JP6993197B2 - Ozone generation system - Google Patents

Description

The present disclosure relates to an ozone generation system capable of generating ozone, for example, inside a container or a storage.

Conventionally, ozone has been used as an oxidative disinfectant, and is also widely used in, for example, the food field and the semiconductor manufacturing field.
As a device for generating ozone, for example, a device for generating high-concentration ozone by silent discharge or creeping discharge is known. Specifically, an ozone generator that generates high-concentration ozone by forming a discharge cell with a high-voltage electrode and a ground electrode, supplying oxygen gas between both electrodes and applying a high voltage is known. (See Patent Document 1).

See Japanese Patent No. 5193086

By the way, for example, when the ozone generator is arranged in the container for transportation, the ozone generator in the container cannot be supplied with electric power from the outside by a commercial power source. Therefore, the power source of the ozone generator is a battery arranged in the container.

However, for example, when shipping a container from Japan to Southeast Asia, it takes about 2 to 3 weeks, so if ozone is always generated with the maximum power by the battery, the power of the battery will be exhausted during the transportation.

On the other hand, if ozone is always generated with the minimum power by the battery, the battery may have the power, but there is a problem that the effect of ozone to sterilize mold fungi cannot be sufficiently exerted.
The present disclosure has been made in view of such a background, and an object of the present invention is to provide an ozone generation system capable of suppressing battery consumption and supplying ozone for a long period of time in a structure. ..

(1) The first aspect of the present disclosure is ozone that generates ozone in a structure having an internal space where ventilation with the surrounding space is restricted and supplies ozone from the inside of the device to the outside of the device. It relates to an ozone generation system equipped with a generator.

This ozone generator is driven by the power of the battery, an ozone generator that generates ozone, an ozone control unit that controls the power supplied to the ozone generator, and the power of the battery, which is generated by the ozone generator. It is equipped with a fan that discharges ozone from the inside of the device to the outside of the device, and a fan control unit that controls the driving state of the fan.

Further, a battery voltage detector that detects the battery voltage, a voltage determination unit that determines whether the battery voltage has dropped below a predetermined determination value, and a battery voltage drop below the determination value. Is provided with a suppression control unit that performs power suppression control for suppressing the power supplied to the ozone generator and / or the power supplied to the fan by the ozone control unit and / or the fan control unit.

In the first phase, the battery voltage is detected, and when the battery voltage drops below a predetermined determination value, the ozone control unit or fan control unit supplies the power to the ozone generator or the fan. By suppressing the electric power, it is possible to suppress the consumption of the electric power of the battery. Further, since the consumption of the electric power of the battery can be suppressed, ozone necessary for sterilization and the like can be suitably supplied for a long period of time as compared with the case where the battery is used with the maximum electric power.

That is, according to the first aspect, it is possible to suppress the consumption of the battery and maintain the ozone concentration inside the container or the like containing the container such as vegetables or meat at an appropriate ozone concentration for a long period of time. .. For example, when the battery is used at the maximum power, the power of the battery may be insufficient during the transportation of the container or the like, and ozone may not be generated. However, according to the first aspect, such a battery is dead. Ozone can be generated over a period of time by suppressing the state.

As a result, the ozone concentration inside the container or the like can be maintained at an appropriate ozone concentration within a possible range for a long period of time, so that the bactericidal activity of mold fungi and the like can be suitably maintained for a long period of time. Therefore, it is possible to suitably suppress the spoilage of contained items such as vegetables and meat.

(2) In the second aspect of the present disclosure, the power supplied to the ozone generator may be set to a predetermined minimum value by the suppression control unit.
In the second aspect, the power consumption of the battery can be suitably suppressed by setting the power supplied to the ozone generator to a predetermined minimum value. The minimum value of this electric power is the minimum value in the range in which ozone can be generated.

(3) In the third aspect of the present disclosure, the electric power supplied to the fan may be set to a predetermined minimum value by the suppression control unit.
In the third aspect, the power consumption of the battery can be suitably suppressed by setting the power supplied to the fan to a predetermined minimum value. The minimum value of this electric power is the minimum value in the range in which the fan can blow air.

(4) In the fourth aspect of the present disclosure, a plurality of determination values may be provided, and the upper limit value of the electric power supplied to the ozone generator may be set according to the region divided by each determination value.
In the fourth aspect, a plurality of determination values are provided in order to determine the voltage of the battery. Then, the upper limit value of the electric power supplied to the ozone generator is set according to the voltage region divided by each determination value. As a result, it is possible to suitably suppress the power consumption of the battery while maintaining the ozone generation amount.

(5) In the fifth aspect of the present disclosure, a plurality of determination values may be provided, and an upper limit value of the electric power supplied to the fan may be set according to the region divided by each determination value.
In the fifth aspect, a plurality of determination values are provided for determining the voltage of the battery. Then, the upper limit value of the electric power supplied to the fan is set according to the voltage region divided by each determination value. As a result, it is possible to suitably suppress the power consumption of the battery while maintaining the amount of air blown by the fan (that is, the amount of air from the fan).

(6) In the sixth aspect of the present disclosure, feedback control of the power supplied to the ozone generator may be performed so that the ozone concentration in the internal space inside the device or the external space outside the device becomes the target ozone concentration.

By performing such feedback control, it is possible to control the ozone concentration in the internal space or the external space so as to be preferably a target ozone concentration. Further, by performing the feedback control in this way, it is possible to suppress the consumption of the battery.

If the power that can be used is limited as described above, for example, if the minimum value is set or the upper limit is set, feedback control should be performed within the range of the power that can be used. Can be done.

It is a block diagram which shows the whole structure of the ozone generation system of 1st Embodiment. It is a block diagram which functionally shows the structure of the control part of the ozone generation system of 1st Embodiment. It is a flowchart which shows the outline of the main control process of the ozone generation system of 1st Embodiment. It is a flowchart which shows the detail of the main control process of the ozone generation system of 1st Embodiment. It is a flowchart which shows the control process of 2nd Embodiment. Experimental example 1 is shown, (a) is a graph showing changes in power and ozone concentration in the case of "without control", and (b) is a graph showing changes in power and ozone concentration in the case of "with control", (c). ) Is a graph showing the change in battery level over time. Experimental example 2 is shown, (a) is a graph showing changes in power and ozone concentration in the case of "without control", and (b) is a graph showing changes in power and ozone concentration in the case of "with control", (c). ) Is a graph showing the change in battery level over time.

Hereinafter, embodiments of the ozone generation system to which the present disclosure has been applied will be described with reference to the drawings.
[1. First Embodiment]
[1-1. Overall configuration of ozone generation system]
As shown in FIG. 1, the ozone generation system 1 of the first embodiment is provided in a structure (for example, a container) 3 having an internal space (K2) in which ventilation with the surrounding space (outside world) K1 is restricted. It is provided with an ozone generator 5 that generates ozone and supplies ozone from inside the device 5 to the outside of the device 5.

Further, inside the ozone generator 5, an internal ozone sensor 7 for detecting the ozone concentration (that is, the internal ozone concentration) of the internal space K3, which is the space inside the ozone generator 5, is provided. Further, outside the ozone generator 5, a plurality of external ozone sensors 9a for detecting the ozone concentration (that is, the external ozone concentration) of the external space K4, which is the space outside the ozone generator 5 (however, the space inside the structure 3). , 9b (collectively referred to as 9). Although two external ozone sensors 9 are illustrated in FIG. 1, the number of external ozone sensors 9 may be one or three or more.

Further, the ozone generator 5 uses an ozone generator 11 for generating ozone, a high-pressure power supply 13 for supplying power for generating ozone to the ozone generator 11, and ozone generated by the ozone generator 11. It includes a fan 15 that discharges (that is, conveys) from the inside of the device 5 to the outside of the device 5, and a control unit 17 that controls the operation of the ozone generator 5.

Further, a battery 19 for supplying electric power to the ozone generator 5 is arranged in the structure 3.
Further, an external controller 23 provided with a display unit 21 is arranged outside the structure 3. The external controller 23 can send and receive information to and from the ozone generator 5 (specifically, the control unit 17) and instruct the operation of the ozone generator 5 by wireless communication. The external controller 23 and the ozone generator 5 may be connected by wire.

[1-2. Each configuration of ozone generation system]
Next, each configuration of the ozone generation system 1 will be described in more detail.
The ozone generator 11 is a well-known ozone generator 11 that generates ozone by being supplied with electric power from a high-voltage power source 13. As the ozone generator 11, for example, the ozone generator 11 described in International Publication No. 2017/098987 can be adopted.

Although not shown, the ozone generator 11 has a structure in which a plurality of electrode panels having discharge electrodes are laminated, and a plurality of plasma panel laminates that generate plasma by applying a voltage between adjacent electrode panels. It is a plasma reactor provided with a clamp for sandwiching and fixing the electrode panel in the stacking direction. In the ozone generator 11, for example, by applying a pulse voltage between the electrode panels, a dielectric barrier discharge is generated, and plasma due to the dielectric barrier discharge is generated between the discharge electrodes. Therefore, this plasma generates ozone from oxygen in the air.

The high-voltage power supply 13 is a power supply that applies the pulse voltage having a peak voltage of, for example, 5 kV (pulse repetition frequency: 100 Hz) in order to generate ozone in the ozone generator 11. The high-voltage power supply 13 is supplied with power required for ozone generation from the power supply 19 via the control unit 17.

Therefore, the power supplied to the ozone generator 11 can be controlled by adjusting the pulse voltage supplied from the high-voltage power source 13 to the ozone generator 11, so that the amount of ozone generated by the ozone generator 11 (for example, per unit time) can be controlled. The amount of ozone generated) can be adjusted.

The operation of the fan 15 is controlled by the control signal from the control unit 17 while being supplied with electric power from the control unit 17. That is, the amount of air blown (hence the amount of ozone carried) is adjusted by the fan 15.

Specifically, when the electric power supplied to the fan 15 increases, the rotation speed of the fan 15 increases, and the amount of air blown (that is, the amount of fan air) increases. For example, when a pulse voltage is applied to a motor that drives a fan 15, the rotation speed of the fan 15 (hence, fan air volume) can be controlled by adjusting the pulse voltage.

The control unit 17 is an electronic control device equipped with a well-known microcomputer or the like, and as shown in FIG. 2, functionally, the fan control unit 25, the ozone control unit 27, the abnormality detection unit 29, and the battery voltage detection unit 31 It has a voltage determination unit 33 and a suppression control unit 35.

Of these, the ozone control unit 27 sets the ozone concentration in the internal space K3 to the target internal ozone concentration (that is, the target internal ozone concentration) based on the signals from the internal ozone sensor 7 and the external ozone sensor 9. Alternatively, it has a function of controlling the operation of the high-voltage power supply 13 so that the ozone concentration of the external space K4 becomes the target external ozone concentration (that is, the target external ozone concentration).

That is, it has a function of controlling the electric power supplied from the high voltage power source 13 to the ozone generator 11 so as to reach the target internal ozone concentration or the target external ozone concentration, that is, a function of performing so-called feedback (FB) control.

The fan control unit 25 controls the power supplied to the fan 15 so that the ozone concentration in the external space K4 becomes the target external ozone concentration (that is, the target external ozone concentration) based on the signal from the external ozone sensor 9. It has a function to perform so-called feedback control.

The abnormality detection unit 29 detects an abnormality in the voltage and / or current of the ozone generator 11. Specifically, a well-known voltage detection circuit or current detection circuit (not shown) detects the voltage and / or current of electricity flowing through the ozone generator 11 itself, and detects the abnormality. Further, the voltage and / or current of the electricity supplied from the high voltage power supply 13 to the ozone generator 11 is detected, and the abnormality is detected.

Further, the abnormality detection unit 29 detects an abnormality of the internal ozone concentration and / or the external ozone concentration by detecting a signal indicating the ozone concentration from the internal ozone sensor 7 and / or the external ozone sensor 9.

The battery voltage detection unit 31 has a function of detecting the voltage of the battery 19 based on a signal from a voltage detection circuit (not shown) that detects the voltage of the well-known battery 19.
The voltage determination unit 33 has a function of determining whether or not the voltage of the battery 19 has dropped to a predetermined determination value (for example, 24V) or less.

When the voltage of the battery 19 drops below the determination value, the suppression control unit 35 supplies power to the ozone generator 11 and / or the fan 15 by the ozone control unit 27 and / or the fan control unit 25. It has a function to perform power suppression control to suppress the supplied power.

Further, the control unit 17 can perform various controls as described below by the suppression control unit 35 and the like.
(1) For example, when the voltage of the battery 19 becomes equal to or less than a predetermined determination value, it is possible to control to set the power supplied to the ozone generator 11 to a predetermined minimum value.

(2) For example, when the voltage of the battery 19 becomes equal to or less than a predetermined determination value, the power supplied to the fan 15 can be set to a predetermined minimum value.
(3) A plurality of the determination values can be provided, and the upper limit of the electric power supplied to the ozone generator 11 can be set according to the region divided by each determination value.

(4) A plurality of the determination values can be provided, and the upper limit of the power supplied to the fan 15 can be set according to the region divided by each determination value.
Further, the external ozone sensor 9 is driven by receiving electric power from the battery 19 or a sensor battery (not shown) arranged in the circuit of the external ozone sensor 9 itself. The external ozone sensor 9 can transmit information on the external ozone concentration to the control unit 17 by wireless communication or by wire. Also, the external ozone sensor 9. It is possible to communicate with the outside of the structure 3 (for example, the external controller 23) by wireless communication.

The external controller 23 is an electronic control device provided with a well-known microcomputer, and is a device capable of instructing the generation and stop of ozone in the ozone generator 11 by wire or wirelessly from the outside of the structure 3. ..

The display unit 21 of the external controller 23 can display an operation (for example, “during ozone generation”) related to the ozone generator 5. Further, the display unit 21 can display the internal ozone concentration and / or the external ozone concentration.

[1-3. Outline configuration of the entire control process]
Next, an outline of the entire control process performed by the control unit 17 of the first embodiment will be described with reference to the flowchart of FIG. In the flowchart of FIG. 3 and the like, the step is referred to as S.

As shown in FIG. 3, in step 100, the power switch (SW) instructing the operation of the ozone generation system 1 is turned on (ON), and in step 110, the ozone generation switch (SW) instructing the generation of ozone is performed. If is turned on, the process proceeds to the following steps 120 and subsequent steps.
In step 120, the internal ozone concentration is detected based on the signal from the internal ozone sensor 7, and the power for ozone generation is adjusted so that the internal ozone concentration becomes the target internal ozone concentration.

That is, the process of this step 120 is a process of controlling the electric power (hence, the amount of ozone generated) supplied from the high voltage power source 13 to the ozone generator 11 in order to achieve the target internal ozone concentration. That is, the feedback control of the internal ozone concentration is performed.

Then, when the target internal ozone concentration is reached, the process proceeds to the following steps 130 and subsequent steps.
In step 130, the external ozone concentration is detected based on the signal from the external ozone sensor 9, and the power supplied to the fan 15 is adjusted so that the external ozone concentration becomes the target external ozone concentration, and the fan air volume is adjusted. adjust.

That is, the process of this step 130 is a process of controlling the electric power supplied to the fan 15 (hence, the ozone transport amount corresponding to the fan air volume) in order to reach the target external ozone concentration. That is, the feedback control of the external ozone concentration is performed.

When the target external ozone concentration is reached by this feedback control of the external ozone concentration (that is, when the concentration adjustment is OK), it is assumed that the external ozone concentration has been adjusted appropriately, and this process is temporarily terminated. That is, the process of adjusting the external ozone concentration described above is continued until the ozone generation switch and the power switch are turned off.

On the other hand, if it is determined that the target external ozone concentration has not been reached even if the fan air volume is controlled for a certain period of time (that is, in the case of concentration adjustment NG), it is assumed that the external ozone concentration has not been adjusted appropriately. Proceed to step 140.

In step 140, the ozone generation mode is switched so that the target external ozone concentration is obtained, and the ozone generation amount is controlled.
That is, the process of this step 140 is a process of controlling the amount of ozone generated in order to obtain the target external ozone concentration. That is, the amount of ozone generated itself is changed to control the feedback of the external ozone concentration.

[1-4. Detailed contents of control processing]
Next, the contents of the control process (main control process) shown in FIG. 3 will be described in detail with reference to FIG.

As shown in FIG. 4, when the power switch instructing the operation of the ozone generation system 1 is turned on in step 200 and the ozone generation switch instructing the generation of ozone is turned on in step 210, the following The process proceeds to the process after step 220 of.

When the power switch is turned on, the LED indicating that is turned on, and when the ozone generation switch is turned on, the LED indicating that is turned on.
In step 220, the timer output is turned on and time counting by the timer is started.

In the following step 230, in order to start the measurement of the internal ozone concentration and the external ozone concentration, the driving (that is, energization) of the internal ozone sensor 7 and the external ozone sensor 9 is started.
In the following step 240, power is started to be supplied to the ozone generator 11 in order to generate ozone in the ozone generator 11.

In the following step 250, the target external ozone concentration is set based on the input from, for example, a switch for setting the ozone concentration.
In the following step 260, it is determined whether or not the time for activating the internal ozone sensor 7 and the external ozone sensor 9 has elapsed from the start of energization of the internal ozone sensor 7 and the external ozone sensor 9. If affirmative judgment is made here, the process proceeds to step 270, while if a negative judgment is made, the process proceeds to wait.

In step 270, the ozone generation amount is set to a predetermined minimum value (however, a lower limit value exceeding 0), and the fan air volume is set to a predetermined minimum value (however, a lower limit value exceeding 0).
For example, in order to minimize the ozone generation amount, the electric power supplied to the ozone generator 11 is set to the minimum value (for example, 4W) in a predetermined supply range, and in order to minimize the fan air volume, the fan 15 is used. The power to be supplied to is set to the minimum value (for example, 1 W) in a predetermined supply range.

In the following step 280, the output power (first output voltage) for the ozone generator 11 is adjusted so as to reach the target internal ozone concentration. That is, the amount of ozone generated is adjusted. The first output voltage is different from the minimum value which is the fixed initial value in step 270, and is the output power according to the target internal ozone concentration in the normal operation of the ozone generator 5.

That is, the first output power is the power output to the ozone generator 11 in order to realize the target internal ozone concentration when the target internal ozone concentration is set to, for example, 0.05 ppm. Is.

The control for achieving this target internal ozone concentration is a feedback control that adjusts the first output voltage based on the internal ozone concentration.
In the following step 290, it is determined whether or not the voltage of the battery 19 (that is, the battery voltage) is equal to or higher than a predetermined voltage (B1: for example, 24V), that is, whether or not the battery voltage is sufficient. If an affirmative judgment is made here, the process proceeds to step 330, while if a negative judgment is made, the process proceeds to step 300.

In step 300, since the battery voltage is low, a map showing the relationship between the battery voltage and the upper limit of the first output voltage is referred to. This map is stored in, for example, a memory (not shown) of the control unit 17.

This map (map 1) is provided with a plurality of determination values of the battery voltage so as to divide the battery voltage into a plurality of regions in the range of the battery voltage less than B1. Then, the upper limit value of the electric power supplied to the ozone generator 11 is set according to the region classified by each determination value. Therefore, by using this map, it is possible to set the upper limit value of the electric power corresponding to the battery voltage.

In the following step 310, it is determined whether or not the first output voltage is equal to or less than the upper limit value obtained from the map. If an affirmative judgment is made here, the process proceeds to step 330, while if a negative judgment is made, the process proceeds to step 320.

In step 320, the first output voltage is set to the upper limit value, and the process proceeds to step 330. That is, in order to suppress the consumption of the battery 19, the upper limit of the output voltage of the battery 19 is defined.
In step 330, it is determined whether or not a predetermined time (T1 hour) has elapsed from the start of adjusting the ozone generation amount. If an affirmative judgment is made here, the process proceeds to step 340, while if a negative judgment is made, the current output power is maintained and the process waits until the T1 time elapses.

In step 340, it is determined whether or not the internal ozone concentration has reached A times the target internal ozone concentration. If an affirmative judgment is made here, the process proceeds to step 350, while if a negative judgment is made, the process returns to step 280.

The A is a numerical value exceeding 1. Here, the reason why A is set to a value higher than 1 is that the internal ozone concentration may be temporarily high or high depending on the location, and the value is set in anticipation of this. That is, this is to prevent erroneous determination that the internal ozone concentration is sufficiently high even when the internal ozone concentration is low on average.

In step 350, it is determined whether or not the external ozone concentration has reached the target external ozone concentration. If an affirmative judgment is made here, the process returns to step 340, while if a negative judgment is made, the process proceeds to step 360.

In step 360, it is determined whether or not a predetermined time (T2 hours) has elapsed from the start of the process of S350. If an affirmative judgment is made here, the process proceeds to step 440, while if a negative judgment is made, the process proceeds to step 370.

In step 370, since the external ozone concentration is low, the fan air volume is adjusted. Specifically, the process of increasing the fan air volume up to now is performed.
In the following step 390, it is determined whether or not the battery voltage is equal to or higher than a predetermined voltage (B2: for example, 24V), that is, whether or not the battery voltage is sufficient. If an affirmative judgment is made here, the process proceeds to step 430, while if a negative judgment is made, the process proceeds to step 400.

In step 400, since the battery voltage is low, a map showing the relationship between the battery voltage and the upper limit of the output voltage for driving the fan (second output voltage) is referred to. This map is stored in the memory of the control unit 17, for example.

This map (map 2) is provided with a plurality of determination values of the battery voltage so as to divide the battery voltage into a plurality of regions in the range of the battery voltage less than B2. Then, the upper limit value of the electric power supplied to the fan 15 is set according to the region divided by each determination value. Therefore, by using this map, it is possible to set the upper limit value of the electric power corresponding to the battery voltage.

In the following step 410, it is determined whether or not the second output voltage is equal to or less than the upper limit value obtained from the map. If an affirmative judgment is made here, the process proceeds to step 430, while if a negative judgment is made, the process proceeds to step 420.

In step 420, the second output voltage is set to the upper limit value, and the process proceeds to step 430.
In step 430, it is determined whether or not a predetermined time (T3 hours) has elapsed from the start of adjusting the fan air volume. If an affirmative judgment is made here, the process returns to step 350, while if a negative judgment is made, the current fan air volume is maintained and the process waits until the T3 time elapses.

On the other hand, in step 440, which is positively determined in step 360 and proceeds, the output power to the ozone generator 11 is adjusted so as to reach the target external ozone concentration. That is, the amount of ozone generated is adjusted.

In a subsequent step 450, it is determined whether or not the battery voltage is equal to or higher than a predetermined voltage (B3: for example, 24V), that is, whether or not the battery voltage is sufficient. If an affirmative judgment is made here, the process proceeds to step 490, while if a negative judgment is made, the process proceeds to step 460.

In step 460, since the battery voltage is low, a map showing the relationship between the battery voltage and the upper limit of the first output voltage supplied to the ozone generator 11 is referred to.
Similar to the map 1, this map (map 3) is provided with a plurality of determination values of the battery voltage so as to divide the battery voltage into a plurality of regions in the range of the battery voltage less than B3. The map 1 can also be adopted as this map.

In the following step 470, it is determined whether or not the first output voltage is equal to or less than the upper limit value obtained from the map. If an affirmative judgment is made here, the process proceeds to step 490, while if a negative judgment is made, the process proceeds to step 480.

In step 480, the first output voltage is set to the upper limit value, and the process proceeds to step 490.
In step 490, it is determined whether or not the external ozone concentration has reached the target external ozone concentration. If an affirmative judgment is made here, the process returns to step 340, while if a negative judgment is made, the process returns to step 360.

Here, for each of the predetermined times (T1, T2, T3), for example, 1 min, 10 min, and 2 min can be adopted, respectively. Each predetermined time (T1, T2, T3) is appropriately set according to the surrounding conditions such as the size of the space K2 inside the structure 3.

The above-mentioned process is continued until the ozone generation switch and the power switch are turned off.
[1-5. effect]
Next, the effect of the first embodiment will be described.

(1) In the first embodiment, the battery voltage is detected, and when the battery voltage drops below a predetermined determination value, it is supplied to the ozone generator 11 by the ozone control unit 27 and the fan control unit 25. By suppressing the electric power and the electric power supplied to the fan 15, it is possible to suppress the consumption of the electric power of the battery 19. Further, since the power consumption of the battery 19 can be suppressed, the amount of ozone required for sterilization and the like can be supplied for a long period of time.

That is, according to the first embodiment, the consumption of the battery 19 is suppressed, and the ozone concentration inside the container or the like for accommodating vegetables, meat, or the like is maintained at an appropriate ozone concentration for a long period of time. Can be done. That is, since the ozone concentration inside the container or the like can be maintained at an appropriate ozone concentration for a long period of time, the bactericidal activity of mold fungi or the like can be suitably maintained for a long period of time. Therefore, it is possible to suitably suppress the spoilage of contained items such as vegetables and meat.

(2) In the first embodiment, a plurality of determination values are provided for determining the battery voltage for the control of the ozone generator 11. Then, when the battery voltage is low, the upper limit value of the electric power supplied to the ozone generator 11 is set according to the region of the battery voltage classified by each determination value. As a result, it is possible to suitably suppress the consumption of electric power of the battery 19 while ensuring the amount of ozone generated.

(3) In the first embodiment, a plurality of determination values are provided for determining the battery voltage for the control of the fan 15. Then, when the battery voltage is low, the upper limit value of the power supplied to the fan 15 is set according to the region of the battery voltage classified by each determination value. As a result, it is possible to suitably suppress the consumption of electric power of the battery 19 while ensuring the fan air volume.

(4) In the first embodiment, since the feedback control of the power supplied to the ozone generator 11 is performed so that the ozone concentration of the internal space K3 or the external space K4 becomes the target ozone concentration, the internal space K3 or the external space K4 or The ozone concentration of the external space K4 can be easily set to the target ozone concentration. Further, by performing such feedback control, it is possible to suppress the consumption of the battery 19.

[1-6. Correspondence of words]
Here, the correspondence between words will be described.
Structure 3, ozone generator 5, ozone generation system 1, battery 19, ozone generator 11, ozone control unit 27, fan 15, fan control unit 25, battery voltage detection unit 31, voltage determination unit of the first embodiment. 33, the suppression control unit 35, respectively, of the present disclosure, the structure, the ozone generator, the ozone generation system, the battery, the ozone generator, the ozone control unit, the fan, the fan control unit, the battery voltage detection unit, the voltage determination unit, It corresponds to an example of the suppression control unit.

[2. Second Embodiment]
Next, the second embodiment will be described, but the same contents as those of the first embodiment will be omitted or simplified. The same configuration as in the first embodiment is given the same number.

Since the control process of the second embodiment is different from that of the first embodiment, different control processes will be described.
The control process of the second embodiment is a control process for suppressing the consumption of the battery 19 when the battery voltage is low.

As shown in the flowchart of FIG. 5, when the power switch is turned on in step 500 and the ozone generation switch is turned on in step 510, the process proceeds to the following steps 520 and subsequent steps. When the power switch is turned on, the LED indicating that is turned on, and when the ozone generation switch is turned on, the LED indicating that is turned on.

The processing after step 520 is repeated every predetermined cycle.
In step 520, it is determined whether or not the battery voltage is equal to or higher than a predetermined voltage (B1: for example, 23V). If an affirmative judgment is made here, the process proceeds to step 530, while if a negative judgment is made, the process proceeds to step 540.

In step 530, normal control is performed, and this process is temporarily terminated. For example, as in the first embodiment, the amount of ozone generated is adjusted so that the internal ozone concentration becomes the target internal ozone concentration. In addition, the fan air volume is adjusted and the ozone generation amount is adjusted so that the external ozone concentration becomes the target external ozone concentration. For example, when the external ozone concentration is low, control is performed to increase the amount of ozone generated.

On the other hand, in step 540, it is notified that the battery 19 is exhausted and the remaining battery level is low, for example, by turning on the LED.
In the following step 550, the mode in which the battery 19 is used is set to the low power consumption mode. For example, set a flag indicating the low power consumption mode.

In the following step 560, the ozone generation amount is set to the minimum value.
In the following step 570, the fan air volume is set to the minimum value, and this process is temporarily terminated.
The second embodiment basically has the same effect as the first embodiment.

In particular, in the second embodiment, the power consumption of the battery 19 can be suitably suppressed by setting the power supplied to the ozone generator 11 to a predetermined minimum value.
Further, by setting the electric power supplied to the fan 15 to a predetermined minimum value, it is possible to suitably suppress the consumption of the electric power of the battery 19.

[2. Experimental example]
Next, Experimental Examples 1 and 2 performed to confirm the effect of the present disclosure will be described.
<Experimental Example 1>
Experimental Example 1 is an investigation of the ozone concentration (external ozone concentration) when the ozone generation and the fan drive are temporarily stopped in the ozone generation system of the first embodiment.

FIG. 6A shows the time change of the ozone concentration when the total of the electric power supplied to the high voltage power source (that is, the ozone generator) and the fan is kept constant at 35 W (average in 1 hour). The electric power supplied to the ozone generator is 20 W, and the electric power supplied by the fan is 15 W, which are constant.

In FIG. 6 (a), the electric power is indicated by a line and the ozone concentration is indicated by a dot (hereinafter, the same applies to FIGS. 6 (b), 7 (a), and 7 (b)).
FIG. 6B shows the state of the ozone generation system switched as in each period of <1>, <2>, <3>, and <4>. The average power of the ozone generator in one hour is 16 W.

In <1>, 24 W of electric power was supplied to the ozone generator. A minimum value of 1 W of electric power was supplied to the fan. In this state, the ozone concentration is slightly high.
In <2>, 24 W of electric power was supplied to the ozone generator. The fan was supplied with 11 W of power, which is higher than the minimum value. This increased the ozone concentration.

In <3>, the generation of ozone was stopped and the fan was also stopped. As a result, the ozone concentration gradually decreased.
<4> indicates that the ozone concentration is 0.1 ppm or less. When this state is reached, the process returns to <1> and the same control is repeated.

Next, a battery having a discharge capacity of 12 V and 50 Ah is divided into a case as shown in FIG. 6 (a) (without control) and a case as controlled as shown in FIG. 6 (b) (with control). Will be described when used under the following conditions.

-Voltage: 24V (two batteries connected in series)
・ Number of batteries: 16 (8 sets of 2 series 24V batteries connected in parallel)
-Current capacity: 50Ah x 8 parallel = 400Ah
[Without control]
In the case of "no control" as in FIG. 6 (a), the battery is consumed in a short time as shown by the broken line in FIG. 6 (c). Specifically, in the case of "no control", it can be seen from the following calculation that the remaining battery level becomes 0 Ah in about 11 days.

35W / 24V = 1.46Ah
400Ah / 1.46Ah = about 274h = about 11 days (Sun)
[With control]
In the case of "with control" as shown in FIG. 6 (b), the battery life is extended as shown by the solid line in FIG. 6 (c). Specifically, in the case of "with control", it can be seen from the following calculation that the remaining battery level becomes 0 Ah in about 25 days.

16W / 24V = 0.66Ah
400Ah / 0.66Ah = about 600h = about 25 days (Sun)
<Experimental Example 2>
Experimental Example 2 is an investigation in the case where the ozone generation and the fan drive are controlled so as to have a target ozone concentration (external ozone concentration) in the ozone generation system of the first embodiment.

FIG. 7A shows the time change of the ozone concentration when the total power supplied to the high voltage power supply (that is, the ozone generator) and the fan is kept constant at 35 W (average power). The electric power supplied to the ozone generator is 24 W, and the electric power supplied by the fan is 11 W, which are constant.

FIG. 7B shows the state of the ozone generation system switched as shown in <1>, <2>, and <3> so as to obtain the target ozone concentration while monitoring the ozone concentration. .. The average power of the ozone generator is 16W.

In <1>, it was driven for several days so that the ozone concentration was 0.3 ppm.
In <2>, it was driven at 15 W for several days so that the ozone concentration was 0.15 ppm.
In <3>, the ozone concentration was driven at 10 W so as to be 0.1 ppm, which is a safety standard.

The drive of the fan was automatically changed according to the conditions as in the first embodiment.
Next, a battery having a discharge capacity of 12 V and 50 Ah is divided into a case as shown in FIG. 7 (a) (without control) and a case as controlled as shown in FIG. 7 (b) (with control). Will be described when used under the following conditions.

-Voltage: 24V (two batteries connected in series)
・ Number of batteries: 16 (8 sets of 2 series 24V batteries connected in parallel)
-Current capacity: 50Ah x 8 parallel = 400Ah
[Without control]
In the case of "no control" as in FIG. 7 (a), the battery is consumed in a short time as shown by the broken line in FIG. 7 (c). Specifically, in the case of "no control", it can be seen from the following calculation that the remaining battery level becomes 0 Ah in about 11 days.

35W / 24V = 1.46Ah
400Ah / 1.46Ah = about 274h = about 11 days (Sun)
[With control]
In the case of "with control" as shown in FIG. 7 (b), the battery life is extended as shown by the solid line in FIG. 7 (c). Specifically, in the case of "with control", it can be seen from the following calculation that the remaining battery level becomes 0 Ah in about 25 days.

16W / 24V = 0.66Ah
400Ah / 0.66Ah = about 600h = about 25 days (Sun)
[3. Other embodiments]
It goes without saying that the present disclosure is not limited to the above-described embodiment, and can be carried out in various embodiments without departing from the present disclosure.

(1) For example, for the ozone generator, various well-known configurations can be adopted in addition to the above-described embodiment.
(2) Examples of the structure include a container, a warehouse, or the like in which an opening (for example, an entrance / exit) is closed or sealed by a door or the like. Further, the ozone generation system of the above-described embodiment is driven, for example, when an opening such as a container or a warehouse is closed by a door or the like. Then, the control of the above-described embodiment is carried out, for example, when an opening such as a container or a warehouse is closed by a door or the like.

(3) The functions of one component in the above embodiment may be dispersed as a plurality of components, or the functions of the plurality of components may be integrated into one component. Further, a part of the configuration of the above embodiment may be omitted. Further, at least a part of the configuration of the above embodiment may be added or substituted with respect to the other configurations of the above embodiment. It should be noted that all aspects included in the technical idea specified from the wording described in the claims are embodiments of the present disclosure.

1 ... Ozone generation system 3 ... Structure 5 ... Ozone generator 11 ... Ozone generator 15 ... Fan 19 ... Battery 25 ... Fan control unit 27 ... Ozone control unit 31 ... Battery voltage detection unit 33 ... Voltage determination unit 35 ... Suppression control Department

Claims (5)

In a structure that has an internal space where ventilation with the surrounding space is restricted,
An ozone generation system equipped with an ozone generator that generates ozone and supplies the ozone from inside the device to the outside of the device.
The ozone generator is
The ozone generator, which is driven by the electric power of the battery and generates the ozone,
An ozone control unit that controls the electric power supplied to the ozone generator,
A fan driven by the electric power of the battery and discharging the ozone generated by the ozone generator from the inside of the device to the outside of the device.
A fan control unit that controls the drive state of the fan,
A battery voltage detection unit that detects the voltage of the battery, and
A voltage determination unit that determines whether or not the battery voltage has dropped below a predetermined determination value, and
When the voltage of the battery drops below the determination value, the ozone control unit controls the power suppression to suppress the power supplied to the ozone generator, and the suppression control unit.
Equipped with
The suppression control unit sets the electric power supplied to the ozone generator to a predetermined minimum value.
Ozone generation system. In a structure that has an internal space where ventilation with the surrounding space is restricted,
An ozone generation system equipped with an ozone generator that generates ozone and supplies the ozone from inside the device to the outside of the device.
The ozone generator is
The ozone generator, which is driven by the electric power of the battery and generates the ozone,
An ozone control unit that controls the electric power supplied to the ozone generator,
A fan driven by the electric power of the battery and discharging the ozone generated by the ozone generator from the inside of the device to the outside of the device.
A fan control unit that controls the drive state of the fan,
A battery voltage detection unit that detects the voltage of the battery, and
A voltage determination unit that determines whether or not the battery voltage has dropped below a predetermined determination value, and
When the voltage of the battery drops below the determination value, a suppression control unit that performs power suppression control to suppress the power supplied to the fan by the fan control unit.
Equipped with
The suppression control unit sets the electric power supplied to the fan to a predetermined minimum value .
Ozone generation system. In a structure that has an internal space where ventilation with the surrounding space is restricted,
An ozone generation system equipped with an ozone generator that generates ozone and supplies the ozone from inside the device to the outside of the device.
The ozone generator is
The ozone generator, which is driven by the electric power of the battery and generates the ozone,
An ozone control unit that controls the electric power supplied to the ozone generator,
A fan driven by the electric power of the battery and discharging the ozone generated by the ozone generator from the inside of the device to the outside of the device.
A fan control unit that controls the drive state of the fan,
A battery voltage detection unit that detects the voltage of the battery,
A voltage determination unit that determines whether or not the battery voltage has dropped below a predetermined determination value, and
When the voltage of the battery drops below the determination value, the ozone control unit controls the power suppression to suppress the power supplied to the ozone generator, and the suppression control unit.
Equipped with
A plurality of the above-mentioned judgment values are provided,
The upper limit of the electric power supplied to the ozone generator is set according to the region classified by each of the determination values.
Ozone generation system. In a structure that has an internal space where ventilation with the surrounding space is restricted,
An ozone generation system equipped with an ozone generator that generates ozone and supplies the ozone from inside the device to the outside of the device.
The ozone generator is
The ozone generator, which is driven by the electric power of the battery and generates the ozone,
An ozone control unit that controls the electric power supplied to the ozone generator,
A fan driven by the electric power of the battery and discharging the ozone generated by the ozone generator from the inside of the device to the outside of the device.
A fan control unit that controls the drive state of the fan,
A battery voltage detection unit that detects the voltage of the battery, and
A voltage determination unit that determines whether or not the battery voltage has dropped below a predetermined determination value, and
When the voltage of the battery drops below the determination value, a suppression control unit that performs power suppression control to suppress the power supplied to the fan by the fan control unit.
Equipped with
A plurality of the above-mentioned judgment values are provided,
The upper limit of the electric power supplied to the fan is set according to the area classified by each of the determination values .
Ozone generation system. In a structure that has an internal space where ventilation with the surrounding space is restricted,
An ozone generation system equipped with an ozone generator that generates ozone and supplies the ozone from inside the device to the outside of the device.
The ozone generator is
The ozone generator, which is driven by the electric power of the battery and generates the ozone,
An ozone control unit that controls the electric power supplied to the ozone generator,
A fan driven by the electric power of the battery and discharging the ozone generated by the ozone generator from the inside of the device to the outside of the device.
A fan control unit that controls the drive state of the fan,
A battery voltage detection unit that detects the voltage of the battery, and
A voltage determination unit that determines whether or not the battery voltage has dropped below a predetermined determination value, and
When the voltage of the battery drops below the determination value, the ozone control unit controls the power suppression to suppress the power supplied to the ozone generator, and the suppression control unit.
Equipped with
The feedback control of the power supplied to the ozone generator is performed so that the ozone concentration in the internal space inside the device or the external space outside the device becomes the target ozone concentration .
Ozone generation system.

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