FI91115C - Method for controlling an electrical switch and an electrical switch - Google Patents

Abstract

The present invention relates to a method of controlling an electronic switch and an electronic switch for carrying out the method. The electronic switch comprises an electromagnetic relay (1) and a controllable bidirectional semi-conductor switch (2), such as a triac, connected parallel with the switch (1b) of the relay and a control unit (3) for controlling the relay and the semi-conductor switch so that when connecting the load to a power source the semi-conductor switch is first turned on at the zero point of the AC voltage, subsequent to which and after a delay the switch of the relay is turned on, and when disconnecting the load from the power source, the switch of the relay is first turned off, subsequent to which and after a delay the semi-conductor switch is turned off at the zero point of the alternating current. According to the invention the control unit (3) also comprises means for turning off the semi-conductor switch (2) subsequent to turning on the switch (1b) of the relay (1) when connecting the load to a power source, and for turning on the semi-conductor switch (2) prior to turning off the switch (1b) of the relay (1) when disconnecting the load from the power source.

Description

i 91115

METHOD FOR CONTROLLING AN ELECTRICAL SWITCH AND ELECTRICAL SWITCH

The invention relates to a method for controlling an electrical switch as defined in the preamble of claim 1.

The invention also relates to an electrical switch according to the preamble of claim 2.

An electrical switch is previously known, which comprises a relay and a semiconductor switch arranged next to this switch. With such a switch, the load can be connected to the mains non-sparkingly at the zero point of the AC switching phase and, accordingly, the load can be disconnected non-sparkingly at the zero point of the AC current. This is accomplished by switching the load to a mains semiconductor switch, such as a triac, at the zero point of the AC voltage phase and then switching on the relay switch after a delay. Correspondingly, when disconnecting the load from the electrical network, the relay is first switched off and then after a delay the control of a semiconductor switch, such as a triac, is removed, whereby the semiconductor switch disconnects the load from the mains, preferably at phase zero.

25 A disadvantage of the current electronic switch and its control method is that over time, the tips of the relay switch become dirty and the voltage across the closed switch of the relay increases. This is due to the fact that only a voltage of approx. 2 volts acts across the relay switch tips at the time of switching on and / or off. This voltage is not enough to clean the relay switch tip, causing the voltage to rise above the closed switch. As a result of the voltage rise, a semiconductor switch, such as a triac, connected in parallel with the relay does not cease to conduct when the relay switch 35 closes, but current continues to flow through the semiconductor switch. This in turn leads to overheating and destruction of the semiconductor switch, such as the triac.

The object of the invention is to provide a new method for controlling an electrical switch and an electrical switch by means of which the above-mentioned problem can be avoided.

The method according to the invention for controlling an electrical switch is characterized by what is stated in claim 1.

The electrical power is connected to the load from an AC mains-10 or similar AC power supply with an electronic switch and the electrical power is cut off accordingly. The electrical switch includes an electromagnetic relay and a controllable bidirectional semiconductor switch, such as a triac, connected in parallel with the relay switch. In the method according to the invention, the relay and the semiconductor switch are controlled in such a way that when the load is connected to the power supply, the semiconductor switch is first switched to the AC state at the relay switch is disconnected, after which, after a delay, the solid-state switch is switched to a non-conducting state at the zero point of the alternating current phase. According to the invention, in addition, the semiconductor switch is switched to the non-conductive state immediately after the relay switch is switched on when switching the load to the power supply, and the semiconductor switch is switched to the conducting state before the relay switch is disconnected.

The electrical switch according to the invention is characterized by what is stated in claim 2.

The electrical switch according to the invention for connecting electrical power to a load from an AC mains supply or a corresponding AC power supply and for switching off the power accordingly, comprises an electromagnetic relay and a controllable bidirectional switch connected in parallel with the relay switch.

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91115 3-way semiconductor switch, such as a triac, for controlling both the control unit relay and the semiconductor switch so that when connecting a load to a power supply, the semiconductor switch is first switched to the AC disconnected, after which the semiconductor switch is switched to a non-conductive state at zero-10 of the AC phase. According to the invention, the control unit further comprises means for switching the semiconductor switch to a non-conductive state as soon as the relay switch is switched on when the load is connected to the power supply, and for switching the semiconductor switch to the conductive state before disconnecting the relay switch from the power supply.

The control unit can be implemented in many different ways as a control logic, which may include, for example, a microprocessor, or as a simple non-intelligent circuit assembled from suitable components. The control unit itself is controlled with a simple on / off switch.

In one embodiment of the electrical switch, the control unit includes a zero phase angle indicating optical switch 25 for controlling the semiconductor switch. Such an optical switch preferably has an AC voltage phase angle detector and a switch connected to the same component, which is additionally optically controllable. With such a component, the number of components used in the electronic switch can be reduced.

In one embodiment of the electrical switch, the control unit includes a time constant circuit, preferably an RC circuit, a reference voltage source for generating three reference voltages and a reference unit for comparing the control voltage and reference voltages coming through the time constant circuit 35 and real-time switching of the relay switch and semiconductor switch. As the control voltage 4, a direct voltage is preferably used, which is connected to the control terminal of the control unit when the load is to be connected to the mains by means of an electrical switch. Then, under the influence of the time constant circuit, the internal control voltage 5 rises during the determining time constant of this circuit to close to the maximum value of the control voltage and exceeds the said values of the reference voltages. When the set reference voltage levels exceed the set value of the internal control voltage, first the semiconductor switch is connected to a conductive ti-10 state, then the relay switch is closed and finally the semiconductor switch is placed in a non-conductive closed state. Correspondingly, switching off the control voltage causes the opposite sequence of events.

In one embodiment of the electrical switch, the 15 reference units comprise three voltage comparators, the first and third voltage comparators controlling the semiconductor switch and the second voltage comparator controlling the relay.

In one embodiment of an electrical switch, the first voltage comparator 20 includes a channel transistor, the threshold voltage of which is used as the first reference voltage to which a control voltage is applied to the semiconductor switch. and a third voltage comparator is connected in front of the channel transistor with it in series to control the semiconductor switch to a non-conductive state after the load is connected to the power supply via the relay switch 30, and to control the semiconductor switch to the conductive state before the relay switch is switched off. Thus, by means of the first voltage comparator, the semiconductor switch is controlled to the conductive state, while by means of the third voltage comparator 35, respectively, the semiconductor switch is controlled to the non-conductive state again after the relay is turned on and the load is switched on.

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91115 5 men through the electricity network. Similarly, the voltage comparators operate in reverse order when the control voltage is disconnected and the electrical switch disconnects the load from the electrical network.

5 In one application of an electrical switch, the reference voltage source includes a resistor circuit for generating a second and a third reference voltage from a predetermined DC voltage. This is a simple and effective way to implement a set of desired benchmarks-10 roads.

The advantage of the invention is that it can replace the relay switch and thus avoid the disadvantages caused by the use of the relay. A further advantage of the invention is that the electrical switch comprises a controllable bi-directional semiconductor switch connected to the relay switch, such as a triac, which the semiconductor switch is kept in a conductive state only in the event of a change, i.e. when the switch is closed and disconnected. In this case, a semiconductor switch such as a triac will not be able to overheat and self-cleaning of the parts of the switch relay 20 will work in a known manner.

The invention will now be described in detail with reference to the accompanying drawings, in which Figure 1 shows a simple block diagram of an electronic switch 25; Fig. 2 shows the control signals of the electrical switch according to Fig. 1 and the mains voltage acting on the load; Figure 3 shows a block diagram of another 30 electrical switches; Figure 4 shows voltage levels and changes at various points in the electrical switch of Figure 3; and Figure 5 shows an embodiment of an electrical switch as a circuit diagram.

The electrical switch in Figure 1 comprises an electromagnetic relay 1 with a control coil 1a and a switch 1b. A controllable 6 bidirectional semiconductor switch 2, such as a triac, is connected in parallel with the relay switch 1b. The poles of the electronic switch are marked L1, L2. One pole is connected to the mains and the other to the load (not shown in the drawings). The control unit 3 controls a 5-kb switch and in particular a relay 1 and a semiconductor switch 2.

The electrical switch is controlled as follows. We refer to Fig. 2. The relay 1 of the electrical switch and the semiconductor switch 2 are controlled by the control unit 3 so that the semiconductor switch 2 is first switched to the conducting state by giving it a control signal To at the zero point of the mains voltage phase. The Tålld load is connected to the AC mains. After the delay at time tb, the control coils 1a of the relay 1 are given a control signal-15 li Ro, whereby the switch lb of the relay 1 is switched on. The semiconductor switch 2 is switched to the non-conducting state at time tc, i.e. immediately after the switch 1b of the relay 1 is switched on, by interrupting the input of the control signal To. The mains current to the load first passes through the conductive semiconductor switch 20, but after the relay is switched on and the semiconductor switch is closed and after the time tc exclusively through the switch 1b of the relay 1.

When disconnecting the load from the AC mains, the semiconductor switch 2 is first switched to the conducting state 25 by applying the control signal To at time td, after which the control signal Ro is switched off at the control coil 1a of the relay 1, whereby the control signal Ro is switched off. Thereafter, at the moment tf, the semiconductor switch 2 is switched to the non-conducting state 30 at the zero point of the mains phase by removing its control signal To. At the same time, the load is disconnected from the power supply. The mains current to the load then passes first through the switch 1b of the relay 1, then through the switch and the semiconductor switch of the relay and finally only through the semiconductor-35 switch before disconnecting the load from the mains. The mains voltage UL acts on the load from moment t to moment tf.

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91115 7

The second electrical switch according to the invention is shown in Figure 3. In the figure, the same reference numerals as in Figure 1 are used for the same parts. The electrical switch also includes an electromagnetic relay 5 1 with a control coil 1a and a switch 1b. A controllable bidirectional semiconductor switch 2, such as a triac, is connected in parallel with the relay switch 1b. The poles of the electrical switch are marked L1, L2, as above in connection with Figure 1. One pole is connected to the mains and the other 10 to the load (not shown in the drawings). The control unit 3 controls the electrical switch S and in particular the reset 1 and the semiconductor switch 2.

In the example of Figure 3, the control unit 3 includes a zero-phase angle indicating optical switch 4 for controlling the semiconductor-15 switch 2. The optical switch 4 includes a light transmitter 4a, such as an LED, a light detector 4b and a zero-phase angle detector 4c. The control unit 3 further comprises a time constant circuit 5, such as a resistor capacitor or RC circuit, a reference voltage source 6 for generating three reference voltages 20 U1, U2, U3 and a comparison unit 7 comprising voltage comparators 8, 9, 10. the values of the control voltage Uin and the reference voltages U1, U2, U3 coming through the circuit 5. The en-25 terminal and the third voltage comparator 8, 10 control the semiconductor switch 2 via the optical switch 4 and the second voltage comparator 9 controls the relay 1, i.e. the relay switch 1b via the control relay 1a.

The electric switch according to the invention in Fig. 3 30 operates as follows. We also refer to Fig. 4. The control voltage Uo is connected to the control input Uin of the control unit 3 at the moment. The control voltage Uo is a suitably sized low DC voltage with respect to the mains voltage. Internal control voltage Uos increases relatively slowly at the output of time constant circuit 5 due to 35 circuits. An internal control voltage Uos is applied to the second input of each of the voltage comparators 8, 9, 10 of the comparison unit 7 and is compared in the first voltage comparator 8 to the voltage U1, in the second voltage comparator 9 to a voltage U2 greater than U1 and in the third voltage greater than 5 than U2. When the internal control voltage Uos rises to U1, the output voltage Uol of the voltage comparator 8 rises to a predetermined value and supplies a control voltage to the optical switch 4. The light transmitter 4b of the optical switch begins to emit optical radiation, which it emits. The zero phase angle 4c of the optical switch detects the next zero point of the phase of the mains voltage Uv at time t2 and then connects a suitable control to the control input of the semiconductor switch 2, whereby the semiconductor switch 2 enters a conductive state. A current begins to flow through the semiconductor switch 2 of the terminal 15 and the load is connected to the mains and is affected by the mains voltage Uk.

The internal control voltage Uos continues to rise continuously and at time t3 reaches the reference voltage 20 U2. A control voltage Uo2 is supplied to the output of the voltage comparator 9 and a control current is applied to the control coils 1a of the relay 1. It follows that relay 1 pulls and its switch lb closes. In this case, both the relay switch 1b and the semiconductor switch 2 are in the conductive state.

25 The internal control voltage Uos continues to rise and at the moment t4 reaches the reference voltage level U3. The voltage comparator 10 then supplies a control voltage Uo3 to the optical switch 4. The control voltage Uo3 cancels the control voltage Uol of the optical switch 4, whereby the light transmitter of the optical switch 4 ceases to emit optical radiation and the semiconductor switch 2 is no longer The semiconductor switch 2 enters the non-conducting closed state at time t4. In this case, only current flows through the switch 1b of the relay 1 to the load.

35 When the load is disconnected from the mains, the control voltage Uo supplied to the control unit 3 is switched off and the control terminal Uin is connected to ground. This takes place

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91115 9 at 4 moment t5. Immediately after this, under the influence of the time-lap circuit 5, the internal control voltage Uos starts to decrease towards zero. At time t6, the control voltage Uos falls below the reference voltage U3, as a result of which the output voltage Uo3 of the voltage comparator 10 drops and the optical switch 4 regains its control Uol, resulting in the semiconductor switch 2 being brought back to conductive at time t6. The internal control voltage Uos continues to decrease and at time t7 it is equal to the voltage U2 of the reference-10, which means that the output voltage Uo2 of the voltage comparator 9, i.e. the control of the relay, drops to zero.

It follows that the switch lb of the relay 1 opens. However, the load is still connected to the mains via a semiconductor switch 2.

15 Internal control voltage Uos continues to decrease and falls below the reference voltage Ul at time t8. The voltage Uol acting at the output of the voltage comparator 8 is reset, as a result of which the light transmitter 4c of the optical switch 4 ceases to operate. However, the zero voltage indicator 4c of the input voltage / current phase associated with the optical il-20 sensor of the optical switch 4 is in operation and shuts off the control UTo at the zero point t9 of the load current Iv to the semiconductor switch 2. In this case, the semiconductor switch 2 enters a non-conductive state, i.e. a closed state 25, in which case the load is also disconnected from the mains. The electrical switch is in the initial state and ready to be reconnected.

Figure 5 shows a circuit diagram for an electrical switch according to the invention. In this figure 30, the same reference numerals for the same parts as in Figs. 1 and 3 are used. The time constant circuit 5 is implemented by means of a resistor 5a and a capacitor 5b. The first voltage comparator 8 includes a channel transistor 11, the threshold voltage Uh of which is used as the first 35 reference voltage U1. The third voltage comparator 10 is connected in series with the channel of the channel transistor 11 on this input side. The reference voltage source 6 includes a DC voltage source 10 from which a predetermined DC voltage Uc is obtained, and a resistor circuit 12, 13, 14 for generating a second and a third reference voltage U2, U3.

The electrical switch of Figure 5 operates as described above in connection with Figures 1 and 3. However, we will briefly state the following about the operation of the circuit and also refer to Fig. 4. When the control voltage Uo is connected to the input of the control unit 3, the capacitor 5b starts to charge and its voltage Uos rises. When the capacitor voltage 10 Uos rises above the threshold voltage Uh = Ul of the channel transistor 11, the channel transistor 11 begins to conduct. The optical switch 4 is controlled and turns on, i.e. brings the mains voltage of the semiconductor switch 2 to the zero point of the next phase. As the voltage Uos of the capacitor 5b 15 continues to rise to the level of the reference voltage U2, the relay 1 turns on. When the voltage Uos of the capacitor 5b rises to the level of the reference voltage U3, the control of the optical switch 4 is removed and the semiconductor switch 2 is brought to a non-conductive state, i.e., it turns off. The load is then connected to the mains via switch 1b of relay 1. Correspondingly, when the control voltage Uo is connected to zero, the voltage Uos of the capacitor 5b begins to decrease, and the above switching sequence (cf. Fig. 4) is repeated in the reverse order. The invention is not limited to the application example presented above only, but many modifications are possible while remaining within the scope of the inventive idea defined by the claims.

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Claims (7)

A method for controlling an electrical coupling, whereby electrical power from an AC current or the corresponding alternating current source is coupled to a load or decoupled from the load by an electrical coupling, which includes an electrical magnetic relay (1) and one with the relay coupling (1b). ) A parallel coupled, controllable bi-directional semiconductor coupling (2), such as a triac, in which the method relay (1) and semiconductor coupling (2) is controlled so that, when the load is coupled to the power source, the semiconductor coupling is first switched in a conductive state in the AC voltage. The zero phase of the phase, after which the relay coupling is switched on with time offset, and when the load is switched off from the power source, the relay coupling is first switched off, after which the semiconductor coupling with time delay is switched in a non-conducting state in the alternating current of the alternating current phase, the semiconductor coupling (2) in a non-conductive t malfunction shortly after the switch (1) of the relay (1) is switched on when the load is coupled to the power source, and the semiconductor coupling (2) is switched in a conductive state before the relay (1) switch (lb) is switched off when the load is switched off. power source. An electrical coupling for coupling electrical power from an AC or equivalent AC shaft to a load and / or disconnection from the load, which coupling comprises an electromagnetic relay (1) and a bi-directional semi-directional semiconductor coupling coupled to the relay (1b). ), such as a triac, as well as a control unit (3) for controlling the relay and semiconductor so that, when the load is coupled to the power source, the semiconductor coupling is first switched on in a conductive state in the zero-voltage phase of the alternating-voltage phase, after which the relay coupling is engaged with time-shifting. and when the load is disconnected from the power source, the relay coupling is first disconnected, after which the semiconductor coupling with time offset is coupled in a non-conducting state in the alternating current of the alternating current phase, characterized in that the control unit (3) further comprises devices for switching the semiconductor coupling. (2) in a non-conducting ti Standby shortly after the switch (1) of the relay (1) is engaged, when the load is coupled to the power source, and for coupling the semiconductor coupling (2) in a conductive state before the switch (1) of the relay (1) is switched off when the load disconnected from the power source. 3. An electrical coupling according to claim 2, characterized in that the control unit (3) for controlling the semiconductor coupling (2) comprises an optical coupling (4) which detects the zero phase angle. 4. An electrical coupling according to claim 2 or 3, characterized in that the control unit (3) comprises a time constant circuit (5), preferably a resistance capacitor (RC) circuit, a parallel voltage voltage source (6) for generating three comparison voltages ( U1, U2, U3) and a comparison unit (7) for comparison of the control voltage (Uin) coming through the time constant unit (5) and the comparison voltage (U1, U2), U3) and for realizing the coupling of the relay (1) coupling (1b) and the semiconductor coupling (2) in raw instant. 5. An electrical coupling according to claim 4, characterized in that the comparator unit 30 (7) comprises three chip comparators (8, 9, 10), the semiconductor coupling (2) being controlled with the first and third chip comparators (8, 10) and the relay ( 1) with the second chip driver (9). 6. An electrical coupling according to claim 5, characterized in that - understanding the voltage comparator (8) comprises a channel transistor (11), spring threshold voltage (Uh) 16 being used to understand the comparison voltage voltage (U1), with which it is through the tent constant circuit (5). the coming control voltage (Uin) is compared for controlling the semiconductor coupling (2) in a conductive state when the load is coupled to the power source and in a non-conducting state when the load is disconnected from the power source; and - the third voltage comparator (10) is connected in front of the channel transistor (11) in series with this for controlling the semiconductor coupling (2) in a non-conductive state after the load has been coupled through the relay coupling (lb) to the power source , and before controlling the semiconductor coupling (2) in a conductive state before the relay coupling (lb) and the load are disconnected from the power source. 7. An electrical coupling as claimed in claim 4, 5 or 6, characterized in that the jam trace source (6) comprises a resistance chain (12, 13, 14) for forming the second and third chamfer voltage (U2, U3) of a predetermined DC voltage 20 (Uc). II