RU125404U1 - DEVICE OF PROTECTION OF THE OZONATOR AGAINST EMERGENCY MODES - Google Patents

Abstract

The utility model relates to electrical engineering, in particular to an electronic switch, as well as to devices for protecting ozonizers from emergency operation. The objective of the proposed utility model is to simplify the design and increase the speed of the device. To achieve the objective, the ozone protection device for emergency operation contains, a control unit, a semiconductor switch, an electromagnetic relay, the control unit being connected to the first output of the semiconductor switch by the first input, and the second control unit connected to the second output of the semiconductor switch, and the third and fourth The input is connected to two inputs of the current transformer. Moreover, the first output of the control unit is connected to the first input of the semiconductor switch, and the second output, the control unit is connected to the second input of the semiconductor switch. Next, the first output of the semiconductor switch is connected to the first output of the electromagnetic relay, and the second output of the electromagnetic relay is connected to the first wire of a single-phase electrical network. And the second output of the semiconductor switch is connected to the second wire of a single-phase electrical network. In addition, both wires of a single-phase electrical network are connected via the contacts of an electromagnetic relay to the inputs of a high-voltage unit. Next, the first output of the high-voltage unit is connected with the primary winding of the current transformer with the first output of the current-limiting resistor, and the second output of the current-limiting resistor is connected with the first output of the discharge gap of the ozonizer. Moreover, the discharge gap of the ozonizer by the second output is connected to the second output of the high-voltage unit. In addition, a semiconductor switch is connected in parallel with the current-limiting resistor.

Description

The utility model relates to electrical engineering, in particular to an electronic switch, as well as to devices for protecting ozonizers from emergency operation.

A device "Electronic switch of an alternating current circuit" (Appl. 95122004/09, dated 12/20/1995) is known. It contains a trigger key, a rectifier bridge, a pulse shaper, an integrator and a triac. This device also contains a current-limiting first resistor and a fuse, and the pulse driver consists of a voltage divider formed by the second and third resistors and a CMOS inverter, one pole of the triggering key is connected to one pole of the AC voltage source, the other pole is connected to one rectifier bridge input, the second input of which is connected to another pole of the source of alternating voltage. One output of the bridge is connected to the common bus, the other is connected to the common bus via a voltage divider formed in series by the second and third resistors. The connection point of the resistors is connected to the input of the CMOS inverter, the output of which is connected to the integrator and through a current-limiting first resistor and fuse to the control electrode of the triac, connected in series with the load. The electronic switch containing the low-power thyristor, the output of the pulse shaper is connected to the control electrode of the low-power thyristor, the anode of which is connected to the power source, also contains the fourth resistor, the cathode of the thyristor is connected through the fourth resistor to the common bus and through the current-limiting first resistor and the fuse to the control electrode of the triac . The electronic switchboard contains, instead of the triggering key, a triggering button of a bipolar switch with the first and second poles with normally open contacts, a low-powered triac and a disconnecting button with normally closed contacts. One input of the rectifier bridge is connected through the normally open contacts of the first pole of the triggering button and a low-power triac connected in parallel with this pole with one pole of the alternating voltage source. The output of the pulse former via the normally open contacts of the second pole of the triggering button is connected to the control electrode of a low-power thyristor, the cathode of which is connected through the current-limiting first resistor, fuse, normally closed contacts of the shutdown button to the control electrode of the low-power triac and to the control electrode of the triac connected in series with the load . The electronic switch, from which the low-power triac is excluded, contains a single-pole start button with normally open contacts and a diode instead of the trigger button of the bipolar switch. One input of the rectifier bridge is connected via normally open contacts of the trigger button with one pole of the alternating voltage source. The output of the pulse shaper is connected to the control electrode of a low-power thyristor, the cathode of which is connected to the cathode of the diode and through the first resistor, the normally closed contacts of the shutdown button and the fuse to the control electrode of the triac, the anode of the diode to the output of the auxiliary voltage source in the power supply, the power supply is the load switched AC circuit. The electronic switchboard, in which, instead of the launching button of a single-pole turn-on, a start-up button of a two-pole turn-on with the first and second poles with normally open contacts, is introduced, it contains a galvanic cell as a power source. One output of the rectifier bridge is connected via normally open contacts of the first pole of the triggering button with one pole of an alternating voltage source, the negative pole of the galvanic cell is connected to the common bus, and the positive pole is connected to the power supply line of the pulse shaper and the low-power anode through normally open contacts of the second pole of the triggering button thyristor. The electronic switch contains the first logical element 2I and includes a D-flip-flop. Moreover, the S- and R-inputs of the trigger are connected to a common bus. C-trigger input, triggered by a positive pulse front, is connected to the output of a pulse shaper. The control signal from an external source is fed to one input of the first element 2I and to the D input of the trigger. A single trigger output is connected to another input of the first logic element 2I, the output of which is connected to an integrator and through a current-limiting first resistor and fuse with a control electrode of a triac connected to an AC circuit in series with the load. Electronic switch, characterized in that the control signal from an external source is fed to the anode of a low-power thyristor. The electronic switch containing the first logic element 2I, the control signal from an external source is excluded from the switch, in addition it contains a control unit. The control unit is formed by, for example, the first one-shot, the second logic element 2I and the second one-shot, the fifth resistor and the first capacitor, which form the timed RC circuit of the first one-shot, the sixth resistor and the second capacitor, which form the timed RC circuit of the second one-oscillator. Moreover, one of the elements of this circuit, for example, the sixth resistor, has a variable resistance value. The direct output of the first one-shot, which is the output of the control unit, is connected to one input of the first logic element 2I and to the anode of a low-power thyristor. The cathode of a low-power thyristor is connected to another input of the first logic element 2I, the output of which is connected to the integrator and through the first resistor and fuse to the control electrode of the triac. The inverse output of the first one-shot is connected to one input of the second logic element 2I, the output of the pulse shaper is connected to another input of which. The output of the second element 2I is connected to the input of the second one-shot. Which is triggered by a positive pulse front. The output of the second one-shot is connected to the input of the first one-shot triggered by a negative pulse front. One pole of the first capacitor is connected to the C-input of the first one-shot, the other to the RC input of the first one-shot and through the fifth resistor to the power supply. One pole of the second capacitor is connected to the C-input of the second one-shot, the other - to the RC input of the second one-shot and through the sixth resistor with a power source. The electronic switch contains a fifth resistor, the fifth resistor has a variable resistance value, the resistance values of the fifth and sixth resistors are changed by one regulator, and when the resistance of the fifth resistor increases / decreases, the resistance of the sixth resistor decreases / increases. The electronic switchboard includes a CMOS inverter, and in the CMOS inverter, the source of the n-structure MOS transistor is connected via the seventh resistor to a common bus.

A significant disadvantage of this device is the complexity of the design.

We take the prototype as the device closest to the proposed utility model (App. 95113710/07, May 29, 1995) of an electronic switch for connecting / disconnecting the load to an AC network, which contains an electromagnetic relay and a controlled two-way semiconductor switch connected in parallel with a relay switch, and a control unit for controlling the relay and a semiconductor switch so that when the load is connected to the power source, the semiconductors first turn on A switch at the zero point of the AC voltage, and after a delay the relay switch turns on, and when the load is disconnected from the power source, the switch switches off first, and after the delay the semiconductor switch turns off at the zero point of the AC, the control unit also includes means for turning off the semiconductor switch with switching on the relay switch when the load is connected to the power source and to turn on the semiconductor switch before disconnecting relay switch when disconnecting the load from the energy source, characterized in that the control unit contains a circuit having a time constant, preferably a resistor-capacitor circuit, a reference voltage source for forming three reference voltages and a comparator unit having three voltage comparators for comparing the control voltage supplied through a circuit having a time constant with reference voltages and for turning on and off the relay switch and the semiconductor switch at a certain time, while When the comparator unit comparing voltages are connected so that the first and third comparators are used for controlling the semiconductor switch, and a second comparator for relay control. In an electronic switch, the first voltage comparator contains a field-effect transistor, the threshold voltage of which is used as the first reference voltage, with which the control voltage of a circuit having a time constant is compared to turn on the semiconductor switch when the load is connected to the power source and to turn it off when the load is disconnected from the source energy, while the third voltage comparator is connected in series with the field-effect transistor in front of it to turn off the semiconductor switch after the load is connected to the power source through the relay switch, and to turn on the semiconductor switch before disconnecting the relay switch and the load of the C-power source. In addition, in the electronic switch, the reference voltage source contains a resistor circuit to form the second and third reference voltages from a predetermined DC voltage, the control unit contains an optical key indicating the zero phase angle of the alternating current for controlling the semiconductor switch.

The disadvantage of this device is the lack of speed.

The objective of the proposed utility model is to simplify the design and increase the speed of the device.

To accomplish the task, the ozone protection device for emergency operation, comprising a control unit, a semiconductor switch, an electromagnetic relay, the control unit is connected to the first output of the semiconductor switch by the first input, and the second control unit is connected to the second output of the semiconductor switch and the third and the fourth input is connected to two inputs of the current transformer. Moreover, the first output of the control unit is connected to the first input of the semiconductor switch, and the second output, the control unit is connected to the second input of the semiconductor switch. Next, the first output of the semiconductor switch is connected to the first output of the electromagnetic relay, and the second output of the electromagnetic relay is connected to the first wire of a single-phase electrical network. And the second output of the semiconductor switch is connected to the second wire of a single-phase electrical network. In addition, both wires of a single-phase electrical network are connected via the contacts of an electromagnetic relay to the inputs of a high-voltage unit. Next, the first output of the high-voltage unit is connected with the primary winding of the current transformer with the first output of the current-limiting resistor, and the second output of the current-limiting resistor is connected with the first output of the discharge gap of the ozonizer. Moreover, the discharge gap of the ozonizer by the second output is connected to the second output of the high-voltage unit. In addition, a semiconductor switch is connected in parallel with the current-limiting resistor.

The proposed utility model is illustrated by drawings. Figure 1 shows the functional diagram of the device protecting the ozonizer from emergency conditions.

The ozonizer protection device for emergency operation includes (Fig. 1) a control unit 1 connected to the first output of the semiconductor switch 2 by the first input, and the control unit 1 is connected to the second output of the semiconductor switch 2 by the second input and connected to two transformer inputs by the third and fourth inputs current 3. Moreover, the first output of the control unit 1 is connected to the first input of the semiconductor switch 4, and the second output, the control unit 1 is connected to the second input of the semiconductor switch 4. e the first output of the semiconductor switch 4 is connected to the first output of the electromagnetic relay 5, and the second output of the electromagnetic relay 5 is connected to the first wire of the single-phase electrical network. And the second output of the semiconductor switch 4 is connected to the second wire of a single-phase electrical network. In addition, both wires of a single-phase electrical network are connected via the contacts of an electromagnetic relay 6 to the inputs of the high-voltage unit 7. Next, the first output of the high-voltage unit 7 is connected to the first output of the current transformer 3 with the first output of the current-limiting resistor 8, and the second output of the current-limiting resistor 8 is connected to the first the output of the discharge gap of the ozonizer 9. Moreover, the discharge gap of the ozonizer 9 is connected to the second output of the high-voltage unit 7 by the second output. In addition, the parallel no current limiting resistor 8 is connected first and the second input of the semiconductor switch 2.

The device protects the ozonizer from emergency modes as follows.

The control unit 1, figure 1, through a current transformer 3 measures the amplitude of the operating frequency currents, as well as the amplitude of the high frequency currents, in the range of 10-100 kHz. In the event that the amplitude of the operating frequency exceeds the set threshold, the control unit 1 stops supplying current to the LED of the semiconductor switch 4, which closes the semiconductor switch 2, thereby, the current limiting resistor 8 is switched on in the circuit between the high-voltage unit 7 and the discharge gap of the ozonizer 9, which limits the current flowing through this circuit to the nominal value.

If the amplitude of the RF current exceeds the set value, the control unit 1, after a set time delay necessary to protect against false positives, stops supplying current to the LED of the semiconductor switch 2, which causes the semiconductor switch 2 to close, thereby connecting the circuit to the high voltage unit 7 and the discharge gap of the ozonizer 9 turns on the current limiting resistor 8, which limits the current flowing through this circuit to the nominal value.

Further, with a time delay necessary to complete the transient process, the control unit 1 again supplies current to the LED of the semiconductor switch 2, which leads to the shunting of the current-limiting resistor 8, returning the circuit to its original state.

If, after reclosing, the amplitudes of the operating frequency and / or RF current exceed the set values, then the control unit 1, without delay, sends a square current pulse of one second duration to the semiconductor switch 4, which causes an alternating voltage pulse to be applied to the coil electromagnetic relay 5, in consequence of which, the contacts of the electromagnetic relay 6 are opened, thus the device is de-energized.

Claims (1)

An emergency ozone protection device containing a control unit, a semiconductor switch, an electromagnetic relay, characterized in that it contains a current transformer, a high-voltage unit, a current limiting resistor, an ozonizer discharge gap, an electromagnetic relay contacts, and the control unit is connected to the first input of the semiconductor switch (2), and the second input of the control unit is connected to the second output of the semiconductor switch (2), and the third and fourth inputs are connected two inputs of the current transformer, the first output of the control unit is connected to the first input of the semiconductor switch (4), and the second output of the control unit is connected to the second input of the semiconductor switch (4), then the first output of the semiconductor switch (4) is connected to the first output of the electromagnetic relay, the second output of the electromagnetic relay is connected to the first wire of a single-phase electrical network, and the second output of the semiconductor switch is connected to the second wire of a single-phase electrical In addition, both wires of a single-phase electrical network are connected via the contacts of the electromagnetic relay to the inputs of the high-voltage unit, then the first output of the high-voltage block is connected to the first output of the current-limiting resistor through the primary current transformer winding , moreover, the discharge gap of the ozonizer by the second output is connected to the second output of the high-voltage unit, moreover, is parallel flax limiting resistor connected semiconductor switch (2) first and second inputs.

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