DE2426002A1 - Temperature measuring and displaying device - uses thermocouple with electric signalling lamp - Google Patents

Abstract

Temperature measuring apparatus for the exhaust gases from an i.c. engine, includes a lamp which lights up when a limit temperature is exceeded. The lamp is in the emitter-base circuit of a transistor belonging to a first stage of a multivibrator, while the multivibrator second stage, coupled to the first through a timing component preferably a feed-back capacitor, has a differential amplifier without negative feed-back as the switching component. It also serves as measurement amplifier for the thermocouple output voltage. When this voltage is above the limit, it delivers a periodic control signal to the above transistor.

Description

Device for measuring and displaying the temperature of a medium, in particular of the exhaust gas of an internal combustion engine. The invention relates to a device for measuring and displaying the temperature of a medium, in particular of the exhaust gas of an internal combustion engine, by means of a thermocouple, the an electrical display element, in particular an electrical display lamp, is assigned that emits a signal when a limit temperature is exceeded.

Such a device is used with advantage in motor vehicles, which have an afterburning system for the exhaust gases of an internal combustion engine. This afterburning plant is equipped with catalysts that have a limited Have a duration of function. When these catalysts are used up, the exhaust gas temperature increases. This temperature increase is measured and activated by switching on the electrical display element, in particular the electric indicator light, communicated to the driver.

The invention is based on the object of such a measuring and display device to create with the relatively accurate measurements of the thermoelectric voltage of the thermocouple can be made and still have a minimum of electronic components requires.

To solve this problem, a device is that mentioned at the beginning Type according to the invention characterized in that the electrical display element in the Emitter-3asis-circuit of a transistor is, which as a switching element to the first One stage of a multivibrator, while the but one a timer, preferably a feedback capacitor, this first stage associated second multivibrator stage one without negative feedback operated operational amplifier as a switching element contains, and that the switching element of the second Mulitvibratorstuie forming operational amplifier at the same time measuring amplifier for the output voltage of the thermocouple, which is at A control signal periodically generates a thermocouple voltage above a limit voltage on the transistor serving as the switching element of the first multivibrator stage.

In this facility there is a separate active electronic Component avoided as a switching element for the second multivibrator stage.

The invention and its advantages are based on the drawing on one Embodiment explained in more detail: Figure 1 shows the circuit diagram of an inventive Measuring and display device.

FIG. 2 shows a functional diagram for the device according to FIG. 1.

In the circuit of the measuring and display device according to the invention the npn transistor V7 forms the switching element of the first stage of an astable Multivibrator, the second stage of which is an operational amplifier as a switching element V3, which is operated as a comparator without negative feedback. An electric one Indicator lamp L is between the collector of transistor V7 and the connection terminal 13 for the positive pole of a power source, the negative pole of which is connected to the terminal 14 is connected, which is connected to ground 15. In the combustion chamber for the exhaust gases A thermocouple g is arranged in the internal combustion engine. The operational amplifier V3 is also the measuring amplifier for the output voltage of this thermocouple T.

At the connection terminal 13 there is one connection of an ohmic resistor R13. Between the other terminal 16 of this ohmic resistor R13 and the ground 15 are the ohmic resistors R1, RS, R3, R4 and R5. One connection of the ohmic resistor Ri is connected to connection 16 and one connection of the ohmic resistor R5 is at ground 15. The ohmic resistor R4 is adjustable (e.g. by means of a parallel resistor R4 '). At the connection line between the ohmic resistors R1 and R2 is the anode and on the connecting line the cathode of a diode V2 is connected between the ohmic resistors R3 and R4. The diode V2 and the ohmic resistors R2 and R3 are used to compensate for the dependency of the thermocouple and the circuit provided by the ambient temperature.

An ohmic resistor R7 is on the connecting line between the ohmic resistors R2 and R3 and at the inverting input 3 of the operational amplifier V3 connected. The negative pole of the thermocouple T is on the connecting line between the ohmic resistors R4 and R5, while the positive pole has a ohmic resistor R6 connected to terminal 16 of ohmic resistor R13 is. Perner is an ohmic resistor R8 with the positive pole of the thermocouple 1 on the one hand and with the non-inverting input 2 of the operational amplifier V3 on the other hand connected.

The operating voltage connection 1 of the operational amplifier V3 is connected at connection 16 of the ohmic resistor R13, during the operating voltage connection 4 of the operational amplifier V3 is connected to ground 15. The output 5 of the operational amplifier V3 is connected to the anode of a diode V5, the cathode of which is connected to the base of the transistor v7 is connected. Furthermore, the output 5 of this operational amplifier V3 is one connection of an ohmic resistor R9, the other connection with the connection 16 of the ohmic resistor R13 is connected.

An ohmic resistor R11 connected to terminal 16 is in Series with another ohmic resistor R12 and a feedback capacitor C connected to the base 15. An ohmic resistor R10 is to the inverting input 3 of the operational amplifier V3 and the connection line between the ohmic resistors R11 and R12. At the non-inverting input 2 of the operational amplifier V3 the anode is one Diode V4 connected, the cathode of which is connected to the connecting line between the ohmic Resistor R12 and the feedback capacitor C is located. Perner is on the connection line the anode of a diode V6 is connected between the ohmic resistors R11 and R12, whose cathode is connected to the collector of transistor V7. Between the base the transistor V7 and the ground 15 is an ohmic resistor R14.

At terminal 16 of the ohmic resistor R13, the cathode is one Zener diode V1 connected, the anode of which is connected to ground 15. With the ohmic resistance R13 and the Zener diode V1 is the one at the connection terminals 13 and 14 lying supply voltage stabilized.

The temperature in the combustion chamber for the exhaust gases from the internal combustion engine is converted into an equivalent voltage at the thermocouple T. The minus connection of the thermocouple T is via the ohmic resistors R1, R2, R3, R4 with R4 'and R5 is placed on a specific potential with respect to ground 15.

The inverting input 3 of the operational amplifier V3 is above the ohmic resistor R7 at a higher potential with respect to ground 15 than the negative connection of the thermocouple T. The one given by the difference between these two potentials Depending on the switching voltage and component tolerance, voltage is generated via resistors R4 set with R4 '. If the temperature-dependent voltage at the thermocouple T is smaller than that through the ohmic resistors R3 and R4 with R4 'between the inputs 2 and 3 of the operational amplifier V3 set voltage, the output is 5 of the operational amplifier V3 is approximately at the potential of the ground 15. Therefore, it is located the base of the transistor V7 is also approximately at the potential of the base 15, so that the transistor V7 blocks. The indicator lamp L is thus also dead. The diode V6 is therefore polarized in the reverse direction, and so are the resistors R10 and R12 are connected to the voltage between terminal 16 via resistor R11 of the ohmic resistor R13 and the ground 15. The inverting input 3 of the Operational amplifier V3 is thus over the ohmic resistor R10 by a fixed Voltage increased to voltage XO. The capacitor C is ohmic across Resistors R11 and R12 to the voltage UcO between terminal 16 and ground 5 charged. As a result, the diode V4 is polarized in the reverse direction.

In Figure 2, the voltage Uc across the capacitor C and over the time t the voltage X at the inverting input 3 and Y at the non-inverting input 2 applied.

If the exhaust gas from the internal combustion engine in the combustion chamber is flawless after burning, the voltage YO is applied to the non-inverting input 2. Elevated the temperature in the combustion chamber and thus also the voltage on the thermocouple T as a result of improper afterburning of the exhaust gases in the combustion chamber a certain point in time t so exceeds at a certain temperature in the combustion chamber at time t1 the voltage Y at the non-inverting input 2 the voltage X at the inverting input 3. The output 5 of the operational amplifier V3 jumps therefore to a positive voltage, and the transistor V17 is ohmic Resistor R9, as well as through the diode V5 polarized in the forward direction. The indicator lamp L is therefore connected to voltage. At the same time, the diode V6 is also in the forward direction polarized, so that the ohmic resistors R10 and R12 via the emitter-collector path of the transistor V7 are placed at the potential of the ground 15. Through this switchover the inverting input 3 of the operational amplifier V3 is increased by one through the Resistors R1, R2, R7 and R10 set the voltage swing more negative. The feedback capacitor C discharges through the ohmic resistor R12, the diode V6 and the emitter-collector path of the transistor V7 until die.Kondensators voltage Uc at time t2 through the voltage across the thermocouple T. Y am non-inverting Input 2 of the operational amplifier V3 falls below. At that moment the Diode V4 polarized in the forward direction, and the voltage at the non-inverting input 2 is equal to the voltage Uc across the capacitor C, which is in the direction of the voltage of the Mass 15 drops.

If the voltage Y = Uc at the non-inverting input 2 at time t3 is equal to the voltage X at the inverting input 3 of the operational amplifier V3, so the output 5 of this operational amplifier V3 is immediately back to the potential the mass 15 switched. The transistor V7 therefore blocks.

The indicator lamp L goes out and the diode V6 is again in the reverse direction polarized. Resistors R10 and R12 are connected to positive voltage again via resistor R11, and the inverting input 3 is back to the specific voltage swing on the XO voltage increased. The capacitor C charges through the ohmic resistor R12 again until the voltage Y - UC at the non-inverting input 2 is equal to the voltage XO at the inverting input 3 at time t4. In that moment the output 5 of the operational amplifier V3 jumps back to a predetermined positive voltage, and the flashing process is started again.

However, at a point in time t5, the voltage across the thermocouple T and so that the voltage at the non-inverting input 2 returns to its initial value YO (normal afterburning) has fallen, the diode V4 remains in the reverse direction polarized, and the flashing process is ended.

In the device of Figure 1, the feedback capacitor C only before the first light time of the indicator lamp L to the voltage between the connection 16 and the mass 15 are charged during the subsequent flashing of the indicator lamp L, however, only to the voltage swing to be set via the ohmic resistors R7 and RiO reloaded. This means that the first light time of the indicator lamp is two to three times longer than the other bright times. As a result of the curved characteristic of the diode V4 the flashing frequency is higher with higher thermal voltage.

Claims (1)

Claim Device for measuring and displaying the temperature of a medium, in particular the exhaust gas of an internal combustion engine, by means of a thermocouple, an electrical display element, in particular an electrical display lamp, is assigned, which emits a signal when a limit temperature is exceeded, characterized in that the electrical display element (t) is in the emitter-base circuit of a transistor (V7), which acts as a switching element for the first stage of a multivibrator heard while using a timer, preferably a feedback capacitor (C), the second multivibrator stage assigned to this first stage, one without negative feedback operating zones operational amplifier (V3) contains as a switching element, and that the Operational amplifier forming the switching element of the second multivibrator stage (V3) at the same time measuring amplifier for the output voltage of the thermocouple (t), the periodically when the thermocouple voltage is above a limit voltage Control signal to the one serving as the switching element of the first multivibrator stage Transistor (V7) emits. Blank page