DE4310513C1 - Overload protection circuit for network supply stage - Google Patents

Abstract

The circuit responds to an overcurrent at the output of the network supply stage, or a short-circuit at the pulse width modulator control device for the switching transistor within the latter. The fault current is detailed in the voltage drop (Ua) across a current sensing resistor (Rsense), coupled to a peak value rectifier (VC) providing a voltage profile (Up) compared with a reference voltage for automatic cut-out of the control device after a timed delay.Pref. cut-out is effected via an electronic switch (E5) activated via a delay element (V2) coupled to the output of the voltage comparator.

Description

The invention describes a circuit arrangement for overload protection for switching power supplies. In particular, the invention relates to circuit arrangements that with primary-side or secondary-side overcurrents and overvoltages or in Short-circuit cases become so effective that a safety-relevant on the secondary side Condition is taken.

A protective device against overcurrent and overvoltage is provided by DE 37 32 334 C2 known. This is a protective device against Overcurrent and overvoltage for switching power supplies that have the characteristic of a Transorb diode as overvoltage detector combined with a current-carrying one Control and shutdown using current transformers. The disadvantage of one current-controlled control is that the secondary side occurring in the event of a short circuit Current two to three times the rated current specified for the switching power supply is. To protect the components in the secondary circuit from destruction, one is the Residual current corresponding oversizing necessary. The result effort is uneconomical because the components increase in size become space-consuming and expensive. It is advantageous that, at temporary overload (a few seconds), the secondary voltage after Eliminating the fault normally rebuilds. Destruction of the components is in excluded in this case.

Another known circuit arrangement for overload protection for switching power supplies is in the "Power Products" DATA BOOK, Siliconix incorporated, edition 1989/90, pp. 5-31, shown and described. The clock output controls one Pulse width modulator Si9110 directly using a 2N7004 MOSFET transistor load-dependent control cycle. This circuit is only for secondary side Overcurrent effective. In the event of a short circuit on the secondary side, everyone would have to Components within the load circuit are oversized so that the Economics for such circuits would no longer exist. A Surge protection cannot be achieved with this circuit.

Accordingly, it is an object of the invention to achieve the above disadvantage  to eliminate the prior art and at the same time their advantages in one Unite circuit arrangement, with destruction of the components in the event of a fault is avoided and overdimensioning of the circuit components over the Nominal current is superfluous.

To achieve this object, the invention provides a circuit arrangement for Specify overload protection for switching power supplies

• - With a control device designed as a pulse width modulator, the one Controls switching transistor,
• - with a power transformer,
• - With a suppressor diode at the output connections of the switching power supply
• - With a protective device that has
  • - a primary-side current sensor
  • - a peak value rectifier
  • - an amplifier
  • - a comparator
  • - a delay element
  • - an electronic switch

with such an operation of the protective device that a fault current generated excessive voltage drop at the current sensor, from which the Peak value rectifier forms a voltage profile that the non-inverting Input of the amplifier is fed, which amplifies the voltage profile and the provides non-inverting input of the comparator, the Comparator the amplified voltage profile with one from the control device Compares the provided reference voltage and gives a comparison result - reference voltage <amplified voltage profile - the delay element starts, which after a definable delay time the electronic switch activated, which causes an immediate shutdown of the control device.

Advantageous embodiments of the invention characterize subclaims 2 to 4. This is a particular advantage with the circuit arrangement according to the invention achieved that the necessary protective measures for one in automation technology, especially used in programmable logic controllers Switching power supply, fully effective and the necessary components  are extremely small and therefore space-saving and inexpensive. The control device is as Pulse width modulator designed to regulate the secondary voltage in normal operation causes. The circuit arrangement is designed such that it also at Overcurrent and overvoltage, or in the event of a short circuit on the secondary side, the pulse width modulator influenced and forcing him to switch off by the switching power supply to bring the supplied control system into the safety-relevant state. By responding in stages to an accident, e.g. B. temporary overload or short-term voltage surge up to short circuit, the availability remains of the control system to be supplied by the switching power supply, without a Oversizing the components becomes necessary. This functional reliability is particularly important for programmable logic control system applications, if they are networked or have to control complex systems.

The effort to be carried out for the circuit arrangement according to the invention is small compared to the existing state of the art. It is achieved that Control systems, in particular programmable logic controllers in the low-cost range, economical to manufacture. The smaller construction is also expedient of the switching power supply, which is achieved by the invention, which also gives the possibility of a more advantageous design is achievable.

In the following, the invention is to be illustrated using an exemplary embodiment with reference to the drawing will be explained in more detail.

It shows

Figure 1 shows the circuit diagram of a switching power supply with the circuit arrangement according to the invention.

Fig. 2 is a flowchart showing the waveform in snapshots at different polling points of the switching power supply.

Fig. 1 shows the circuit diagram of a switching power supply with the inventive circuit arrangement.

The voltage U _{inp applied} on the primary side is applied to the winding W1 of the power transformer U1 and is chopped by the switching transistor T1 and transformed to the winding W3 of the power transformer U1 on the secondary side. The transformed voltage is rectified on the secondary side and stabilized via capacitor C1. The secondary voltage U _out is detected on the primary side with the winding W2 of the power transformer U1 and is applied as the control voltage U _REG to the control unit PWM designed as a pulse width modulator.

In normal operation, the switching power supply - within the permissible nominal load - the control is active on the on winding W2 of the power transformer U1 transformed control voltage U _REG, wherein the control voltage U _REG determines the switching frequency of the pulses for the control output S _clock, which switches the switching transistor T1. If there is an overload on the secondary side in the event of a fault, the suppressor diode (surge arrester diode, transorb diode) ÜA generates a cross current Iq. This cross current Iq is transferred inversely proportional to the transmission ratio of the power transformer U1 to the winding W1.

The fault current Iqf causes on the one hand an increase in the sensor voltage U _sens and on the other hand a voltage drop UA which is excessive at the current sensor R _sense . The sensor voltage U _sens influences the switching frequency on the switching transistor T1 and thus on the control process. In the event of a long-term overload and / or in the event of a short-circuit on the secondary side, the circuit arrangement 1 acts. A peak value rectifier VC forms a voltage profile Up from the voltage drop UA and makes this value available to the non-inverting input of an operational amplifier D1. The amplifier D1 amplifies the voltage profile Up to a voltage value Upv, which is fed to the non-inverting input of a comparator D2. The inverting input of the comparator D2 is compared with a constant reference voltage U _ref , which is provided by the control unit PWM. If the reference voltage U _{ref is} less than the amplified voltage profile Upv, the comparator D2 switches through. A delay element VZ thus starts a delay. If the current / time integral generated by the fault current Iqf is greater than the running time (delay), the electronic switch ES switches and activates the RESET input of the PWM control device. The control device PWM is thus switched off, ie the control clock S _clock is suppressed and the switching transistor T1 remains permanently blocked. Circuit arrangement 1 goes through the same procedure if a secondary short circuit occurs. A short-circuit current has the same effects as the cross current Iq generated by the suppressor diode ÜA.

FIG. 2 shows a flow chart which shows the signal curve at different query points of the switching power supply.

The signal curve over time is shown as a function of the output load, which determines the output current I _{OUT of} the switching power supply.

The signal state is in three areas - normal operation A, current-controlled control B, initiation phase of the shutdown C - broken down.

Normal operation A shows that the output current I _{OUT is} below the nominal current In. The fault current Iqf determines the value of the voltage profile Up, which is clearly below the reference voltage U _ref provided by the control unit PWM. The comparator D2 does not switch and the interrogation points U2 and U3 remain inactive. The output voltage U _out remains stable.

Area B illustrates the current-controlled control. The output current I _out slightly exceeds the nominal current In. The fault current Iqf causes the voltage profile Up to rise, but it has not yet reached the value of the reference voltage. The circuit arrangement for overload and short-circuit protection remains inactive. The output voltage U _out experiences a corresponding sag, typical for the current-controlled regulation, for the time of the slight overload. The area C shows the initiation phase of the switching off of the output voltage U _out at time D. The output current I _out exceeds the nominal current in such a way that the fault current Iqf causes the value of the voltage profile Up to rise above the constant value of the reference voltage U _ref . The comparator D2 switches and triggers the delay element VZ with the signal U2. After the running time (delay), the electronic switch ES switches and activates the reset input RESET of the control device 1 . The electronic switch ES permanently stops the switching state until a defined reset process. The reset input RESET switches the control device 1 off. The result is an immediate shutdown of the output voltage U _out at time D. The effect of the signal curve described in area C and the shutdown at time D is effective in the event of a permanent overload and in the event of a short circuit. The running time (delay) activated by the time delay element VZ has the effect that a brief overload and a brief short circuit do not influence the output voltage U _out and that the control system remains available.

Claims (5)

1. Circuit arrangement for overload protection for switching power supplies,

• with a control device (PWM) designed as a pulse width modulator, which controls a switching transistor (T1),
• - with a power transformer (U1),
• - With a suppressor diode (ÜA) at the output connections (A) of the switching power supply
• - With a protective device ( 1 ), which has
  • - a primary-side current sensor (R _sense ),
  • - a peak value rectifier (VC),
  • - an amplifier (D1),
  • - a comparator (D2),
  • - a delay element (VZ),
  • - an electronic switch (ES),

with such a mode of operation of the protective device ( 1 ) that a fault current (Iqf) generates an excessive voltage drop (Ua) at the current sensor (R _sense ), from which the peak value rectifier (VC) forms a voltage profile (Up) that corresponds to the non-inverting input of the amplifier ( D1) is supplied, which amplifies the voltage profile (Up) and makes it available to the non-inverting input of the comparator (D2), the comparator (D2) the amplified voltage profile (Upv) with a reference voltage provided by the control device (PWM) ( U _ref ) compares and with a comparison result - reference voltage (U _ref ) <amplified voltage profile (Upv) - the delay element (VZ) starts, which activates the electronic switch (ES) after a definable delay time (delay), which switches the control device off immediately (PWM) causes. 2. Circuit arrangement according to claim 1, characterized in that the electronic switch (ES) is only activated by the delay element (VZ) when the amplified voltage profile (Upv) obtained from the fault current (Iqf) increases after the delay time (delay) than the reference voltage (U _ref ). 3. Circuit arrangement according to claim 1 or 2, characterized in that above nominal load (In) lying a current-controlled control by means of a primary proportional sensor voltage (U _sens ) by the control device (PWM) is effective as long as either the amplified voltage profile (Upv) remains smaller than the reference voltage (U _ref ) or in the case of a larger voltage profile (Upv) the delay time (Delay) has not yet expired. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the circuit arrangement ( 1 ) is designed as an application-specific integrated circuit.