DE4022253A1 - Current limiting circuit for telecommunication installation - couples source electrodes of two FETs via resistance - Google Patents

Abstract

One terminal of the resistor is connected to the source electrode, and the other terminal the gate electrode of a FET (4). A second FET (6) is coupled to the first FET (4) such that the source of the first is connected to the source of the second via the resistor (5), and the gate of the first FET is connected to the source of the second via a first diode (7) with through flow direction from gate to source. The gate of the second FET is connected to the source of the first via second diode (8) with the through flow from to direction gate source. USE/ADVANTAGE - Symmetrical w.r.t current direction. Passage resistance and current loadability and linearity satisfy requirements for application in telecommuication systems.

Description

The invention relates to a current limitation circuit, consisting of a self-conducting field effect transistor and a resistor, the source electrode is connected to the gate electrode via the resistor.

As protection circuits against overcurrent, as in protection plugs are used for telecommunications systems, are, for example, PTC thermistors, fuses and solder pills known, the thermal shutdown at too high a current flow trigger process. Dependency is a disadvantage here the triggering process from the ambient temperature and the available tripping energy.

Furthermore, current-limiting components, such as one Field effect diode or curristor, known to be similar to one voltage-limiting component, such as a varistor or one Zener diode, limit the current to a maximum value. Curristors of this type can be implemented in terms of circuitry basically from a self-conducting field effect transistor in combination with a negative feedback resistor, as in Tietze-Schenk, semiconductors, 3rd edition, 1974, Chapter 20.7 is described. You come without external voltage and are therefore current-limiting two-pole elements insert directly into the current path, similar to a fuse bar.

The disadvantage here is that the o. G. Circuit for only one Current direction (I <= 0) is suitable. With negative currents the field effect transistor is operated in the 3rd quadrant and the function of a curristor is no longer ge give.  

The forward resistance of the curristor is the sum of the negative feedback resistance and the field Effect transistor resistance. This sum is allowed to permissible series resistance of the protective circuit stride. The achievable forward resistance lies here at around 300 ohms, making it for most protection circuits unsuitable in the telecommunications sector, their Resistances generally do not exceed a few ohms allowed to.

Furthermore, the current carrying capacity is only around 20 mA is too low in the known circuits, the telephoto communication range but 100 to 500 mA are required.

The field effect diode is the current-limiting element in the longitudinal branch of the signal path and is therefore subject to high Requirements for the linearity in the pass band in order to Ver to avoid strains due to the inactive protective element. In the known circuit, the linearity is u. U. unung sufficient.

The task is therefore to ent a current limiting circuit wind that is symmetrical with respect to the current direction and their forward resistance, current carrying capacity and line arity the requirements of use in telecommunications systems is sufficient.

The solution to this problem arises from the mark the features of claim 1.

If the circuit is interpreted as a two-pole circuit, then this corresponds to  Drain electrode of the first field effect transistor of the anode and that of the second field effect transistor Cathode. A current flow through such a fiction according to the two-pole effect from the anode to the cathode u. a. a voltage drop across the coupling resistor. This will via the feedback the gate potential and thus the Resistance of the first field effect transistor certainly. When a certain current is reached this resistance is so great that no further increase in Current is possible even if the voltage is above the circuit is increased. The second field effect transistor is always low-resistance in this current direction. A Reversal of the current direction symmetrically swaps the Functions of the respective field effect transistors. Now the second field effect transistor limits its dynamic resistance the current during the first field effect transistor is turned on. The fiction according current limiting circuit therefore works bidi rectional and is for use in telecommunication systems usable.

By connecting several bidirectional units in parallel the current can be divided by dividing the current path Increase resilience and at the same time the forward resistance reduce stand. The parallel connection also shows, due to sta differentistic behavior, one higher linearity than the individual bipoles. Such Parallel connection is as a hybrid module or in inte grier form to realize.

Further advantageous embodiments of the invention result itself from the subclaims.

In the following the invention and its preferred Ausge  events explained using the drawings. Show it:

Fig. 1 shows the characteristic curve of a field effect diode,

Fig. 2 shows the equivalent circuit diagram of a field effect diode,

Fig. 3, the bi-directional current limiting circuit with a common balancing resistor,

Fig. 4 shows the bidirectional current limiting circuit with separate trimming resistors and

Fig. 5 shows the characteristic of a bidirectional current limiting circuit.

Fig. 1 shows the characteristic of a known current-limiting field effect diode. The current through the field effect diode is shown as a function of the voltage across the diode. In the front part I, the work area, the current increases linearly with the voltage. In part II, the function shows a non-linear behavior and in part III, the limiting range, the maximum current through the diode is independent of the voltage applied.

Fig. 2 shows a technical implementation of a field effect diode, which consists of a field effect transistor 1 and a negative feedback resistor 2 . The negative feedback resistor stood 2 connects the source electrode of the field effect transistor 1 to its gate. First of all, the potential at gate G and source S is the same (ie U _GS = 0) and thus the self-conducting field effect transistor 1 has a low resistance. When current begins, the source potential increases, ie U _GS becomes negative and the field effect transistor thus has a higher resistance. Above a certain current, the field effect transistor 1 is so high-resistance that a further increase in the current is no longer possible, even if the voltage across the circuit is increased.

Fig. 3 shows a bidirectional current limiting circuit according to the invention with a common trimming resistor. A field-effect transistor 4 is connected via a coupling resistor 5 to a field-effect transistor 6 in such a way that the two field-effect transistors 4 , 6 are source-coupled. The gate of the field effect transistor 4 is acted upon by the source potential of the field effect transistor 6 , ie the potential at point 10 after the resistor 5 . Analogously, the gate of the field effect transistor 6 is applied with the potential at point 9 in front of the resistor 5 . In the gate-source branches, diodes 7 , 8 with the forward direction gate-source are contained. First, when a current is not flowing, the potential at the source and gate of the first field effect transistor 4 is the same and the field effect transistor 4 is thus low-resistance. When current begins, the current flowing from the drain D of the first field-effect transistor 4 to the drain of the second field-effect transistor 6 , the voltage in point 9 before the coupling resistor 5 is higher than in point 10 after the coupling resistor 5 . The gate-source voltage of the field-effect transistor 4 is thus negative and the latter becomes high-resistance. The diode 7 is in the conductive state. It applies to the field effect transistor 6 that at the beginning the source and the gate potential are also the same and thus the field effect transistor 6 has a low resistance. With the onset of the current, the potential in point 9 is greater than that in point 10 and thus blocks diode 8 . The field effect transistor 6 remains conductive in this current direction.

A change in the current direction causes the functions of the two field effect transistors 4 , 6 to be exchanged symmetrically. Now the field effect transistor 6 changes its resistance and has a current-limiting effect while the field effect transistor 4 is conductive.

The diodes 7 and 8 serve on the one hand to create defined potential relationships at the gates of the field effect transistors 4 , 6 and on the other hand prevent junction field effect transistors (JFET) from an undesirable current flow in the gate-source branches.

Fig. 4 shows a bi-directional current limiter with separate balancing resistors 11, 12. The source electrode of a field effect transistor 14 is connected via a resistor 11 and a further resistor 12 to the source electrode of a field effect transistor 16 . The gate electrodes of the two field effect transistors 14 and 16 are acted upon by the potential between the two resistors 11 and 12 of the point 13 . In each of the two gate branches there is a diode 17 and 18 , the forward direction of which points away from the gate. The shape of the characteristic curve is separated by the two resistors 11 , 12 for both forward directions. This is necessary if the two field effect transistors 14 and 16 have different characteristics.

A common adjustment for both forward directions, as is carried out in a circuit according to FIG. 3, requires identical field effect transistors 14 and 16 .

Fig. 5 shows the resulting characteristic of a bidirectional current limiting circuit according to the Invention according to the basic bipoles shown in Fig. 3 or 4. Darge represents the forward current as a function of the applied voltage. In working area II this is a linear function of the voltage, in the positive transition area II and in the negative transition area IIa there is a deviation from this linear relationship, so that the current in the positive limiting area III is set to a positive maximum current and in the negative limiting area IIIa to a negative limiting current . These maximum let-through currents are independent of the applied voltage in the limiting areas, and there is a bidirectional current limiting element with a symmetrical current curve.

Claims (4)

1. Current limiting circuit comprising a field effect transistor and a resistor, one pole of the resistor being connected to the source electrode and the other to the gate electrode of the field effect transistor ( 4 ), characterized in that a second field effect transistor ( 6 ) is connected to the first field effect transistor ( 4 ) is coupled such that the source of the first field effect transistor ( 4 ) via the resistor ( 5 ) with the source of the second field effect transistor ( 6 ) is connected to the gate of the first field effect transistor ( 4 ) via a first diode ( 7 ) Pass-through gate-source to the source of the second field-effect transistor ( 6 ) is connected and that the gate of the second field-effect transistor ( 6 ) is connected via a second diode ( 8 ) to the pass-through direction gate-source to the source of the first field-effect transistor ( 4 ) . 2. Current limiting circuit according to claim 1, characterized in that the two field effect transistors ( 4 , 6 ) are connected to one another by two serial coupling resistors ( 11 , 12 ), the gate voltages of the two field effect transistors ( 14 , 16 ) between the two resistors ( 11 , 12 ) can be tapped. 3. Current limiting circuit according to claim 1 or 2, characterized by a parallel connection of at least two two poles, each consisting of two field effect transistors ( 4 , 6 ; 14 , 16 ), two diodes ( 4 , 8 ; 17 , 18 ) and a resistor ( 5 ; 11 , 12 ). 4. Current limiting circuit according to claim 3, characterized records that the parallel connection as a hybrid module or is carried out in an integrated form.