is determined from the determined values for the current and the voltage,
the relative extreme value of the resistance characteristic is determined on the basis of these resistance values and
it is checked whether the relative extreme value lies within or outside a predeterminable resistance range. 2. The method according to claim 1, characterized in that a defect is displayed if the relative extreme value is within the specifiable Resistance range is. 3. The method according to claim 1 or 2, characterized in that the electric heating element is a PTC resistor and that the relative Extreme value is a relative minimum value of the resistance characteristic. 4. Method for monitoring the function of an electrical heating element or within a group of electrically connected electrical heating elements, the heating element or the group of heating elements having a resistance characteristic curve over temperature with a characteristic relative extreme value, and in the method
during a heating or cooling process, the current flowing through the heating element or the group of heating elements and the voltage falling across the heating element or the group of heating elements is determined,
the resistance is determined from the determined values for the current and the voltage,
the change in the resistance characteristic is determined on the basis of these resistance values,
on the basis of the change in the resistance curve, it is determined within which area of the resistance curve the operating point of the heating element or the group of heating elements is located and
the temperature of the heating element or the group of heating elements is determined on the basis of the resistance value of the heating element or the group of heating elements at the operating point and the determined range of the resistance characteristic. 5. The method according to claim 4, characterized in that a defect is displayed when the determined temperature of a set temperature deviates by more than a predeterminable amount. 6. The method according to claim 5, characterized in that the determination the resistance characteristic range in which the current operating point of the heating element or the group of heating elements passing the relative extreme value of the determined Resistance characteristic takes place. 7. The method according to any one of claims 4 to 6, characterized in that that the cooling phase while the heating element operated at the operating point or at the operating point operated group of heating elements. 8. The method according to any one of claims 4 to 7, characterized in that the heating-up phase after switching off in the meantime is run through after the heating element or group of Heating elements following a during operation in the working point intermittent switching off is switched on again. 9. The method according to any one of claims 4 to 8, characterized in that the electrical heating element is a PTC resistor and that the relative extreme value is a relative minimum value of the resistance characteristic.