FR2469031A1 - Protector for current limited power supplies - uses changing resistance of diode in output current path to produce rapid recirculating current at high output - Google Patents

Abstract

The power dissipation of the pass element (1) in a series regulated power supply rises to high levels under feedback current limiting. This occurs when over current protection is provided by comparison of load current (R1,Rs) against ballast current (R1,R2) voltage dividers in each current path. By inclusion of a non-linear element (7) such as a diode, in the output current path (R7,Rs) the voltage at the over current comparator (6) input reflects the change in impedance of the diode as it moves from heavily conductin to lightly conducting. This allows a rapid initial current foldback, so reducing pass element dissipation; and as the current falls the diode resistance increases, so the current changes little. The current limiter is linked to the ballast resistor by two diodes which are connected to the bases of two transistors. A capacitor is connected in parallel to R1, to accelerate current limitation provided by the transistors.

Description

The present invention relates to a device for protecting a stabilized voltage supply. It also relates to stabilized voltage supplies comprising such a device.

 The operation of the stabilized voltage power supplies generally comprises two phases: - a regulation phase, during which the current flowing in the variable load impedance of the power supply varies so as to maintain the stabilized voltage at output; - a phase of limitation of the current flowing in the variable load impedance during which the stabilized voltage is no longer maintained at the output.

Current limitation can be achieved in different ways. This limitation can in particular be achieved by measuring the difference of the currents flowing in the variable load impedance and in a constant load impedance and by maintaining this difference at a limit value. The difference in currents can be obtained, to within a constant, by a differential device which receives the voltages across two resistors in series with the load impedances. This device generally also ensures the comparison of the difference in voltages it receives to a limit value and the action on the ballast which delivers the current so that the difference in voltages does not exceed the limit value.

The characteristic VS = f (Is), which represents the variations of the output voltage Vs across the terminals of the variable load impedance, as a function of the current IS in this impedance, is formed (as shown in FIG. 3) , during the regulation phase, by a horizontal line, -because the output voltage is the regulated voltage VSR and during the current limitation phase, by a line segment of positive slope which connects a point
A with coordinates VSR, ISM at a point B on the ordinate
VS zero.

The power dissipated in the ballast is substantially equal to (VR - Vs). , where V, represents the voltage at the input of the ballast which is higher than the regulated voltage VSR. The power dissipated in the ballast is more important since the difference between the voltages VR and YB is high and the value of the current 's is high. It is in the limitation phase, - when the IS current is greater than
ISM12, that the power dissipated in the ballast is the most important. Indeed, in this zone the current IS has a high value and close to its maximum value 'SM and the difference between VR and Vs is not negligible.

The problem that arises is that the ballast must be fitted with large radiators whose thermal dissipation depends on the maximum power to be dissipated, while this maximum power is only dissipated exceptionally and in an operating zone fairly small ballast.

The present invention solves this problem.

The device for protecting a stabilized voltage supply according to the invention comprises a non-linear element as a function of the current, mounted in series with one of the load impedances, which ensures, within a range of variation of the load impedance variable, for the same value of this impedance, three different values of the output voltage of the power supply Vs. Only the extreme values of the output voltage correspond to stable operating points and the highest value is equal to the stabilized voltage VSR. The non-linear element can in particular be constituted by a diode or by a DC voltage source0
The protective device according to the invention modifies the characteristic Vs = f (Is) of the power supply (as shown in FIG. 5).

This characteristic always includes a regulation phase which consists of a horizontal line at the VSR value. The characteristic Vs = f (Is) is modified in the current limitation phase which is no longer constituted by a straight line but by a curve. What is interesting is that this curve has an unstable operating zone which is precisely that which was annoying because the power dissipated by the ballast was the greatest there. Consequently, with the device according to the invention, it is no longer possible to have stable operation with current limitation in the area of the characteristic where IS is greater than 3sM / 2. From an unstable point, in order to obtain stable operation, one passes either to a point of the characteristic VS = f (IS) for which the voltage Vs is equal to the regulated voltage, or to a point of the characteristic VS = f ( IS) for which the current IS and the power dissipated by the ballast are low.

the protective device according to the invention therefore makes it possible to reduce the maximum power that the ballast must dissipate; smaller heat dissipation radiators are then sufficient to protect the ballast.

Other objects, characteristics and results of the invention will emerge from the following description, given by way of nonlimiting example, and illustrated by the appended figures which represent
- Figure 1, a block diagram of a stabilized ballast voltage supply
- Figure 2, a block diagram of a current limiting device by the differential method, according to known art
- Figure 3, the characteristic Vs = f (IS) of a power supply comprising a device according to Figure 2; ;
- Figure 4, a schematic diagram of an embodiment of a power supply according to the invention!
- Figure 5, the characteristic V5 = f (Is) of the power supply of Figure 4
- Figure 6, a practical embodiment of the ballast and the current limiting device in the case of the power supply of Figure 4.

 In the various figures, the same references designate the same elements, but, for reasons of clarity, the dimensions and proportions of the elements have not been respected.

 Figure 1 shows a block diagram of a stabilized ballast voltage supply.

This supply comprises a brush which is a linear amplifier which supports the difference between its input voltage VR which is generally a rectified voltage and the output voltage of the supply Vs. A comparator 4 receives, on the one hand, a voltage i: swimming of the output voltage V vs yes is obtained by a circuit 3 connected to the output of the power supply and, on the other hand, a reference voltage Vz which can be obtained by a circuit 2 connected to the voltage VRo During the regulation phase, the comparator 4 controls the ballast 1 as a function of the difference (Vz - α Vs) so that it delivers a current I which makes it possible to obtain the regulated voltage VSR at the output of the power supply. A current limiting device 5 measures the current IS which flows through the variable load pedance of the power supply, which is not shown in FIG. 0 device 5 limits the current IS by acting on the. ballast 1 when this current becomes excessive. We then operate in limitation and the output voltage of the power supply is no longer equal to the regulated voltage.

FIG. 2 represents a block diagram of a device for limiting current by the differential method according to the known art. As already mentioned above, this device measures the difference of the currents IS and I1 which flow in the variable load impedance of the power supply and in a constant load impedance0 In the following description, the different impedances will be considered as only resistive, but it is understood that the invention applies to cases where the impedances are not only resistive
This device is made up of variable load resistors RS and fixed resistors R2. your resistors RS and R2 are each in series -with another resistance, respectively R- and R1. your resistances R, RS
and R1, R2 are connected in parallel. The difference of the currents I and I1 which circulate in R and R
U 2 is obtained, to within a constant, by a differential device 6 which receives the voltages across the resistors R1 and -R. This device also ensures the comparison of the difference of the voltages it receives to a limit value and the fact on the ballast
1 so that this difference does not exceed the limit value.

Figure 3 shows the characteristic
VS = f (IS) of a power supply comprising a device according to FIG. 2o As has already been said previously, this characteristic is constituted during the regulation phase, by a horizontal straight line at the value of the regulated voltage, VsR and during the phase of limitation, by a segment of -right AB of positive slope which connects a point A of
VSR, ISM coordinate at a point B coordinate, VS
equals zero and ISm. It has been shown that the power dissipated by the ballast is maximum when 15 =
ISo / 2, where ISo is the current at the point of intersection of the line passing through A and 3 and the line represented
feeling the variation of V-as a function of IS which de
increases with Is. your dissipated power is thus always maximum when 15 is higher than ISM / 2 It is thus approximately the part of the characteristic which
is indicated by a double arrow in FIG. 3 which
is the most dangerous for ballast.

your Figure 4 shows a block diagram of an embodiment of a power supply according to the invention. the power supply according to the invention differs from the known art because it comprises a non-linear element as a function of current 7, mounted in series with one of the resistors R (as shown in the figure 4), R1 or-R2
the non-linear element as a function of the current 7 can be constituted by a diode or by a DC voltage source. This non-linear element as a function of the current ensures in a range of variation of the variable load resistance RS, for a same value of this resistance, three different values of the output voltage of the supply Vs. Only the extreme values of the output voltage correspond to stable operating points and the highest value is equal to the stabilized output voltage VSR .

Figure 5 shows the characteristic
VS = f (IS) of a power supply comprising a protection device according to the invention0
This characteristic always includes a regulation phase, which consists of a horizontal straight line at the VSRO value. What changes is the appearance of the characteristic during the current limitation phase. The characteristic ngest more then constituted by a straight line segment but by a curve which always goes from point A of coordinates VSR, 'SM to point B of coordinates Vs equals zero and ISm.

Your concavity of the curve Au is such that the line of equation V5 = R5015 does not cut it for the values of resistance R5 greater than R3. When R5 equals R3, the line of equation VS = R3.Iss is tangent to the curve AB at a point F. For the values of the variable load resistance ES greater than R3, we therefore operate in regulation.

 For each value of the variable load resistance between R3 and R4, the line of equation Vs = RS.IS, intersects the curve AB at two points and the horizontal line of regulation at another point. The value ~ R4 is that for which the line of equation VS = RS.Is goes to point A. There are therefore for each value of the load resistance, three different possible values of the output voltage of the power supply.

We will examine the stability of the three possible operating points when the load resistance is between R3 and R4, taking for example in Figure 5 a line of equation VS = RS.Is which cuts the curve AB in two points
D and E and the regulation line at point C
Points C and E correspond to the extreme values of the output voltage and the highest value of the output voltage is the stabilized voltage VSR at point C.

Point C is of course a stable operating point because, if for any reason, there is a slight increase in the current IS, as symbolically represented in Figure 5 by an arrow parallel to the equation line VS = RS.IS which passes to point C, the comparator 4 acts on the ballast 1 so that the output voltage which had become slightly higher than VSR. Finds the value VSR, this is symbolized by an arrow in opposite direction to the first in figure 5.

If, on the contrary, there is a slight decrease in the current Is, the output voltage becomes slightly lower than VSR and the comparator 4 acts on the ballast 1 so that the voltage becomes again equal to the stabilized voltage VSR.

We will now examine the stability of the intermediate point D. The curve AB satisfies the condition Vt = 1, where Vg-represents the difference of the voltages applied to the device 6 in figure 4 and where 1 equals the limit value at which the device 6 stabilizes the difference in voltages V.. The curve A3 divides the plane into two zones, the zone on the left which contains the regulation phase and or is less than 1 and the zone on the right where V is greater than 1. When for some reason there is a slight increase in the current IS from point D, the operating point passes into the zone where V is less than 1, consequently the device 6 does not act on the ballast 1 to limit the current and the latter continues to coulter until that the operating point arrives at point C which is a stable operating point as we saw previously. Similarly, if from the point
D there is a slight decrease in the IS current, the operating point passes into the zone where is greater than 1. The device 6 then acts on the ballast 1 to decrease the current Is. Da decrease in the IS current continues until what the operating point passes to point E which is a stable operating point as we will see. The point D is therefore an unstable operating point.

When from point E, a slight increase in current occurs, the operating point passes in the zone where VC is greater than 1, the device 6 then acts as the ballast 1 to limit the current 15 and the point of operation returns to point E.

Similarly when from point E, the current
Is undergoes a slight decrease, the operating point passes in the region where V is less than 1.

Be device 6 does not act on the ballast 1 to limit the current, but the comparator 4 associated with circuits 2 and 3 then acts on the ballast 1 to increase the output voltage and causes a slight increase in the current which brings back the point of operating at point E. te point E is therefore a stable operating point.

your power supply operating points are stable when the slope of the equation line
VS = R5. IS is less than the first derivative of the AB curve. This is what produces on the BS portion of this curve. Bes power supply operating points are unstable when the slope of the right
VS = RS. IS is greater than the first derivative of, the curve AB, this is what occurs on the portion AS of this curve. your portion AF of the curve AB, for which the consumption of the ballast would be the greatest if there were stable operation, corresponds to unstable operation and this makes it possible to limit the importance of the radiators associated with the ballast.

Ba FIG. 6 represents a practical embodiment of the ballast and of the device for limiting the current in the case of the power supply shown in FIG. 4.

 The current limiting device is constituted by a transistor 21 of the N27J type, the base of which is connected to the point common to the resistors R1 and R2 and the emitter of which is connected to the point common to the non-linear element 7 and to the resistor variable charge Rs. In FIG. 6, the element 7 is constituted by a diode. The collector of T1 is connected to the input of the ballast. The ballast is essentially constituted by two transistors T2 and T3, of the NPN type, which are mounted in Darlington, resistors R5 and R6 complete the assembly.

 The current limiting device is connected to the ballast via two diodes D2, and D which are connected to the bases of the transistors 22 and T3. Two other diodes D1, between the emitter of T2 and the resistor R1 and D4, between the ground and the point common to D2 and D3 are used to protect the assembly.

A capacitor C1 is connected in parallel to R1. It accelerates the limitation of the current that T1 must achieve. comparator 4 is connected to the base of transistor T3.

Claims (5)

REVESI) ICATIOTS 1. Device for protecting a stabilized voltage supply ensuring the limitation of the current flowing in a variable load impedance, this limitation being achieved by measuring the difference of the currents flowing in the variable load impedance and in a constant load impedance and maintaining this difference at a limit value, characterized in that it comprises a non-linear element as a function of the current (7) connected in series with one of the load impedances, which ensures, within a range of variation of the variable load impedance, for the same value of this impedance, three different values of the power supply output voltage, only the extreme values corresponding to stable operating points and the highest value being equal to the stabilized voltage (VER )  2. Device according to claim 1, characterized in that the non-linear element (7) is a diode. 3. Device according to claim 1, characterized in that the non-linear element (7) is a source of direct voltage. 4. Stabilized voltage supply ensuring the limitation of the current flowing in a variable load impedance, this limitation being achieved by measuring the difference of the currents flowing in the variable load tolerance and in a constant load impedance and by maintaining this difference at a limit value, characterized in that it comprises a device according to one of claims 1 to 3. 5 Power supply according to claim 4, characterized in that the difference in currents is obtained, to within a constant, by a differential device (6) which receives the voltages across two resistors (R, R1) in series with the load impedances (RS, R2) this device also ensuring the comparison of the difference in voltages that l1 receives at a limit value (1) and the action on the ballast (1) which delivers the current (Is) so that the difference in voltages does not exceed the limit value.