JPH08225306A - Ozone generating circuit - Google Patents

Abstract

PURPOSE: To safely operate an ozone generating circuit by impressing a high voltage to a creeping discharge material, electrically discharging, attaching a circuit for detecting fan stopping and abnormal discharge to an ozone generating circuit provided with a fan and shutting-off the circuit in response to the detection. CONSTITUTION: A fan is connected to terminals P2 and P4 , a pulse signal corresponding to the number of revolutions is led to P3 and connected through an OR circuit 12 and an AND circuit 13 to an input terminal S of a flip-flop 14. The flip-flop 14 detects abnormality of the fan when a switching wave form of the terminal P3 exceeds a threshold level. An electric current of the creeping discharging material 1 is partially taken out and added through the circuit 12 and the AND circuit 13 to the inlet terminal S of the flip-flop 14 to adjust a threshold level voltage. When an input voltage exceeds the threshold level by reduction in rotation of the fan or abnormality of a discharging circuit, the flip-flop 14 is set and an output terminal turns off a switch 17 and shuts-off the ozone generating circuit.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ozone generation circuit for generating ozone by applying a high voltage to a creeping discharge body.

[0002]

2. Description of the Related Art In an ozone generator, a high voltage obtained by boosting an AC signal from a self-excited oscillator with a step-up transformer is applied to a creeping discharge body having a fine ceramic as a dielectric layer, and air is generated by discharging the creeping discharge body. There is one that is made to react to obtain ozone. In this type of ozone generator, a piezoelectric element is attached to the discharge element for ozone generation, in order to prevent problems during discharge such as prevention of deposits (dirt) and improvement of nitrate mist, etc. Is provided to drive the piezoelectric element (Japanese Patent Laid-Open No. 62-2016).
38, 63-190702).

[0003]

The conventional ozone generator described above is provided with a fan to blow the generated ozone in order to uniformly output a predetermined amount. However, if this fan stops due to a failure during ozone generation, ozone will not be output properly, ozone concentration will occur depending on the area, and high concentration ozone will be around the device, which is a health problem. It may remain in the device and adversely affect circuit elements.
Further, even if the fan is rotating, an excessive current flows due to an abnormal discharge of the creeping discharge body, which may cause ignition, or a high voltage is used, so that the device may be damaged if the abnormal discharge is left unattended. Furthermore, if only the fan is rotating even when ozone is not normally generated, it may give a false impression that the device is operating normally. However, the conventional ozone generator is not equipped with any means for dealing with the abnormality, and has a problem in reliability and safety.

The present invention has been made in view of the above problems, and an object thereof is to provide a highly reliable ozone generating circuit which detects an abnormal condition and operates safely. There is.

[0005]

According to another aspect of the present invention, there is provided an ozone generating circuit, wherein a voltage boosted by a drive transformer is applied to a creeping discharge body to cause discharge to generate ozone, and a fan is additionally provided. A fan stop detection circuit that detects a stop of the discharge circuit, and / or a discharge abnormality detection circuit that detects an abnormality of the discharge circuit of the creeping discharger; and a circuit that shuts off the circuit in response to the fan stop detection and / or the discharge abnormality detection. It is equipped with the characteristic.

In this ozone generation circuit, when the rotation of the fan is stopped (including low speed), this is detected by the fan stop detection circuit. When the discharge current of the creeping discharge body exceeds a predetermined value (abnormal discharge or short circuit), the discharge abnormality detection circuit detects it. When the fan stop detection or the discharge abnormality is detected, the fan is stopped and the operation of the discharge circuit is stopped. This avoids continuation of the operation in the abnormal state.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in more detail with reference to embodiments. FIG. 1 is a circuit connection diagram of an ozone generating circuit according to an embodiment of the present invention. In the figure, P ₁ is a + power supply connection terminal, a fan (not shown) is connected to terminals P ₂ and P ₄ , and a pulse signal corresponding to the rotation speed of the fan is derived to P ₃ . This is the terminal P ₃ are integrated circuits configured constituted by capacitor C _5, R _7, the terminal P ₃ are connected to the set input S of the flip-flop 14 via the OR circuit 12, the AND circuit 13. When the switching waveform at the terminal P ₃ exceeds the threshold level, the flip-flop 14 is set to detect the fan abnormality and sets the flip-flop 14. Similarly, a part of the current (20 KHz) of the creeping discharger 1 is taken out by the resistors R ₅ and R ₆ , and the OR circuit 12 and AND
It is added to the set input terminal S of the flip-flop 14 via 13. The resistance R is set so that the threshold level voltage of the flip-flop 14 is reached by a current about twice that in the normal state.
₆ and R ₅ are selected. Further, a timer 16 is provided, and the rising voltage when the power is turned on is set to the resistance R ₈
Reset timer 16 via 5, then AN in 2 seconds
The logic "1" is input to the D circuit 13 and resets itself via the OR circuit 15 with the output of "10 minutes". The output terminal Q of the flip-flop 14 is an ON / OFF switch 1
It is connected to Nos. 7 and 18, and O when set output Q = "1".
The N / OFF switch 17 and 18 are turned off.

Assuming that the fan is rotating normally in the ozone generating circuit of this embodiment, the waveform input to the terminal P ₃ is up to t _{1 in} FIG. The input also does not exceed the threshold level TH. Therefore, the flip-flop 14 is not set. However, when the rotation speed of the fan decreases to 60 _rpm or less, the threshold level TH is exceeded and the flip-flop 14 is set as shown at time t ₂ in FIG.
Is turned off, the discharge is stopped, and the power supply to the fan is cut off. However, as described above, one end of the AND circuit 13 does not become "1" for about 2 seconds after the operation is started, so that the flip-flop 14 is not set and therefore the cutoff function does not work.

Even when the fan is operating normally, when an abnormally large current flows due to water drops or the like, the voltage applied to the OR circuit 12 becomes large due to the resistors R ₅ and R ₆ , and the threshold level is exceeded. , Flip-flop 14 is set. Switch 17 turns O with this set output
FF, discharge is stopped, switch 18 is turned off
After that, the fan also stops operating.

The flip-flop 14 is a timer 1
It resets with the 10-minute signal of 6, and if there is an instantaneous abnormality, 1
It can be used again after 0 minutes. FIG. 3 is a whole circuit of an ozone generating apparatus in which the ozone generating circuit of the above embodiment is incorporated. The main circuit of FIG. 1 corresponds to the circuit portion 32 of FIG. Hereinafter, in FIG. 3, circuits other than the circuit portion of FIG. 1 will be described.

In FIG. 3, the circuit portion 30 is the same as that shown in FIG.
It shows a logical circuit, 1 is fine ceramic
A surface discharger for ozone generation used in the dielectric layer
A piezoelectric element 2 is attached to prevent an object (dirt) or the like.
Secondary winding N of step-up transformer 3 _sAre both electrodes of creeping discharger 1
Connected directly to point A of the primary winding of step-up transformer 3.
One end of the DC power supply 4 is connected, and the other end of the DC power supply 4 is
Booster transformer 3 via emitter and collector of transistor 6
Is connected to point B. The base of the transistor 6
The oscillation source 5 is connected to the switch. Also, a step-up transformer
The primary winding of 3 is winding N_P1In addition, winding N_P2Is added
Then, tap C point and tap A point are connected to the piezoelectric element 2.
ing.

In this ozone generating circuit, the DC power source 4
The DC voltage of V 1 is self-excited including the transformer 3 when the transistor 6 is turned ON / OFF by the signal from the oscillation source 5, and the voltage V ₁ boosted by the step-up transformer 3 at a ratio of N _s / N _P1. Is applied to the creeping discharger 1,
Are discharged, and at that time, the air reacts to generate ozone.
In addition, the winding N _P1 and N further wound on this winding N _P1
A voltage V ₂ due to _P2 is applied to the piezoelectric element 2 and vibrates the piezoelectric element 2.

With this circuit, the voltage of the power supply 4 is now 12 VDC.
When the discharge voltage V ₁ = 2800V _{P- P} and the frequency of the oscillation source 5 is 19.5 KHz, the voltage V ₂ of the piezoelectric element ₂ is 50 V _PP (sine wave), and the desired vibration effect is obtained. . In the related art, when a piezoelectric element drive circuit is provided separately from the step-up transformer 3, it is 17 KHz, 20
Compared to the fact that only the control up to V _PP was possible and the vibration effect was extremely small, this is a remarkable advance.

In FIG. 3, a circuit portion 31 shows a concrete circuit in FIG. 5, and includes a resistor R ₄ , a capacitor C ₃ ,
The transistor 6, the step-up transformer 3, and the creeping discharge body 1 constitute a transformer-coupled self-excited oscillation circuit, and a high voltage is applied to the creeping discharge body 1. Step-up transformer 3
Of the secondary winding N _s is connected to the GND (ground) via the resistor R ₅ . The resistor R ₅ constitutes the discharge current detection circuit 9. One end of the capacitor C ₁ is connected to the connection point between the step-up transformer N _s and the resistor R ₅ , and the capacitor C ₁
Is connected to the base of the transistor 7, and the resistor R ₁ is connected between the other end of the capacitor C ₁ and GND. Filter 1 In this capacitor C ₁ and resistor R ₁
Configures 0. The transistor 7 is provided to amplify the signal from the filter 10, and has an emitter connected to GND and a collector connected to a + 12V power source via a resistor R ₃ . A rectifying diode D is connected to the collector of the transistor 7,
A capacitor C ₂ and a resistor R ₂ are provided on the output side of the diode D.
Is connected to the base of the transistor 8 which controls the oscillation state of the self-excited oscillation circuit.
The resistor R ₄ is a variable resistor and is used for adjusting the oscillation intensity.

In this circuit portion 31, the creeping discharger 1
The waveform of the current flowing through is shown in FIG. The middle waveform a is the main component, which is the charging / discharging current flowing in the capacitor component between the discharge electrodes, and the frequency is 20 KHz to 40 K.
Hz. The waveform b is a pulsed noise of 1 μsec (1 MHz or more) that is superimposed on the main component due to discharge in air. This component b is proportional to the discharge strength in air. Therefore, in the embodiment, the resistor R ₅ detects the current flowing in the creeping discharge body 1, the filter 10 derives only the pulse component b, the transistor 7 amplifies the pulse component b, the diode D rectifies it, and the smoothing is performed. The DC voltage smoothed by the circuit 11 is fed back to the transistor 8, and when the feedback voltage is high, the self-excited oscillation is weakened, and when the feedback voltage is low, the self-excited oscillation is strengthened. As feedback control,
The amount of discharge is constant. A resistor R ₂ and a capacitor C ₂
The feedback response speed is stabilized by the time constant of.

[0016]

According to the present invention, the fan stop abnormality and the discharge abnormality are detected, and the circuit is shut down by any one of the abnormalities, for example, the fan is stopped and the discharge is stopped. There is an advantage that leakage of concentrated ozone, abnormal ozone generation, adverse effects due to heat generation of circuit components, and the like can be prevented.

[Brief description of drawings]

FIG. 1 is a circuit connection diagram showing an ozone generating circuit according to an embodiment of the present invention.

FIG. 2 is a waveform diagram for explaining the operation of the ozone generation circuit of the same embodiment.

FIG. 3 is a circuit connection diagram showing an entire circuit of an ozone generating apparatus in which the ozone generating circuit of the same embodiment is incorporated.

FIG. 4 is a circuit connection diagram showing a partial circuit of the ozone generator.

FIG. 5 is a circuit connection diagram showing another partial circuit of the ozone generator.

FIG. 6 is a waveform diagram for explaining the operation of a part of the circuit of the ozone generating circuit according to the same embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Creeping discharger 14 Flip-flop 17, 18 switch 22 Fan R ₇ , C ₅ integrating circuit

Claims (1)

[Claims] 1. A voltage boosted by a drive transformer is applied to a creeping discharge body to cause discharge to generate ozone, and
In an ozone generation circuit provided with a fan, a fan stop detection circuit for detecting stop of the fan, and / or a discharge abnormality detection circuit for detecting abnormality of the discharge circuit of the creeping discharge body, the fan stop detection and / or discharge abnormality An ozone generation circuit comprising: a circuit that cuts off the circuit in response to detection.