FR2627920A1 - INTENSITY LIMITING CIRCUIT FOR TELEPHONE INSTALLATION - Google Patents

Abstract

This limiting circuit is intended to limit the intensity of the current in at least one annex device supplied by the public network line; it comprises a limiter 22 mounted in series between, at the input, a line terminal 101 and, at the output, an apparatus terminal 102. According to the invention, the circuit comprises a follower transistor 12 and means for measuring the current 23 controlling the follower transistor 12, the limiter 22 being mounted in parallel with the follower transistor 12. The current measuring means 23 control the follower transistor 12 in such a way that this follower transistor 12 turns off for high current values of l annex equipment and lead for the low intensity values of the annex equipment. The limitation is thus practically independent of the ambient temperature, despite the presence of a PTC resistor 13 in the limiter 22.

Description

 The present invention relates to a limiter circuit for telephone installation, intended to limit the intensity of the current in at least one auxiliary device supplied by the line of the public network, this circuit comprising a limiter connected in series between, at the input, a line terminal and, at the output, an apparatus terminal.

 Telephone installations comprising ancillary equipment supplied by the public network line must have a current limiting circuit enabling them to comply with the prescribed connection standards. This current limiting circuit is placed at the input of the telephone installation, after the overvoltage protection and after the protection against reverse polarity, in series with the auxiliary equipment.

It consists, in the state of the art, of three elements connected in parallel, namely a capacitor, a resistance of predetermined fixed value and a resistive element with positive temperature coefficient (PTC element). Compliance with connection standards will be obtained by careful adaptation of the three elements to the auxiliary equipment.

 In operation, there will be a more or less significant voltage drop in this current limiting circuit, depending on the supply current.

 If the auxiliary equipment has a low current, the current limiting circuit will have low resistance because the PTC element will be cold. On the other hand, for a higher intensity, the resistance will increase due to the heating of the PTC element due to the passage of the current. The operation of the current limiting circuit therefore strongly depends on the ambient temperature, in particular in the case of low currents.

 The object of the present invention is a limiter circuit intended for telephone installations comprising an auxiliary apparatus, a circuit which is simple, which makes it possible to meet connection standards, which exhibits, in the case of low intensities, a low dependence on with respect to the ambient temperature thanks to a negligible voltage drop, and which makes it possible to ensure the supply of energy to the auxiliary equipment, in particular to allow the charging of an accumulator.

 To this end, according to the present invention, the limiter circuit comprises a follower transistor and means for measuring the current controlling the follower transistor, and the limiter is mounted in parallel on the follower transistor.

We will now give an exemplary embodiment of the invention, described with the aid of the appended drawings in which
FIG. 1 shows the input circuit of a telephone set, and
- Figure 2 shows the diagram of a current limiter.

 A telephone installation is made up, for example, of an input circuit, a telephone set and at least one auxiliary device. In FIG. 1, the public network line, the telephone set and the auxiliary equipment have generally been indicated only by their corresponding connection contacts. Thus, the input circuit of the telephone set is connected to the public network line by input contacts 1 and 2, to the telephone set by telephone set contacts 3 and 4 and to the auxiliary equipment by contacts d apparatus 5 and 6. The input circuit comprises a protection against overvoltage 7, a protection against reverse polarity 8, a voltage regulator 9 and a limiter circuit 10.

 The overvoltage protection 7 protects the telephone installation against undesirable voltage peaks which may appear on the line of the public network. The protection against reverse polarity 8 allows the telephone system to be connected without worrying about the polarity of the line of the public network. The voltage regulator 9 limits the voltage to a value compatible with the auxiliary equipment. The limiter circuit 10 limits the intensity of the current in the auxiliary equipment within the limits provided for by the connection standards.

 The two inputs 71 and 72 of the overvoltage protection circuit 7 are connected to the input contacts 1 and 2.

One of the outputs 13 of the overvoltage protection circuit 7 is connected to the telephone set contact 3 and to one of the inputs 81 of the polarity reversal protection circuit 8. The other output 74 of the protection circuit against overvoltages 7 is connected to the telephone set contact 4 and to input 82 of the polarity reversal protection circuit 8. From one of the outputs 83 of the polarity reversal protection circuit 8, apply to an input 91 of the voltage regulator 9 a voltage, for example positive, and, from the latter, the regulated voltage present at output 92 is applied to the switchgear contact 5. The other output 84 of the reverse protection circuit of polarity 8, output which is, in the example, of negative polarity, is connected at the input of the limiter circuit 10, on a line terminal 101. At the output of the limiter circuit 10, a conductor connects the switchgear terminal 102 to the switchgear contact 6 A connection is provided between the line terminal 101 and a reference terminal 93 of the voltage regulator 9, as well as between a potential terminal 103 of the limiter circuit 10 and the switchgear contact 5.

 FIG. 2 shows an exemplary embodiment of the limiter circuit 10. This includes a transistor 11 which, in the example shown, is a PNP transistor, a follower transistor 12, a PTC element 13, a capacitor 14, an upstream resistance 15, a follower resistor 16, a base resistor 17, a collector resistor 18, a Zener diode 19 and a voltage limiter 20.

 For the follower transistor 12, a field effect MOS transistor is preferably chosen, because of its low consumption. This follower transistor 12 is connected to the circuit by a source electrode 121, a drain electrode 122 and a gate electrode 123.

 The transistor 11 comprises emitter 111, collector 112 and base 113 electrodes and constitutes, with the resistors 15, 17 and 18, a means for measuring the current 23, protected by the Zener diode 19. These means measure the current consumed by the auxiliary equipment and control in particular the conductivity of the follower transistor 12, via the potential of the gate electrode 123.

 The components 13, 14 and 16 are mounted in parallel between a terminal 21 and the switchgear terminal 102, and constitute a current limiter 22 according to the state of the art.

The upstream resistor 15 connects the terminal 21 to the line terminal 101. The follower transistor 12 is mounted in parallel on the current limiter 22, the source electrode 121 being connected to terminal 21, the drain electrode 122 to the switchgear terminal 102 and the gate electrode 123 at one of the contacts of the collector resistor 18. The other terminal of the collector resistor 18 leads to the potential terminal 103. The transistor 11 is connected by its collector 112 at the gate electrode 123, by its emitter 111 at the line terminal 101 and by its base 113 at one of the terminals of the base resistance 17. The other terminal of the base resistance 17 terminates to terminal 21. The Zener diode 19 connects the gate electrode 123 to the source electrode 121, the voltage limiter 20 being mounted between the two connection terminals 101 and 102.

 If the current consumed by the auxiliary equipment exceeds a given value, determined by the upstream resistance 15, the transistor 11 of the current measurement means 23 will pass to saturation, so that the gate electrode 123 will be practically at the potential. from line 101.

The follower transistor 12 will then block the flow of current between its source electrode 21 and its drain electrode 122, so that the limiter circuit 10 will allow it to be kept within the limits of connection standards, the current being limited by the current limiter 22 and the influence of the upstream resistance 15, of very low value, being negligible.

 If the current passing through the upstream resistance 15 falls below a predetermined value, the current in the base resistance 17 of the base 113 will become too weak.

The transistor 11 will start to block and the potential on the gate electrode 123 will take the value present on the potential terminal 103. The conductivity of the follower transistor 12 will increase rapidly between its electrodes 121 and 122, short-circuiting the current limiter 22. Only the upstream resistance 15, of very low value, will then be active between the terminals 101 and 102 in the limiter circuit 1C. Unlike the PTC element 13, this resistance is practically independent of the ambient temperature.

 If the ancillary equipment includes an electric accumulator to provide the relay during peak consumption, the limiter circuit 10 allows rapid charging of this accumulator to a predetermined voltage value, thanks to an advantageous reduction in the resistance value between the terminals 101 and 102 of the limiter circuit 10, which then plays the role of load resistance.

 In an advantageous embodiment, a transistor of the BC546 type is chosen as the transistor 11 and as a follower transistor 12 an IRF710 type field effect MOS transistor. Typical resistance values are 20 Q for the upstream resistance 15, 750 n for the follower resistance 16, 100 kfl for the base resistance 17 and 1 Mn for the collector resistance 18. The Zener diode 19 limits the voltage between l grid electrode 123 and the source electrode 121 to approximately 16 V. The voltage limiter limits the voltage between the line terminal 101 and the switchgear terminal 102 to approximately 33 V. The capacitor 14 typically has a capacity of 22 FF, and it consists for example of a low-loss electrolytic capacitor provided for a direct voltage of 63 V. The PTC element 13 has a resistance value of approximately 110 n at 200C.

 Of course, those skilled in the art can easily imagine, depending on the needs, different embodiments of this circuit, either by modifying the values of the resistors, by reversing the polarities - the transistor 11 of PNP type being then replaced by an NPN type transistor - or by replacing the follower transistor 12 by a bipolar transistor or by a Darlington circuit, more expensive.

 The limiter circuit 10 can be advantageously used in public telephone installations with automatic coin mechanism.

Claims (6)

 1. A limiter circuit for telephone installation, intended to limit the intensity of the current in at least one auxiliary apparatus supplied by the line of the public network, this circuit comprising a limiter (22) mounted in series between, at the input, a terminal of line (101) and, at the output, an equipment terminal (102), characterized in that it includes a follower transistor (12) and means for measuring the current  (23) controlling the follower transistor (12), and in that the limiter (22) is mounted in parallel on the follower transistor (12).  2. The limiter circuit of claim 1, in which the current measuring means (22) control the follower transistor (12) in such a way that this follower transistor (12) is blocked for high intensity values of the auxiliary equipment and drive for the low intensity values of the auxiliary equipment.  3. The limiter circuit of one of the preceding claims, in which the voltage across the limiter circuit (10) is limited, between the line terminal (101) and the switchgear terminal (102), by a Zener diode (20).  4. The limiter circuit of one of the preceding claims, in which the transistor (21) is an MOS field effect transistor.  5. The limiter circuit of one of the preceding claims, in which the current measuring means (23) comprise a transistor (11) with an upstream resistance (15) and a basic resistance (17) in its current mesh and in that the upstream resistance (15) is mounted, between the line terminal (101) and the switchgear terminal (102), in series with the assembly formed by the current limiter (23) and the follower transistor (12) connected in parallel.  6. A telephone installation comprising a limiter circuit according to one of the preceding claims, characterized in that it is connected to the limiter circuit (10)  - on the one hand: by the potential terminal (103), to a first switchgear contact (5) and, by the switchgear terminal (102), to a second switchgear contact (6) of the additional equipment,  - and on the other hand: by the line terminal (101), to a protection circuit against reverse polarity (8)