DE10105138A1 - Electrical circuit arrangement - Google Patents

Abstract

The invention relates to a circuit arrangement (11) having the following features: a switched mode power supply unit with a transformer (13), a rectifier with an applied input alternating voltage, a switched mode regulator IC (14) a first control circuit (15) with a first optocoupler (OK1), the first control circuit being connected to the switched mode regulator IC (14) and being used to regulate a determined working voltage by means of a Zener diode (ZD1), a monitoring circuit (12) with a Zener diode (ZD2) and a thyristor (T) for detecting a voltage threshold value. The monitoring circuit is mounted parallel to the primary side of the transformer (13) and is triggered by the return voltage. The monitoring circuit is also connected to the switched mode regulator IC (14). If the working voltage exceeds a determined threshold value as a result of an error produced by the first control circuit, the monitoring circuit disconnects the first control circuit.The advantage of such a system is that components can no longer be damaged by an overvoltage as a result of a defective first control circuit.

Description

The invention relates to an electrical circuit arrangement according to the preamble of claim 1. In particular, it can is a circuit arrangement for the power supply a control circuit of a household appliance or the like. act.

Errors can occur in circuit arrangements of this type in the generation of the secondary or output voltage, the especially fatal for the first control loop can. As with all switching power supplies, there is a risk of output overvoltage in the event of an open off gangs control loop. An open output control loop can arise from soldering defects, bad solder joints or through Component failure. In the case of an open output control loop the output voltage reaches dangerously high values because that Switching power supply - due to the incorrect control variable - constantly trying to reach the output voltage value and for this reason with its greatest possible  Performance works. In the event of an error, that, for example, due to a component defect, an optocoupler A high voltage in the first control circuit on the switching regulator IC tried to set as the intended.

Such an error can result in protection extra-low voltages maximum permissible voltage exceeded is, components of the supplied circuit or control be damaged and there is a risk of fire.

TASK AND SOLUTION

The invention is based on the object of a circuit to create arrangement of the type mentioned, in which the Risk of overvoltage in the circuit arrangement or is eliminated on the secondary side of the switching power supply.

According to the invention, this object is achieved by a scarf arrangement with the features of claim 1. Advantageous te embodiments of the invention are the subject of the Unteran sayings and are described in more detail below.

According to the invention, such a monitoring circuit is opened the primary side. It should preferably be on the Act directly on the primary side, so the energy of either Keep transmitter away or the energy transfer itself influence. The monitoring circuit should exceed the voltage on the primary side of the transformer via a detect a certain voltage limit. This happens in that the monitoring circuit the check chip voltage of the secondary voltage detected on the primary side and at if the voltage limit value is exceeded, that the energy transfer by means of the transformer to the Secondary side is limited. In this way it is possible  a voltage exceeding also on the primary side limit value to be recorded on the secondary side.

One advantage is that the monitoring circuit already sits on the side of the transmitter on which be an interruption in the transmission of energy is particularly advantageous can be done. A limitation of the Energy transmission because it causes damage can be avoided on the secondary side. An over Guard circuit can be done in different ways leads, as will be explained below.

The energy transfer through the is particularly preferred Intervention of the monitoring circuit completely below broken. In this way, damage is avoided in any case.

According to one possibility, the voltage supply of the Transmitter controlled by the monitoring circuit Switching means are disconnected. Such circuitry can be, for example, relays connected to different Can sit in the circuit or a contact can open, possibly also close.

Activation of the monitoring circuit is preferred dissipated the energy stored in the switching power supply preferably discharged on the primary side. This can damage the in generally more sensitive secondary side can be avoided.

The energy present on the primary side is particularly preferred destroyed in front of the transmitter, preferably turned into heat delt by a suitable component. For example, this is possible in a primary-side thyristor, including the Primary winding is connected in parallel.  

The monitoring circuit can be connected to the primary side or Primary winding of the transformer to be connected. At a preferred embodiment, it is the primary side immediately upstream bar.

The monitoring circuit can have components that when the applied voltage is exceeded via a be the voltage limit value automatically cause a function ken. For example, Zener diodes have been used for this purpose turned out to be particularly advantageous.

On the one hand, the monitoring circuit can be in one Jump in after an error and after eliminating the critical Status immediately go back to the monitoring status. However, the activated state of the monitoring is preferred circuit permanent or stable. So one can get up once diving mistakes do not go under again without after its cause was sought. An advantageous option it is, for example, that the switching rule IC after the Activation of the monitoring circuit is switched off.

Other circuit components can of course depending on the desired functionality, however not necessary for the basic invention itself. It is also possible to connect to an input voltage a DC connector or an AC connector to choose with rectifier. Then the rectifier advantageously an intermediate circuit and a freewheeling circuit downstream.

These and other features go beyond the claims also from the description and the drawings, wherein the individual features individually or separately several in the form of sub-combinations in one embodiment  of the invention and in other fields his and advantageous as well as protectable execution can represent conditions for which protection is claimed here. The division of the application into individual sections as well Subheadings limit those made under them Statements are not generally applicable.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention are in the drawings are shown and are explained in more detail below. In the Shows the drawings

Fig. 1 shows a possible circuit arrangement for the energy supply of the control of a HOUSEHOLD APPLIA Raets,

Fig. 2 shows an alternative to Fig. 1 with an optocoupler for switching off the switching regulator ICs and

Fig. 3 shows another alternative with a relay.

DETAILED DESCRIPTION OF THE EMBODIMENTS

In Fig. 1 an exemplary circuit arrangement 11 according to the invention is shown. On the left a rectifier is connected to the input voltage, usually 230 volts. This is followed by an intermediate circuit with an electrolytic capacitor and a capacitor. This is followed by a freewheeling circuit with a resistor and a capacitor, which can also be replaced by a Zener diode in another embodiment. The freewheeling circuit also has a freewheeling diode D.

A monitoring circuit 12 is integrated in the freewheeling circuit and comprises a Zener diode ZD2, a thyristor T and two resistors and a capacitor. Their function is discussed below.

A transformer 13 connects to the freewheeling circuit with its primary side or winding. Furthermore, a switching control IC 14 is provided, which is connected with a connection D to the primary winding of the transformer 13 . The connections S1 to S5 are grounded as internal ground inputs of the IC 14 .

The secondary side of the transformer 13 is connected to two supply connections for control electronics or the like via a diode and a coil, two electrolytic capacitors and a capacitor for voltage stabilization. These special components can of course also be designed differently.

An optocoupler OK1 is connected to the secondary voltage or the supply connections via a resistor R1 and a Zener diode ZD1. These components form a control circuit 15 for stabilizing the secondary voltage. An output of the optocoupler OK1 is connected to a connection EN and internal ground connections S1 to S5 of the switching control IC 14 . In this way, the secondary voltage is held or stabilized at a certain value of the working voltage for the connected control electronics, for example 12 V.

A connection BP (bypass) of the switching control IC 14 is connected to the optocoupler OK1 via a capacitor. A model with a thyristor or triac output, for example TLP 3052 , can be used as the optocoupler. Instead of the Zener diode ZD1, a unijunction transistor or a diac can also be used.

The modification of the circuit arrangement 111 in FIG. 2 again has a Zener diode ZD2 as a monitoring circuit 112 with a function corresponding to that in FIG. 1 and a resistor R2. The optocoupler OK2 is controlled via ZD2, which controls the switching control IC 114 with electrical isolation via connections A and B. The switching control IC is controlled via the inputs BP and one of the internal ground inputs. The other circuit including the transformer 113 and the control circuit 115 corresponds essentially to FIG. 1. Only the input voltage supply and the voltage-smoothing components on the secondary side have been partially omitted.

The modification in Fig. 3 has as part of the monitoring circuit 212 again a Zener diode ZD3 as a switching means for detecting an excessively high flashback voltage. When the Zener diode ZD3 is switched on, a relay K is triggered, which opens its contact Ö via connection 217 . In this example, contact Ö is located in the intermediate circuit in order to separate it. Alternatively, a contact Ö in the input voltage supply can sit in front of the rectifier or on the secondary side if there is no need for electrical isolation. The relay K can be a bistable relay in order to maintain the terning state.

Another option for a relay is to use this a contact parallel to the freewheeling diode in the freewheeling circuit to switch. When the relay is triggered, the Contact closed and thus the freewheeling diode short closed. Even so, the energy transfer via the Transformer be turned off.  

According to a further possibility, the overvoltage can also be determined by thermal measurement. This is done in that a corresponding component of the monitoring circuit on the primary side heats up due to the excessive reverse voltage. This can be, for example, a Zener diode corresponding to the Zener diode ZD2 in FIG. 1 or 2, which is heated when a voltage limit value is exceeded. This heating can be detected by a thermally influenced switch and lead to one of the measures mentioned above, in particular similar to the contact Ö of the relay K. Such a switch could be a purely thermal switch, for example with a bimetal element and switch contacts.

FUNCTION

In the exemplary circuit arrangement 11 in FIG. 1, the working voltage is set to 11 volts and 1 volt internally for the optocoupler OK1 by the Zener diode ZD1 and the resistor R1. The optocoupler OK1 in conjunction with the switching control IC 14 normally stabilizes the working voltage to this voltage value. Typical values for the output power of such a circuit arrangement are in the range of a few VA, for example 5 to 10 VA.

The generation of the voltage on the secondary side takes place in that the primary side of the transformer 13 is charged with energy by means of the switching control IC 14 and delivers this with a translated voltage ratio on the secondary side. Via the Zener diode ZD1, the secondary-side working voltage is limited to a desired value, determined by the threshold voltage of the Zener diode ZD1. This happens because the Zener diode ZD1 switches through when the threshold voltage is exceeded and down-regulates the switching control IC 14 via the optocoupler OK1. The optocoupler is used primarily because of the galvanic isolation between the circuits of the transmitter 13 . Thus, the secondary voltage of the transformer 13 is kept or stabilized at a certain value of the working voltage for the connected control electronics or the like.

In the event of a fault, for example within the OK1 optocoupler, the OK1 optocoupler in conjunction with the switching regulator IC 14 tries to set a higher voltage than the desired one, up to a maximum of the mains input voltage. The working voltage rises and a preset limit value of the working voltage, for example 15 volts, is exceeded. This working voltage present on the secondary side is induced by the transformer 13 as a so-called return voltage from the secondary winding on the primary winding. This flashback voltage can thus be accessed and determined or measured on the primary winding. It is usually approximately 130 V here. In the circuit arrangement 11 shown, this is done by the monitoring circuit 12 , in particular the Zener diode ZD2. If their threshold voltage is exceeded, this leads to a diode current flowing into the gate terminal of the thyristor T, which thereby ignites. The energy stored in the transformer 13 can be dissipated on the primary side via this ignited thyristor T. A resistor protects the semiconductor circuit against overload in the case of the fired thyristor T. As a result, the sequential circuit is no longer supplied with energy. The switch in the switching control IC 14 is protected by the diode D in the freewheeling circuit.

It can be advantageous if the monitoring circuit activated once or once after a single activation remains, for example due to information storage properties  one of their components. However, this is not inevitably necessary, it can also reactivate itself constantly ren.

The circuit examples in FIGS. 2 and 3 and the described embodiments work accordingly.

Claims (10)

1. Electrical circuit arrangement ( 11 ), in particular for the energy supply of a controller of a household appliance, with:
a switching power supply with a transformer ( 13 , 113 , 213 ) with a primary side and a secondary side,
a switching control IC ( 14 ),
a first control loop ( 15 , 115 , 215 ),
the first control circuit ( 15 ) being connected to the switching control IC ( 14 ) and setting a specific working voltage via the transformer ( 13 ) on the secondary side of the transformer ( 13 ),
characterized by :
a monitoring circuit ( 12 , 112 , 212 ) for determining that the voltage on the primary side of the transmitter ( 13 ) exceeds a certain voltage limit value,
wherein the monitoring circuit detects the flashback voltage of the secondary voltage on the primary side and intervenes when the voltage limit is exceeded in such a way that the energy transmission via the transformer ( 13 ) is limited to the secondary side. 2. Electrical circuit arrangement according to claim 1, characterized in that the energy transmission is completely interrupted by the intervention of the monitoring circuit ( 12 , 112 , 212 ). 3. Electrical circuit arrangement according to claim 1 or 2, characterized in that the voltage supply to the transmitter ( 13 , 113 , 213 ) by the monitoring circuit ( 12 , 112 , 212 ) controlled switching means is separated, preferably by a relay (K, Ö ). 4. Electrical circuit arrangement according to claim 1 or 2, characterized in that the energy before the transformer ( 13 , 113 , 213 ) is destroyed, preferably in a thyristor (T). 5. Electrical circuit arrangement according to one of the preceding claims, characterized in that by activating the monitoring circuit ( 12 , 112 , 212 ) the energy stored in the switching power supply is dissipated, preferably is dissipated on the primary side. 6. Electrical circuit arrangement according to one of the previously outgoing claims, characterized in that the Detection of an overvoltage occurs thermally on a component on the primary side, which by a Overvoltage undergoes heating, preferably a thermal switch can be actuated by the heating to interrupt the energy transmission.   7. Electrical circuit arrangement according to one of the preceding claims, characterized in that the monitoring circuit ( 12 , 112 , 212 ) is connected to the primary side of the transmitter ( 13 , 113 , 213 ), in particular the primary side is connected directly upstream. 8. Electrical circuit arrangement according to one of the preceding claims, characterized in that the monitoring circuit ( 12 , 112 , 212 ) has components which automatically cause a function when the applied voltage exceeds a certain voltage limit value, in particular a Zener diode (ZD2 , ZD3) is provided. 9. Electrical circuit arrangement according to one of the preceding claims, characterized in that the activated state of the monitoring circuit ( 12 , 112 , 212 ) is permanent or stable. 10. Electrical circuit arrangement according to one of the preceding claims, characterized in that the switching control IC ( 14 ) is switched off after the activation of the monitoring circuit ( 12 , 112 , 212 ).