JP4094926B2 - Ozone generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an ozone generator that includes ozone generating means and an internal power source inside a case, and enables sterilization and deodorization of a closed space such as the interior of an automobile.
[0002]
[Prior art]
Conventionally, when this type of ozone generator is equipped with a battery inside the device and is capable of generating ozone alone, a main switch is provided and the ozone generation time is regulated by turning the switch on and off. Is common. It is also conceivable to use a cigarette lighter as a power source for ozone generation and to control the ozone generation time by turning on and off the power supply by switching the ignition key.
[0003]
[Problems to be solved by the invention]
By the way, ozone has a sterilizing or deodorizing effect, but it is harmful to the human body, and an environment that inhales ozone for a long period of time is not preferable. High nature.
[0004]
The present invention has been made in view of such inconveniences, and is generated by enabling the ozone generating means to be driven by an internal power source and starting ozone generation after detecting the off operation of the external power source. An object of the present invention is to provide an ozone generator that prevents the danger of human exposure to ozone as much as possible.
[0005]
Another object of the present invention is to provide an ozone generator suitable for in-vehicle use by using an in-vehicle battery as an external power source and supplying power from a cigarette lighter.
[0006]
It is another object of the present invention to provide an ozone generator that can prevent forgetting to turn off ozone generation by automatically stopping ozone generation when a preset condition is achieved.
[0007]
Furthermore, it is possible to generate negative ions and ozone by the difference in applied voltage to the same electrode, and to generate ozone exclusively by the secondary battery charged by the external power source, while generating negative ions by the external power source. Thus, an object of the present invention is to provide an ozone generator that can effectively use two types of power sources.
[0008]
[Means for Solving the Problems]
As shown schematically in FIG. 1, the ozone generator 16 according to the present invention includes an ozone generator 12 and an internal power supply 14 inside the case body 10, and interlocks with the switching operation of the switch 82. The ozone generator 12 can be driven by the power source 14.
[0009]
Further, the voltage Vo can be supplied to the inside of the case body 10 from the external power supply 18 provided outside the case body 10, the driving of the ozone generating means 12 is selected by the switch 82, and the external power supply 18 is selected. After the stop of the external voltage Vo supplied is detected by the external power source detecting means 19, wherein the driving of the ozone generator 12 by the internal power supply 14 is started.
[0010]
A car battery is used as the external power source 18, and power into the case body 10 is performed via a cigarette lighter plug 26, and the operation of regulating the supply of the external voltage Vo is like a switching operation of an ignition switch. It is preferably performed in conjunction with the start and stop operations of the automobile.
[0011]
Further, the ozone generating means 12 is automatically stopped when the preset condition is satisfied by the drive timing regulating means 24. As the drive timing regulating means 24, a timer circuit 20 as shown in FIG. 5 is preferable, and the ozone generating means 12 is forcibly stopped from being energized by the internal power supply 14 after a set time has elapsed since the timer circuit 20 started to drive. The In addition, the count value of the timer circuit 20 is reset in conjunction with the off operation of the external power supply 18 described above.
[0012]
The internal power supply 14 is a secondary battery and is charged using the external power supply 18 described above. The case body 10 further includes negative ion generation means 22, and the negative ion generation means 22 is driven by an external power source 18. The ozone generator 12 and the negative ion generator 22 are controlled by changing the voltage applied to the single discharge electrode 42.
[0013]
The switching state of the switch 82 and the ozone generation state are preferably displayed separately. As this display method, a part or all of the case body 10 is formed of a translucent member, and display can be performed by light emission of a light emitting element provided inside the case body 10.
[0014]
【The invention's effect】
As described above, the present invention makes it possible to drive the ozone generating means 12 by the internal power source 14 and to start generating ozone after detecting the off operation of the external power source 18, thereby exposing a person to the generated ozone. The risk of being lost is prevented as much as possible.
[0015]
Using an in-vehicle battery as the external power supply 18 and supplying power from the cigarette lighter, the external voltage is stopped in conjunction with the ignition key turning-off operation. Is generated.
[0016]
Even after the above-described ozone generation is started, forgetting to turn off ozone generation is prevented by automatically stopping ozone generation after a set time elapses by a preset condition, for example, the timer circuit 20. Furthermore, since the timer circuit 20 resets the count value in conjunction with the off operation of the external power supply 18, a sufficient time for ozone generation is reliably maintained.
[0017]
Further, by using a secondary battery as the internal power source 14 and charging the external power source 18, it is possible to reliably prevent a shortage of ozone generating power source.
[0018]
Furthermore, the negative ion generating means 22 is provided at the same time and driven by the external power source 18, so that the internal power source 14 can be prevented from being consumed. In addition, the device configuration can be simplified by generating ozone and negative ions by utilizing the difference in the applied voltage to the same discharge electrode.
[0019]
In addition, since the switching state of the switch 82 and the ozone generation state can be individually displayed, the operation state of the device can be accurately grasped. Further, by providing a light emitting element inside the case body 10 and performing light emission display through the case body 10 having translucency, it is possible to combine display and illumination.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
As shown in FIG. 2, the ozone generator 16 according to the present invention includes an electronic circuit having a configuration illustrated in FIG. 1 inside a case body 10 formed in, for example, a substantially cubic shape. Further, the power supply plug 26 is extended from the center of the back surface side of the case body 10, and the plug 26 is inserted into a cigarette lighter that is always provided by the automobile. Is supplied to the electronic circuit.
[0021]
In the present embodiment, since a cigarette lighter provided in the vehicle is used as the external power source 18, a cigarette lighter plug 26 is integrally provided for supplying power to the inside of the device. However, when other power sources are used as the external power source 18, a plug or socket suitable for the power source used on the wall surface of the case body 10 is provided, or a power supply cord is extended from the case body 10 to It is also possible to provide a predetermined electrode at the tip. In addition, as long as power necessary for driving an electronic circuit can be supplied, the type of power supplied or a specific configuration for supplying the power is not limited, such as a power supply in a wireless state. . Further, the shape of the case body 10 can be arbitrarily modified, such as a spherical shape, and can be arbitrarily modified such as a form that is self-supporting on a dashboard or the like in addition to being held by the plug portion.
[0022]
The electronic circuit provided inside the case body 10 includes a discharge unit 28 that generates negative ions and ozone, and switching that switches between ion generation and ozone generation, as schematically illustrated in FIG. Unit 30, display unit 32 enabling display corresponding to the display state in discharge unit 28, power supply unit 34 for supplying drive voltage to discharge unit 28, and control unit 36 for regulating the operation of ozone generating means 12. Consists of
[0023]
Here, when the power supply unit 34 is configured for in-vehicle use as in this embodiment, as shown in FIG. 3, the external voltage Vo supplied from the external power supply 18 via the cigarette lighter and the internal power supply 14 And an internal voltage Vi supplied from.
[0024]
The internal power supply 14 is a secondary battery or a large-capacity capacitor that can be charged and discharged a plurality of times, such as a nickel-cadmium battery. Further, the internal power supply 14 uses the output voltage Vo from the external power supply 18 by the charging circuit 38 constantly or appropriately. It is charged at the time, and a predetermined charge capacity can be maintained. Further, the output voltage Vi from the internal power supply 14 is set to a low voltage of about 2.5V, while the DC 12V or 24V external voltage Vo supplied from the cigarette lighter is stepped down to 2.5V using the step-down circuit 40. As a result, the external power supply 18 and the internal power supply 14 are set to substantially the same output voltage Vl so that both power supplies 18 and 14 can be switched and used in common in the following circuits.
[0025]
As shown in FIG. 4, the discharge unit 28 applies a negative high voltage to an electrode unit 46 composed of a needle-like discharge electrode 42 and a ring-shaped counter electrode 44, thereby leading the tip of the discharge electrode 42. The corona discharge is caused to occur, and negative ions and ozone are simultaneously generated by the discharge.
[0026]
That is, when corona discharge is caused by applying a high voltage of negative polarity, as shown in FIG. 6, at the same time as negative ions are generated, ozone is also generated although the amount is smaller than that. Furthermore, the amount of generation increases as the applied voltage Vh increases.
[0027]
Here, for example, the amount of ozone h generated when the applied voltage is 3.5 kV is sufficiently smaller than the amount of negative ions generated e, and the sterilizing effect or the like is not exhibited. As a result, the influence of ozone can be ignored, and it can be considered that only negative ions are substantially generated. Therefore, the discharge state when this voltage is applied is referred to as “ion mode”. Furthermore, when the applied voltage to the discharge electrode 42 is increased to, for example, about 5 kV, the amount of ozone generated reaches a level H suitable for sterilization and deodorization, so that only E is generated at the same time, “Ozone mode” is set.
[0028]
The discharge unit 28 changes the negative polarity voltage applied to the discharge electrode 42 in two steps, upper and lower, corresponding to the two selected modes, and applies a low-voltage DC voltage Vl to a medium-pressure pulsating flow. A first booster circuit 48 that converts the voltage Vm into a voltage Vm, and a second booster circuit 50 that generates a high discharge voltage Vh from the medium-pressure pulsating voltage Vm.
[0029]
The first booster circuit 48 forms a medium-voltage AC voltage of about 100 V from a low-voltage DC voltage Vl of about 2.5 V by the inverter circuit 52, and then performs half-wave rectification by the rectifier circuit 54, whereby FIG. The voltage Vm as shown in FIG.
[0030]
The second booster circuit 50 includes a pulse voltage generation circuit 56 and a high voltage generation circuit 58. Here, the pulse voltage generation circuit 56 has a configuration in which a capacitor 64 is connected in series with the primary coil 62 of the step-up transformer 60, and a Sidac 66 is connected in parallel with the serial connection.
[0031]
The Sidac 66 is off while the applied voltage is low, but is turned on when the value of the input pulsating voltage Vm exceeds a threshold value Vs of about 80 V, for example. The capacitor 64 is charged with the pulsating voltage Vm, and when the charging current is turned on, the charging current is abruptly discharged through the side winding 66 and the primary coil 62 and the side winding 66 is turned off. By repeating this operation periodically until the pulsating current voltage Vm drops below the threshold value Vs and the Sidac 66 is always turned off, the pulse voltage Vp as shown in FIG. 60 is generated in the primary coil 62.
[0032]
The pulse voltage Vp is boosted in accordance with the winding ratio between the primary coil 62 and the secondary coil of the step-up transformer 60, and then generates a high voltage composed of a diode 68 and a capacitor 70 connected in series with the secondary coil 63. Applied to circuit 58.
[0033]
In the high voltage generation circuit 58, a high voltage Vh having a negative polarity as shown in FIG. 7C is formed by integrating the high voltage pulse voltage intermittently output from the secondary coil 63 of the step-up transformer 60. The voltage Vh is applied to the electrode portion 46 and corona discharge is performed between the discharge electrode 42 and the counter electrode 44.
[0034]
Next, as a method of changing the value of the generated high voltage, in this embodiment, the Sidak 66 in the pulse voltage generation circuit 56 is switched and used. That is, the relay of the voltage switching circuit 99 that turns on the second sideac 66a having the threshold value Vs2 lower than the threshold value Vs1 in conjunction with the operation mode switching operation in parallel with the first sideac 66 having the threshold value Vs1. The connection is made via the switch contact 72 of 71.
[0035]
Then, the value of the generated high voltage changes due to the difference in threshold value. For example, when the threshold value Vs2 is the average value of the high voltage generated in the case of the threshold value Vs1, it is −3. It drops to 5 kV. Therefore, the amount of ozone generated decreases from H to h shown in FIG. At this time, the amount of negative ions is only reduced from E to e, which is extremely suitable for generating negative ions.
[0036]
It should be noted that the specific circuit configuration for forming the high voltage Vh is not limited to the above, and it is needless to say that it can be implemented with appropriate modifications such as using a known booster circuit that has been used conventionally. . For example, in FIG. 4, only one of the Sidac 66a is configured to change the connection state with a relay contact. However, a switching transistor is interposed one by one in series with the two Sidac 66 and 66a, Both sideacs can be connected individually.
[0037]
Further, in order to change the amount of ozone generated, the discharge state is not changed by mechanically changing the distance between the discharge electrode 42 and the counter electrode 44, but by changing the value of the high voltage applied to the discharge electrode 42. Can be changed. In addition, as described above, the circuit for generating ozone and negative ions, the discharge electrode or the discharge mode are not shared. It is also possible to switch to use.
[0038]
Further, in this embodiment, a blower circuit 78 including a blower motor 74 and a fan 76 is provided, and ions or ozone generated by forming an air flow with the fan 76 rotated by the motor 74 is collected at the front center of the case body 10. It is configured to forcibly blow out of the case body 10 from the discharge port 80 provided in the case. However, without providing the blower circuit 78, it may be naturally released by the ion flow generated at the time of discharge.
[0039]
Next, the switching unit 30 includes a sliding mode changeover switch 82 and first and second switching circuits 84 and 86 that are turned on and off in conjunction with the changeover operation of the changeover switch 82.
[0040]
Here, the change-over switch 82 is provided on the outer peripheral surface of the case body 10 as shown in FIG. 2 and is switched by the operator's slide operation. In the intermediate position, the electronic circuit inside the case body 10 is Although off operation, a changeover switch 82 as shown in FIG. 3, the "ion mode" switching to a'side, b, in switching to b'side to "ozone mode" that The drive mode can be switched alternatively.
[0041]
That is, when the changeover switch 82 is switched to the “ion mode”, the output voltage V ₂ from the external power supply 18 is applied to the first switching circuit 84 by the switching transistor 90 via the diode 88, The driving power can be supplied to the discharge unit 28. The output voltage V ₂ is also applied to the voltage switching circuit 99. The first switching circuit 84 is interposed in series with the discharge unit 28. When the changeover switch 82 is switched from the off state to the ion mode, the switching transistor 90 is turned on, and the discharge unit 28 is driven by the external power source 18. At the same time, the voltage switching circuit is turned on, the high voltage value is changed to -3.5 KV, negative ions are generated, and the blower circuit 78 is driven to forcibly generate the generated ions. 10 to the outside.
[0042]
On the other hand, when the changeover switch 82 is switched to the “ozone mode” side, the drive voltage Vl is supplied from the internal power supply 14 side to the discharge unit 28, and as a result, the voltage Vi output from the internal power supply 14 instead of the external power supply 18. Thus, the discharge unit 28 can be driven.
In this embodiment, the mode changeover switch is set to manual. However, as shown in FIG. 8, the switching unit 30 is automatically switched by the signal from the external power supply detection means. May be. Specifically, in the state where the external power source is connected, the negative ion switching unit 30a is turned on. When the external power source is detected to be off, the negative ion switching unit 30a is activated by a signal from the external power source detection means 19. While being turned off, the ozone switching unit 30b is turned on.
[0043]
Here, the first switching circuit 84 interposed in series with the discharge unit 28 is applied with the control signal S2 via the diode 92 and the second switching circuit 86 which is turned on by the output signal S1 sent from the control unit 36. It is configured to be. Therefore, the first switching circuit 84 is turned on only during a period in which the changeover switch 82 is switched to the ozone mode side and the output signal S1 from the control unit 36 is output, and the discharge unit 28 can be operated. .
[0044]
As shown in FIG. 5, the control unit 36 includes a timer circuit 20 and an external power supply detection circuit 94. When the external power supply detection circuit 94 detects the stop of the external voltage Vo output from the external power supply 18, the timer circuit 20 The count value is reset to the initial value, and the count-up operation is started to output the signal S1 to the second switching circuit 86. Further, when the timer circuit 20 finishes counting for a predetermined time, the output of the signal S1 is turned off, and the operation of the discharge unit 28 can be forcibly stopped.
[0045]
The external power supply detection circuit 94 connects a switching transistor 98 in parallel with the capacitor 96, applies the output voltage Vo from the external power supply 18 to the control terminal of the transistor 98, and further connects both ends of the capacitor 96 to the timer circuit 20. Connected to the reset terminal.
[0046]
With this configuration, during the period when the external voltage Vo is input, the transistor 98 is turned on, the capacitor 96 is discharged, and the reset terminal of the timer circuit 20 is grounded. Here, when the output from the external power supply 18 is stopped, the transistor 98 is turned off, and when the capacitor 96 is charged, the reset signal Sr is applied to the timer circuit 20 and the count value is reset to zero.
[0047]
The timer circuit 20 starts counting when the reset signal Sr is input while the drive voltage Vi is applied from the internal power supply 14, and starts outputting the signal S1 from the output terminal. Further, when the count value reaches a set number of about 8 minutes, for example, the output of the signal S1 is stopped.
It is possible to start the timer circuit 20 immediately after the external voltage Vo is stopped to generate ozone. However, for example, a waiting time of about several minutes is provided until the timer circuit 20 is started. It is also possible to provide a predetermined time margin before leaving the vehicle.
[0048]
Next, the display unit 32 can distinguish and display the switching state between the ozone mode and the negative ion mode by the changeover switch 82 and the operation of the discharge unit 28.
[0049]
Here, the operation mode is switched by disposing the first and second indicators 85 and 87 on the wall surface of the case body 10 corresponding to both sides of the changeover switch 82 in the moving direction of the knob 83. The selected modes are distinguished and displayed by individually lighting the indicators 85 and 87.
[0050]
In this embodiment, when the generation of negative ions that are good for the body is selected, for example, a green light emitting diode that lights up safety is turned on. On the contrary, when the generation of ozone is selected, the mode selection state can be displayed as an image to the operator by using a red light emitting diode that images danger.
[0051]
On the other hand, the third indicator 89 that displays the operation of the discharge unit 28 is disposed inside the case body 10 and the case body 10 itself is formed to be transparent or translucent, thereby When the entire case body 10 is turned on by lighting, the case body 10 itself has a form of indoor lighting, and can display while ions or ozone are being released.
[0052]
Here, since the first indicator 85 is for displaying the selection time of the negative ion mode, as shown in FIG. 3, the first display 85 is supplied from the step-down circuit 40 that is output when the changeover switch 82 is switched to the negative ion mode. A current is supplied at a voltage of 5 to emit light.
[0053]
In addition, since the second indicator 87 is lit when the ozone mode is selected, the indicator 87 constituted by a light emitting diode is applied by applying the driving voltage of the timer circuit 20 of the controller 36 shown in FIG. Light.
[0054]
Further, since the third indicator 89 is lit and displayed in response to the operation of the discharge unit 28, it is configured to be driven by the output voltage from the inverter circuit 52 in the discharge unit 28 shown in FIG. Yes.
[0055]
However, in place of or in addition to the display using the light emitting diode as described above, if the mode selection described above and the actual operation state can be distinguished and displayed, such as display using a picture or text on the liquid crystal, it can be changed as appropriate. Can be implemented.
[0056]
With the above configuration, when the external voltage Vo is not supplied through the plug 26, the first and second indicators 85 and 87 are not lit even when the changeover switch 82 is slid, and the operation of the discharge unit 28 is performed. Of course, it is displayed that the mode cannot be selected.
[0057]
Next, when the automobile engine is started by operating the ignition key in the state of being inserted into the plug 26, the external voltage Vo is supplied to the inside of the case body 10 through the plug 26. Then, in response to the change of the slide position of the changeover switch 83, the first display 85 or the second display 87 is turned on, and the selection of “ion mode” or “ozone mode” is displayed from the lighting color. Further, when the selection mode is the ion mode, the external voltage Vo is supplied to the discharge unit 28, and the third indicator 89 is turned on to display the generation time of negative ions.
[0058]
On the other hand, when the “ozone mode” is selected, the second indicator 87 is lit to indicate that the mode has been selected, but at that stage, the third indicator 89 is not lit but discharged. The unit 28 continues to be stopped. In this state, when the ignition key is turned off to stop the vehicle and the person goes out of the vehicle, the timer circuit 20 starts counting, starts the discharge unit 28, and starts ozone generation.
[0059]
Further, when ozone generation continues for a set time, the timer circuit 20 is timed up, and the ozone generation by the discharge unit 28 is forcibly stopped, so that the sterilization and deodorizing operations by ozone are also terminated, so that humans are exposed to ozone. This is prevented in advance.
[0060]
In addition to the configuration described above, a sensor for detecting the presence of a person is provided. If a person is detected, the ozone generation operation does not start even if the supply of the external voltage Vo is cut off. Safety can be further increased by generating ozone after detecting this.
[0061]
The application location of the ozone generator according to the present invention is not limited to the interior of an automobile, but can be applied even when ozone is generated in a closed space where people enter and exit, such as a toilet. In this case, the disconnection from the external power supply is a disconnection from the commercial power supply unlike the case of the automobile, and therefore a disconnection switch is provided as necessary. In addition to manual switching, the cutting switch may be linked to a human body sensor or the like in consideration of usability. Moreover, when applying in a toilet etc., the structure linked with the illumination switch in a toilet is also considered. Specifically, a configuration in which the present ozone generator is incorporated in a lighting device and an external power source is connected in parallel to the lamp input unit side and the input unit side of the ozone generator is desirable.
[Brief description of the drawings]
FIG. 1 is a block diagram schematically showing an overall configuration of the present invention.
FIG. 2 is an external perspective view showing an example in which the present invention is implemented.
FIG. 3 is an electric circuit diagram specifically showing a configuration of a power supply unit and a switching unit.
FIG. 4 is an electric circuit diagram showing a configuration of a discharge unit.
FIG. 5 is an electric circuit diagram showing a configuration of a control unit.
FIG. 6 is a graph showing the relationship between the voltage applied to the discharge electrode and the amount of ozone.
FIG. 7 is a waveform diagram for explaining the operating state of the discharge unit.
FIG. 8 is a block diagram schematically showing an overall configuration of another embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Case body 12 Ozone generating means 14 Internal power supply 16 Ozone generating instrument 18 External power supply 20 Timer circuit 22 Negative ion generating means 24 Driving timing regulating means 26 Power supply plug 28 Discharge part 30 Switching part 32 Display part 34 Power supply part 36 Control part 38 charging circuit 40 step-down circuit 42 discharge electrode 44 counter electrode 46 electrode 48 first booster circuit 50 second booster circuit 52 inverter circuit 54 rectifier circuit 56 pulse voltage generation circuit 58 high voltage generation circuit 60 step-up transformer 62 primary coil 64 capacitor 66 sideac 68 Diode 70 Capacitor 72 Switch contact 74 Motor 76 Fan 78 Blower circuit 80 Ozone outlet 82 Changeover switch 84 First switching circuit 86 Second switching circuit 88 Diode 90 Switching transistor 92 Diode De 94 external power supply detection circuit 96 the transistor 99 voltage switching circuit of capacitor 98 switching

Claims (8)

Inside the case body (10), an ozone generator (12) , an internal power supply (14) which is a secondary battery charged by an external power supply (18) provided outside the case body (10), and negative ions Generating means (22), in conjunction with the switching operation of the switch , driving of the negative ion generating means (22) by the external power supply (18) and of the ozone generating means (12) by the internal power supply (14). An ozone generating device that can selectively switch between driving and
To the inside of the case body (10), thereby enabling supplying the driving voltage Vo from the external power supply (18),
After the driving of the ozone generating means (12) is selected by the switch and the stop of the driving voltage Vo supplied from the external power supply (18) is detected, the ozone generating means (12 by the internal power supply (14) is detected. ) Driving is started. The external power source (18) is an automobile battery, and power is supplied to the case body (10) via a cigarette lighter, and the power supply regulation operation stops the output voltage from the cigarette lighter. The ozone generator of Claim 1 performed by doing. The ozone generating device according to claim 2, wherein the ozone generating means (12) is automatically stopped when a preset condition is satisfied. A timer circuit (20) is provided in the case body (10), and the ozone generating means (12) is energized from the internal power source (14) after a set time from the start of driving by the timer circuit (20). The ozone generator according to claim 3, which is forcibly stopped. The timer circuit (20) resets the count value and counts in conjunction with the external power source (18) being turned off during the period when power is supplied from the internal power source (14). The ozone generating device according to claim 4, which is started. The ozone generator according to claim 1, wherein switching between the ozone generating means (12) and the negative ion generating means (22) is performed by changing a voltage applied to a single discharge electrode (42). The ozone generating device according to claim 6 , wherein the switch switching state and the ozone generation state are individually displayed. The ozone generation according to claim 7 , wherein a part or all of the case body (10) is formed of a translucent member, and the display is performed by light emission of a light emitting element provided inside the case body (10). Instruments.

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