JP6344060B2 - Ozone generator monitoring method and ozone generator monitoring system - Google Patents

Description

  The present invention relates to an ozone generator monitoring method and an ozone generator monitoring system that can appropriately notify the time of maintenance or the like.

  Conventionally, ozone generators that generate ozone water and ozone gas have been used. This type of ozone generator uses, for example, the generated ozone water to sterilize, deodorize, remove mold, slime, etc., or use the generated ozone gas to remove indoor floating bacteria, deodorize indoor air, It is used to sterilize places that are hard to reach such as walls and ceilings.

  Since the ozone generator holds the generated ozone gas or ozone water at a predetermined ozone concentration, it is necessary to measure the ozone concentration periodically. For this reason, conventionally, for example, the ozone water generated by the ozone generator is manually taken out, and the detection unit of the measuring device is immersed in the extracted ozone water to determine the ozone concentration. However, the manual measurement has a complicated measurement work, and there is a possibility that an accurate measurement cannot be performed in the case of an incapable operator.

  As another method for measuring the ozone concentration of ozone gas or ozone water, a method of incorporating an ozone concentration measuring device in the ozone generator and measuring the ozone concentration with this ozone concentration measuring device is also conceivable. According to this method, the measurement work can be automated, and variations in the measured value can be prevented as compared with the measurement by the operator. However, in the case of a built-in type ozone concentration measuring device, the detection part (a pair of electrodes, etc.) is immersed in ozone water. There was a risk that correct ozone concentration could not be measured due to adhesion and lamination.

JP 2003-306316 A

  On the other hand, since ozone has a strong oxidizing action, components through which ozone passes in the ozone generator are likely to deteriorate, and they must be periodically replaced. For this reason, the usage time (usable time) is set in advance for each part to be replaced, and the usage time of each part is integrated. When the usage time is reached, a message such as part replacement is notified. , So that maintenance was performed.

  Since the usage time changes corresponding to the ozone concentration (the higher the ozone concentration, the shorter the usage time), it is preferable that the usage time corresponds to the ozone concentration. However, in reality, as described above, even in the case of an ozone generator incorporating an ozone concentration measuring device, it is difficult to measure an accurate ozone concentration over time. The usage time when the ozone water and ozone gas were always flowed was used.

  And when the usage time is set as above, if the ozone concentration of the ozone water or ozone gas actually flowed is low, the part can be replaced even though it can actually be used for a longer time. There was a problem that the maintenance cost could not be reduced.

  The present invention has been made in view of the above points, and the purpose of the present invention is to obtain an appropriate ozone concentration over time and to perform appropriate notification at a time when maintenance or the like should be performed. An object of the present invention is to provide an ozone generator monitoring method and an ozone generator monitoring system that can reduce the maintenance cost.

The present invention provides an acquisition step of acquiring a value of an electrical physical quantity required for the ozone generator to generate ozone, an amount of flowing water that the ozone generator has flowed to generate ozone water, and the acquired electric on the basis of the physical quantity values and water flow, a calculation step asking you to ozone concentration of the ozone generator the ozone water is generated, based on the calculated ozone concentration was, the ozone generating apparatus require maintenance A determination step for determining whether or not to perform, and a notification step for notifying that maintenance should be performed when it is determined that maintenance of the ozone generator is necessary as a result of the determination in the determination step; It is in the ozone generator monitoring method which has this.
“Ozone” here includes both ozone gas and ozone water. The value of the electrical physical quantity includes a current value, a voltage value, a power value, and the like. The notification may be performed in an ozone generator that requires maintenance, may be performed in a management device described below, may be performed in a mobile terminal described below, or may be performed in another device.
According to the present invention, the ozone concentration is calculated based on the acquired value of the electrical physical quantity, and it is configured to determine whether maintenance is necessary using the calculated ozone concentration. Even if ozone water or ozone gas is not touched, it is possible to calculate the appropriate ozone concentration over time, so that notification that maintenance is necessary can be performed at an appropriate time, and parts at an appropriate time Maintenance such as replacement can be performed.
Further, according to the present invention, by further acquiring the amount of running water, the ozone concentration of ozone water can be calculated without directly contacting the ozone concentration measuring device with the ozone water, thereby generating ozone water. It is possible to notify the generation device that maintenance is necessary at an appropriate time.

In the present invention, the acquisition step further acquires an energization time required for the ozone generator to generate ozone, and the determination step includes the ozone concentration calculated in the calculation step and the acquired energization time. Based on the above, it is characterized in that it is determined whether or not the ozone generator requires maintenance.
According to the present invention, it is possible to easily and appropriately determine whether or not the ozone generator requires maintenance by further acquiring the energization time.

The present invention further includes a storage step of storing a location where the ozone generator is installed, and a location information acquisition step of acquiring location information of a mobile terminal possessed by a maintenance staff, wherein the notification step includes: Of the portable terminals that have acquired the position information in the position information acquisition step, the portable terminal close to the installation location of the ozone generator stored in the storage step is notified that maintenance is to be performed. .
According to the present invention, since a notification that maintenance is to be performed is given to a portable terminal held by a maintenance worker near the ozone generator that requires maintenance, the maintenance can be performed quickly.

The present invention is also directed to an ozone generator monitoring system in which an ozone generator and a management device that manages the ozone generator are connected via a communication line, wherein the management device causes the ozone generator to generate ozone. Based on the value of the electrical physical quantity required to obtain the amount of flowing water that the ozone generator flowed to generate ozone water, the value of the obtained electrical physical quantity and the amount of flowing water , a calculating means for ozone generator is Ru seek ozone concentration of ozone water is generated, based on the calculated ozone concentration was, the ozone generator is a determination unit configured to determine whether to require maintenance, the determination As a result of determination by means, when it is determined that maintenance of the ozone generator is necessary, notification means for notifying that maintenance should be performed, It is characterized in that was example.

  In the present invention, the acquisition unit further acquires an energization time required for the ozone generator to generate ozone, and the determination unit includes the ozone concentration calculated by the calculation unit and the acquired energization time. Based on the above, it is characterized in that it is determined whether or not the ozone generator requires maintenance.

  The present invention further includes storage means for storing a place where the ozone generator is installed, and position information acquisition means for acquiring position information of a portable terminal held by a maintenance staff, and the notification means includes: Of the portable terminals that have acquired the position information by the position information acquisition means, the portable terminal close to the installation location of the ozone generator stored in the storage means is notified that maintenance should be performed. .

1 is an overall schematic configuration diagram of an ozone generator monitoring system 1. FIG. 1 is a schematic configuration diagram of an ozone generator 10. It is a figure which shows an example of the ozone gas density | concentration with respect to a supply electric current value. 3 is a diagram illustrating an example of a functional block diagram of a management apparatus 200. It is a processing flow figure (the 1) of the monitoring method of ozone generating device. It is a processing flow figure (the 2) of the monitoring method of the ozone generator.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is an overall schematic configuration diagram of an ozone generator monitoring system 1 according to an embodiment of the present invention. As shown in the figure, the ozone generator monitoring system 1 includes a plurality of ozone generators 10, a management device 200 that manages the ozone generator 10, and a plurality of maintenance personnel that perform maintenance on the ozone generator 10. A plurality of portable terminals 300 possessed are connected via a communication line 400.

  FIG. 2 is a schematic configuration diagram of the ozone generator 10. As shown in the figure, the ozone generator 10 uses the outside air supplied from the air dryer 11 by the pump 13 and the high voltage from the high voltage power supply 17 controlled by the controller 15 in the ozone generator 19. Ozone gas is generated, and the generated ozone gas is directly discharged to the outside through the switching means 21 and the concentration meter 23, while the ozone gas generated in the ozone generator 19 is led to the gas-liquid mixing means 25 through the switching means 21, Ozone water is generated by mixing with tap water supplied via the flow meter 27, and the generated ozone water is released to the outside via the gas-liquid separator 29 and the concentration meter 31. Further, an exhaust ozone decomposer 33 that decomposes exhaust ozone gas discharged from the gas liquid separator 29 is connected to the gas liquid separator 29.

  The air dryer 11 includes a drying means using a desiccant or the like and an air cleaning means using a filter or the like, and is an apparatus for drying and cleaning the outside air introduced by these means. The pump 13 sucks the outside air into the air dryer 11 and supplies clean and dry air discharged from the air dryer 11 to the ozone generator 19.

  The control device 15 controls a high voltage power supply (its supply voltage, supply current, frequency, energization time, etc.) supplied from the high voltage power supply 17 to the ozone generator 19. The control device 15 has storage means for storing the energization time and current value (electrical physical quantity value) of the high voltage power source supplied from the high voltage power source 17 to the ozone generator 19 over time. Further, the control device 15 is configured to be able to communicate with the management device 200 (a communication unit 207 described below) via the communication line 400. The control device 15 starts and stops the ozone generator 10, and the high pressure stored in the storage means. The energizing time and current value of the power supply, measurement data from the flow meter 27 described below, and the like are appropriately transmitted to the management device 200.

  The ozone generator 19 is a device (silent discharge method) that generates (generates) ozone gas by applying high voltage from the high-voltage power supply 17 to discharge the introduced air. FIG. 3 is a diagram showing an example of the ozone gas concentration with respect to the supply current value of the ozone gas generated by the ozone generator 19 when the amount of supplied air is constant. As shown in the figure, the ozone gas concentration can be controlled by controlling the supplied current value.

  In this example, the switching means 21 uses a flow path switching solenoid valve, and has a function of switching the supply destination of the ozone gas introduced from the ozone generator 19 to the concentration meter 23 or the gas-liquid mixing means 25. The concentration meter 23 is a device that measures the ozone concentration of ozone gas. The gas-liquid mixing means 25 uses an aspirator in this example, and the ozone generator 19 is supplied to water (tap water) supplied to the gas-liquid mixing means 25 by utilizing a reduced pressure state due to the venturi effect of the aspirator. The ozone gas supplied from the side is effectively dissolved.

  The gas-liquid separator 29 is a device that separates the introduced liquid and gas in a built-in tank, takes out the separated liquid as ozone water, and takes out the separated gas as exhaust ozone gas to the exhaust ozone decomposer 33. is there. The concentration meter 31 is a device that measures the ozone concentration of ozone water. The exhaust ozone decomposer 33 uses a catalytic cracking method in which ozone is decomposed into oxygen by contacting ozone with the surface of silica (SiO2), alumina (Al2O3) or the like using, for example, a catalyst (manganese dioxide (MnO2) or the like). Device. In addition, as the exhaust ozone decomposing unit 33, an apparatus using an activated carbon adsorption decomposition method, a heat decomposition method, a wet method, or the like may be used.

  The ozone generator 10 configured as described above can be set to blow out ozone gas or to flow out ozone water by operating an operation unit (operation panel) (not shown) by a user. When the ozone gas is blown out, for example, the blowing start time and the blowing end time are set in advance, and then an ozone gas blowing command is issued (specifically, the ozone gas switch is turned on). On the other hand, when ozone water is caused to flow out, for example, an ozone water outflow command is issued in advance (specifically, the ozone water switch is turned on). When an ozone gas blowing command is issued, the apparatus is automatically activated when the blowing start time is reached, and the blowing of ozone gas starts. When the blowing end time is reached, the apparatus is automatically stopped and the blowing of ozone gas is terminated. On the other hand, when the ozone water outflow command is issued, when the ozone water faucet (not shown) installed on the downstream side of the concentration meter 31 is opened, the apparatus is automatically activated to start outflow of ozone water. When is closed, the device automatically stops and the outflow of ozone water stops. Hereinafter, specific operations of each part when the ozone generator 10 is activated will be described.

  In other words, when the ozone generation device 10 is started when the ozone water faucet is opened or when the ozone water faucet is opened, the air dried and purified by the air dryer 11 and the pump 13 is introduced into the ozone generator 19. At the same time, a high voltage is applied to the introduced air by the high-voltage power source 17 to generate ozone gas. At this time, the storage unit of the control device 15 that controls the high-voltage power supply 17 stores the energization time and current value of the supplied high-voltage power supply over time, and transmits it to the management device 200 as appropriate.

  When the ozone generator 10 receives an ozone gas blowing command, the switching means 21 is switched to the concentration meter 23 side, so that the ozone gas generated by the ozone generator 19 is taken out to the outside as it is. . At that time, the ozone concentration of the ozone gas is detected by the densitometer 23 and, for example, the concentration can be displayed on a display unit (not shown).

  On the other hand, when the ozone generator 10 receives an ozone water outflow command, the switching means 21 is switched to the gas-liquid mixing means 25 side, so that the ozone gas generated by the ozone generator 19 is gas. Introduced into the liquid mixing means 25, mixed with tap water supplied to the gas-liquid mixing means 25 and dissolved in water, ozone water is generated. The generated ozone water is introduced into the gas-liquid separator 29, and after ozone gas that has not dissolved in water is removed, the ozone water is taken out as ozone water. At that time, the ozone concentration of the ozone water is detected by the densitometer 31, and the concentration can be displayed on the display unit (not shown), for example. The flow rate of water supplied to the gas-liquid mixing means 25 is measured by the flow meter 27, and the measurement data is transmitted to the control device 15, stored in the storage unit, and appropriately transmitted to the management device 200. .

  FIG. 4 is a diagram illustrating an example of a functional block diagram of the management apparatus 200. As shown in the figure, the management apparatus 200 includes a CPU 201, a ROM 203, a RAM 205, a communication unit 207, a display unit 209, and an input unit 211. These components are connected to each other via a bus 213. Connected through the network. The CPU 201 controls the operation of the management apparatus 200 by executing a control program stored in the ROM 203. The ROM 203 stores various information such as the control program. The RAM 205 is a storage unit that temporarily stores various information. The communication unit 207 is a communication interface for communicating with various external devices via the communication line 400. The display unit 209 is, for example, a liquid crystal display, and displays information for an operator who operates the management apparatus 200. The input unit 211 includes various keys for receiving various commands from an operator who operates the management apparatus 200.

  Next, the monitoring method of the ozone generator 10 performed using the ozone generator monitoring system 1 will be described. 5 and 6 are process flow diagrams of a monitoring method for one ozone generator 10 by the management device 200. FIG. The management device 200 monitors each of a plurality of ozone generators 10, and a monitoring method for one of the ozone generators 10 will be described below.

  First, as described above, when it is time to blow out or when the faucet of ozone water is opened, the control device 15 activates the high-voltage power supply 17 and supplies the ozone generator 19 with a predetermined high-voltage power supply. This information is transmitted from the control device 15 to the management device 200. That is, the management device 200 first determines whether or not the target ozone generator 19 has been activated in FIG. 5 based on the information received from the control device 15 (step 1). Next, the energization time and the current value are acquired from the control device 15 of the ozone generator 10 (step 2). Here, the energization time is initially the time from step 1 to step 2, but when step 2 to step 12 are repeated thereafter, it is the time from step 2 to step 2 again. Next, the management device 200 calculates the ozone gas concentration based on the acquired current value (step 3). The calculation method uses, for example, the data of the graph shown in FIG.

  Next, it is determined whether ozone water or ozone gas is to be supplied (step 4). In the case of ozone water, the amount of flowing water is further acquired from the flow meter 27 (step 5), and the concentration of ozone water is calculated. (Step 6). The ozone water concentration can be calculated by multiplying a predetermined coefficient using the calculated ozone gas concentration, the dissolution rate of ozone gas in water, and the amount of flowing water. Alternatively, the relationship between the ozone gas concentration (or the current value) and the ozone water concentration with respect to each flowing water amount may be stored as a graph, and may be calculated by other various methods such as obtaining from the data of this graph. In short, what is necessary is just to calculate the ozone concentration of ozone water based on the acquired current value and the amount of flowing water.

  Next, based on the calculated ozone concentration and energization time, it is determined whether maintenance of the ozone generator 10 is necessary (step 7). The determination method is as follows.

  That is, when ozone gas is used, the integrated value a ′ is obtained by integrating the ozone gas concentration and the energization time, and the integrated value a ′ obtained so far is integrated and added. To obtain a new cumulative integrated value a. Then, it is determined whether or not the cumulative integrated value a has reached a replacement determination value An (n = 1... N) determined in advance for each component (1 to N), and the ozone generator 10 is configured. It is determined whether maintenance of each part to be performed is necessary (step 7). That is, for example, whether or not maintenance is necessary for each part such as the ozone generator 19, the switching means 21, and each ozone hose from the ozone generator 19 until the ozone gas is ejected through the switching means 21 and the concentration meter 23. to decide. Here, the replacement determination value An is defined in advance as An = (usage time) × (ozone gas concentration), and is stored in the RAM 205. Here, the usage time is the cumulative usage time up to the replacement time of the part when the part is used at a predetermined ozone gas concentration or from the time of replacement, and this usage time is approximately inversely proportional to the ozone gas concentration. The value An obtained by multiplying the two is used as the replacement determination value. Since this usage time varies depending on each component, the replacement determination value An varies depending on each component (the same is true for the replacement determination value Bm described below).

  When it is determined that the cumulative integrated value a exceeds the replacement determination value An, it is determined that the part needs to be replaced. That is, if the state with a high ozone gas concentration is long, the part replacement time is early (the usable time is short), and if the state with a low ozone gas concentration is long, the part replacement time is late (the usable time is long). The ozone gas concentration is changed automatically or manually according to the purpose of use (for example, 0.03 ppm when used for deodorization of meat in commercial freezing warehouses, etc. when used for sterilization and deodorization in cooking chambers) 0.05ppm etc.). For example, when the usable time until the replacement time of the ozone hose is 10000 hours when the ozone gas having a high concentration is always flowed, until the replacement time of the ozone hose when the ozone gas is flowed at an ozone concentration half of the above concentration The usable time of is 20000 hours. That is, the management device 200 calculates the ozone concentration (in this case, the ozone gas concentration) based on the acquired current value, and determines whether maintenance is necessary based on the calculated ozone concentration and the energization time. Therefore, it is possible to calculate an appropriate ozone concentration over time without installing a densitometer that directly contacts ozone gas. In other words, an appropriate ozone gas concentration can be calculated without being affected by deposits such as calcium, and thereby notification that maintenance is necessary can be performed at an appropriate time. By the way, in this ozone generator 10, the concentration meter 23 which measures the density | concentration of ozone gas by direct contact is installed, but this displays the numerical value on the display part which is not illustrated of the ozone generator 10 as a standard. It is installed for the purpose. For example, the data of the densitometer 23 is compared with the ozone concentration value calculated from the current value, and when the difference between the two concentration values becomes large, it is notified that it is time to replace the densitometer 23. May be.

  On the other hand, when ozone water is used, the accumulated value a ′ obtained by accumulating the ozone gas concentration and the energization time is added to the accumulated accumulated value a that has been accumulated and added up to the new accumulated value. In addition to the integrated value a, the integrated value b ′ obtained by integrating the ozone water concentration and the energization time for water for generating ozone water is added to the integrated integrated value b that has been integrated and added so far. Add to a new cumulative integrated value b. First, it is determined whether or not the cumulative integrated value a has reached the replacement determination value An previously determined for each component (1 to N) from the ozone generator 19 to the gas-liquid mixing means 25, It is determined whether or not maintenance of each part from the ozone generator 19 to the gas-liquid mixing means 25 is necessary. At the same time, in step 7, the cumulative integrated value b is determined in advance for each part (O to Y) from the gas-liquid mixing means 25 to the ozone water drain port (m = O... Y). It is determined whether or not maintenance of each part is necessary until ozone water is discharged from the gas-liquid mixing means 25.

  That is, it is determined whether or not maintenance is necessary for each part from the ozone generator 19 that comes in contact with ozone gas to the gas-liquid mixing means 25, and at the same time, each part from the gas-liquid mixing means 25 that comes in contact with ozone water to draining the ozone water Determine whether maintenance is necessary. The replacement determination value Bm is defined in advance as Bm = (usage time) × (ozone water concentration) and is stored in the RAM 205. Here, the usage time is the cumulative usage time until the replacement time of a part when the part is used at a predetermined ozone water concentration or from the time of replacement, and this usage time is approximately inversely proportional to the ozone water concentration. Therefore, the value Bm obtained by multiplying the two is used as the replacement determination value.

  When it is determined that the cumulative integrated value a exceeds the replacement determination value An, or when it is determined that the cumulative integrated value b exceeds the replacement determination value Bm, it is determined that the part needs to be replaced. That is, the management apparatus 200 calculates the ozone concentration (in this case, the ozone gas concentration and the ozone water concentration) by acquiring the amount of flowing water before being generated in the ozone water in addition to the current value, and the calculated ozone concentration Because it is configured to determine whether or not maintenance is necessary based on the energization time, it is possible to calculate an appropriate ozone concentration over time without installing a densitometer that directly contacts ozone gas or ozone water Can do. That is, it is possible to calculate the proper ozone gas concentration and ozone water concentration without being affected by deposits such as calcium, and thereby notify that maintenance is necessary at an appropriate time. In this ozone generator 10, in addition to the concentration meter 23, a concentration meter 31 that measures the concentration of ozone water by direct contact is installed, but this is also the same as the concentration meter 23. 10 is installed for the purpose of displaying the numerical value as a guide on a display unit (not shown). For example, the data of the densitometer 31 is compared with the ozone concentration value calculated from the current value, and it is notified that it is time to replace the densitometer 31 when the error between the two concentration values becomes large. May be.

  It should be noted that for each component in the exhaust system of exhaust ozone gas discharged from the gas-liquid separator 29, the necessity of maintenance may be determined by the same method as in the case of the ozone gas or ozone water. That is, for example, the relationship between the ozone concentration of ozone water supplied to the gas-liquid separator 29 and the ozone gas concentration of exhaust ozone gas discharged from the gas-liquid separator 29 is stored in advance as a graph, and the data of this graph From the gas-liquid separator 29, exhaust ozone gas is exhausted by a determination method similar to the above-described determination method, such as calculating the ozone gas concentration from the above, and obtaining the cumulative integrated value by integrating the ozone gas concentration and the energization time. What is necessary is just to judge whether the maintenance of each component is necessary.

  As described above, when the management apparatus 200 determines in step 7 that maintenance is not required for any part, the process proceeds to step 12. On the other hand, if the management device 200 determines in step 7 that maintenance is required for any of the components, it outputs a command to notify the ozone generation device 10 (step 8). The notification method includes a display on a display unit (not shown) of the ozone generator 10 that is determined to require maintenance, an alarm sound generated in the ozone generator 10, and a display on the display unit 209 of the management device 200. Etc. are considered.

  Next, in step 9, the management apparatus 200 acquires the respective position information from each mobile terminal 300. Next, based on these pieces of position information, the mobile terminal 300 closest to the ozone generator 10 among the mobile terminals 300 is calculated (step 10). Then, the calculated portable terminal 300 is notified that the maintenance of the ozone generator 10 should be performed (step 11). As a result, the maintenance staff closest to the ozone generator 10 can rush to the ozone generator 10 and perform maintenance quickly.

  In step 12, if the ozone generator 10 is not stopped, the process returns to step 2 and the above process is repeated. On the other hand, if the ozone generator 10 is stopped, the series of processes is terminated.

  When a part is replaced based on the above notification, the cumulative integrated value a or b for the part is reset to zero and stored in the ROM 203 of the management apparatus 200. On the contrary, even if the processing up to step 12 is completed, if the component replacement notification is not performed, the cumulative integrated values a and b are stored in the ROM 203 of the management apparatus 200 as they are.

  As described above, according to the monitoring method of the ozone generator 10, the acquisition step (step 2) for acquiring the energization time and the current value required for the ozone generator 10 to generate ozone, and the acquisition On the basis of the calculated current value, the ozone generation apparatus 10 calculates the ozone concentration of ozone generated by the ozone generation apparatus 10 (steps 3 to 6), and the ozone generation apparatus 10 is based on the calculated ozone concentration and energization time. A determination step (step 7) for determining whether or not maintenance is required, and a result of determination in the determination step indicates that maintenance should be performed when it is determined that maintenance of the ozone generator 10 is necessary. Since it has a notification step (steps 8 to 11) for performing notification, an appropriate ozone concentration (ozone gas concentration and ozone water concentration) is obtained over time. Able to output, it is possible to perform appropriate notification to when to perform maintenance or the like, whereby it is possible to cost reduction of maintenance costs.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea described in the claims and the specification and drawings. Is possible. It should be noted that any configuration not directly described in the specification and drawings is within the scope of the technical idea of the present invention as long as the effects and advantages of the present invention are exhibited. For example, the ozone generator is an apparatus having a structure for generating and supplying both ozone gas and ozone water, but the present invention can also be applied to an ozone generator having a structure for supplying only one of them. In the ozone generator, the ozone concentration is calculated based on the current value required for the ozone generator to generate ozone. However, instead of the current value, other electrical physical quantities such as a voltage value and a power value are calculated. The ozone concentration may be calculated using the value. The ozone generator generates ozone by the silent discharge method. However, even if the ozone generator is configured to generate ozone by the electrolysis method or the ultraviolet lamp method, the ozone generator can generate ozone based on the acquired electrical physical quantity value such as current value. The present invention can be applied to any method that can calculate the ozone concentration generated by the generator. The method for calculating the ozone concentration is not limited to the above example, and various other methods may be used, such as calculation using mathematical formulas from the values of electrical physical quantities such as acquired current values.

  Moreover, in the said ozone generator monitoring system, although the management apparatus and the some ozone generator were connected via the network, you may make a control apparatus of one ozone generator share a management apparatus. In the above example, the mobile terminal that has acquired the position information is notified that the maintenance should be performed on the mobile terminal closest to the installation location of the ozone generator that performs maintenance. However, it may be configured to notify a mobile terminal that is not the closest mobile terminal but is the closest mobile terminal. Furthermore, you may comprise so that it may alert | report to several near portable terminals including the nearest portable terminal. Moreover, you may comprise so that the alerting | reporting from a management apparatus may be performed only to a portable terminal instead of an ozone generator.

DESCRIPTION OF SYMBOLS 1 Ozone generator monitoring system 10 Ozone generator 11 Air dryer 13 Pump 15 Controller 17 High voltage power supply 19 Ozone generator 21 Switching means 23 Concentration meter 25 Gas-liquid mixing means 27 Flow meter 29 Gas-liquid separator 31 Concentration meter 33 Exhaust Ozonizer 200 Management device 201 CPU
203 ROM 205 RAM
207 Communication unit 209 Display unit 211 Input unit 213 Bus 300 Mobile terminal 400 Communication line

Claims (6)

An acquisition step of acquiring a value of an electrical physical quantity required for the ozone generator to generate ozone and an amount of water flowed to generate ozone water by the ozone generator ;
Based on the value and water content of the obtained electrical physical quantity, a calculation step of the ozone generator is Ru seek ozone concentration of ozone water is generated,
A determination step of determining whether or not the ozone generator needs maintenance based on the calculated ozone concentration;
As a result of the determination in the determination step, when it is determined that maintenance of the ozone generator is necessary, a notification step of performing notification that maintenance should be performed;
An ozone generator monitoring method comprising: The acquisition step further acquires an energization time required for the ozone generator to generate ozone,
2. The determination step according to claim 1, wherein the determination step determines whether or not the ozone generator needs maintenance based on the ozone concentration calculated in the calculation step and the acquired energization time. Ozone generator monitoring method. A storage step of storing a place where the ozone generator is installed;
A position information acquisition step of acquiring position information of the mobile terminal possessed by the maintenance staff, and
The notification step notifies the portable terminal close to the installation location of the ozone generator stored in the storage step that the position information is acquired in the position information acquisition step to the effect that maintenance is to be performed. The ozone generator monitoring method according to claim 1 , wherein the ozone generator is monitored. In an ozone generator monitoring system in which an ozone generator and a management device that manages the ozone generator are connected via a communication line,
The management device
An acquisition means for acquiring a value of an electrical physical quantity required for the ozone generator to generate ozone and an amount of water flowed to generate ozone water by the ozone generator ;
Based on the value and water content of the obtained electrical physical quantity, a calculation means for the ozone generator is Ru seek ozone concentration of ozone water is generated,
Determination means for determining whether or not the ozone generator requires maintenance based on the calculated ozone concentration;
As a result of determination by the determination means, when it is determined that maintenance of the ozone generator is necessary, notification means for notifying that maintenance should be performed;
An ozone generator monitoring system characterized by comprising: The acquisition means further acquires an energization time required for the ozone generator to generate ozone,
The determination means according to claim 4, wherein the basis calculation means ozone concentration calculated in the in the energization time during which the acquired, the ozone generator is characterized in that determining whether to require maintenance Ozone generator monitoring system. Storage means for storing a place where the ozone generator is installed;
Position information acquisition means for acquiring the position information of the mobile terminal possessed by the maintenance staff,
The notification means notifies the portable terminal close to the installation location of the ozone generator stored in the storage means that the maintenance is to be performed among the portable terminals that have acquired the position information by the position information acquisition means. The ozone generator monitoring system according to claim 4 or 5 , wherein

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