KR0135705B1 - Ozonizer - Google Patents

Abstract

The present invention relates to an ozone generator, and more particularly, to an ozone generator that maintains a constant amount of ozone regardless of ambient temperature.

To this end, the high voltage transformer 4 that applies a high voltage to the ozone generator 5 is turned on and off, and is composed of a resistor R1, R2, transistor TR, diode D, and variable resistor VR. In the ozone generating device comprising a section (3), connected in series with a variable resistor (VR) connected to the emitter terminal of the transistor (TR) to vary the output voltage of the high-voltage transformer (4) in accordance with the change in room temperature The temperature sensing means 6 is provided to maintain a constant amount of ozone regardless of room temperature change.

Description

Ozone generator

1 is a control circuit of a conventional ozone generator.

2 is a control circuit of the ozone generator according to the present invention.

* Explanation of symbols for main parts of the drawings

1: power supply unit 2: rectifier circuit

3: switching unit 4: high voltage transformer

6: temperature sensing means TR: transistor

Th: Dummyster R1-R4: Resistance

The present invention relates to an ozone generator, and more particularly, to an ozone generator for maintaining a constant amount of ozone regardless of the ambient temperature.

In the conventional ozone generating apparatus generally used, as shown in FIG. 1, two resistors R1 and R2 are connected in series at an output terminal of the power supply unit 1 for changing and stabilizing an AC power source into a DC voltage. Between (R1) and (R2) is provided with a switching unit (3) connected to the base of the transistor (TR) and at the same time the variable resistor (VR) at the emitter end thereof, and the diode (D) at the collector side in the reverse direction. The first coil L1, which is the primary coil of the high voltage transformer 4, is connected to the output terminal of the power supply unit 1 and the transistor TR collector terminal, and the second coil L2 is connected to the resistor R3 in series. An ozone generator 5 is connected to the third coil L3 which is the secondary coil of the high voltage transformer 4.

The conventional ozone generator, which is configured as described above, is first stabilized and output by being rectified to DC voltage by the rectifying circuit 2 of the power supply unit 1 when AC 110V or 220V is input, and then smoothed by passing through the capacitor C. The output voltage of the stable power supply unit 1 is divided by the resistors R1 and R2 of the switching unit 3 and applied to the transistor TR base as a bias voltage, thereby turning on. Energy is accumulated in the first coil L1. At this time, current is induced in the second coil L2, which is the secondary coil of the high voltage transformer 4, and energy is accumulated, thereby allowing the transistor TR to be continuously turned on. Will be.

On the other hand, as the voltage across the first coil L1 drops while the primary coil L1 of the high voltage transformer 4 is saturated, the voltage of the secondary coil 2 is also reduced, thereby reducing the transistor TR. When the voltage drops to a level that cannot be turned on, the transistor TR is turned off. At this time, the energy accumulated in the on state starts to discharge in the off state, accumulates energy, and the discharge of the third coil L3 ends. At this point, the voltage of the second coil L2 is increased to perform the repeating operation of turning on the transistor TR again.

Therefore, a high voltage is generated on the secondary coil 3 of the high voltage transformer 4 due to the on / off repetition of the transistor TR, which is the switching unit 3, and the ozone generator 5 is driven by the high voltage. The ozone is generated, and the collector current of the transistor TR is controlled by controlling the variable resistor VR to change the frequency voltage applied to the ozone generator 5.

In the conventional ozone generator, when the room temperature is low, the ozone generation amount increases, and when the room temperature is high, the ozone generation amount decreases, and the ozone generation amount is severely changed according to the ambient temperature, and thus a pleasant indoor environment cannot be maintained. In addition, this results in increased power savings, resulting in a lower reliability of the ozone generator.

The present invention adds a temperature sensing means in which a resistor and a dummyster are connected in parallel to the transistor emitter side of the switching unit to solve the above problems, and the oscillation frequency and high voltage supplied to the ozone generating unit by the temperature sensing means are automatically adjusted. It is an object of the present invention to provide an ozone generator that can reduce the power consumption and maintain the indoor environment comfortably by releasing the ozone generation constant regardless of the ambient temperature change.

The present invention for realizing such an object turns on / off the high voltage transformer 4 that applies a high voltage to the ozone generator 5, and provides resistors R1 (R2), transistors (TR), and diodes (D). In the ozone generator comprising a switching unit (3) made of a variable resistor (VR), the high voltage transformer is connected in series with the variable resistor (VR) connected to the emitter terminal of the transistor (TR) in accordance with the change in room temperature The temperature sensing means 6 for varying the output voltage of (4) is provided so as to keep the ozone generation constant regardless of room temperature change.

Hereinafter, described in detail by the accompanying drawings as follows.

2 is a control circuit diagram of an ozone generator according to the present invention, in which two resistors R1 and R2 are connected in series to an output terminal of a power supply unit 1 for changing and stabilizing an AC voltage to a DC voltage, and the resistor R1. R2 is connected to the base of the transistor TR, and the variable resistor VR is connected to the base of the transistor TR, and on the collector side, a switching unit 3 having a diode D connected in a reverse direction is provided. A first coil L1, which is a primary coil of the high voltage transformer 4, is connected to an output terminal of the transistor 1 and a collector terminal of the transistor TR, and a second coil L2 is connected to the resistor R3 in series. The generator 5 is connected to the third coil L3, which is a secondary coil of the high voltage transformer 4.

In addition, a temperature sensing means 6 is connected to the variable resistor VR connected to the emitter terminal of the transistor TR of the switching unit 3, and the temperature sensing means 6 includes a dummyster Th and a resistor R4. It is configured in parallel connection.

The present invention made as described above, when AC 110V or 220V is input, is rectified to DC voltage by the rectifier circuit 2 of the power supply unit 91, and then is stabilized and output by smoothing as it passes through the capacitor C. The output voltage of the stable power supply unit 1 is divided by the resistors R1 and R2 of the switching unit 3 and is turned on as it is applied to the transistor TR base bias voltage so that the first coil of the high voltage transformer 4 is turned on. Energy is accumulated at L1. At this time, current is induced in the third coil L2, which is the secondary coil of the high voltage transformer 4, so that energy is accumulated, so that the transistor TR can be continuously turned on.

On the other hand, as the voltage across the first coil L1 drops while the primary coil L1 of the high voltage transformer 4 is saturated, the secondary coil 2 voltage is also reduced to turn on the transistor TR. When the state becomes impossible, the transistor TR is turned off. At this time, the energy accumulated in the on state starts to discharge in the off state and accumulates energy.

Where Vout is the third coil L3 voltage, N3 is the number of turns of the third coil L3, N2 is the number of turns of the second coil, V _BE is the base and emitter voltage of the transistor TR, and V2 is the second. Is the number of turns of the coil L2).

Then, when the discharge of the third coil L3 is completed and turned off, the third coil L3, which is the secondary coil, is inducted into the second coil L2, which is the secondary coil. The transistor TR is turned on, where the voltage V2 of the second coil L2 is

By this action, the transistor TR is turned on / off to generate a high frequency.

Accordingly, a high voltage is generated on the secondary coil 3 of the high voltage transformer 4 due to the on / off repetition of the transistor TR, which is the switching unit 3, and the ozone generator 5 is driven by the high voltage. The ozone is generated, and the collector current of the transistor TR is controlled by controlling the variable resistor VR to change the frequency voltage applied to the ozone generator 5.

At this time, the room temperature is sensed by the dummyster Th of the temperature sensing means 6, but when the room temperature is high, the collector voltage of the transistor TR decreases as the self-resistance value of the dummyster Th increases. When the room temperature is low, the self-resistance value of the dummyster Th decreases and the collector voltage of the transistor TR increases.

Therefore, the transistor (TR) collector voltage is fluctuated due to a change in the room temperature, and as a result, the voltage applied to the first coil (L1), the primary coil of the high voltage transformer (4), is changed, thereby changing the secondary output coil. Since the voltage induced in the three coils L3 is changed in proportion to the room temperature, the ozone emission amount of the ozone generator 5 becomes constant, and the resistor R4 connected in parallel to the dummyster Th of the temperature sensing means 6. ) Acts to slow the tolerance compensation and a large change in the resistance value of the dummyster (Th) to reduce the error due to the temperature change of the dummy (Th).

As described above, the present invention provides a temperature sensing means in which a resistor and a dummyster are connected in parallel to the transistor emitter side of the switching unit, and the oscillation frequency and the high voltage supplied to the ozone generator are automatically adjusted by the temperature sensing means. Regardless of the change in the surrounding temperature, the ozone emission is released constantly, which reduces power consumption and maintains the indoor environment comfortably.

Claims (1)

A high voltage transformer 4 that applies a high voltage to the ozone generator 5 is turned on and off, and includes a switching unit including resistors R1, R2, transistors TR, diodes D, and variable resistors VR. 3) A ozone generator comprising: 3) a temperature sensing device connected in series with a variable resistor VR connected to an emitter terminal of the transistor TR to vary an output voltage of the high voltage transformer 4 according to a change in room temperature; An ozone generator, comprising means (6) to maintain a constant amount of ozone regardless of room temperature changes.