DE4140034A1 - Energising circuit for mains voltage electromagnetic switch controlling e.g. washing machine - has two parallel-connected semiconductor switches in series with capacitor which is charged and discharged during positive and negative half cycles - Google Patents

Abstract

The electromagnetic switch drive circuit has a semiconductor switch in series with the relay coil, controlled by an electronic circuit. The semiconductor switch is formed by two semiconductor switches, e.g. triacs with series diodes (D1, T1; T2, D2), in parallel, one for the positive and the other one for the negative half-cycles of the mains a.c. voltage. The parallel semiconductor switches are connected in series with a capacitor (C), charged by the mains frequency via one semiconductor switch, and discharge via the other one, with the two switches uninterrupted. Each semiconductor switch is pref. formed by a triac (T1, 2) and a diode (D1, 2) in series. USE/ADVANTAGE - For household machines such as washing machine, drier, or dishwasher. Reliable contactor disconnection when fault occurs in one active element of semiconductor switch.

Description

The invention relates to a control circuit for a AC contactor through which one Load, especially in a household machine, such as Washing machine, dryer or dishwasher, is switchable, with one controlled by an electronic circuit Semiconductor switching device connected in series to the coil the shooter lies.

In such control circuits according to the state of the art Technology that switches the small contactor or relay Semiconductor switching device a triac. Safety regulations require that in the event of a defect in the Triac, for example a short circuit, the contactor continues must work properly, or at least not the load may turn on more so that it does not become a Permanent switching on of the load, especially heating one Washer, dryer or dishwasher can come. Because such a continuous activation can dangerous conditions.

To meet the safety requirements suggested two of the electronics circuit the same controlled triacs in series. If so a triac is disturbed by a short circuit, the in  Second triac lying alone switching the Contactor. With such a series connection lies only one of the triacs at reference potential. Such However, series connection does not easily meet that Security regulations. Because then when the on Reference triac due to a defect interrupts, the other triac loses Reference potential. This allows over from its anode its gate connection unwanted AC voltage in the the electronic circuit is destroyed, or that Contactor is switched incorrectly.

The object of the invention is a control circuit of the propose the type mentioned in the event of malfunctions an active element of the semiconductor switching device a dropout of the contactor is guaranteed.

According to the invention, the above task is for a Control circuit of the type mentioned in the introduction solved that the semiconductor switching device a Parallel connection of two semiconductor switches, whose one for the positive half waves and the other for the negative half-waves of the AC mains voltage is provided, and that this parallel connection in series to a capacitor that is undisturbed Semiconductor switches with the mains frequency above one Semiconductor switch charges and above the other Semiconductor switch discharges.

With undisturbed semiconductor switches, the contactor flows attracted alternating current into its positive Half waves over the one semiconductor switch and in its negative half waves over the other Semiconductor switch.

Is the one semiconductor switch defective and it forms thereby a short circuit and only the other semiconductor  is blocked by the control signal, then loads the capacitor to a peak voltage and remains charged. The one flowing over the coil of the contactor Current is interrupted, so that the contactor falls off. The circuit works for the on state also with a shorted semiconductor switch flawless.

If one of the two triacs is defective, it will form an interruption, then the capacitor overcharges the other semiconductor switch to a peak voltage on and stays charged on this peak voltage since he about the broken triac representing an interruption can no longer be unloaded. The stream through the The coil of the contactor is also in this case interrupted, so that in this case the contactor Load switches off, or cannot switch on.

Another advantage of this control circuit is in that none on the electronic circuit Mains AC voltage arrives so that when the Semiconductor circuit is not destroyed.

It is also advantageous that the two Semiconductor switch to the same reference potential and in particular to the same reference potential as that Electronic circuit can be placed.

Advantageous refinements of the invention result from the subclaims and the following description. The drawing shows:

Fig. 1 shows a control circuit on the AC line voltage for a load and

FIG. 2 shows a detail of an alternative to FIG. 1.

At the poles ( 1 , 2 ) of the AC mains voltage there is a load (L) which is, for example, the heating resistor of a washing machine. In series with the load (L) are two switching contacts ( 3 , 4 ) of a contactor, the coil of which is labeled S. In series with the coil (S) is a capacitor (C), to which a parallel connection of two semiconductor switches is connected in series.

One semiconductor switch consists of a triac (T1) and a diode (D1) connected in series. The other semiconductor switch also consists of a triac (T2) and a diode (D2) connected in series. The diodes (D1, D2) are reversed in the series connection, so that one semiconductor switch passes the positive half-waves and the other semiconductor switch the negative half-waves. The triacs (T1, T2) are connected to the pole ( 2 ) as a reference potential. In the series connection of the coil (S), the capacitor (C1) and the parallel connection with the switching elements (D1, T1, D2, T2), the capacitor (C) lies between the coil (S) and the aforementioned parallel connection. This series connection lies between the poles ( 1 , 2 ) of the AC mains voltage.

The gate connections of the triacs (T1, T2) are connected to an electronic circuit (E), which is also at the reference potential of the pole ( 2 ). A voltage supply ( 5 ) is connected to the pole ( 1 ) for the voltage supply of the electronic circuit (E). The electronic circuit (E) controls the two triacs (T1, T2) simultaneously.

The operation of the circuit described is approximately the following:

If the triacs (T1, T2) are undisturbed and controlled by the electronic circuit (E), then the positive half-waves flow via the diode (D1) and the triac (T1) and charge the capacitor (C). The negative half-waves of the AC mains voltage flow through the diode (D2) and the triac (T2) and discharge the capacitor (C). As a result, an alternating current flows through the coil (S), which causes the two switching contacts ( 3 , 4 ) to close, that is to say the load (L) is switched on.

If the electronic circuit (E) does not ignite the triacs (T1, T2), then no alternating current flows through the coil (S), so that the switch contacts ( 3 , 4 ) open and the load (L) is switched off.

If, for example, the triac (T1) is defective in such a way that it forms a short circuit, then it can no longer switch blocking at its gate connection by the electronic circuit (E) even when its control signal is switched off. As a result, the capacitor (C) charges to a peak voltage and remains charged. The capacitor (C) can no longer discharge via the other triac (T2) because this triac is switched off. As a result, the current through the coil (S) is interrupted, so that the switch contacts ( 3 , 4 ) open.

The same applies if the triac (T2) is defective and forms a short circuit. It has a corresponding effect also a short circuit of one of the diodes (D1, D2). The normal function is not disturbed.

Another malfunction can be that, for example, the triac (T1) is interrupted. In this case, the capacitor (C) charges to a peak voltage via the triac (T2) and the diode (D2), since it can no longer discharge via the triac (T1). This also interrupts the alternating current through the coil (S), so that the switch contacts ( 3 , 4 ) open.

The same applies if the triac (T2) is replaced by a  Defect is interrupted. The same applies if one of the diodes (D1, D2) interrupted by a defect is.

Even if the capacitor (C) is disturbed by a short circuit or an interruption, this can not lead to the fact that the coil (S) is constantly flowed through by alternating current, and therefore no longer open the switch contacts ( 3 , 4 ) (series connection to the semiconductor switches).

Fig. 2 shows a circuit for the capacitor (C), which is cheaper than the use of an unpolarized capacitor. According to FIG. 2, the capacitor (C) is replaced by a series connection of two electrolytic capacitors (C1, C2). The electrolytic capacitors (C1, C2) are polarized in opposite directions. A diode (D3, D4) is connected in parallel with each of the electrolytic capacitors (C1, C2). The diodes (D3, D4) have the opposite polarity as the associated electrolytic capacitors (C1, C2).

The AC resistance of the capacitor (C) or the Capacitors (C1, C2) is much smaller than that AC resistance of the coil (S). This is achieved that through the series connection with the Capacitor (C or C1, C2) through the coil (S) flowing current is not significantly reduced.

Claims (8)

1. Control circuit for a contactor connected to mains AC voltage, by means of which a load, in particular in a household machine such as a washing machine, dryer or dishwasher, can be switched, with a semiconductor switching device controlled by an electronic circuit, which is connected in series with the coil of the contactor, characterized in that the semiconductor switching device is a parallel connection of two semiconductor switches (D1, T1; D2, T2), one of which is provided for the positive half-waves and the other for the negative half-waves of the mains AC voltage, and that this parallel connection in series with one Capacitor (C) is located which, in the case of undisturbed semiconductor switches (T1, D1; T2, D2), charges at the mains frequency via one semiconductor switch and discharges via the other semiconductor switch. 2. Control circuit according to claim 1, characterized characterized in that each semiconductor switch by one Triac (T1, T2) with a diode (D1, D2) connected in series is formed. 3. Control circuit according to claim 2, characterized in that the two triacs (T1, T2) are at the same reference potential ( 2 ). 4. Control circuit according to claim 3, characterized in that the two triacs (T1, T2) are at the same reference potential ( 2 ) as the electronic circuit (E). 5. Control circuit according to one of the preceding Claims, characterized in that the capacitor (C) between the parallel connection (T1, D1; T2, D2) and the Coil (S) is. 6. Control circuit according to one of the preceding Claims, characterized in that the Line frequency the AC resistance of the capacitor (C) is significantly smaller than that of the coil (S). 7. Control circuit according to one of the preceding Claims, characterized in that the two Triacs (T1, T2) always from the same time Electronic circuit (E) are controlled. 8. Control circuit according to one of the preceding Claims, characterized in that the capacitor by two oppositely polarized, connected in series Electrolytic capacitors (C1, C2) is formed, each one of the two electrolytic capacitors (C1, C2) Diode (D3, D4) is connected in parallel.