FR2625381A1 - Method and device for protecting an electronic unit for controlling the electrical supply to a load - Google Patents

Abstract

In the event of a short-circuit of the load R1, the transistor T2 commands the charging of the capacitor C1. According to the invention, a circuit T3, T4 with two transistors then periodically switches off and switches on a control unit T1 so as to limit the dissipation in the unit T1. The circuit becomes inoperative when the short-circuit disappears. Control of the current in the load, through a control signal S applied to the base of the transistor T3, is then reestablished. Application to the protection of a Darlington transistor for controlling the supply to an indicator light.

Description

METHOD AND DEVICE FOR PROTECTING AN ORGAN
ELECTRONICS OF POWER SUPPLY
ELECTRICALLY CHARGED
The present invention relates to a method and a device for protecting an electronic member for controlling the electrical supply of a load and, more particularly. to such a method and such a device designed to protect this member from overcurrents resulting from an accidental short-circuit of the load.

 Conventionally, such protection is achieved by limiting the current in the control member using a closed loop linear regulation device. During a short circuit of the load, the current then reaches a limit value and this results in a high dissipation of thermal energy at the level of the control member, which is detrimental to its proper functioning unless provision is made for an evacuation of this energy by a bulky radiator.

 The present invention therefore aims to provide a method and a device for protecting the control member which make it possible to considerably reduce the dissipation of thermal energy in the control member during a short circuit of the load supplied. through this body.

 The present invention also aims to provide such a method and such a device which ensure automatic resetting of the control member, with the elimination of the short circuit.

 Another object of the present invention is to produce such a protection device comprising a reduced number of electronic short standard components, which is reliable and which allows adjustment of the power dissipated during a short circuit.

 These aims of the invention are achieved, as well as others which will appear below, with a method of protecting an electronic control member for the electronic supply of a load against an overcurrent of the current admitted into this member. , characterized in that (a) the control member is blocked in response to an excess of the intensity of the current admitted into the control member compared to a predetermined value, (b) the member is periodically released pout control: then compare the intensity of the current admitted into the member with this predetermined value, (c) the control member is again blocked if the intensity of the admitted current is still greater than this predetermined value.

 For the implementation of this method, the invention provides a device for the protection of an electronic control member placed in the supply circuit of a load in series with a resistance for measuring the intensity of the current. admitted to this body. characterized in that it comprises a semiconductor member controlled by the voltage across the measurement resistor to trigger the charging of a capacitor when the intensity of the current admitted into the control member exceeds the predetermined value, and a circuit controlled by the voltage across this capacitor to perform periodic unlocking of the control member, so as to trigger the charging of the capacitor through the member when the intensity of the unlocked current is greater than the predetermined value . the circuit becoming inoperative otherwise.

 I1 thus appears that the device according to the invention provides control by switching, of the current in the electronic control member during a short circuit. This results in a much lower energy dissipation than that observed with conventional protection devices which use linear closed-loop regulation. In addition, the device according to the invention ensures automatic resetting of the control member as soon as the short circuit has disappeared, at the time delay established by the constant de.temps of the near circuit.

In the accompanying drawing, given only by way of example
- Figure 1 is a diagram of an embodiment of the device according to the invention in its application to the control of an indicator light, the electronic control member being disposed on the "ground" side of a source of supply of electrical energy to this indicator,
FIG. 2 is a set of timing diagrams useful for describing the operation of the device in FIG. 1, and
- Figure 3 is a diagram of another embodiment of the device according to the invention, in the same application, the electronic control member then being disposed on the "Supply" side of the source of electrical energy.

 Reference is made to FIG. 1 to describe the structure and the operation of a first embodiment of the device according to the invention, in an application for the control of an indicator light signaling the existence of a malfunction. of an appliance, for the attention of the driver of a motor vehicle, for example. Of course, this application is in no way limitative and it will become clear later on to those skilled in the art that the invention can find very many other applications in the very general field of the protection of electronic organs for controlling the current of a load, in particular against short circuits of said load.

In FIG. 1, a resistive load such as an indicator light R1 is connected on the one hand to the positive pole + ALIM of an electric power source and on the other hand to a line
Who supplies the protection device according to the invention in particular. A resistor R2 for measuring the current supplied by the line A to an electronic control member T1 is connected between the line A and an electrode of this member Ti, which controls the indicator light R1. The member Ti can be, for example, a Darlington type transistor. as shown schematically in Figure .1, where the resistor R2 is then connected to the collector of this transistor. Thus the resistor R2 "sees" the current admitted into the member T1. At the terminals of the resistor R2 is connected the protection device according to the invention, which essentially comprises a semiconductor member such as a transistor T2 of the PNP type in the emitter-collector circuit of which a capacitor C1 is placed. between the collector of T2 and the ground, and a circuit comprising first and second transistors T3 and T4 respectively, of opposite conductivity type NPN and PNP respectively, connected together so that the collector of one is connected to the base on the other in a configuration called the thyristor type. The bases of the transistors Ti and T4 have a common point and a resistor R3 is connected between this common point and the line A. The emitter of the transistor T4 is connected to the common point to the collector of T2 and to the capacitor C1. via a resistor R4. The transistor emitter
T3 is connected to ground.

The two transistors (T3, T4) could be replaced by a programmable unijunction transistor (PUT)
The indicator light R1 is used to signal the operating status of a device to an observer. When the device is operating normally, the R1 indicator is off. It lights up in the event of abnormal operation of the monitored device.

 The lighting and extinction of the indicator light Ri are controlled by a means (not shown) generating a control signal S applied, for example, on the base of the transitor T3i through a diode D and a resistor R5 placed at series.

According to a variant, the control control signal S could be applied to the base of the transistor T1.

 When the device is operating normally, the signal S is in a "high" state which saturates the transistor T3 to thereby block the transistor T1. The R1 indicator then remains off. It will be noted that then an application of the voltage + ALIM on the line A, in the event of a short-circuit of the indicator light Ri, has no effect on the dissipation of the transistor Ti.

When an operating anomaly of the monitored device is detected, the control signal 5 goes to a "low" state to block the transistor T3 by absence of basic current (the capacitor Cl then being discharged). Transitor T1 is then conductive due to the establishment of a current in its base via the resistor
R3. The indicator R1 then lights up. The resistor R2 is chosen so that the voltage across its terminals is less than the conduction threshold of the transistor T2 for the normal operating current in the load, that is to say in the LED assimilated to a resistor of value R1.

 We now refer to the timing diagrams of FIG. 2, where there is shown in A, the voltage VA on line A of the device of FIG. 1, in B the current ITL in the transistor Tl, in C the voltage VC1 at the terminals of the capacitor C1 and in D the voltage VbTl on the basis of the transistor T1.

In the event of a short-circuit of the load constituted by the indicator R1 (time t1 of the timing diagram A in Fig. 2), the voltage at A takes the value of the voltage + ALIM. -and the short-circuit current then exceeds a predetermined value and produces a reinforced voltage drop in
R2 (see Fig. 2, B), insofar as T1 leads to the instant when the short-circuit appears. Resistor R2 is then chosen so that this voltage drop exceeds the threshold
Conduction vbe of the transistor T2 which becomes conductive and authorizes the charging of the capacitor C1.

When charging this capacity, the emitter voltage of transistor T4 rises. As long as this voltage remains below a predetermined threshold SI, (see
Fig. 2, C), the transistor T4 remains blocked and has a high input impedance on its emitter. The threshold voltage S1 is defined by the following relation
51 = Vbe (TL) + Vbe (T4) or Vbe (T1) and Vbe (T4) are the falls. dc emitter-base voltage of transistors T1 and T4 respectively.

If we consider that T1 is a transistor of
Darlington, S1 is of the order of 2Vbe + Vbe = 3Vbe,
Vbe being the emitter-base voltage drop of a transistor
be standard.

When the emitter voltage of transistor T4 becomes greater than the threshold voltage S1., Transistor.T4 conducts and causes transistor T3 to conduct. This saturates and then decreases the tension on the bases of Tl and T4, which causes more T4 to drive and blocks T1. The application in
A voltage + ALIM due to the short circuit has no effect on the dissipation of the transistor TL which is thus protected. according to the invention, thermal effects of this short circuit.

The transistor T4 remains conductive as long as its emitter current remains sufficient to keep the transistor T3 at saturation. The duration of this situation is fixed by the time constant of the circuit (C1, R4, T3, T4) and by a voltage threshold S2 (see Fig. 2, C) defined as follows S2 = Vbe (T4) + Vce sat (T3) where Vbe (T4) is the emitter-base voltage drop of transistor T4, and V sas (T3) is the voltage drop
this sat emitter-collector at saturation of transistor T3.

 When the emitter voltage of the transistor T4 becomes lower than the threshold voltage S2, T4 is blocked causing the blocking of the transistor T3 which, in turn, triggers the unlocking of the transistor T1.

 If at the time of unlocking T1. there is always a short circuit of the indicator light, the protection device of the transistor T1 according to the invention again executes the operating cycle described above to block T1 again and thus avoid excessive heat dissipation in this transistor. Thus the transistor T1 will remain on for a very short time interval ET1 (see Fig. 2, B), of the order of a few microseconds, conditioned by the saturation times of the transistors T3 and T4 and by the desaturation time of the transistor T1 and by the charging time of the capacitor C1. The very brief duration of AT1 then limits the heat dissipation in the transistor TI. at a value lower than a predetermined value, below which there is no degradation of the operation of the transistor T1.

The operating cycle described above is repeated until the short circuit disappears (instant t2,
Fig. 2, A). In this case, at the instant t3 corresponding to the unlocking of the transistor T1 which immediately follows the instant t2, the intensity of the current in the supply circuit automatically returns to its nominal value IN (Fig. 2, B). The capacity C1 is completely discharged (Fig. 2, C) and the protection device according to the invention is made inoperative automatically. there is automatic unlocking or resetting of the control transistor Tî of the indicator light, with a delay (t3-t2) relative to the instant t2 of the disappearance of the short-circuit which is not greater than the time interval AT2 (Fig. 2, B) which separates two successive unlocks, of duration ATl, from the control transistor Tl, in the presence of a short circuit of the indicator light. This time interval ET2 depends on the values fixed for the thresholds S1 and S2 and on the time constant of the discharge circuit (C1, R4, T3, T4).

 In the application of the invention to the protection of a sight glass, described above by way of nonlimiting example.

AT1 and ET2 have the following values
AT1 N 10 vs
dT2 ~ 2 ms by choosing the following values for the passive components of the device according to the invention
R2 = 0.3Q
R3 = 2.2 kQ
R4 = 4.7 kQ
R5 = 1.5 kQ
C1 = 100 nF
The resistance of indicator R1 is such that. When the LED is on, the source delivers 100 mA at a voltage +
14 V POWER SUPPLY

According to an advantageous characteristic of the protection device of the invention, the transistors used are inexpensive standard transistors, with operating parameters of conventional values, in particular as regards the values of V and V this sat
be this sat '
The mounting of transistors T3 and T4 and the operation of this mounting in circuit sensitive to the two thresholds S1 and S2 are the basis of the device according to the invention and provide the following advantages
- low impedance on the transmitter of T4 and on the collector of T3 when these two transistors conduct,
- high impedance on the transmitter of T4 and on the collector of T3 when T4 is blocked,
- avalanche type switching as in a thyris.tor
- sensitivity to the two thresholds S1 and S2 establishing a hysteresis making it possible to control the duration ET2 of blocking of the control transistor T1 in the event of a short circuit.

 - realization of a "monostable" function of duration AT2 using only two inexpensive standard transistors.

The protection device of FIG. 1 is associated with a control transistor T1 placed on the "GROUND" side of the supply circuit. Of course, the invention also applies to the protection of such a control transistor placed on the "+ ALIM" side of this circuit. FIG. 3 shows such a device in which components identical or similar to those of FIG. 1 are identified by the same reference. The structure and operation of the device of FIG. 3 being very similar to those of the device of Fig.l, we will mention in the following only its distinctive features. It will be noted that the types of the transistors T1 to T4 are complementary to those used in the device of the
Fig. 1. Furthermore, the lines + ALIM and MASS are inverted with respect to the corresponding lines of the device in FIG. 1.The operation of the device
Fig. 2 is very similar to that of the device of FIG. 1, as those skilled in the art readily understand. It is therefore not described below.

 Of course, the invention is not limited to the embodiments described and shown which have been given only by way of example. In general, the invention applies to the protection of any semiconductor member controlling the supply of any electrical charge when it is subject to accidental short-circuits, a situation encountered by example, when repairing an electronic control unit. A short circuit can then result from accidental, and often 'fug-itive, contact of a metal tool with conductive parts of a circuit contained in the housing. When the contact is fleeting, the invention provides the advantage of protecting the circuit without apparently disturbing its operation.

 The device according to the invention also provides the advantage of being made up of standard components, of low cost and in reduced number. No component is critical, which makes mounting particularly reliable. Furthermore, the power dissipated during a short circuit can be controlled by the choice of the values of the resistor R4 and of the capacitor C1.

Claims (11)

1. A method of protecting an electronic control member of the electrical supply of a load against an overcurrent of the current admitted into this member, characterized in that (a) the control member is blocked in response to a exceeding the intensity of the current admitted into the control member with respect to a predetermined value, (b) the member is released periodically. control to then compare the intensity of the current admitted into the member with this predetermined value, (c) the control member is again blocked if the intensity of the admitted current is still greater than this predetermined value. 2. Method according to claim 1, characterized in that for step b), the control member is released during an interval. time (dut1) duration such that the thermal energy then released in this member remains less than a predetermined value, below which there is no degradation of the operation of L the control member. 3. Device for implementing the method according to any one of claims 1 and 2, for the protection of an electronic control member (Tl) placed in the feed circuit of a load (R1) in series with a resistance for measuring the intensity of the current admitted into this member (T1), characterized in that it comprises a semiconductor member (T2) controlled by the voltage across the terminals of the measurement resistor (R2) to trigger the charging of a capacity (C1) when the intensity of the current admitted into the control member (Tl) exceeds the predetermined value, and a circuit (T3, T4) controlled by the voltage across this capacity (C1) for perform a periodic unlocking of the control member (T1), so as to trigger the charging of the capacity C1 through the member (T2) when the intensity of the unlocked current is greater than the predetermined value, the circuit (T3 , T4) becoming inoperative otherwise. 4. Device according to claim 3, characterized in that the circuit (T3.T4) consists of a first and a second transistors T3, T4, respectively, of opposite conductivity types, the base of one being connected to the collector of the other, the collector of the first transistor (T3) being connected to a control electrode of the control member (T1) while the capacitor (C1) is connected between the emitter of the transistor (T3 ) and the point common to the collector of the transistor (T2) and to a resistor (R4) connected in series on the emitter of the transistor (T4). 5. Device according to claim 4, characterized in that a load resistor (R3) is connected between the load output terminal (R1) and the control electrode of the control member (T1). 6. Device according to any one of claims 3 to 5, characterized in that it further comprises means for applying a signal S for controlling the organ (T1) to trigger the supply of the load (Ri), or cutting off this supply, when the circuit (T3.T4) is inoperative. 7. Device according to claim 6, characterized in that the control signal S is applied to the base of the transistor (T3), through a resistor and a diode. 8. Device according to claim 6, characterized in that the control signal S is applied to the control electrode of the member (Tî), through a resistor and a diode. 9. Device according to any one of claims 3 to 8, characterized in that the control member (T1) is constituted by a transistor of the type Darlington. 10. Device according to claim 3, "characterized in that the circuit (T3, T4) is replaced by a programmable unijunction transistor. 11. Application of the device according to any one of claims 3 to 10, to the protection of the control of an electrically powered indicator light.