DE4403156A1 - Microcomputer control of solenoid valve for fuelled heater - Google Patents

Abstract

A solenoid valve (3) controls the flow of fuel to a heater and is operated by signals generated by a microcomputer (1). The computer provides square-wave signals (5A) to a control circuit (2) that operates as a bandpass device such that the valve is only controlled when the frequency lies within a specific range. The control circuit is based upon three retriggerable monostable multivibrators (6, 7, 8). The output is fed back (4) to the computer.

Description

The invention relates to a device for controlling a Consumer, especially a solenoid valve of a burn fabric-heated heat source, with a microcomputer, the off output signals with a rectangular characteristic of a defined frequency and defined duty cycle that generates a frequency selective drive circuit are supplied, the output control signals the consumer.

In microcomputer systems for safety-critical applications special measures must be taken to ensure that in the event of a to be able to prevent disrupted program execution potentially dangerous output signals passed on to the periphery become. For this purpose it is known to be intermittent Control of a dangerously acting consumer, for example game of a gas solenoid valve, from the microcomputer instead of one static output signal defines a square wave Frequency and defined duty cycle. This signal is fed to the input of a control circuit leads, which controls the consumer on the output side. The An Control circuit has both gain in the general case as well as a certain frequency transmission behavior. There by the activation of the consumer is prevented, if  the microcomputer due to incorrect program execution static output signal or a square wave signal with a wrong frequency. A frequency too low or a static output signal causes a high-pass behavior the control circuit the desired shutdown of the consumption chers. But especially since the appearance is relative high-frequency error signals must be expected, increased additional low-pass character of the control circuit the Si overall system security. The frequency transmission characteristics The control circuitry is crucial for the fact that the consumer is switched off if the microcomputer processed his program incorrectly. The frequency changes transmission behavior due to the occurrence of internal errors in the control circuit, the protective radio described tion go unnoticed. This shortcoming is caused by the proposed invention resolved.

The invention is accordingly based on the object Control device of the above-mentioned type with high functional safety security for critical applications that specify it cheaper with little circuitry and use Standard components allow faulty program execution detection by the microcomputer and the consumer in this case switch off, a loss of the mis circuit recognition effect by soft goods-supported self-monitoring should be noticed.

According to the invention the object is achieved in that the end input signal of the control circuit via with a query  direction is fed to an input of the microcomputer that the microcomputer cyclically test square wave signals, whose frequency is outside the target passband of the on Control circuit is located, and / or static test output signals and that the microcomputer program determines the off change signal at at least one of its signal outputs changes if the interrogator during the output of the Test signal by the microcomputer no shutdown signals the consumer.

In this way, the frequency transmission behavior of the An control circuit checked by the microcomputer programmatically by the microcomputer generates test signals which, when properly ordered according to a functioning control circuit for a shutdown of the consumer must do what the microcomputer means an interrogator checks.

The protective function can also be carried out by the interrogation device a change in the frequency transmission behavior by the Internal errors do not occur in the control circuit get lost more unnoticed. The functional safety of the An control device for safety-critical applications is there with vastly improved.

According to an advantageous embodiment of the invention the control circuit from a retriggerable monostable Multivibrator and an adapter circuit, the input of the monostable multivibrator with the microcomputer Output with the input of the adapter circuit and its output  is connected to the consumer and being the adapter scarf tion has high-pass characteristics.

The retriggerable monostable multivibrator acts as a additional low pass:

If the frequency of the input square wave signal the Rezi prokwert of the characteristic output pulse duration of the mono stable multivibrator, it remains open constantly excited due to its retriggerability. It therefore emits a static output signal, which we the high-pass behavior of the downstream adapter scarf device causes a shutdown of the consumer.

According to a further preferred embodiment of the device the retriggerable monostable multivibrator Release input on, which retrig with the output of a second connectable monostable multivibrators is connected and is between the first monostable multivibrator and the Adap a third retriggerable monostable multivi arranged brator.

The second multivibrator generates at frequencies above one maximum cutoff frequency constantly in the excited state. Thereby its output acts on the release input of the first mono stable multivibrators with an enable signal. At sub If the lower limit frequency is exceeded, the second Multi leaves vibrator temporarily the excited state, causing the first Multivibrator at the time when its control input  Received input pulses, no enable signal available stands. As a result, the output of the first multivibrator decreases statically the non-excited state, causing shutdown of the consumer. When an upper limit is exceeded frequency remains the first monostable multivibrator in the excited state, and here too its static effect Output signal the shutdown of the consumer.

The third monostable multivibrator is used to control the Tastver Ratio of the square wave signal to the subsequent circuit to fit which turns on the consumer. Should this be fit may not be necessary, so the third monostable There is no need for a multivibrator.

Under certain conditions it is also possible to click on the High-pass behavior of the adapter scarf feeding the consumer to do without. The adapter circuit must be procured in this way be that it only turns on the consumer when the controlling third monostable multivibrator in excited Condition. Furthermore, this third must also be monostable Multivibrator can be retriggerable, and its characteristic Output pulse duration must be greater than the characteristic off gear pulse duration of the second monostable multivibrator. The third monostable multivibrator can only be permanent remain in the excited state when the second is monostable Multivibrator emits a square wave. Only then will it Consumer activated.  

If no adjustment is required, the adapter can also be used circuit can be replaced by a connecting line.

Advantageous embodiments are in the subclaims cha characterizes or go from the following Be spelling out an embodiment of the invention based on the drawing.

Show it:

Fig. 1 is a schematic diagram of an embodiment of an inventive device and

Fig. 2 signal waveforms at several nodes of FIG. 1.

The illustrated in FIG. 1 device consists we sentlichen of a microcomputer 1, a cross signals from its Off applied drive circuit 2, a by-connected loads 3 and a with the output of the On control circuit 2 connected interrogator 4 which, in turn, connected to the microcomputer 1 communicates.

To control the consumer 3, the microcomputer 1 feeds a square-wave signal of a specific frequency f into the input 5 of the control circuit 2 . In this, the square-wave signal is converted into an output signal suitable for controlling the consumer 3 . The control circuit 2 has z. B. bandpass behavior, so that the consumer 3 is only controlled when the frequency f of the input signal is within half of a certain frequency interval.

In order to switch off the consumer 3 and at the same time to test the function of the frequency-selective means of the control circuit 2 , the microcomputer 1 programmatically generates a square-wave signal, the frequency of which lies outside the target range 2 of the control circuit 2 . With intact control circuit 2 , the consumer 3 is switched off.

If the control circuit 2 is defective and still emits a switch-on signal to the consumer 3 , the microcomputer 1 uses the interrogator 4 to recognize that the consumer 3 has not been switched off and responds to it in a suitable manner. For example, another switch-off path (not shown here) could be activated and an error message could be issued.

A bandpass behavior of the control circuit 2 is tested in that, according to the program, the microcomputer 1 for switching off the consumer 3 alternately generates differently frequency square-wave signals, the frequency of which is sometimes above and sometimes below the desired passband. Analogously, only high-pass or low-pass behavior is tested by the microcomputer emitting a square-wave signal which is below the high-pass target cutoff frequency or above the low-pass setpoint cutoff frequency.

If there is an erroneous program processing by the microcomputer 1 , this generates either a static output signal or a square wave signal with suitably designed software, the frequency of which does not agree with the frequency required for the proper activation of the consumer 3 .

A static output signal leads due to the high-pass character (possibly as part of a bandpass behavior) of the control circuit 2 to the desired shutdown of the consumer in the event of a fault. 3

A square-wave signal, the frequency of which is outside the target pass-through range of the control circuit 2 , also effects the desired consumer shutdown.

The bandpass function of the control circuit 2 is realized in Chen wesentli by three monostable retriggerable multivibrators 6 , 7 and 8 . The signal output of the Mikrocom computer 1 feeds both the input of the first retriggerable monostable multivibrator 6 , which has a separate enable input 9 and whose characteristic output pulse duration is T1, and also the input of the second retriggerable mono-stable multivibrator 7 , whose characteristic output pulse duration is T2 . T2 must be greater than T1. Only when the frequency of the square wave signal generated by the microcomputer 1 is between 1 / T2 and 1 / T1 does a square wave signal appear at the output 10 of the first monostable multivibrator 6 . At frequencies less than 1 / T2, the second monostable vibrator 7 is no longer in the excited state when a normal, pulse-triggering signal edge reaches the input of the first monostable multivibrator 6 . This signal edge can not be effective because the output 11 of the second monostable multivibrator 7 only releases the enable signal to the enable input 9 of the first monostable multivibrator 6 if the switching delay time of the second monostable multivibrator 7 has elapsed since the occurrence of the signal edge. Consequently, the first monostable multivibrator 6 is not excited and a static signal is present at its output 10 .

At frequencies greater than 1 / T1, a static signal also appears at the output 10 of the most monostable multivibrator 6 , but of opposite polarity, because the temporal spacing of consecutive input in the pulse edge is smaller than T1 and the first monostable Mul tivibrator 6 because of it Retriggerability remains constantly in the excited state.

Only if the input frequency f lies in the specified interval, the output 10 of the first monostable multivibrator 6 passes a square-wave signal to the third monostable multivibrator 8 , which serves to adapt the duty cycle of the square-wave signal to the subsequent adapter circuit 12 , which the consumer 3 switches on. If this adjustment is not necessary, the third monostable multivibrator 8 can be omitted. The adapter circuit 12 can have a high-pass behavior and possibly an amplifier function and / or a rectifier function. The specific design of the adapter circuit 12 depends on the nature and requirements of the consumer 3 . A high-pass behavior of the adapter circuit 12 acting on the consumer 3 is unnecessary in certain cases.

Fig. 2 shows possible signal waveforms at input 5 (A) of the control circuit ( 2 ), at output 10 (B) of the first monostable multivibrator 6 , at output 7 (C) of the second monostable multivibrator 7 and at the output (D) of the third Multivibrators 8 , which is identical to the input of the adapter circuit 12 . It can be seen that a square-wave signal of frequency f is only switched through to point D if f lies within the frequency band 1 / T2 to 1 / T1. If f exceeds the value 1 / T1, the first monostable multivibrator 6 generates a static output signal at its output 10 , point B. Consequently, there is also a static output signal at the output of the third monostable multivibrator 8 , point D. If f falls below the value 1 / T2, the second monostable multivibrator 7 periodically falls back from the excited state into the idle state, that is to say a square-wave signal appears at its output 11 , point c. The triggering (here posi tive) signal edge of a pulse at input 5 , point A, the control circuit 2 can then only affect the second mono-stable multivibrator 7 , because the enable input 9 of the first monostable multivibrator 6 at the point in time of the named signal edge A is not yet activated. The activation takes place only after the switching delay time of the second monostable multivibrator. When the release signal reaches the release input 9 , the signal change at point A has already taken place and the first monostable multivibrator 6 can no longer react to it. Consequently, a static signal appears at its output 10 , point B. Because of the lack of control at the input, a static signal also occurs at the output, point D, of the third monostable multivibra 8 .

The invention is not limited to the above bene embodiment. Rather, it is a number of variants conceivable, even if fundamentally different Execution make use of the features of the invention.

Claims (6)

1. Device for controlling a consumer, in particular a solenoid valve of a fuel-heated heat source, with a microcomputer that generates output signals with a rectangular characteristic of defined frequency and defined duty cycle, which are fed to a frequency-selective control circuit, the output signals of which control the consumer, characterized in that the output signal of the control circuit ( 2 ) via an interrogation device ( 4 ) an input of the microcomputer ( 1 ) to that the microcomputer ( 1 ) cyclically test square wave signals, whose frequency outside the target pass range of the control circuit ( 2 ), and / or static test output signals, it generates and that the microcomputer ( 1 ) program determines the output signal at at least one of its signal outputs if the interrogator ( 4 ) during the output of the test signal by the microcomputer ( 1 ) no par aging of the consumer ( 3 ) signals. 2. Device according to claim 1, characterized in that the control circuit ( 2 ) consists of a retriggerable monostable multivibra gate ( 6 ) and an adapter circuit ( 12 ) be, the input of the monostable multivibrator ( 6 ) with the microcomputer ( 1 ) , its output ( 10 ) with the input of the adapter circuit ( 12 ) and the output of which is connected to the consumer ( 3 ) and the adapter circuit ( 12 ) has a high-pass characteristic. 3. Apparatus according to claim 2, characterized in that the retriggerable monostable multivibrator ( 6 ) has a release input ( 9 ) which is connected to the output ( 11 ) of a second retriggerable monostable multivibrator ( 7 ), the input of which is connected to the input the first monostable multivibrator ( 6 ) is connected and that between the first monostable multivibrator ( 6 ) and the adapter circuit ( 12 ) a third re triggerable monostable multivibrator ( 8 ) is arranged. 4. The device according to claim 3, characterized in that the third monostable multivi brator ( 8 ) through a connecting line he is. 5. Device according to one of claims 1 to 4, characterized in that the adapter scarf device ( 12 ) has no high-pass characteristic. 6. Device according to one of claims 1 to 4, characterized in that the adapter scarf device ( 12 ) through a connecting line he is.