KR102339609B1 - Operating system of air pollutant removal facility - Google Patents

Abstract

The present invention relates to an operating system of an air pollutant removal facility, which includes: a control center including a control server receiving and storing operation data related to the operation of a remote air pollutant removal facility and providing an operation management plan based on the stored operation data; an air pollutant removal facility terminal transmitting a replacement request and repair request signal with respect to consumables and components in the air pollutant removal facility in accordance with the operation management plan provided by the control server; a maintenance service providing unit providing the air pollutant removal facility with a service corresponding to the replacement request and repair request in accordance with the replacement request and repair request signal from the air pollutant removal facility terminal and then transmitting to the control server maintenance data related to the service corresponding to the replacement request and repair request; and a regeneration service providing unit receiving an activated carbon cartridge required to be regenerated from the maintenance service providing unit, regenerating the cartridge, and then providing the cartridge to the maintenance service providing unit in a case where the content of the replacement request and repair request is related to activated carbon cartridge replacement in the air pollutant removal facility.

Description

Air pollutant removal facility operation system {OPERATING SYSTEM OF AIR POLLUTANT REMOVAL FACILITY}

The present invention relates to an air pollutant removal facility operating system, and more specifically, for air pollutant facilities within a workplace, not only for workplaces with a relatively high total annual air pollutant generation amount but also for workplaces with a relatively low It relates to an air pollutant removal facility operating system that can be efficiently managed.

In Article 25 of the Air Conservation Act, workplaces are classified into types 1 to 5 according to the amount of pollutants generated. Worksites weighing less than 80 tons are classified as type 2 workplaces, workplaces weighing between 10 tons and less than 20 tons are classified as type 3 workplaces, workplaces weighing more than 2 tons and less than 10 tons are classified as type 4 workplaces, and workplaces weighing less than 2 tons are classified as category 5 workplaces. Among business sites, at present, the external monitoring system is being operated for air pollutant emission facilities within the business sites, limited to large-scale business sites, namely, type 1 and type 2 business sites, which generate relatively large amounts of air pollutants annually. to be.

However, monitoring of all air pollutant removal facilities in the workplaces not only for the first and second workplaces with relatively high total annual air pollutant generation, but also for the relatively low third and fifth workplaces. needs to be strengthened. In addition, the external monitoring system applied to the existing type 1 business sites and type 2 business sites only monitors the amount of air pollutants generated, and various consumables or parts in the air pollutant removal facilities in these business sites, such as , activated carbon cartridge filter, corrugated pipe filter, pre-filter, and various sensors are irrelevant to direct monitoring of replacement cycles or failures. Since it depends only on the manager's judgment or requests for replacement or repair, an air pollutant removal facility operating system for more efficient management is required in this technical field.

The problem to be solved by the present invention is to more effectively manage the failure occurrence monitoring or replacement cycle of consumables and parts such as activated carbon cartridge filters, corrugated pipe filters, pre-filters, and various sensors of air pollutant removal facilities, and air pollution It is to provide an air pollutant removal facility operation system that can more efficiently monitor the overall operation status of the material removal facility.

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An air pollutant removal facility operating system according to an aspect of the present invention for solving the above problems receives operating data related to the operation of an air pollutant removal facility located at a remote location, and an operation management method based on the received operating data A control center including a control server that provides The air pollutant removal facility including a terminal for air pollutant removal facility for transmitting a request signal related to replacement and repair, according to the request signal from the air pollutant removal facility terminal, corresponding to the request signal A maintenance service providing unit that provides a service to the air pollutant removal facility, and transmits maintenance data related to the service corresponding to the request signal to the control server side after providing, and the content of the request signal is the air pollution In the case of the replacement of the activated carbon cartridge filter in the material removal facility, a regeneration service providing unit is provided, which is provided by the maintenance service providing unit, and the activated carbon cartridge filter required for regeneration is regenerated and then provided to the maintenance service providing unit. and the request signal includes a first notification, a second notification, and a third notification regarding the activated carbon cartridge filter, wherein the first notification is the average concentration of the emission VOC moving arithmetic (based on 30 minutes) of the air pollutant removal facility When the emission limit is exceeded, it is a notification that there is an abnormality, the second notification is a notification to inform that replacement is imminent when the total VOC emission reaches 70% of the initial set value, and the third notification is the When the total VOC emission reaches 90% of the value excluding the activated carbon adsorption capacity margin from the initial set value, it is a notification to inform that replacement work is required, and the total VOC emission amount is Calculated as cumulative (in kg) of daily VOC emissions. And, the daily VOC emission is calculated as the accumulation of VOC inflow concentration (ppm) * 92.14/22.4 * design air volume (m ³ /min) to the air pollutant removal facility, and the initial set value used for the second notification is calculated as the amount of filling of activated carbon in the activated carbon cartridge filter (unit kg) * activated carbon adsorption performance (unit kg / kg) * activated carbon adsorption capacity margin ratio, and the activated carbon adsorption performance margin used for the third notification is not considered. The set value, characterized in that calculated as the amount of filling of the activated carbon in the activated carbon cartridge filter (unit kg) * activated carbon adsorption performance (unit kg / kg), the air pollutant removal facility operating system.
According to an embodiment, the maintenance service providing unit receives, from the control server, maintenance result data and a future schedule, which are data updated by reflecting the maintenance data related to the service corresponding to the request signal.
According to an embodiment, the regeneration service providing unit provides detachment data including a history of the activated carbon cartridge filter provided to the maintenance service providing unit to the control server, and receives a notification of a detachment schedule from the control server.
According to an embodiment, the operation data related to the operation of the air pollutant removal facility include supply air volume, VOC concentration data at the outlet, exhaust air volume, activated carbon differential pressure, filter differential pressure, VOC concentration data at the inlet, filter backwash implementation data, use Includes wattage and uptime.
According to an embodiment, the maintenance result data includes a visit history of the air pollutant removal facility, business person information, filter installation date, filter replacement date, activated carbon cartridge filter installation date, specifications of activated carbon in the activated carbon cartridge filter, and Include the manufacturer, the date of replacement and collection of the activated carbon cartridge filter, and the date of receipt of the activated carbon cartridge filter after regeneration.
According to an embodiment, the desorption data includes a management history for each activated carbon cartridge filter, a desorption time of each activated carbon cartridge filter, and data for a sample taken from each activated carbon cartridge filter.
According to an embodiment, the operation management plan includes the supply air volume, the VOC concentration data of the outlet, the exhaust air volume, the activated carbon differential pressure, the filter differential pressure, the VOC concentration data of the inlet, and the filter backwash implementation data, respectively. If it is out of a preset reference range for each, it includes data on occurrence of anomalies for each.

The present invention, by providing an improved air pollutant removal facility operating system, the failure occurrence monitoring or replacement cycle of consumables and parts such as activated carbon cartridge filter, corrugated pipe filter, pre-filter, various sensors, etc. of the air pollutant removal facility It can be managed more efficiently, and the overall operational status of the air pollutant removal facility can be monitored more efficiently.

1 is a block diagram of an air pollutant removal facility operating system according to an embodiment of the present invention;
2A to 2F are views for explaining the operation data (S1) related to the operation of the air pollutant removal facility and the air pollutant removal facility provided from the air pollutant removal facility side to the control center side;
3 is a view for explaining the maintenance result data (S3) provided from the maintenance service provider side to the control center side,
It is a view for explaining the detachment data S4 provided from the reproduction service providing unit 400 to the control center 100 with reference to FIG. 4 ,
5 is an operation management plan (R1) provided to the air pollutant removal facility 200 side with the control center 100 as the center in the air pollutant removal facility operating system of the present invention, and a maintenance service providing unit 300 It is a diagram for explaining data including maintenance result data provided to the side, a later schedule (R3), and a detachment schedule (R4) provided to the reproduction service providing unit 400 side,
6A and 6B are tables divided with respect to the usage rights of data for each painting company (automotive company), maintenance service, and removal service,
7 is a table shown in FIGS. 6A and 6B, showing only the usage right and management status for data in the terminal 210 for the air pollutant removal facility on the side of the automobile industry,
8 is an operational flow chart from the air pollutant removal facility 200 side,
9 is an example of the management screen shown in the terminal 210 for air pollutant removal equipment,
10 shows an example of the configuration of the initial screen in the configuration of the management screen of FIG.
11 shows an example of a graph for inflow/outflow VOC for the day in the driving data section on the management screen of FIG.
12 is a display of the driving data section as a calendar screen in the management screen of FIG.
13 is an example of a screen configured to store the driving data section in the management screen of FIG. 9 as an Excel file for each day or hour,
14 is an example of a screen constituting a maintenance section in the management screen of FIG. 9,
15 is an example of a screen constituting a notification history section in the management screen of FIG. 9;
16 is a table shown in FIGS. 6A and 6B, showing only the usage right and management status of the data on the maintenance service provider 300 side separately,
17 is a maintenance service operation flow chart in the maintenance service providing unit 300,
18A and 18B are another example of a service operation flowchart in the maintenance service providing unit 300,
19 shows an example of the main center screen configuration of the maintenance service providing unit 300 side,
20 is an example of a screen configuration displayed on a mobile device of a site-visiting person in charge of the maintenance service providing unit 300 side,
Figure 21 is a specific embodiment of Figure 20,
22 is an example of displaying on the mobile device screen of the on-site person in charge of repairing breakdowns, replacement of consumables, replacement of activated carbon cartridge filter, self-repairing history, and notification details in FIG. 20;
23 is an example of displaying on the screen of the mobile device of the person in charge of field visits the contents of the calendar, item-by-item details, input/industry confirmation, etc. within the breakdown repair history in FIG. 20,
24 is an example of displaying the contents of a calendar, item-by-item details, input/industry confirmation, etc. on the screen of the mobile device of the person in charge of field visits within the consumable replacement details in FIG. 20,
25 is a calendar, adsorption cartridge removal request / removal cartridge receipt, activated carbon cartridge filter QR code scan, activated carbon cartridge filter corresponding code input, and input / industrial company confirmation within the activated carbon cartridge filter replacement history in FIG. This is an example displayed on the screen of a mobile device,
26 is an example of showing the details of self-repair and notification details of industrial companies/control centers in FIG. 20 on the screen of a site visitor's mobile device;
27 is a specific implementation example of the configuration of the main center screen on the side of the maintenance service providing unit 300 shown in FIG. 19,
28 is a calendar screen in the breakdown repair history section of FIG. 19;
29 is an example showing the details of each item in the breakdown repair history section of FIG. 19 on the screen;
30 is an example showing the details of each industry in the breakdown repair history section of FIG. 19 on the screen;
31 is an example showing the details of each person in charge in the breakdown repair history section of FIG. 19 on the screen;
32 is a calendar screen in the activated carbon cartridge filter replacement history section of FIG. 19;
33 is an example showing the details of each person in charge in the activated carbon cartridge filter replacement history section of FIG. 19 on the screen,
Figure 34 is a calendar screen in the industry history / control center notification section section of Figure 19,
35 is an example showing on the screen the details of each item in the notification history section of the industrial company / control center of FIG.
FIG. 36 shows only the usage right and management status for data on the reproduction service providing unit 400 side in the table shown in FIGS. 6A and 6B separately,
37 is a flowchart showing a detachment service operation of the reproduction service providing unit 400 side,
38 is a screen configuration example of the management server on the reproduction service providing unit 400 side,
Figure 39 is a detailed screen configuration example for each section of Figure 38,
40 is a calendar screen of the suction cartridge stocking history section in FIG. 38,
41 is an example showing on the screen the details of each industry company of the adsorption cartridge stocking details and the desorption service request reception details in FIG.
Figure 42 is a calendar screen of the detachable cartridge shipment history section in Figure 38,
43 is an example showing a screen showing details of each industry company and detachment notification details of the detachable cartridge shipment history section in FIG. 38;
45 is a table shown in FIGS. 6A and 6B, showing only the usage right and management status for data on the control center side separately,
46 is a screen configuration example of a terminal connected to the control server 110 of the control center 100,
In FIG. 46, the operation status/detail section by industry company, the status/detail section by driving condition, the removal service operation status/detail section, the maintenance notification status (history) section, and the notice section are divided into the screen in FIG. It is a specific embodiment shown,
48 is an example showing the operating status, management glare, installation history and location on the screen in the operating status/detail section by industry in FIG. 46;
49 is an example showing on the screen inflow/outflow VOC, activated carbon/filter differential pressure, failure/repair, consumable replacement, and activated carbon cartridge filter replacement in the status/detail section by operating condition in FIG. 46;
50 is an example showing the contents of the activated carbon cartridge filter stocking status, activated carbon cartridge filter shipment status, activated carbon cartridge filter management status, desorption conditions and desorption analysis, etc. on the screen in the desorption service operation status / history section in FIG. 46,
FIG. 51 is an example in which the contents related to the maintenance notification standard and the maintenance notification history in the maintenance notification history section of FIG. 46 are displayed on the screen.

Hereinafter, with reference to the accompanying drawings, it will be described in detail with respect to the air pollutant removal facility operating system of the present invention. It should be noted that the accompanying drawings and the embodiments described with reference to them are exemplified for the purpose of helping those of ordinary skill in the art to understand the present invention.

1 is a block diagram of an air pollutant removal facility operating system according to an embodiment of the present invention.

Referring to FIG. 1 , the air pollutant removal facility operating system includes a control center 100 , a terminal for air pollutant removal facility 210 , a maintenance service provider 300 , and a regeneration service provider 400 . do.

The control server 110 located in the control center 100 receives and stores operation data S1 related to the operation of the air pollutant removal facility 200 located at a remote location, and operates based on the stored operation data S1. A management plan (R1) is provided. Although not shown separately in the drawing, the control center 100 includes a terminal connected to the control server 110 .

The air pollutant removal facility terminal 210 is located in the air pollutant removal facility 200 or in the vicinity of the air pollutant removal facility 200, and the operation management plan (R1) provided by the control server 110 Accordingly, a replacement request and a repair request signal R2 for consumables and parts in the air pollutant removal facility 200 are transmitted. The replacement request and repair request signal R2 is a service provision request to the maintenance service providing unit 300 . The air pollutant removal facility 200 includes consumables and parts such as a sensor, a filter (pre-treatment filter), and an activated carbon cartridge filter to remove air pollutants. The air pollutant removal facility 200 side can read data through the terminal 210 for the air pollutant removal facility and take a management notification action. The terminal 210 for air pollutant removal equipment may be a PC or a mobile device.

The maintenance service providing unit 300 receives the request signal R2 related to replacement and repair from the terminal 210 for air pollutant removal equipment, and, accordingly, the service S2 corresponding to the request signal R2. is provided to the air pollutant removal facility 200 , and after the provision, maintenance data S3 related to the service corresponding to the request signal R2 is transmitted to the control server 110 in the control center 100 . In addition, the maintenance service providing unit 300 reflects the maintenance data S3 related to the service corresponding to the replacement request and the repair request in the request signal R2 and is updated with the maintenance result data and the future schedule ( R3) is received from the control server 110 . The replacement request and repair request, which are the contents of the replacement request and repair request signal R2, may be a replacement request or a repair request for a sensor, a pretreatment filter, or an activated carbon cartridge filter. Accordingly, the service S2 corresponding to the request signal R2 may be, for example, a replacement service of the pre-processing filter if the request signal R2 includes a request for replacement of the pre-processing filter, for example, the request signal R2 If it includes a request for inspection of the activated carbon cartridge filter, it may be a repair or replacement service after the inspection of the activated carbon cartridge filter.

The regeneration service providing unit 400, when the replacement request and the repair request in the request signal R2 are related to the replacement of the activated carbon cartridge filter in the air pollutant removal facility 200, the maintenance service providing unit 300 After receiving and regenerating an activated carbon cartridge filter, that is, an adsorption cartridge, from which regeneration is required, it is provided to the maintenance service providing unit 300 . The maintenance service providing unit 300 couples the regenerated cartridge, that is, the regenerated cartridge, that is, the detachable cartridge to the air pollutant removal facility 200 . That is, the maintenance service providing unit 300 separates the adsorption cartridge from the air pollutant removal facility 200 and provides it to the regeneration service providing unit 400 , and receiving the detachable cartridge from the regeneration service providing unit 400 again. Provides a service (S2) coupled to the air pollutant removal facility (200). Reference numeral R5 denotes a direct supply path of the adsorption cartridge, and reference numeral S5 denotes a direct supply path of the desorption cartridge. In addition, the regeneration service providing unit 400, the activated carbon cartridge filter provided to the maintenance service providing unit 300, the removal data (S4) including the history of the regenerated cartridge (desorption cartridge) to the control server (110) provided, and is informed of the detachment schedule (R4) from the control server (110).

The maintenance service providing unit 300 and the reproduction service providing unit 400 are provided with respective terminals or mobile devices so as to process data and receive or transmit a request signal, although not specifically shown in the drawings.

The operation data S1 related to the operation of the air pollutant removal facility provided from the air pollutant removal facility 200 side to the control center 100 side is the air supply air volume and the concentration of VOC (Volatile Organic Compounds) at the outlet. It includes data, exhaust air volume, activated carbon differential pressure, filter differential pressure, inlet VOC concentration data, filter backwash operation data, power consumption and operating time, etc.

2a to 2f, a specific example of the air pollutant removal facility 200, and the operation related to the operation of the air pollutant removal facility provided from the air pollutant removal facility 200 side to the control center 100 side The data S1 will be described. First, reference numerals D1 to D7 in FIG. 2A are related to locations of the driving data S1. That is, the air supply air volume (D1) is the inflow flow rate to the air supply side for supplying clean air to the interior of the workplace (eg, a painting company) where the air pollutant removal facility 200 is installed, and the VOC concentration data (D2) of the outlet is the VOC concentration data on the outlet side of the prevention facility installed in the workplace, that is, the air pollutant removal facility. In the present specification, the air pollutant removal facility 200 is used to mean not only the prevention facility itself, but also the entire workshop (eg, a painting company) facility in some cases. In addition, although an example of a painting company, which is an example of a workshop, is described in this specification, it is not limited to a painting company and may be any company that induces air pollutants. Note that a painting company is also referred to as a painting company or an automobile company hereafter. Exhaust air volume (D3) means the flow rate of exhaust exhaust from the prevention facility to the outside, the activated carbon differential pressure (D4) is the pressure difference within the activated carbon cartridge filter, and the filter differential pressure (D5) is on the side of the pretreatment filter installed in front of the activated carbon cartridge filter is the pressure difference, the VOC concentration data at the inlet (D6) is the VOC concentration data on the inlet side of the prevention facility, and the filter backwashing data (D7) is the number of times or whether or not backwashing (washing through reverse flow) of the pretreatment filter is performed. data related to it. The activated carbon cartridge filter is also referred to simply as a cartridge for convenience.

The pre-processing filter may be divided into a pre-filter 211 and a pleated pipe filter 212 as shown in FIGS. 2B and 2C . The pre-filter 211 ((c) of FIG. 2C) is positioned at the rear end of the inlet, is formed in a rectangular shape, and primarily serves to remove large dust. The pleated pipe filter 212 at the rear end of the pre-filter 211 ((b) of FIG. 2C) is a filter bag that is folded approximately 50 times, and serves to remove relatively fine particles of dust compared to the pre-filter 211. do. The activated carbon cartridge filter 213 at the rear end of the pleated pipe filter 212 (FIG. 2c (a)) is filled with cartridges weighing approximately 300 kg to 400 kg inside the mesh network, and serves to remove gaseous contaminants. Contaminants generated in the painting booth of the workshop (painting company) are the use of paint and thinner, and contain gaseous and particulate mixed substances. Reference numerals 211 to 217 are configured to remove these contaminants with a primary pre-filter 211 , a secondary corrugated filter 212 , and a tertiary activated carbon cartridge filter 213 . That is, it is configured to primarily remove large dust from the pre-filter 211 , secondarily remove fine dust from the pleated pipe filter 212 , and thirdly remove gaseous contaminants from the activated carbon cartridge filter 213 . . Pressure sensors 214 , 215 , and 216 are provided to measure the differential pressure of each stage. That is, the pressure sensors P1 and 216 are provided to measure the activated carbon differential pressure (D4 in FIG. 2A), the pressure sensors P2 and 215 are provided to measure the corrugated pipe filter differential pressure, and the pre-filter differential pressure is measured. A pressure sensor (P3, 214) is provided to enable it. The pre-filter differential pressure and the corrugated pipe filter differential pressure are collectively referred to as the filter differential pressure (D5 in Fig. 2A). The flow of pollutants is induced by the blower 217, and a VOC sensor (not shown) is introduced to measure the VOC concentration data at the outlet (D2 in FIG. 2A) and the VOC concentration data at the inlet (D6 in FIG. 2A). It can be located on the side and the outlet side.

In addition, as described above with reference to FIG. 1 , the replacement request and repair request signal R2 from the terminal 210 side for the air pollutant removal facility for the maintenance service providing unit 300 is, for example, an activated carbon cartridge filter as follows. 213 , the pleated pipe filter 212 , and the pre-filter 211 may be divided into three types of notifications. In the case of the activated carbon cartridge filter 213, the first notification is a notification to notify that there is an abnormality when the emission limit value is exceeded, and the second notification is a notification for notifying that replacement is imminent when a certain percentage of the initial set value is reached. , and the third notification is a notification for notifying that a replacement operation is required when another predetermined percentage of the initial setting value (a setting value higher than the initial setting value in the second notification) is reached. In the case of the corrugated pipe filter 212, the first notification is a notification to notify when it is higher than the initial setting value, and the second notification is a notification to notify when a certain percentage of the initial setting value (eg, about 70% level) is reached, replacement is imminent This is a notification for notifying that it has been done, and the third notification is a notification for notifying that a replacement operation is required when a certain percentage (eg, about 90% level) of the initial setting value is reached. Also, similarly to the case of the pre-filter 211 , the initial first notification is a notification for notifying when it is higher than the initial setting value, and the second notification is a certain percentage of the initial setting value (eg, about 70% level) It is a notification to inform that replacement is imminent when reached, and the third notification is a notification to inform that replacement operation is required when a certain percentage (eg, about 90% level) of the initial setting value is reached.

The third notification for the activated carbon cartridge filter 213 , the pleated pipe filter 212 , and the pre-filter 211 , that is, a basic example of a replacement notification is summarized in Table 1 below. Basically, it informs the replacement time according to the degree of use after giving the lifespan to the consumables, and in the case of the inlet and outlet VOC sensors, it can be recorded for monitoring purpose and degree of use.

input type unit input Automatic Manual Usage note uptime hr 0-20 Automatic Manual For cumulative calculation to calculate uptime throughout the year design air volume m ³ /min 0 to 9999 Automatic Manual In order to convert the VOC concentration and moving arithmetic mean into mass units, it is done automatically through the watt-hour meter if possible, and manually if difficult. Activated carbon dosage kg 0 to 9999 manual Entered to determine the lifetime of the activated carbon. Activated Carbon Adsorption Performance kg/kg 0-2.00 manual Entered to determine the lifetime of the activated carbon. VOC Moving Arithmetic Average Time min 0-1440 manual Based on the 30-minute average according to the Air Environment Conservation Act. Adsorption performance margin - 0~1.0 manual The margin ratio is entered in the adsorption performance depending on environmental factors and toluene conversion. Maximum filter bag differential pressure mmAq 0~1000 manual Input to determine the life of the filter, and input a differential pressure of about 1.3 to 1.7 times the initial differential pressure. Maximum pre-filter differential pressure mmAq 0~1000 manual Input to determine the life of the filter, and input a differential pressure of about 1.3 to 1.7 times the initial differential pressure. Preliminary Notification Criteria % 0 to 100 manual Enter % of maximum life as a basis for giving reminders to prepare for replacement. Replacement Notification Criteria % 0 to 100 manual Enter the % of the maximum lifespan as a criterion to notify that replacement is imminent. VOC inflow/outflow concentration ppm - Automatic For real-time monitoring and calculation of moving average concentrations and emissions. VOC moving average concentration (based on 30 minutes) ppm - Automatic Determination of whether the emission limit is exceeded. 110ppm
standard VOC Removal Efficiency % - Automatic Automatic calculation using inlet/outlet VOC concentration. VOC emissions per day kg - Automatic To reduce the life of the activated carbon. filter differential pressure mmAq - manual It must be possible to input within the range to notify an abnormality of the filter differential pressure. power consumption kwh - Automatic It should be recorded automatically by receiving the signal from the electronic watt-hour meter of the electric switchboard. The flow rate is judged according to the amount of electricity.

The lifetime of activated carbon means the total amount of VOC adsorption capacity, and the unit is kg, and can be calculated as follows.

Lifespan of activated carbon (total VOC adsorption capacity, kg) = Activated carbon charge (kg) * Activated carbon adsorption performance (kg/kg) * Activated carbon adsorption capacity margin.

Here, the activated carbon adsorption performance refers to the amount (kg) of toluene that is collected when 1 kg of activated carbon is added, and the activated carbon adsorption capacity margin is because other materials other than toluene may also be adsorbed depending on the environment when the activated carbon is applied on-site. it will be taken into account As in the example below, it may be a number between 0 and 1 (eg, 0.9).

VOC emissions per day (kg) can be calculated by converting Y-axis ppm into mg. That is, mg = ppm * 92.14/22.4 * design air volume (m ³ /min). By integrating the Y-axis (mg) during the day calculated in this way, the daily VOC emissions (kg) can be calculated.

The above-mentioned initial setting value is divided into a total setting value before initial operation and an automatic setting value of accumulated data, and may be, for example, as follows.

1) All set values before initial operation

- Operating hours per day: 8 hours

- Airflow: 300 m3/min

- Activated carbon input: 330kg

- Activated carbon adsorption performance: 0.35 kg/kg (when saturated, based on toluene, for the atmosphere of the first carbon 4mm pellets)

- VOC average concentration standard time: 0~1.440 min (Example, 30 minutes)

- Activated carbon adsorption capacity margin: between 0 and 1 (eg, 0.9)

- Filter bag input value (multiple): between 1 and 10 (eg, 1.5 times)

- Pre-filter input value (multiple): between 1 and 10 (eg, 1.4 times)

- Ready Reminder: 0 ~ 100% (Example, 70%)

- Replacement notification: 0 ~ 100% (eg, 90%)

2) Accumulated data automatic set value

- Influent VOC concentration: Average of integral values over one week (based on mass, toluene)

- Electricity amount of prevention facilities: cumulative

- Blower operating time: cumulative

The standard of the consumable replacement set value may be set as follows for the activated carbon, the corrugated pipe filter, and the pre-filter as follows.

1) Activated carbon

Total adsorption capacity of VOC: 330kg*0.35kg/kg*0.9 (free rate) = 103.95kg

Average inflow VOC (kg mass, toluene): Daily average for one week of monitoring (about 2.24kg/day)

1st notification (abnormal): When the emission limit is exceeded, 2nd notification (preparation): When 70% of 103.95 kg (72.765 kg VOC) is adsorbed, 3rd notification (replacement): 90% of 115.5 kg ( 93.55kg VOC) is adsorbed.

Runoff concentration Exceeding the allowable emission standard: 30-minute moving average

Unconditional replacement when the differential pressure rises 1.5 times.

2) Pleated pipe filter

The replacement standard of the pleated pipe filter may be described with reference to FIG. 2D.

Replacement criteria: When the differential pressure increases by 1.5 times compared to the initial differential pressure.

After 10 months of operation, the differential pressure of activated carbon increased 1.7 times from 100mmAq to 170mmAq.

When the filter bag differential pressure rises 1.5 times from 80mmAq to 120mmAq after 10 months of operation.

The differential pressure value is not initially entered, because the differential pressure may be different for each site condition by design or inverter adjustment of the blower. And the reason for not inputting the efficiency is that dust inflow and oil concentration must be monitored, and the efficiency may also be different depending on environmental conditions.

3) Pre-filter

The replacement time of the pre-filter may be when the final differential pressure is 5.1 times the initial differential pressure. For reference, the medium filter, the demister, and the HEPA filter may be replaced when they reach 6.2, 2.0, and 1.5 times, respectively.

Figure 2e shows a graph comparing the dust removal efficiency and dust collection amount of each of the pre-filter, the intermediate filter, the demister, and the HEPA filter.

2f is a flowchart showing the flow of replacing consumables according to the first notification (abnormal), the second notification (preparation), and the third notification (replacement) from the input of the initial set values of the activated carbon cartridge filter, the pleated pipe filter, and the pre-filter, have.

Referring back to FIG. 2A , in the air pollutant removal facility 200, in order to view and correct the maintenance history for services such as replacement or repair, an individual activated carbon cartridge filter and an air pollutant removal facility at any place The QR code can be attached with an iron plate engraving, and the terminal 210 of the paint industry company, that is, the terminal 210 for air pollutant removal equipment, can be prohibited from arbitrarily modifying the history. In addition, the management history of individual activated carbon cartridge filters can be tracked through the QR code with the mobile device of the person in charge of field visits on the side of the maintenance service provider 300 , and the disposal of the activated carbon can also be determined.

Next, the maintenance result data S3 provided from the maintenance service providing unit 300 side to the control center 100 side will be described with reference to FIG. 3 . The maintenance result data (S3) is the history of visits (replacement/repair/inspection) to the painting company, that is, the air pollutant removal facility 200 from the maintenance service provider 300 side, information on the person in charge of the work (maintenance work), Filter (pre-treatment filter) installation date, filter (pre-treatment filter replacement date, activated carbon cartridge filter installation date, standard and manufacturer of activated carbon in activated carbon cartridge filter, replacement or collection date of activated carbon cartridge filter (adsorption cartridge, which is a cartridge that requires regeneration), It includes the date of entrustment of the desorption service of the adsorption cartridge, the date of receipt of the activated carbon cartridge filter after regeneration (the desorption cartridge that is the cartridge after regeneration), the management history of each cartridge, and the like.

Next, with reference to FIG. 4 , the detachment data ( S4 , FIG. 1 ) provided from the reproduction service providing unit 400 to the control center 100 will be described. The desorption data S4 includes a management history for an individual activated carbon cartridge filter, that is, a desorption management history, a desorption time and characteristics of each activated carbon cartridge filter, and the like. In addition, the desorption data (S4) may include data on the sample collected from the individual activated carbon cartridge filter and the desorption tube test (Tube test) and the test result data, and furthermore, the date of receipt of the adsorption cartridge and the The date of delivery may be included.

5 is an operation management plan (R1) provided to the air pollutant removal facility 200 side with the control center 100 as the center in the air pollutant removal facility operating system of the present invention, and a maintenance service providing unit 300 It is a diagram for explaining data including maintenance result data provided to the side, a future schedule R3, and a detachment schedule R4 provided to the reproduction service providing unit 400 side.

The operation management plan (R1) is based on the VOC concentration data of the inlet/outlet (inlet and outlet), the replacement cycle of activated carbon based on the inflow/outflow VOC concentration data, the average replacement cycle of activated carbon, the average replacement cycle of the pretreatment filter, and the average operation It includes calculation of management cost and deduction of operation/management improvement plan (for air supply/exhaust/painting booth/prevention facility, etc.) through overall operation review. Also, the operation management plan R1 includes an air supply air volume, an exhaust air volume, an activated carbon differential pressure, and a filter differential pressure. The operation management plan (R1) is out of the preset reference range for each of these supply air volume, inlet/outlet (inlet and outlet) VOC concentration data, exhaust air volume, activated carbon differential pressure, filter differential pressure, and filter backwash implementation data, respectively. It includes data on the occurrence of anomalies.

Maintenance result data and future schedule (R3) are activated carbon cartridge filter replacement schedule, activated carbon average replacement cycle, pretreatment filter replacement schedule, pretreatment filter average replacement cycle, individual activated carbon cartridge filter replacement cycle/activated carbon in cartridge through treatment performance review including whether it is necessary to dispose of You can discuss with the paint company (painting company) about the need to replace the activated carbon cartridge filter, replace the pre-treatment filter, and discard the activated carbon.

Regarding the desorption schedule (R4), individual activated carbon cartridge filter replacement cycle/processing performance data, determination of whether or not the activated carbon in the activated carbon cartridge filter needs to be refilled, a plan to improve the activated carbon cartridge filter removal process, information on the activated carbon replacement cycle by region/business, and operation of desorption services It may include data related to the schedule (weekly/monthly/region/desorption processing number selection), etc.

6A and 6B are tables divided with respect to the usage rights of data for each painting company (automobile manufacturer), maintenance service, and removal service, and can be identified as one table by connecting FIG. 6B to the right side of FIG. 6A. The vertical direction of FIGS. 6A and 6B is an itemized list with respect to the driving data (S1), the maintenance result data (S3), and the detachment data (S4), illustrated in FIGS. 2A, 3 and 4, respectively. , the horizontal direction indicates whether each server, terminal, or mobile device can be executed by the automobile manufacturer, the maintenance service provider, the regeneration service provider (detachable service), and the control center, respectively. In the table, the areas marked in yellow are feasible and those marked in blue are inoperable. Execution includes viewing, management notification, management implementation and correction. In the table, automobile manufacturers have terminals for air pollutant removal facilities, maintenance service is a terminal or mobile device of the maintenance service provider, removal service is a terminal or mobile device of the recycling service provider, and control center is a control server means each, and the degree of access to data through each screen is shown in a table.

In the table, for example, the driving data S1 provided by the automobile manufacturer can be viewed by the automobile manufacturer, and among them, the cartridge replacement history, filter replacement history, and failure/repair history (including sensors) are maintenance services Management notification can be processed to the provider side. In addition, on the side of the automobile manufacturer, the maintenance result data (S3) is configured so that information in charge of maintenance work can be read. In addition, on the maintenance service provider side, all of the maintenance result data and operation data (S1), filter backwashing history, cartridge replacement history, filter replacement history, failure/repair history (including sensors), self-measures, etc., and detachment It is configured to be able to read all of the data (S4). In addition, on the maintenance service provider side, in the maintenance result data (S3), the removal service consignment date, the removable cartridge receipt date, and the individual cartridge management history can be management notification processing to the reproduction service provider side.

On the other hand, all data can be viewed from the control center side, and among the operation data (S1), air supply air volume, activated carbon differential pressure, filter differential pressure, filter backwash operation record, cartridge replacement history, filter replacement history, failure/repair history (including sensors), etc. can be handled as a management notification to the automobile manufacturer. And on the control center side, all of the detachment data (S4) can be managed notification processing.

FIG. 7 shows, in the table shown in FIGS. 6A and 6B , only the usage authority and management status for data in the terminal for air pollutant removal equipment ( 210 in FIG. 1 or 2A ) of the automobile industry side by separating it. The table of FIG. 7 is the same as the table of FIG. 6a, and on the automobile manufacturer side, whether there is an abnormality in the supply air volume, whether there is an abnormality in the exhaust airflow, whether there is an abnormality in the activated carbon differential pressure, whether there is an abnormality in the differential pressure in the filter, whether there is an abnormality in the VOC entering the prevention facility, whether there is an abnormality in the VOC outflow from the prevention facility, The operation data S1 is generated by managing the presence or absence of filter backwashing abnormalities (reduced backwashing efficiency, reduced pressure) and other sensor abnormalities, and transmitted to the control server 110 side of the control center 100 .

8 is an operation flow chart from the air pollutant removal facility 200 side. Referring to FIG. 8 , when an abnormality occurs or an abnormality is predicted in the air pollutant removal facility 200 , the air pollutant removal facility 200 side operates a terminal for the air pollutant removal facility 200 ( 210 in FIG. 1 ). Through the control server 110, the control center 100 is notified of this as the operation data (S1). Of course, it is also possible to self-check the air pollutant removal facility 200 side without notice. The control center 100 grasps the situation, and whether it is more than the supply air volume, more than the exhaust air volume, more than the activated carbon differential pressure, more than the filter differential pressure, whether it is more than the VOC inflow of the prevention facility, whether it is more than the VOC outflow from the prevention facility, and the filter backwashing abnormal (efficiency /pressure, etc.), a sensor error, or other abnormalities. If the air pollutant removal facility 200 is capable of self-solving, it executes its own measures. To receive a service from the maintenance service provider 300 for consumables and parts. In the case of taking measures by itself or requesting the maintenance service provider 300 to receive services, the measures are recorded, and the measures taken and contact details are input through the terminal 210 for air pollutant removal facilities, and control In the center 100, the maintenance service providing unit 300 and the reproduction service providing unit 400, each of the terminals or mobile devices connected to the servers, etc., and necessary measures (eg, the tables of FIGS. 6A, 6B and 7 and same treatment).

9 is an example of the configuration of the management screen shown in the air pollutant removal facility 200 side of the terminal 210 for the air pollutant removal facility. Referring to FIG. 9 , on the screen displayed through the server for air pollutant removal facility 210 , sections such as operation data, maintenance, notification history, and notice may be independently displayed on the initial screen. In the operation data section, contents such as supply/exhaust air volume, inflow/outflow VOC concentration, activated carbon/filter differential pressure, and wattage/operation time can be displayed, and each can be expressed as a chart or graph. In the maintenance section, information related to troubleshooting, self-care, replacement of consumables, and cartridge replacement can be displayed. In the notification history section, information regarding maintenance scheduled and emergency maintenance notification may be displayed. In addition, in the notice section, various notices such as a notice related to payment of maintenance fees may be displayed.

10 shows an example of the configuration of the initial screen in the configuration of the management screen of FIG. 9, and sections such as operation data, maintenance history, notification history, and notices may be divided into quarters under the main image. .

11 shows an example of a graph for the inflow/outflow VOC for the day in the operation data section of the management screen of FIG. 9. In the graph, the Y-axis means the VOC concentration, and the portion indicating the peak value is the air pollutant removal facility. In other words, it indicates the concentration of VOCs during the painting work in the painting industry.

FIG. 12 is a view showing the driving data section as a calendar screen on the management screen of FIG. 9, and the calendar screen may display the highest (maximum), lowest (minimum), and average values for each day.

13 is an example of a screen configured to store the driving data section in the management screen of FIG. 9 as an Excel file for each day or time.

14 is an example of a screen constituting a maintenance section in the management screen of FIG. 9 . As shown in FIG. 14 , the maintenance section may be divided into four sections and displayed on the screen so that contents related to replacement of consumables, activated carbon cartridge filter, troubleshooting, and self-care can be displayed.

FIG. 15 is an example of a screen constituting a notification history section in the management screen of FIG. 9 . As shown in FIG. 15 , the status of the cartridge and filter can be displayed on the screen as an image according to the replacement schedule, and the remaining replacement date of the activated carbon cartridge filter, the remaining replacement date of the pretreatment filter, and the presence or absence of abnormality in the activated carbon differential pressure etc. can be displayed graphically on the screen.

FIG. 16 shows only the usage right and management status for data on the side of the maintenance service providing unit 300 in the table shown in FIGS. 6A and 6B separately. In FIG. 16, the table part is the same as that of FIG. 6b, and on the maintenance service provider 300 side, a maintenance request from a painting company through a terminal or a mobile device, adsorption cartridge processing consignment, removal cartridge receipt, from the control center You can check the inspection request, etc. The terminal or mobile device on the side of the maintenance service providing unit 300 is configured to access the control server 110 by separately executing the application to view, manage notification, manage management, and modify the necessary data.

17 is a flowchart illustrating a maintenance service operation in the maintenance service providing unit 300 . Referring to FIG. 17, when a notification (corresponding to the request signal R2 in FIG. 1) is received from the painting company, that is, the air pollutant removal facility 200 side, the notification is received and the air pollutant removal facility 200 ), select a person in charge to visit the site and record the details. In addition to the notification from the air pollutant removal facility 200 side from above, it is possible to receive a notification from the control center 100 side as well. When the selected person in charge visits the site, the maintenance service is performed, the action is confirmed, and the person in charge reports to the control center 100 through a mobile device or terminal, thereby ending the situation.

18A and 18B are another example of a service operation flow chart in the maintenance service providing unit 300, and FIG. 18A shows that the selected person in charge starts the repair and inspection procedure so that the air pollutant removal facility 200 operates normally. 18b is a flowchart showing the process of completing to understand the situation The situation can be grasped by the person in charge scanning the QR code, and the contents are, for example, more than the supply air volume, more than the exhaust air volume, more than the activated carbon differential pressure, more than the differential pressure of the filter, more than the VOC inflow of the prevention facility, and the VOC out of the prevention facility. , filter backwash (efficiency/pressure, etc.) abnormality, sensor abnormality, and the like. For example, when it is determined that there is an abnormality in the sensor, the repair check procedure is carried out, the situation is ended by recording and inputting the action details, and when it is determined that the replacement of consumables and cartridges is necessary, after the replacement operation is carried out The situation ends by recording and entering the action details, and even when repairs are necessary rather than replacement of these consumables and cartridges, the situation ends by taking a repair action and recording and inputting the action details. Recording and input are made through a terminal or mobile device on the side of the maintenance service provider.

19 shows an example of the configuration of the main center screen of the maintenance service providing unit 300 side. The main center of the maintenance service provider 300 may be a server separately operated by the maintenance service provider. Referring to FIG. 19 , the screen of the main center of the maintenance service provider side, that is, the screen displayed on a terminal connected to a separately operated server, is an initial screen, and is an initial screen. , activated carbon cartridge filter replacement history, self-repair history, industrial company/control center notification history, and notice section can be displayed separately. In addition, in the breakdown repair history section, the consumable replacement history section, and the activated carbon cartridge filter replacement history section, details such as a calendar screen, a breakdown by item, a breakdown by industry company, and a breakdown by person in charge can be configured to appear on the screen appropriately.

20 is an example of a screen configuration displayed on a mobile device of a site-visiting person in charge of the maintenance service providing unit 300 side. As shown in FIG. 20 , on the mobile device of the person in charge of the field visit, sections such as QR code scan, corresponding company code input, industrial company/control center notification, person in charge input, and notice may be displayed in divided sections.

21 is a specific implementation example of FIG. 20, and as shown in the mobile device of the field visit person in charge, a QR code scan section, a corresponding company code input section, a person in charge input section, and a section such as notes and manuals when visiting an industrial company It can be displayed in 4 divisions.

22 is an example showing the contents of the breakdown repair history, consumable replacement history, activated carbon cartridge filter replacement history, self-repair history, and notification history, etc. on the mobile device screen of the person in charge of the field visit in FIG. In the breakdown repair history, it is an example of displaying the contents of the calendar, item-specific details, input/industrial company confirmation, etc. on the mobile device screen of the on-site visiting person in charge, FIG. 24 is a calendar, item-specific details in FIG. It is an example of displaying the contents of input/industrial company confirmation on the screen of the mobile device of the person in charge of field visits, and FIG. 25 is a calendar within the activated carbon cartridge filter replacement history in FIG. , activated carbon cartridge filter corresponding code input, and input/industrial company confirmation are examples displayed on the site visitor's mobile device screen, and FIG. This is an example displayed on the screen.

27 is a detailed implementation example of the configuration of the main center screen of the maintenance service providing unit 300 side shown in FIG. 19 . As shown in FIG. 27, into the industrial company/control center notification section, trouble repair history section, consumable replacement history section, activated carbon cartridge filter replacement history section, industrial company/control center notification history section, self-repair history section and notice section It can be divided and displayed on the screen.

FIG. 28 is a calendar screen in the troubleshooting history section of FIG. 19 , FIG. 29 is an example showing item-by-item details in the troubleshooting history section of FIG. 19 on the screen, and FIG. It is an example showing the details by each industrial company on the screen, and FIG. 31 is an example showing the details by the person in charge in the breakdown repair history section of FIG. 19 on the screen.

Although not shown in a separate drawing, also in the consumable replacement history section of FIG. 19, each of the calendar screen, the breakdown by item, the breakdown by industry company, and the breakdown by person in charge may be the same as the form shown in FIGS. 28 to 31 .

FIG. 32 is a calendar screen in the activated carbon cartridge filter replacement history section of FIG. 19 , and FIG. 33 is an example showing details of each person in charge in the activated carbon cartridge filter replacement history section of FIG. 19 on the screen.

In addition, although not shown in a separate drawing, the calendar screen and the breakdown screen by industry in the self-repair history section of FIG. 19 may be the same as the screen shapes of FIGS. 28 and 30 , respectively.

34 is a calendar screen in the industrial history/control center notification section of FIG. 19, and FIG. 35 is an item-by-item breakdown in the industrial history/control center notification section of FIG. is an example displayed on the screen.

FIG. 36 shows only the usage right and management status for data on the reproduction service providing unit 400 side in the table shown in FIGS. 6A and 6B separately.

37 is a flowchart illustrating a desorption service operation on the side of the regeneration service providing unit 400. Referring to FIG. 37, an adsorption cartridge is received from the air pollutant removal facility 200 through the maintenance service providing unit 300. If this is done, the desorption operation will proceed. If the desorption standard is not satisfied, the activated carbon is replaced, and the desorption standard and replacement cycle are considered at this time, and if necessary, a self-desorption experiment is performed, and information about the self-experimental content and the activated carbon manufacturer is also input. When the detachment criterion is met, the detachment is completed and the maintenance service providing unit 300 is notified that the detachment is complete, the cartridge-related information is recorded, and the cartridge-related information is reported to the control center 100 side, and then the detachable cartridge is transferred to the maintenance service providing unit 300 . Information input, detachment completion report, recording, and reporting of cartridge-related information in the reproduction service providing unit 400 are performed through a terminal or a mobile device on the reproduction service providing unit 400 side.

38 is a screen configuration example of the management server on the reproduction service providing unit 400 side. As shown in FIG. 38 , the screen of the management server on the side of the regeneration service providing unit 400 may be divided into sections such as adsorption cartridge storage history, desorption cartridge shipment history, desorption conditions and notices.

39 is a specific screen configuration example for each section of FIG. 38, FIG. 40 is a calendar screen of the suction cartridge wearing history section in FIG. 38, and FIG. An example of the request reception details displayed on the screen, FIG. 42 is a calendar screen of the detachable cartridge shipment history section in FIG. 38, and FIG. to be.

FIG. 45 shows only the usage right and management status for data on the control center side in the table shown in FIGS. 6A and 6B separately.

46 is an example of a screen configuration of a terminal connected to the control server 110 of the control center 100 . As shown in Figure 46, it can be displayed in sections such as operation status/detail by industry company, status/detail by driving condition, removal service operation status/detail, maintenance notification history, operation abnormal alarm by industry company, and notices have.

In FIG. 46, the operation status/detail section by industry company, the status/detail section by driving condition, the removal service operation status/detail section, the maintenance notification status (history) section, and the notice section are divided into the screen in FIG. It is a specific implementation example shown.

48 is an example showing the driving status, management glare, installation history and location in the driving status/detail section by industry in FIG. 46 on the screen, and FIG. 49 is inflow/outflow in the status/detail section by driving condition in FIG. VOC, activated carbon/filter differential pressure, failure/repair, consumable replacement, and activated carbon cartridge filter replacement are examples displayed on the screen, and FIG. It is an example showing the contents of the shipment status, the activated carbon cartridge filter management status, the desorption condition and desorption analysis on the screen, and FIG. example shown in

It should be noted that the data access rights or screen configuration examples shown in FIGS. 6A to 51 can be modified in any other content or form, and the scope of the present invention is defined by the claims below.

Through the air pollutant removal facility operating system of the present invention described above, the failure occurrence or replacement cycle of consumables and parts such as an activated carbon cartridge filter, pretreatment filter, and various sensors of the air pollutant removal facility is more efficiently monitored and It can be managed, and the overall operation status of the air pollutant removal facility can be efficiently monitored.

100: control center
110: control server
200: Air pollutant removal facility
210: terminal for air pollutant removal equipment
300: maintenance service provider
400: playback service provider

Claims (10)

As an air pollutant removal facility operating system,
a control center including a control server that receives operation data related to the operation of an air pollutant removal facility located in a remote location and provides an operation management plan based on the received operation data;
Waiting for transmitting the operation data to the control server side and transmitting a request signal related to replacement and repair of consumables and parts in the air pollutant removal facility according to the operation management plan provided by the control server the air pollutant removal facility including a terminal for the pollutant removal facility;
According to the request signal from the terminal for the air pollutant removal facility, the service corresponding to the request signal is provided to the air pollutant removal facility, and after providing, maintenance data related to the service corresponding to the request signal is provided. a maintenance service provider that transmits to the control server side; and
When the content of the request signal relates to the replacement of the activated carbon cartridge filter in the air pollutant removal facility, the maintenance service providing unit receives and regenerates the activated carbon cartridge filter required for regeneration from the maintenance service providing unit It includes; a reproduction service providing unit that provides
The request signal includes a first notification, a second notification and a third notification regarding the activated carbon cartridge filter, and the first notification is the emission VOC moving arithmetic average concentration (based on 30 minutes) of the air pollutant removal facility is allowed to be discharged When the standard value is exceeded, it is a notification that there is an abnormality, the second notification is a notification to inform that replacement is imminent when the total VOC emission reaches 70% of the initial set value, and the third notification is the total VOC This is a notification to inform that replacement work is necessary when the discharge amount reaches 90% of the value excluding the activated carbon adsorption capacity margin from the initial set value,
The total VOC emission is calculated as the cumulative (unit kg) of daily VOC emissions flowing into the air pollutant removal facility, and the daily VOC emission is the VOC inflow concentration (ppm) into the air pollutant removal facility (ppm) * 92.14/ 22.4 * Calculated as the accumulation of design air volume (m ^{3 /min),}
The initial set value used for the second notification is calculated as the amount of filling of activated carbon in the activated carbon cartridge filter (unit kg) * activated carbon adsorption performance (unit kg / kg) * activated carbon adsorption performance margin ratio, and is used for the third notification Air pollutant removal facility operation, characterized in that the initial setting value not considering the activated carbon adsorption capacity margin ratio is calculated as the amount of charging of activated carbon in the activated carbon cartridge filter (unit kg) * activated carbon adsorption performance (unit kg/kg) system.

delete delete The method according to claim 1, The maintenance service providing unit,
The air pollutant removal facility operating system, characterized in that the maintenance result data and the future schedule, which are data updated by reflecting the maintenance data related to the service corresponding to the request signal, are received from the control server.
The method according to claim 1, wherein the reproduction service providing unit,
Air pollutant removal facility operating system, characterized in that the desorption data including the history of the activated carbon cartridge filter provided to the maintenance service provider is provided to the control server, and a desorption schedule is notified from the control server.
delete The method according to claim 1, The operation data related to the operation of the air pollutant removal facility,
Air pollutant removal facility operating system, characterized in that it includes supply air volume, VOC concentration data at the outlet, exhaust air volume, activated carbon differential pressure, filter differential pressure, VOC concentration data at the inlet, filter backwash operation data, power consumption and operating time.
The method according to claim 4, The maintenance result data,
Visit history of the air pollutant removal facility, business person information, filter installation date, filter replacement date, activated carbon cartridge filter installation date, standard and manufacturer of activated carbon in activated carbon cartridge filter, replacement and collection date of activated carbon cartridge filter, after regeneration Air pollutant removal facility operating system, characterized in that it includes the date of receipt of the activated carbon cartridge filter.
The method according to claim 5, The desorption data,
An air pollutant removal facility operating system comprising: a management history for an individual activated carbon cartridge filter; a desorption time of each activated carbon cartridge filter; and data for a sample taken from an individual activated carbon cartridge filter.
The method according to claim 7, The driving management method,
When out of the preset reference range for each of the supply air volume, VOC concentration data at the outlet, exhaust air volume, the activated carbon differential pressure, the filter differential pressure, the VOC concentration data at the inlet, and the filter backwash operation data, for each Air pollutant removal facility operating system, characterized in that it includes abnormal occurrence data.

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