DE3525942C2 - - Google Patents

Description

The invention relates to a switching power supply, in which the rectified mains voltage over a clockwise operable, controllable circuit breaker on one Transformer is given, in which the control input of the Circuit breaker with a first output one as Control circuit with pulse width modulator Protection functions related, which under connection corridors has at least one protective input, with A certain amount of voltage is applied to this protection input the control circuit the circuit breaker over the the first output is permanently switched off and the one on the Output side of the tapped voltage Control voltage for the control circuit is obtained on led a control input of the integrated control circuit and the size of which is the cyclical duty cycle of the Circuit breaker depends.

Such a switching power supply is from the brochure of Siemens AG "Integrated Switching Power Supply Control Circuits", in particular page 26, published in May 1984, is known. At the known switching power supply is the rectified network voltage by means of a controllable circuit breaker in one high on the primary part of a transformer frequency AC voltage implemented. The secondary voltages of the transformer are rectified and screened. Consequently are the same at the output terminals of the switching power supply tensions available. The controllable circuit breaker is about a power driver from a pulse train tenmodulators acting integrated control circuit ert. The integrated control circuit has a plurality  of inputs, one of which is a control input, and others serve as protective inputs, e.g. B. as a surge input and as an input for dynamic current limitation. Size comparisons are made at these protective inputs protective functions triggered by voltages. The integrated Control circuit changes in its property as an impulse width modulator the duty cycle of the circuit breaker at constant switching frequency depending on one of the Control input applied control voltage. This control voltage is proportional to the difference from an output voltage of the switching power supply and its setpoint. Falls short the output voltage its setpoint because of a changed Power output, the control voltage increases and the on Switching duration of the circuit breaker is through the integr te control circuit increases until the output voltage of the Switching power supply reaches its setpoint. For galvanic Isolation are the output terminals of the switching power supply and the control input of the integrated control circuit an optocoupler separated.

As already pointed out, the integrated control scarf via the protective inputs protective and monitoring radio perceive. One that acts as an overvoltage input Protective input of the integrated control circuit is on the ver connection point of a voltage divider, at which the equal line voltage is present. An over voltage occurs there on, the control circuit switches the circuit breaker from. The protective input for dynamic current limitation is in place in conjunction with a measuring resistor in the circuit of the Circuit breaker is. If the current through the Circuit breaker a maximum value, so lowered the control circuit the duty cycle of the power scarf ters, whereby the output voltage is reduced and the Current through the circuit breaker and current through the Components on the output side of the switching power supply is limited. This type of current limitation has  a short circuit on the output side of the switching power supply the disadvantage that the short-circuit current is limited, but nevertheless power loss in the components of the switching power supply is generated, causing the components to heat up considerably.

From EP-0 082 105 A1 it is known a power supply device with an undervoltage release equip that when the output voltage drops from 12 V to about 10.5 V. For this, the output voltage compared to a reference voltage. When falling short a control signal is given to the reference voltage, another control signal via a decoupling diode is superimposed. A delay circuit ensures that the If the output voltage drops only briefly, this is not switched off unnecessarily.

EP-0 084 245 A1 describes a circuit for limiting the output current a switching power supply described, the one Comparator contains one of the output current of the power supply compares proportional voltage with a reference voltage and a lock signal to the driver in the event of an overload of the switching transistor and thus the output current of Power supply reduced to a permissible level.

The invention has for its object a circuit create order in the event of a short circuit on the output side of the switching power supply switches off the output side. To The solution to this problem is a switching power supply unit as described in the introduction Kind so designed that a protective circuit on the input side on one on the output side of the transformer applied voltage is connected and on the output side with one of the protective inputs of the control circuit stands and that the protection circuit the voltage of certain size switches to this protective input if the value of the pending Voltage reaches a threshold for a certain time. A protective circuit is thus obtained with little effort, which no further switching elements to switch off the  Output side of the switching power supply is required, because the existing control circuit is used.

Is the protective circuit on the input side with the control input of Control circuit connected to the voltage of certain size switches to the protective input when the value of the control voltage exceeds a predetermined value for a certain time, so you can to get a simple protection circuit that Take advantage of the fact that in the event of a short circuit on the output side of the switching network, the control voltage assumes its maximum value.

The protective circuit expediently consists of a timing element and a subordinate threshold switch. The Timing element prevents brief increases in the control voltage, as they e.g. B. when turning on the  Switching power supply occur on the input of the threshold value switch. These short term increases would otherwise an unwanted shutdown of the output side of the switching power supply.

It is recommended for a simple construction of the protective circuit yourself that the timer of the protection circuit from a Series connection of a resistor and a capacitor exists, the control input of the control circuit with the one end of this timer is connected and the verb point between resistor and capacitor at the on gang of the threshold switch is connected and that the output of the threshold switch via an the output the protective circuit forming diode with one of the protection inputs is connected. The diode also prevents a reverse current to the output of the threshold switch.

Another advantageous development of the invention results by the fact that at the connection point of the row scarf device of resistor and capacitor a discharge circuit connected to the capacitor, which is the condensate sator after a certain period of time after the off gear side of the switching power supply is switched off, discharges. This means that the off is automatically switched on again gear side of the switching power supply possible if the short conclusion that had led to the shutdown was eliminated.

In the following the invention will be explained in more detail with reference to the embodiment shown in FIGS . 1 and 2 of the drawing. The

Fig. 1 shows the circuit diagram of a switching power supply according to the invention.

Fig. 2 shows a part of the circuit diagram of a slightly modified wide ren embodiment.

The line voltage indicated by the arrow 1 is first rectified after entry into the switching power supply and converted into a high-frequency AC voltage by means of a controllable circuit breaker 2 , which is applied to the primary part of a transformer 3 . The secondary voltages of the transformer 3 are also rectified and screened, so that DC voltages are available at all output terminals 4 , in particular the output terminals 5 and 6, for a consumer (not shown).

The control input 7 of the circuit breaker 2 is connected to the output 9 of an integrated control circuit 10 via a power driver 8 . This integrated control circuit device 10 acts as a pulse width modulator and has protective functions. The integrated control circuit can e.g. B. of the type TDA 4714, which is shown in the brochure mentioned on page 8. Other pulse width modulators with protective functions are listed in the textbook by Tietze / Schenk, "Semiconductor circuit technology", Springer Verlag 7th edition, in Figure 18.74 on page 562. The integrated control circuit 10 has a protective input 11 acting as an overvoltage input and a protective input 12 for dynamic current limitation. The protective functions described at the outset are triggered when the voltages at these protective inputs 11 , 12 are of a certain size. The integrated control circuit 10 also contains the control input 13 . It controls the cyclical duty cycle of the circuit breaker 2 as a function of a control voltage at the control input 13 . This control voltage is proportional to the difference between the output voltage at the output terminals 5 , 6 and their setpoint. If the output voltage at the output terminals 5 , 6 falls below its setpoint, the control voltage at the control input 13 increases and the duty cycle of the circuit breaker 2 is increased by the control circuit 10 until the output voltage at the output terminals 5 , 6 reaches its setpoint. The Regelein input 13 is galvanically isolated from the output terminals 5 , 6 via an optocoupler 14 .

To enable switching off the output side of the switching power supply in the event of a short circuit or overload, a protective circuit 15 is provided. The input of the protective circuit 15 is connected to the control input 13 . The output of the protective circuit 15 is connected to the protective input 12 for dynamic current limiting. The protective circuit 15 consists of a series connection of a resistor 16 and a capacitor 17 serving as a timing element, to which a threshold switch 18 is connected.

The threshold switch 18 essentially consists of an operational amplifier connected as a comparator, the (+) input of which lies at the connection point of the timing element. The (-) - input of the operational amplifier is supplied with a comparison voltage, the value of which results from the supply voltage U _{s of} the integrated control circuit 10 and the Zener voltage of the upstream Zener diode 19 .

The mode of operation of the protective circuit 15 will be explained below. In the event of a short circuit or overload on the output side of the switching power supply, the output voltage at the output terminals 5 , 6 drops sharply. As a result, the control voltage at control input 13 rises above its highest value during undisturbed operation. A voltage builds up on the capacitor 17 , the value of which is greater than the voltage at the (-) input of the threshold value switch 18 .

At the output of the threshold switch 18 , a voltage occurs which is connected via the diode 20 to the protective input 12 for dynamic current limitation. This voltage is substantially greater than the voltage at the measuring resistor 21 2 in the current circuit of the circuit breaker and it causes the integrated control circuit 10, a gänzliches switching off of the circuit breaker. 2

In Fig. 2, a modified protection circuit 15 is provided, which can also be connected to the protection input 12 and the control input 13 of the integrated control circuit 10 . The same reference numerals are used for the same parts.

At the connection point of the first timing element consisting of the resistor 16 and the capacitor 17 , a discharge circuit 22 for the capacitor 17 is connected in dash-dot lines. The discharge circuit 22 consists of a series circuit serving as a second timing element of a resistor 23 and a capacitor 24 , the connection point 25 of which is connected to the control input 26 of a controllable switch 27 . The second timing element in the discharge circuit 22 has a greater time constant than the first timing element comprising resistor 16 and capacitor 17, which has already been described for the exemplary embodiment according to FIG. 1.

If the circuit breaker 2 is switched off by means of the protective circuit 15 after a short circuit, a high control voltage is still present at the input of the protective circuit 15 , so that the capacitor 24 of the discharge circuit 22 also charges. When the voltage across the capacitor 24 has reached a certain predetermined level, the controllable switch 27 ignites and the capacitor 17 is discharged. As a result, no voltage occurs at the output of the threshold switch 18 and the integrated control circuit 10 switches the circuit breaker 2 off. If the short circuit has now been eliminated, the switching power supply unit starts operating normally. Otherwise, a sufficient voltage builds up again on the capacitor 17 , which causes the threshold switch 18 to apply a voltage to the protective input 12 for dynamic current limitation, which leads to the circuit breaker 2 being switched off again.

Claims (5)

1. Switched-mode power supply, in which the rectified mains voltage is applied to a transformer via a cyclically operable, controllable circuit breaker, in which the control input of the circuit breaker is connected to a first output of a control circuit acting as a pulse width modulator with protective functions which has at least one protective input under connection inputs , With the presence of a voltage of a certain size at this protective input, the control circuit permanently switches off the circuit breaker via the first output and a control voltage for the control circuit is obtained from a voltage tapped on the output side of the transformer, which leads to a control input of the control circuit is and on the size of the clock-wise duty cycle of the circuit breaker depends, characterized in that a protective circuit ( 15 ) on the input side on one on the output side of the transformer ( 3 ) existing voltage is connected and the output side is connected to one of the protective inputs ( 11 , 12 ) of the control circuit ( 10 ) and that the protective circuit ( 15 ) switches the voltage of a certain magnitude to this protective input ( 11 , 12 ) when the value of the voltage present reached a threshold value for a certain time. 2. Switching power supply according to claim 1, characterized in that the protective circuit ( 15 ) is connected on the input side to the control input ( 13 ) of the control circuit ( 10 ) and the voltage of a certain size switches to the protective input ( 11 , 12 ) when the value of the rule voltage exceeds a predetermined value for a certain time. 3. Switching power supply according to claim 1 or 2, characterized in that the protective circuit ( 15 ) consists of a timer and a downstream of this threshold switch ( 18 ). 4. Switching power supply according to claim 3, characterized in that the timing element of the protective circuit ( 15 ) consists of a series circuit of a resistor ( 16 ) and a capacitor ( 17 ), the control input ( 13 ) of the control circuit ( 10 ) with one end of this Time element is connected and the connection point between the resistor ( 16 ) and capacitor ( 17 ) is connected to the input of the threshold switch ( 18 ) and that the output of the threshold switch ( 18 ) via a diode ( 20 ) forming the output of the protective circuit ( 15 ) is connected to one of the protective inputs ( 11 , 12 ) of the control circuit ( 10 ). 5. Switching power supply according to claim 4, characterized in that at the connection point of the series connection of resistor ( 16 ) and capacitor ( 17 ) a discharge circuit ( 22 ) containing a second timing element for the capacitor ( 17 ) is connected, which the capacitor ( 17 ) discharges after a certain period of time after the output side of the switching power supply is switched off.