FR2495331A1 - Fault detector for photocoupler - includes four voltage comparing detectors linked to junctions on photocoupler and joined to common output - Google Patents

Abstract

The fault detector for a photocoupler, has a light-emitting diode, and a phototransistor, and includes four detectors and an indicating circuit common to all four detectors. A potential dividing bridge consisting of three resistors is connected between positive and negative supply terminals, and provides one of the inputs to each of the detectors. The second input for each detector is derived from a point on the photocoupler with resistors providing the appropriate bias. Any fault in the photocoupler provides an output to one of the detectors which in turn provides outputs via diodes connected to an input of a further detector in the common circuit. This detector controls a warning light on its output.

Description

Fault detector on photocoupler
The invention relates to a fault detector on photocouplers to detect faults during checks of correct operation.

 A photocoupler comprises a photoemissive diode and a phototransistor: the faults can consist in the opening of any one of the anode or cathode electrodes of the photoemissive diode, emitter or base or collector of the phototransistor, or in a short circuit between any two electrodes. These faults can be permanent, in which case they are often easily detectable, but they can be intermittent and occur during a duration test or during a test in a temperature range for example between -250C and + 1000C.

 The object of the invention is to detect faults in the photocouplers during a check of correct operation.

 Another object of the invention is to detect intermittent faults which occur during checks of correct operation over time and in particular during checks in the operating temperature range of the photocouplers.

 The subject of the invention is a photocoupler fault detector comprising a photoemissive diode and a phototransistor, mounted on a support with five terminals, the photoemissive diode having an anode connected to a first terminal and a cathode connected to a second terminal, the phototransistor. having a transmitter, a collector and a base connected to a third, a fourth and a fifth terminal, respectively, characterized in that it comprises four detectors and a signaling device common to the detectors, that a first divider bridge consisting of three resistors is connected between a positive polarity and a negative polarity of a DC power source having its negative polarity to ground, that said positive polarity is connected by a first resistance to the first terminal and by a second resistance to the fourth terminal, that the second terminal is connected to ground, that the third terminal is connected to ground by a third resistor, that the cin fourth terminal is connected to ground by a fourth resistor, the fourth terminal is connected to ground by a second divider bridge consisting of two resistors in series, that a first detector has a positive input connected to the fourth terminal and an input negative connected to a first point of the first divider bridge, that a second detector has a positive input connected to the first point of the first divider bridge and a negative input connected to the fifth terminal, that a third detector has a positive input connected to a second point of the first divider bridge and a negative input connected to the third terminal, and a fourth detector to a positive input connected to the third terminal and a negative input connected to a point of the second divider bridge.

 The signaling device makes it possible to permanently signal an intermittent fault; for this it comprises a detector and a signaling means connected between an output of the detector and the ground, a positive input of the detector being connected, by a resistor at a point common to the outputs of the four detectors, and to the ground by another resistor , an output of the detector being connected by a diode to said common point, and a negative input of the detector being connected to the positive polarity of the DC power source.

 Other characteristics and advantages of the invention will emerge from the description which follows of an exemplary embodiment illustrated by the single appended figure which is an electrical diagram of a fault detector object of the invention.

 In this figure a photocoupler constituted by a photoemissive diode D and a phototransistor T is mounted on a support S with five terminals marked a, b, c, d, e; the photoemissive diode has its anode connected to terminal a and its cathode connected to terminal b; the phototransistor has its emitter connected to terminal c, its collector connected to terminal d, and its base connected to terminal e. A continuous power source has its negative polarity connected to ground and its positive polarity V = 5 volts connected on the one hand to terminal a by a resistor RI, and on the other hand to terminal d by a resistor R2. Terminal b is connected to ground, terminal c is connected to ground by a resistor R3, terminal d is connected to ground by two resistors R5 and R6 in series, and terminal e is connected to ground by a resistor R4.A divider bridge consisting of three resistors R7, R8, R9, in series, is connected to the terminals of the DC power source, the resistor R7 being connected to the positive polarity V and the resistor R9 being connected to ground . The positive polarity V of the DC power source is connected to ground by two capacitors C1 and C2 in parallel, the capacitor C1 having a low capacity, 10 nanofarads for example, the capacitor C2 having a high capacity, 47 microfarads for example .

A first detector 1 has a positive input connected to the terminal d of the support S, and a negative terminal connected to a point A common to the resistors R7 and R8 of the divider bridge. A second detector 2 has a positive input connected to point A, and a negative input connected to terminal e of the support S. A third detector 3 has a positive input connected to a point B common to resistors R8 and
R9 of the divider bridge and a negative input connected to terminal c of support S. A fourth detector Il has a positive input connected to terminal c of support S and a negative input connected to a point E common to resistors R5 and R6. Detectors 1, 2, 3, 4 have their outputs connected to a point C, through diodes 6, 7, 8, 9, respectively.

 A signaling device 14 is connected between point C and ground; it comprises a detector 5, a positive input of which is connected by a resistor R10 at point C and by a resistor R11 to ground. A circuit consisting of a diode 11 and a push button 12 in series is connected in parallel to the Roll resistor.

A negative input of the detector 5 is connected to the positive polarity V of the DC power source. The output of detector 5 is connected to point C by a diode 10, and to ground by a resistor R12 and a light-emitting diode 13 in series.

 The detectors 1, 2, 3, 4, 5 are for example operational amplifiers, and are supplied by another continuous power source having a positive polarity U = 12 volts relative to the ground.

The continuous power source supplying the photocoupler
unC having / voltage of 5 volts (V = 5 volts compared to the mass), the resistors have the following values.

ni = 120 ohms, R2: 681 ohms, R3 = 681 ohms
R4 = 470,000 ohms, R5 = 1000 ohms, R6 = 330,000 ohms
R7 = 464 ohms, R8 = 102 ohms, R9 = 464 ohms,
R10 = 1000 ohms, Ril = 10,000 ohms, R12 = 470 ohms
The potentials, with respect to ground, of the terminals and points of the divider bridge are as follows, in normal operation
1.2 volt terminal a
2.4 volt terminal c
terminal d at 2.6 volts
terminal e at 3.05 volts
Point A at 2.75 volts
Point B at 2.25 volts
The potential of point E (resistances R5, R6) is about 9 millivolts lower than that of terminal d.

 The photocoupler being supplied by a DC voltage of 5 volts, the photoemissive diode D is crossed by a current of 32 milliamps, which causes the saturation of the phototransistor 5. The fault detector of the invention allows the detection of the following faults, which are signaled, after detection, by the signaling device 14. Opening of the light-emitting diode D, opening of an electrode of the phototransistor T, short-circuit of the light-emitting diode, short-circuit between two electrodes of the phototransistor, short-circuit between the light emitting diode and the phototransistor.

 The detection of the various faults is as follows (the photoemissive diode will be designated by "diode" and the phototransistor by "transistor") 1. Opening of the anode of the diode.

Since the diode does not emit radiation, the transistor
blocks and its collector, terminal d, goes to potential + V = 5 volts.

 Detector 1 detects the fault.

2. Opening the cathode of the diode.

 Same process as for opening the anode.

3. Opening of the base of the transistor.

With the base off, there is no base current in
resistance R4 and terminal e of the support goes to potential
mass. Detector 2 detects the fault.

4. Opening of the transistor emitter.

There is no current in the transistor. Terminal c of
support goes to ground potential. The fault is detected
by the detector 3.

5. Opening of the transistor collector.

There is no current in the transistor. Terminal d of
support goes to 5 volt potential and detector 1 detects
the failure.

6. Anode-cathode short circuit of the diode.

As the diode does not emit radiation, the transistor
blocks and its collector, so terminal d, goes to potential
+ 5 volts. Detector 1 detects the fault.

7. Short-circuit anode of the diode-base of the transistor.

The base, therefore the terminal e, passes to the potential of the anode,
or 1.2 volts. Detector 2 detects the fault.

8. Short-circuit anode of the collector diode of the transistor.

The collector, therefore the terminal d, goes to the potential of the anode,
or 1.2 volts; the transmitter, so terminal C goes to potential
0.8 volts. Detector 3 detects the fault.

9. Short-circuit anode of the emitting diode of the transistor.

The transmitter, therefore terminal c, goes to the potential of the anode,
or 1.2 volts. Detector 3 detects the fault.

10. Short-circuit cathode of the diode-base of the transistor.

 The base, therefore the terminal e, passes to the ground potential.

 Detector 2 detects the fault.

11. Short-circuit cathode of the collector diode of the transistor.

The collector, therefore terminal d, goes to the potential of the
ground, which causes the emitter, so terminal c, to pass
to the potential of the mass. Detector 3 detects the fault.

12. Short-circuit cathode of the emitting diode of the transistor.

 The transmitter, therefore terminal c, goes to ground potential.

 Detector 3 detects the fault.

13. Base-collector short-circuit of the transistor.

This short circuit passes the potential of the collector,
so that of terminal d, of the 2.6 volts vals to the value
+ 2.85 volts. Detector 1 detects the fault.

14. Short-circuit base-emitter of the transistor.

The transistor is blocked and the collector, therefore the terminal d,
goes to potential + 5 volts. Detector 1 detects the fault.

15. Collector-emitter short-circuit of the transistor.

In normal operation the detector 4 works in diff
profitable between the collector and the emitter; point E, (resis
tances R5, R6) being at a lower potential of approximately 9
millivolts to that of the collector is therefore at a potential
higher than that of the transmitter and the detector 4 is blocked.

During a short circuit between the collector and the transmitter,
the potential of point E is less than the common potential
of the collector and the transmitter and the fault is detected by
the detector 4.

It will be noted that certain faults can be detected by several detectors. For example, in the case of faults 1 / and 2 / the transmitter goes to ground potential and the fault is also detected by detector 3.

 In the case of fault 4 /, for example, the collector goes to potential + 5 V and the fault is also detected by detector 1.

 In the case of fault 14, for example, the potential of the emitter and of the base practically passing to that of the ground, the detectors 2 and 3 also detect the fault.

 The signaling device 14 makes it possible to permanently signal an intermittent fault which may occur during a function check of a certain duration, as is for example the case when a correct function check is carried out in function of the temperature. The diode 10 constitutes a feedback loop; as soon as a fault has been detected by one or more of the detectors 1, 2, 3, 4 and signaled by the signaling device 14, the voltage at the output of the detector 5 is applied to point C, so that even a intermittent fault remains signaled, the light-emitting diode 13 remaining permanently supplied.

 The push button 12 of the signaling device makes it possible to suppress the signaling as soon as the photocoupler under test is removed from the support 5; when the push button 12 is pressed, the positive input of the detector 5 is forced to ground potential, which cancels the voltage at the output of the detector.

 The light-emitting diode 13 can of course be replaced by any other display means; an audible signaling means may also be provided, alone or with a viewing means.

 The signaling device therefore stores a fault, which allows the fault detector of the invention to detect, in addition to permanent faults, intermittent or fugitive faults, as soon as such faults have appeared.

Claims (3)

1 / Fault detector on photocoupler comprising a photoemissive diode (D) and a phototransistor (T) mounted on a support (S) with five terminals, the photoemissive diode having an anode connected to a first terminal (a) and a cathode connected to a second terminal (b), the phototransistor having an emitter, a collector and a base connected to a third, a fourth and a fifth terminal, respectively, characterized in that it comprises four detectors (1, 2, 3, 4 ) and a signaling device (14) common to the detectors, that a first divider bridge consisting of three resistors (R7, R8, R9) is connected between a positive polarity (+ V) and a negative polarity of a source of DC power supply having its negative polarity to ground, that said positive polarity is connected by a first resistor (R1) to the first terminal (a) and by a second resistor (R2) to the fourth terminal (d), than the second terminal (b) is connected to ground, that the third terminal (c) is re linked to ground by a third resistor (R3), that the fifth terminal (e) is connected to ground by a fourth resistor (R4) that the fourth terminal (d) is connected to ground by a second divider bridge constituted by two resistors (R5, R6) in series, that a first detector (1) has a positive input connected to the fourth terminal (d) and a negative input connected to a first point (A) of the first divider bridge, that a second detector (2) has a positive input connected to the first point (A) of the first divider bridge and a negative input connected to the fifth terminal (e), that a third detector (3) has a positive input connected to a second point (B) of the first divider bridge and a negative input connected to the third terminal (c) and that a fourth detector (4) has a positive input connected to the third terminal (c) and a negative input connected to a point (E ) of the second divider bridge. 2 / fault detector according to claim 1, characterized in that the signaling device (14) comprises a detector (5) and a signaling means (13) connected between an output of the detector and the ground, that an input positive of the detector is connected, by a resistor (R70) to a common point (C) to the outputs of the four detectors (1, 2, 3, 4), and to ground by another resistor (R11), than an output of the detector (5) is connected by a diode (10) to said common point (C), and that a negative input of the detector (5) is connected to the positive polarity (V) of the DC power source.  3 / fault detector according to claim 2, characterized in that the signaling device (14) comprises a diode (1f) and a push button (12), in series, the assembly being connected between the positive input of the detector ( 5) and the mass.