DE4008904A1 - Network supply circuit for LV load resistances - uses trial controlled by ignition circuit with schmitt trigger - Google Patents

Abstract

The network supply circuit uses a triac (TC) receiving ignition pulses from an ignition circuit (5) during the positive half waves of the network voltage, with a charge capacitor (C2) connected in parallel across the load resistance. The ignition circuit (5) has a Schmitt trigger (6) with a first transistor (T1) controlled by a capacitor (C1) which is connected in series with a diode (D). A Zener diode (Z1) lies in parallel with the series circuit, the Zener voltage limiting the charge of the control capacitor (C1), which provides the ignition pulse energy. ADVANTAGE - Simplified ignition circuit.

Description

The invention relates to a power supply for generating a Low voltage on a load resistor from the Mains AC voltage, with a triac or thyristor an ignition circuit with opposite Zero voltage crossings of the AC mains voltage phase-shifted ignition pulses ignite and the shortly before blocks the zero voltage passage.

Such a power supply is in the literature "Introduction to Electronics", Ed. Jean Pütz, 4. Edition, April 1974, page 204. There is the Low voltage is not DC voltage, but one AC voltage. Accordingly, are in the positive and the negative half-wave ignition pulses are provided.

Another power supply is in the reference "Siemens Components 21 "(1983), No. 1, pages 19, 20 under the Title "Transformerless DC voltage generation from the Network with Sipmos transistor ". It is here on Load resistance generates a DC voltage. The named Transistor is a special component. The load resistance is a charging capacitor connected in parallel. The named Transistor is only during the positive line half-wave conductive. The charging process of the charging capacitor is done by the transistor at a certain peak voltage  canceled.

For electronic circuits, their components in CMOS technology are built, the power requirement is low in itself. Therefore, according to the state of the art instead an expensive transformer power supply an inexpensive capacitor or resistance power supply used. With these power supplies the difference between the mains voltage and the low voltage drops on a series resistor. The current flows through this which is also consumed by the load resistor. For this Basically, these power supplies are already medium Unsuitable power consumption. If the series resistor is ohmic, it consumes a lot of power in the form of heat. Is he capacitive, then the power supply becomes expensive. In which Resistor power supply is the ratio of Input voltage at the power supply to the output voltage at Load resistance crucial for the uselessly consumed Energy (heat). That's why resistance power supplies usually with only one of the two network half-waves operated via a one-way rectification.

The object of the invention is a power supply unit of the beginning to propose the type mentioned with a triac or Thyristor works and its ignition circuit is simple.

According to the invention, the above task is for a power supply unit initially mentioned type solved in that the Ignition circuit the triac or thyristor only for positive Half waves ignite, so that the triac or thyristor one charging capacitor parallel to the load resistor only with reloads a rest of the positive half waves that the Ignition circuit has a Schmitt trigger, the second transistor at the gate of the triac or thyristor lies and the first transistor on a capacitor lies, with a diode connected in series to it is connected in parallel to a zener diode, the Ignition pulse arises in that after loading the Capacitor with the positive half-wave through to one  the zener voltage limited value, the second transistor turns on and ignites the triac or thyristor, where the capacitor is the energy of the ignition pulse delivers.

This circuit has several advantages. On the one hand is the power switching element, namely the triac or Thyristor, as a commercially available, widely used component cheap. A triac is preferably used since this is usually much cheaper to buy than a thyristor. On the other hand, in the circuit Energy consumption at a series resistor is low because of the Current only flows when the charging capacitor is on the desired low voltage is charged. This has not only the advantage of low energy consumption, but in particular also the advantage that the series resistor correspondingly less heated.

It is also favorable that no additional component for Rectification is necessary.

It is particularly advantageous that the capacitor is double is used. On the one hand, it serves to determine the time until the ignition pulse occurs. On the other hand, it serves with its charge as an energy source for the ignition pulse. It is a short, powerful ignition pulse without further achieved. The ignition circuit is overall high impedance, what with low power consumption connected is. It still delivers that for the triac necessary, powerful ignition pulse.

In a preferred embodiment of the invention, the negative half wave the Zener diode in the forward direction operated and the capacitor kept discharged, being the first transistor is turned on. This is the time of the ignition pulse in the positive half wave (Phase shift) can be precisely defined.  

Further advantageous embodiments of the invention result from the subclaims and the following Description of an embodiment. In the drawing demonstrate

Fig. 1 is a circuit diagram of a power supply with complete representation of the ignition circuit,

Fig. 2 shows the voltage curve at the Zener diode,

Fig. 3, the voltage acting on the charging capacitor and

Fig. 4 shows the voltage across the load resistor.

A power supply unit has connections ( 1 , 2 ) for connecting the neutral conductor (N) and the phase (L) of the household AC network. The consumer (load resistor) to be supplied can be connected to connections ( 3 , 4 ) and requires a small DC voltage compared to the AC mains voltage. The consumer is, for example, a microcomputer circuit or another electronic circuit, for example for controlling a household appliance.

The power supply unit has a triac (TC), one main electrode of which is connected to the connection ( 2 ) and the other main electrode of which is connected to a charging capacitor (C 2 ) via a series resistor (R 10 ).

An ignition circuit ( 5 ) is located at the gate connection of the triac (TC). The ignition circuit ( 5 ) has a Schmitt trigger ( 6 ) consisting of resistors (R 3 to R 8 ) and a first transistor (T 1 ) and a second transistor (T 2 ). The collector of the second transistor (T 2 ) is at the gate of the triac (TC). A resistor (R 9 ) between the gate and the one main electrode of the triac (TC) serves to safely lock the triac (TC).

The base of the transistor (T 1 ) is located across the resistor (R 4 ) between a diode (D) and a capacitor (C 1 ). The resistor (R 3 ) is parallel to the diode (D). The capacitor (C 1 ) is connected to the connection ( 2 ). A zener diode (Z 1 ) is connected in parallel with the series connection of the capacitor (C 1 ) and the diode (D). The diode (D) is connected via resistors (R 1 , R 2 ) to the connection ( 1 or 3 ). The charging capacitor (C 2 ) is also related to this.

To stabilize the output voltage (UG) at the connections ( 3 , 4 ), a shunt regulator ( 7 ) is provided, which has a series resistor (R 11 ) and a parallel transistor (T 3 ), at the base of which a Zener diode (Z 2 ) lies.

The circuit works as follows:
The Zener diode (Z 1 ) is operated in the pass when the negative half-wave of the mains AC voltage is present at the connection ( 2 ) with respect to the connection ( 1 ). The small diode forward voltage of approximately 0.5 V drops at the zener diode (Z 1 ). The capacitor (C 1 ) is completely discharged via the diode (D) and the resistors (R 1 , R 2 ). There can be no ignition pulse (see FIG. 2 for "first half-wave" and "third half-wave").

With the beginning of the positive half-wave as seen from the neutral conductor connection ( 1 ), the voltage at the ignition circuit ( 5 ) rises fairly quickly to the value of the Zener voltage Uz of the Zener diode (Z 1 ) and then initially remains constant. This is shown in FIG. 2 for the "second half-wave". In this representation, the voltage curve is related to the connection ( 2 ) to which the phase (L) of the network is applied. The voltage rise at the ignition circuit ( 5 ) is therefore negative. The transistor (T 1 ) is conductive via the base resistor (R 4 ). The transistor (T 2 ) is blocked accordingly. The capacitor (C 1 ) charges in the direction of the Zener voltage (Uz) (cf. FIG. 2) of the Zener diode (Z 1 ) via the resistors (R 3 , R 4 , R 8 , R 1 , R 2 ) . As soon as the voltage on the capacitor (C 1 ) reaches a value which corresponds to the Zener voltage minus the voltage dropping across the resistor (R 8 ), the Schmitt trigger ( 6 ) tilts to its second stable state. The transistor (T 1 ) is now blocked. The transistor (T 2 ) is conductive and ignites the triac (TC) at the time (tz) (cf. FIGS. 2, 3). It discharges capacitor (C 1 ) via transistor (T 2 ), resistor (R 8 ) and diode (D) to the gate of the triac (TC). The capacitor (C 1 ) thus acts as an energy store for the ignition pulse. So there is a short, powerful ignition pulse.

Via the ignited triac (TC), the charging capacitor (C 2 ) is charged or recharged with the remainder of the positive half-wave present between the time (tz) and the time (t0) of the next zero crossing (cf. FIG. 3). This creates the voltage curve shown in FIG. 4, for example. Since the triac (TC) is only fired after the amplitude of the positive half-wave, only the rest of the decaying positive half-wave is present at the capacitor (C 2 ) (cf. FIG. 3). It is thereby achieved that no particularly high voltage occurs at the charging capacitor (C 2 ) for the desired low voltage (UG), which is, for example, 12 V, in any case very low in comparison with the mains AC voltage. The resistance (R 10 ) itself could also be omitted. However, there would then be the danger that in the event of an undesired interference pulse at the beginning of a half-wave, the full mains voltage would be at the charging capacitor (C 2 ), as a result of which the charging capacitor (C 2 ) and the downstream electronics would be destroyed.

As soon as the mains voltage at connection ( 2 ) falls below the value of the voltage at capacitor (C 2 ), the triac (TC) locks automatically. The capacitor (C 1 ) is completely discharged again via the diode (D). Since the capacitor (C 1 ) is always completely discharged at the beginning of the half-wave in which ignition takes place, a stable, defined ignition point (Tz) is achieved in each positive half-wave.

Claims (7)

1.Power supply unit for generating a low voltage at a load resistor from the AC line voltage, with a triac or thyristor which an ignition circuit ignites with ignition pulses which are phase-shifted with respect to the zero voltage crossings of the AC line voltage and which blocks shortly before the zero voltage passage, characterized in that the ignition circuit ( 5 ) den Triac (TC) or thyristor ignites only for positive half-waves, so that the triac (TC) or thyristor only recharges a charging capacitor (C 2 ) parallel to the load resistor with a remainder of the positive half-waves that the ignition circuit ( 5 ) detects a Schmitt Trigger ( 6 ), the second transistor (T 2 ) is located at the gate of the triac (TC) or thyristor and the first transistor (T 1 ) is connected to a capacitor (C 1 ), which is connected to it in series with a diode (D) is connected in parallel to a Zener diode (Z 1 ), the ignition pulse resulting from the fact that after charging the capacitor (C 1 ) m it the positive half-wave to a value limited by the Zener voltage, the second transistor (T 2 ) turns on and the triac (TC) or thyristor ignites, the capacitor (C 1 ) delivering the energy of the ignition pulse. 2. Power supply according to claim 1, characterized in that in the negative half-wave the Zener diode (Z 1 ) is operated in the forward direction and the capacitor (C 1 ) is kept discharged, the first transistor (T 1 ) being turned on. 3. Power supply according to claim 1 or 2, characterized in that the ignition circuit ( 5 ) ignites the triac (TC) in the decaying region of the positive half-wave. 4. Power supply according to one of the preceding claims, characterized in that a series resistor (R 10 ) is connected between the charging capacitor (C 2 ) and the triac (TC). 5. Power supply according to one of the preceding claims, characterized in that the diode (D) is poled so that the capacitor (C 1 ) discharges through it. 6. Power supply according to claim 5, characterized in that a resistor (R 3 ) is connected in parallel with the diode (D). 7. Power supply according to one of the preceding claims, characterized in that the Zener diode (Z 1 ) on the one hand at one terminal ( 2 ) of the AC mains voltage and on the other hand via a resistor (R 1 , R 2 ) at the other terminal ( 1 ) of the AC mains voltage.