SU1490710A1 - Ac switch - Google Patents

Abstract

The invention is intended to drive several loads with half-waves of a mains voltage. The goal is to expand the area of use and simplification. The alternating current key contains thyristors 1 and 2 in the antiphase connection of loads 3 and 4 to the mains supply buses 5.6, thyristor optocoupler 9, resistive voltage divider 11, capacitor 12, switches 16, 17 at the outputs of the execution unit 19 with the control unit element 20 at the entrance. The introduction of diodes 8, 10, 13 reduces to one the number of used optocouplers and accordingly simplifies the device, and the introduction of a divider 15 frequency controlled by element 20 with the help of block 19 and keys 16, 17 allows the energy released in the loads to be varied and to switch from the basic to the duty mode of operation when using electric bulbs to illuminate the landings of houses and auxiliary premises as loads. 2 Il.

Description

The invention relates to a pulse technique and can be used for lighting stairwells of houses and auxiliary premises.

The purpose of the invention is the expansion of the scope by providing adjustment of the currents in the loads and simplification by reducing the number of optocouplers.

Figure 1 presents the circuit diagram of the device; figure 2 - diagram of its individual blocks, an example of execution.

The alternating current switch (Fig. 1) contains the first and second thyristors 1 and 2 in the out-of-phase connection circuits of the first and second loads 3 and 4 to the buses 5 and 6 of the supply network. A LED of the optocoupler 9 is connected to the buses 5 and 6 through the resistor 7 and the first diode 8 in the direction of the thyristor 2 conductivity. According to the thyristor 2, a second diode 10 is connected between its cathode and the phase bus 5. The thyristor 2 control electrode is connected to the midpoint of the voltage resistive divider 11 and the first output of the capacitor 12, the second output of which is connected to the cathode of the optocoupler thyristor 9, and the anode of the photothyristor of the optocoupler 9 is connected to the cathode of thyristor 2. The third diode 13 is connected according to thyristor 1 between the zero bus 6 and the connection point of the second the ode of the capacitor 12 with the output of the divider 11, the other output of which is connected to the load terminal 3 and the cathode of the thyristor 1, the control electrode of which is connected through the fourth diode 14 to the output of the frequency divider 15, controlled by the first and second keys 16 and 17, which are connected through the fifth diode 18 bus 5. Keys 16 and 17 are the output elements of the Executive unit 19 with a control element 20 at the input.

It is possible to excite simultaneously with loads 3 and 4 additional loads 21 and 22, respectively (shown by the dashed line in figure 1).

Block 19 (figure 2) can be made in the form of a relay with windings 23 and 24, which are connected through decoupling diodes 25 and 26 to a power source 27. The key 16 is the output element of the relay with the winding 23 and is presented in figure 2 by the closing contacts 16.1 and 16.2, and the key 17 is the output element of the relay with the winding 24 and is shown in figure 2 by the closing contacts 17.1 and 17.2. The frequency divider 15 can be performed on a single-junction transistor 28 (Fig.2) with time-varying capacitors 29 and 30, which are connected by contacts 16.2 and 17.2, respectively.

The device (figure 1) can be in one of three operating states.

In the first state, the loads 3 (21) and 4 (22) are disconnected. It is determined by the position of the control element 20, turning off the power of the Executive unit 19, which, in turn, turns off the power of the divider 15. Thyristors 1 and 2 are closed, since the output of the divider 15 there are no control signals.

In the second state, the first half-wave of the mains current flows through loads 3 and 2 1, and the second half-wave flows through loads 4 and 22. This state is determined by the fact that the control element 20 energizes the relay with the winding 23 with the current flowing from the source 27 through the diode 25. In this case, contacts 16.1 and 16.2 are closed, through which the first (positive) half-wave of the mains voltage is supplied to the divider 15. Since there is a capacitor 29 in operation, which sets the division coefficient equal to unity, signals are output from the output of the divider 15 to the thyristor 1 control electrode 1, which open the thyristor 1 during each positive half-wave of the mains voltage.

After turning on the thyristor 1, the capacitor 12 charges to the voltage released on the lower part of the divider. 11. When the polarity of the mains voltage changes (the second half of the period), the thyristor 1 closes, stopping the current through the load 3. The LED of the optocoupler 9 is excited by the current flowing through the resistor 7 and diode 8, opening the photothyristor of the optocoupler 9. Thus, a condition is created for the discharge of the capacitor 12 through the control electrode-cathode of thyristor 1, which is turned on, providing excitation of load 4 of the second (negative) half-wave network current.

The third operating state of the device corresponds to the changed division coefficient of the divider 15, which is achieved by excitation of the relay coil 24 and the connection of a larger capacitor 30 instead of a capacitor 29.

Thus, currents of the opposite direction flow through loads 3 and 4 during one period of the mains voltage. When 3 electric lamp loads of one entrance are used as a load, and 4 electric lamp loads of another entrance are used as a load with a counter (not shown) connected to buses 5 and 6, the correct metering of energy consumption is ensured.

As element 20, an electronic clock can be used with the busbars of the supply network in the direction of conductivity of the second thyristor, the first and second keys at the outputs of the executive unit with a control element at the input, characterized in that, in order to expand the scope of use and simplification, a frequency divider is introduced , second, third, fourth and fifth diodes, the second diode being connected in accordance with the second thyristor between its cathode and the network phase bus, the anode of the optocoupler thyristor is connected to the cathode of the second thyristor, controlling second electrode of which is connected to the control rammnym

Claims (1)

Claim An alternating current switch containing the first and second thyristors in the antiphase connection circuits of the first and second loads to the supply busbars, a resistive voltage divider, the midpoint of which is connected to the first output of the capacitor, the second output of which is connected to the cathode of the optocoupler thyristor, the LED of which is through the resistor and the first the diode is connected tn to the first output of the capacitor, the third diode is connected according to the first thyristor between the zero bus of the network and the connection point of the second output of the capacitor with the output of the resistive elitelya voltage, the other terminal of which is connected to the first terminal of the load and the cathode of the first thyristor whose control electrode through the fourth diode connected to the output of the frequency divider controlled by said first and second switches, through the fifth diode connected bus network. used to phase G I I I I A-ί