JP2023008519A - Maintenance management system - Google Patents

Abstract

To provide a maintenance management system for a plant facility which determines an operating state of the plant facility by explicitly formalizing knowledge concerning odor which is implicit perception of each operator.SOLUTION: A maintenance management system includes: five-sensory sensor information acquiring means 100 which acquires five-sensory sensor information measured by a five-sensory sensor installed in a plant facility; sensory information acquiring means 200 which acquires sensory information confirmed by an operator in a field; sensory information/sensor information integrating means 300 which integrates the five-sensory sensor information acquired by the five-sensory sensor information acquiring means and the sensory information acquired by the sensory information acquiring means; plant information acquiring means 400 which acquires plant information which is an operating state of the plant facility; plant normal/abnormal state determining means 500 which, based on the plant information, determines whether the operating state of the plant facility is normal or abnormal; and sensory information/plant information integrating means 600 which integrates the integrated five-sensory sensor information and the sensory information with the plant information having a determination result.SELECTED DRAWING: Figure 1

Description

The present invention relates to a maintenance management system for plant facilities such as chemical plants, electric power plants, water and sewage plants, and waste disposal plants.

In the maintenance and management of plant equipment such as chemical plants, power plants, water and sewage plants, and waste treatment plants, for example, if an operator hears an abnormal noise that does not normally exist, the plant equipment will be stopped. , plant facilities may be maintained and managed depending on the five senses and experience of operators.

When the plant equipment is continuously operated for 24 hours, there is a case where an operator stays at the plant equipment all the time to deal with the maintenance work. However, Japan's working-age population (ages 15 to 64) is on the decline, and if a labor shortage occurs in the future, there is a fear that such measures will become difficult.

In order to continue such maintenance work even in the event of a labor shortage, operators' five senses and experience will be replaced with IoT (Internet of Things) technology and AI (artificial intelligence) technology. For example, instead of the operator's vision, a camera is installed in the plant equipment, image data and video data captured by the camera are processed, and changes in the appearance of the plant equipment are detected. In addition, instead of the auditory sense of the operator, a microphone is installed in the plant equipment, and the audio data collected by the microphone is processed to detect abnormal noise in the plant equipment.

In addition to the operator's sight and the operator's hearing, the operator's sense of smell is also important for detecting offensive odors (such as burnt odors and offensive odors) generated in plant equipment. However, the sense of smell differs from person to person in terms of thresholds for sensing offensive odors, and there are individual differences. Therefore, it becomes tacit knowledge of each operator, making it difficult to inherit knowledge.

Therefore, in place of the olfactory sense of operators, odor sensors and concentration sensors that can acquire the concentration of odorous substances are installed in plant equipment to detect offensive odors generated in the plant and use them for maintenance and management work.

As background art in such a technical field, there is Japanese Patent Application Laid-Open No. 2014-209307 (hereinafter referred to as Patent Document 1).

Patent Document 1 discloses event information forming means for extracting events that have occurred in plant facilities, response information forming means for extracting responses to events executed by skilled operators having a certain level of ability, and event information Storage means for storing the event extracted by the formation means and the correspondence extracted by the correspondence information formation means in association with each other, current event information formation means for extracting the current event occurring in the plant equipment, and current event information and corresponding information selection means for selecting an event from the storage means that matches the event extracted by the formation means.

Further, Patent Document 1 describes acquisition of a voice of "smell" uttered by a skilled operator.

JP 2014-209307 A

An operation system (maintenance management system for plant equipment) described in Patent Literature 1 associates a "smell" voice uttered by a skilled operator with an event occurring in the plant equipment.

However, it is ambiguous whether the voice of "smell" alone expresses the strength of the odor or whether it expresses the comfort of the odor, such as pleasant/unpleasant. It can be done, but another operator may not be able to understand it.

Therefore, the present invention makes the knowledge about odors, which has been tacit knowledge of each operator until now, explicit knowledge, so that even if another operator does not have know-how, the operating state of the plant equipment can be determined. Provide a maintenance management system.

In order to solve the above-described problems, the maintenance management system of the present invention includes a five-sensory sensor information acquisition means for acquiring five-sensory sensor information measured by the five-sensory sensors installed in the plant equipment, and sensory information confirmed by the operator at the site. sensory information acquiring means to acquire, sensory sensor information acquired by the sensory sensor information acquiring means, and sensory information/sensor information integrating means for integrating sensory information acquired by the sensory information acquiring means; Plant information acquisition means for acquiring certain plant information, plant normality/abnormality determination means for determining whether the operating state of plant equipment is normal or abnormal based on the plant information, and integrated sensor information and sensory information. , sensory information/plant information integrating means for integrating plant information having a discrimination result.

According to the present invention, the knowledge about odors, which has been tacit knowledge of each operator until now, is made into explicit knowledge, so that even if another operator does not have know-how, the operating state of the plant equipment can be determined. A maintenance management system can be provided.

Problems, configurations, and effects other than those described above will be clarified by the description of the embodiments below.

It is an explanatory view explaining a maintenance management system in Example 1. FIG. FIG. 2 is an explanatory diagram illustrating evaluation items for odor in Example 1; 4 is an explanatory diagram illustrating a database integrating sensory information and plant information in Example 1. FIG. FIG. 2 is an explanatory diagram for explaining maintenance and management using odor in Example 1; It is an explanatory view explaining a maintenance management system in Example 2. FIG. It is an explanatory view explaining a maintenance management system in Example 3. FIG. 10 is an explanatory diagram illustrating the relationship between the odor intensity and the odor level of each operator in Example 3;

Embodiments of the present invention will be described below with reference to the drawings. In addition, in each drawing, the same code|symbol is used for substantially the same or similar structure, and when description overlaps, the overlapping description may be abbreviate|omitted.

First, the maintenance management system in Example 1 is demonstrated.

FIG. 1 is an explanatory diagram illustrating a maintenance management system in Embodiment 1. FIG.

The maintenance management system for plant equipment described in Example 1 has the following configuration.
(1) Five-sensory information acquisition means 100 for acquiring five-sensory sensor information measured by five-sensory sensors installed in plant equipment.
(2) Sensory information acquisition means 200 for acquiring sensory information (operator's sensory information) confirmed by the operator at the site.
(3) Sense information/sensor information integration means 300 for integrating (combining) the sensor information acquired by the sensor information acquisition means 100 and the sensor information acquired by the sensor information acquisition means 200 .
(4) Plant information acquisition means 400 for acquiring plant information, which is the operational status of plant equipment.
(5) Plant normality/abnormality determination means 500 for determining whether the operating state of plant equipment is normal or abnormal based on plant information.
(6) Integrating (combining) the integrated five-sensory sensor information and sensory information with plant information having determination results (integrating five-sensory sensor information, sensory information, determination results, and plant information) sensory information/plant information Integration means 600 .

Communication means for connecting each means is not particularly limited, and may be a wireless LAN (Local Area Network), a wired LAN, or the like.

In addition, the maintenance management system is stored in a computer having computing means such as a CPU (Central Processing Unit) (not shown), storage means such as memory and hard disk, and input/output means such as an interface, preferably as software Stored.

In Embodiment 1, the maintenance management system is stored as software in a computer having computing means, storage means, and input/output means, but the maintenance management system is necessarily installed in plant equipment. It is not necessary and may be installed at a location remote from the plant equipment.

Further, the sensory information/sensor information integrating means 300 and the sensory information/plant information integrating means 600 may be integrated to collectively integrate the five senses sensor information, the sensory information, the discrimination results, and the plant information.

The five senses sensor information acquisition means 100 is a five senses sensor installed in plant equipment such as a chemical plant, a power plant, a water and sewage plant, and a waste treatment plant, and acquires five senses sensor information of the plant equipment.

Here, the five sense sensors are cameras that acquire image data and video data (including infrared cameras that visualize heat), microphones that acquire audio data, odor sensors that measure odors, and can acquire the concentration of odorous substances. It is a sensor that substitutes for human senses, such as a concentration sensor.

The five sense sensors may be fixed sensors or mobile (handy) sensors. When a mobile sensor is used, one mobile sensor can be used even if there are a plurality of locations where information from the five senses is acquired. When a mobile sensor is used, a GPS (Global Positioning System) function is added to the mobile sensor, and the acquisition location of the five sense sensor information is also acquired together with the five sense sensor information.

Here, information from five sense sensors includes image data and video data acquired by a camera, audio data acquired by a microphone, odor level acquired by an odor sensor, and odor acquired by a concentration sensor capable of acquiring the concentration of an odorant. For example, the concentration of a substance.

Image data, video data, and audio data may be subjected to preprocessing. Specifically, image data and video data may be subjected to image processing and video processing to extract luminance information, color tone information, and pattern information of specific locations, and may be used as sensor information for the five senses. FFT (fast Fourier transform) processing may be performed to extract the power spectrum value for each frequency, and the overall value of the entire frequency may be extracted and used as the sensor information of the five senses. In other words, the information required for the maintenance and management work of the plant equipment should be obtained from various information.

In Example 1, the odor of a sewage treatment plant in a water and sewage plant will be described as an example.

A sewage treatment plant is a plant facility that purifies sewage sewage and discharges the treated water into rivers, lakes, or the sea, and is composed of a plurality of plant facilities. For example, a sewage treatment plant has a plurality of plant equipment such as settling tanks, primary sedimentation tanks, reaction tanks, final sedimentation tanks, sludge thickening tanks and sludge dewatering facilities.

Sewage is treated in these multiple plant facilities, and in the process of treating the sewage, odor-causing substances are diffused from the sewage and treated water and released into the atmosphere.

Odor-causing substances (odor components) are mainly hydrogen sulfide, methyl mercaptan, methyl sulfide, methyl disulfide, chlorine and ammonia. In sewage treatment plants, these odor-causing substances (bad odors) are collectively treated as odors.

In the case of water purification plants, when disinfecting treated water as a countermeasure against viruses and bacteria, chlorine (the substance that causes odors) used for disinfection also causes odors such as chlorine and chlorine odors. In addition, the musty odor of the treated water (geosmin, 2-МIB), earthy odor, algae odor, etc. are also odors.

In the first embodiment, an odor sensor is used as the sensor for five senses, and odor sensor information, which is information on substances causing odors, is acquired as sensor information for the five senses.

The odor sensor collectively measures the concentration, index, intensity, etc. of odor-causing substances and displays them as numerical values. The odor sensor information is measurement information of an odor sensor, specifically, odor concentration, odor index, odor intensity, and odor level indicated by the odor sensor. (e.g. odor level). The odor level is a value indicated by the odor sensor, and is obtained by converting the current value obtained by the odor sensor into the concentration of the causative substance of the odor. In the first embodiment, especially, the odor level of the reaction tank (the place where the five sense sensor information is obtained) in the sewage treatment plant is acquired.

For the odor sensor, there are several types of odor sensors: a semiconductor type that uses an oxidation-reduction reaction by attaching an odor-causing substance to the surface of a semiconductor; a chemical type that uses an adsorption film that adsorbs an odor-causing substance; Various odor sensors have been put to practical use, or are being researched and developed, such as a photoacoustic spectroscopic type that irradiates light and measures vibration, or a bio type that uses olfactory cells of humans, animals, and insects.

The odor sensor used in Example 1 should be able to measure hydrogen sulfide, methyl mercaptan, methyl sulfide, methyl disulfide, chlorine, and ammonia, which are the main odor-causing substances in sewage treatment plants, as odors. In particular, it is not limited.

Also, for plant equipment other than the sewage treatment plant, any odor sensor that can measure the odor generated in each plant equipment may be used.

The sensory information acquisition means 200 acquires sensory information confirmed by the operator at the site.

Here, sensory information is information obtained from the operator's five senses, such as sight, hearing, and smell. Here, the site is an installation location of plant equipment where plant equipment is installed, for example, an installation location of a reaction tank in a sewage treatment plant where a reaction tank is installed.

For example, in a reaction tank (where sensory information is acquired) in a sewage treatment plant, sensory information includes the height of the treated water surface, the color of sludge, and the appearance of bubbles due to aeration. In the case of , there is the operating sound of the agitator that agitates the treated water, and in the case of olfaction, the strength of the odor, the comfort of the odor such as pleasant/unpleasant, the acceptability of the odor, the impression (type) of the odor, etc. There is odor information.

In Example 1, the sensory information acquisition means 200 uses a recording device such as a tablet (portable information terminal) that can be operated by an operator by touching the screen, for example, for the odor of a reaction tank in a sewage treatment plant. Then, sensory information (odor information) confirmed at the site is recorded, and this recorded sensory information (odor information) is acquired.

When sensory information is recorded using a recording device such as a mobile information terminal, the time (date and time) when the operator records the sensory information is recorded together with the sensory information, and the recorded sensory information and time are recorded. , to the sensory information/sensor information integrating means 300 .

In addition, for example, when sensory information is recorded using a handwritten record table, etc., the sensory information recorded in the handwritten record table, etc. can be input from an interface such as a keyboard, together with the time when the sensory information was recorded. , the input sensory information and the time are sent to the sensory information/sensor information integrating means 300 .

The sensory information/sensor information integrating means 300 integrates the sensory information obtained by the sensory information obtaining means 100 and the sensory information obtained by the sensory information obtaining means 200 . Then, the five-sensory sensor information and sensory information acquired at the same time are integrated (as a key) based on that time. Then, the integrated information exists in the storage means and is stored in a database attached to the sense information/sensor information integration means 300 and the sense information/plant information integration means 600 . The integrated information may be output (visualized) using an interface such as a monitor.

The plant information means 400 acquires plant information, which is the operating state of the plant equipment at the same time. That is, the plant information means 400 acquires plant information such as plant data and plant operation signals from many sensors installed in plant equipment.

Here, the plant data are the water temperature, pH, oxidation-reduction potential, total organic carbon (TOC), dissolved oxygen concentration, sludge concentration, flow rate, aeration air volume, etc. of the reaction tank, and the plant operation signal is the chemical agent in the reaction tank. It is a setting value or a control value of a control signal such as an input amount, a valve opening degree, or the like.

The plant information also includes an alarm log (for example, sludge pump minor failure, aeration blower major failure, etc.) issued when an abnormality occurs in plant equipment.

In addition, in the first embodiment, in particular, the plant information of the reaction tank (plant information acquisition location) in the sewage treatment plant is acquired.

The plant normality/abnormality determination means 500 determines whether the operating state of the plant equipment is normal or abnormal based on the plant information. That is, the plant normality/abnormality determination means 500 determines, for example, whether or not the acquired plant data (plant information) exceeds a preset threshold value for the plant data (plant information). Determine whether the operating state is normal or abnormal.

Then, the determination result (normal or abnormal) of the operating state of the plant equipment is stored in the database together with the acquired plant data (plant information). In particular, in the case of an abnormality, when an alarm log has been issued, the contents of the abnormality (for example, aeration blower abnormality) together with the contents of the alarm log (for example, serious failure of the aeration blower) Store in database. That is, the plant information and the determination result are stored in the database.

The sensory information/plant information integrating means 600 integrates the sensory information and the sensory information integrated at the same time with the plant information having the determination result at the same time. That is, the sensory information/plant information integrating means 600 integrates the sensor information and sensory information integrated by the sensory information/sensor information integrating means 300 at the same time, and the plant information in the plant normality/abnormality determination means 500 at the same time. and the discrimination result are integrated (as a key) based on the time. In this way, the sensory information/plant information integrating means 600 integrates sensor information, sensory information, discrimination results, and plant information at the same time. Then store it in the database.

That is, the database stores sensor information and sensory information integrated by the sensory information/sensor information integrating means 300 and plant information and determination results integrated by the sensory information/plant information integrating means 600 at the same time. .

Next, evaluation items for odor in Example 1 will be described.

FIG. 2 is an explanatory diagram for explaining odor evaluation items in Example 1. FIG.

In Example 1, when an operator confirms odor information at the site, the operator uses a recording device such as a portable information terminal to obtain odor information such as strength of odor and pleasant/unpleasant odor. comfort, odor acceptability, and odor impression (type).

Here, in Example 1, these four evaluation items are evaluated in six stages (0 to 5). For example, there are six levels of odor intensity: "odorless," "weak," "easily perceived," "slightly strong," "strong," and "intense." There are six levels of odor acceptability: normal, slightly unpleasant, unpleasant, and extremely unpleasant. ”, “Very unacceptable”, and “-”, and the impression (type) of the odor was “smell of rotten eggs (hydrogen sulfide)”, “smell of rotten onions (methyl mercaptan)”, and “irritating odor”. (ammonia)", "disinfection smell (chlorine)", "burnt smell", and "others".

In addition, regarding the evaluation items (4) that are items for evaluating odor information (sensory information) and the evaluation stages (6 stages) that are levels for evaluating evaluation items, based on the odor information generated in each plant facility, What is necessary is just to set an evaluation item and an evaluation stage.

Thus, in Example 1, the sensory information acquiring means 200 uses the odor information evaluated by the operator at the site as an evaluation item that is an item for evaluating the odor information and an evaluation stage that is a level for evaluating the evaluation item, get.

In Example 1, the relationship between such evaluation items and evaluation grades is displayed on a recording device such as a portable information terminal, and the operator can record the odor information confirmed on site. Thereby, the odor information can be quantified at the evaluation stage for the evaluation items. Then, the sensory information acquiring means 200 can acquire quantified odor information.

In Example 1, olfactory ambiguity was determined by defining odor information by evaluation items (odor intensity, odor comfort, odor acceptability, odor impression (type)), that is, by defining olfaction. can be avoided.

Thus, in Example 1, by evaluating the odor information in terms of evaluation items and evaluation stages, the value of the information increases, and the tacit knowledge of each operator about odors can be made into explicit knowledge. In addition, knowledge about odor, which was tacit knowledge of experienced operators, can be made into explicit knowledge, and even if another operator does not have know-how, the operating state of the plant equipment can be determined.

Next, a database that integrates sensory information and plant information in the first embodiment will be described.

FIG. 3 is an explanatory diagram for explaining a database that integrates sensory information and plant information according to the first embodiment.

The database stores five-sensory sensor information, sensory information, discrimination results, and plant information based on time (date and time), and these information are stored as time-series trend data.

In the first embodiment, the five sense sensor information includes odor level, the sensory information includes odor strength, odor comfort, odor acceptability, and odor impression (type), and the plant information includes plant information. plant information (flow rate, dissolved oxygen concentration, water temperature) and alarm log of the acquisition location (reaction tank).

In addition, these information may include five senses sensor information, sensory information, and plant information other than these information. Also, such information other than the reaction tank may be included.

In addition, in Example 1, for convenience of explanation, the odor sensor was installed only in the reaction tank to acquire the information, but there are cases where the odor sensor is installed in a plurality of places other than the reaction tank. In this case, when acquiring the sensory information, it is also necessary to acquire the installation location of the odor sensor (for example, the reaction tank) at the same time.

That is, it is preferable to unify the acquisition location of the five senses sensor information, the acquisition location of the sensory information, and the acquisition location of the plant information, and to acquire the five senses sensor information, the sensory information, and the plant information at the same time.

Here, No. 1 is the information on the date and time of AA month BB day cc:dd, the odor level is "200", the odor strength is "3", the odor comfort is "3", and the odor acceptability is "2". ", the odor impression (type) is "1", the flow rate is "2000 m ³ / h", the dissolved oxygen concentration is "3.5 mg / L", the water temperature is "25 ° C", the alarm is "-", and the discrimination Results are normal.

On the other hand, No. 2 is the information on the date and time EE month FF day gg hour hh minutes, the odor level is "15", the odor intensity is "1", the odor comfort is "0", and the odor acceptability is "1". Odor impression (type) is 1, flow rate is 1800 m ³ /h, dissolved oxygen concentration is 0.5 mg/L, water temperature is 25°C, alarm is 'aeration blower major failure'. and the determination result is abnormal.

In the first embodiment, the plant normality/abnormality determination means 500 determines whether the operating state of the plant equipment is normal or abnormal based on, for example, the dissolved oxygen concentration (plant information), which is plant data. That is, the plant normality/abnormality determination means 500 determines whether or not the dissolved oxygen concentration obtained is below the predetermined threshold value, for example, with respect to the dissolved oxygen concentration (predetermined threshold value) set in advance. Determine whether the operating state of the plant equipment is normal or abnormal.

The numbers for odor intensity, odor comfort, odor acceptability, and odor impression (kind) are evaluation grades evaluated by operators.

Thus, even if the odor is low, it is not necessarily normal. Experienced operators understand that even if the odor is small, the dissolved oxygen concentration will decrease due to the small amount of aeration, and the cause may be the malfunction of the aeration blower, and the odor may be small. Grasping it as knowledge about odor, which is tacit knowledge.

Therefore, according to the first embodiment, the sensor information of the five senses, the sensory information, and the plant information are integrated. It is possible to make other operators who do not have know-how understand that there is a possibility that the blower is malfunctioning and the sensory information is low. As described above, according to the first embodiment, by making explicit knowledge about odor, which is tacit knowledge, even another operator can determine the operating state of the plant equipment.

By accumulating such information, that is, by constructing such a database, odors can be used for maintenance work of plant equipment.

Also, using the acquired information, a correlation analysis, which is one of statistical analyses, may be performed to perform a correlation analysis between the plant information and the information from the five senses and/or the sensory information to create a model. Also, neural network technology or data clustering technology may be used to perform machine learning to create a model for detecting signs of anomalies. The method of using the acquired information is not particularly limited.

Next, maintenance management using odor in Example 1 will be described.

FIG. 4 is an explanatory diagram illustrating maintenance using odor in Example 1. FIG.

The upper diagram in FIG. 4 shows changes in odor level with respect to time, and the lower diagram in FIG. 4 shows changes in intensity of odor with respect to time.

In FIG. 4, in a reaction tank in a sewage treatment plant, when the odor level and odor intensity fall below preset control values, an alarm is output indicating that a problem has occurred in the aeration blower. . In other words, when the odor level falls below the control value and the evaluation of the operator's odor intensity (evaluation item) falls below the evaluation level "3" (control value) from the evaluation level "2", an alarm is issued. Output.

This allows the operator to identify the reaction tank based on odor level and odor intensity. Also, if there is a discrepancy between the movement of the odor level and the movement of the odor intensity, the odor sensor can be checked. In this way, odors can be used for maintenance work on plant equipment.

In particular, there are individual differences in the sense of smell, that is, the sense of smell, which is often relied on by the five senses of operators, has individual differences in how it is sensed. Thus, according to Example 1, even if there are individual differences in the sense of smell of one operator and the sense of smell of another operator, implicit knowledge can be obtained based on the odor level and the strength of the odor. Since the knowledge about the odor is formalized, it is possible to determine the operating state of the plant equipment.

In addition, in Example 1, by integrating odor sensor information (e.g., odor level) from an odor sensor and sensory information (e.g., intensity of odor) from an operator, sensory information (there are individual differences and is ambiguous). by quantifying plant information and quantified sensory information, and by integrating the plant information and quantified sensory information, sensory information, which is tacit knowledge of each operator, can be used to determine the operating state of plant equipment (normality of plant equipment). / abnormality judgment).

In addition, since it is difficult to constantly monitor odors, plant facilities that generate odors are operated on the safe side with respect to odors. , the plant equipment can be operated optimally, and the energy-saving operation of the plant equipment can be realized.

Next, the maintenance management system in Example 2 is demonstrated.

FIG. 5 is an explanatory diagram for explaining the maintenance management system according to the second embodiment.

The maintenance management system described in the second embodiment is compared with the maintenance management system described in the first embodiment. and an environmental impact assessment means 800 for assessing the impact of environmental information on. That is, the maintenance management system described in the second embodiment has a function of judging the validity of the sensor information acquired by the sensor.

The environmental information acquisition means 700 acquires sensor information for measuring environmental information such as wind speed and wind direction that affect the odor sensor information, for example. Environmental information such as wind speed and direction is a factor that affects the diffusion of odor-causing substances, and an anemometer with a built-in wind direction observation means is used. Moreover, you may use an anemometer and a wind vane together.

Environmental information other than wind speed and wind direction includes humidity and temperature. For example, when the humidity is high, odor-causing substances tend to stay in the air. Therefore, it is preferable to install a hygrometer, a thermometer, or the like to measure environmental information such as humidity and temperature.

In addition, when a deodorizing blower or the like is installed in the plant equipment, the operation status of the blower may also affect the operation.

In this way, in the space where the odor sensor acquires odor sensor information, all environmental information that affects odor is defined as environmental information, and it is preferable to acquire at least one piece of environmental information.

The environmental impact assessment means 800 uses the environmental information acquired by the environmental information acquisition means 700 to determine the validity of the five sense sensor information acquired by the five sense sensors. Evaluate the impact of information.

For example, if a threshold is set for the wind speed, and it is determined that the environmental impact is large when the wind speed is above the threshold, and the information from the five senses may be inaccurate, an environmental impact label is assigned and the environmental impact Labels are also stored in a database attached to the sensory information/sensor information integrating means 300 . The same applies to other environmental information.

In this way, by judging the validity of the five-sensory sensor information acquired by the five-sensory sensors, it is possible to eliminate inaccurate sensory sensor information when performing statistical analysis, thereby improving the accuracy of the model. can be done.

According to the second embodiment, the provision of the environmental information acquiring means 700 and the environmental impact evaluating means 800 increases the value of the information from the five sense sensors, and makes it possible to more accurately determine the operating state of the plant equipment.

Next, the maintenance management system in Example 3 is demonstrated.

FIG. 6 is an explanatory diagram for explaining the maintenance management system according to the third embodiment.

Compared with the maintenance system described in the first embodiment, the maintenance system described in the third embodiment has sensory test condition acquisition means 900 for acquiring sensory test conditions of the operator.

The sensory test condition acquisition means 900 acquires an identification number (eg, name or employee number) of an operator who has confirmed sensory information (eg, odor information) at the site, that is, the operator's sensory test conditions. The identification number is also stored in a database attached to the sensory information/sensor information integrating means 300 . This makes it possible to visualize differences in the sense of smell of each operator.

Next, the relationship between the odor intensity and the odor level of each operator in Example 3 will be described.

FIG. 7 is an explanatory diagram illustrating the relationship between the odor intensity and the odor level of each operator in the third embodiment.

For example, if an odor with an odor level equivalent to the control value is generated, when Operator A, Operator B, and Operator C each check the odor at the site, the intensity of the odor will differ from person to person. , and operator A has an evaluation level of "2", operator B has an evaluation level of "3", and operator C has an evaluation level of "4".

For example, when the odor level is not acquired and the evaluation of the operator's odor intensity (evaluation item) falls below the evaluation level "3" (control value) from the evaluation level "2", When performing a predetermined action, the operator B and the operator C may not be able to perform the predetermined action.

Further, for example, even if the odor level has not been acquired, the operator B is a skilled operator, the evaluation level is determined to be "3", and the predetermined action can be executed. When the odor level is higher than the control value, the operator A performs a predetermined action, and when the odor level is lower than the control value, the operator C may perform a predetermined action, and the optimum maintenance work may not be performed.

Therefore, by giving quantitative feedback to each operator based on the odor level, the maintenance management ability of each operator can be improved and the maintenance management ability of each operator can be homogenized.

For example, the operator A is instructed to perform a predetermined action when his personal sense of smell is evaluated as "2", and the operator B is instructed to perform a predetermined action when his personal sense of smell is evaluated as "3". is instructed to perform a predetermined action, and the operator C is instructed to perform a predetermined action in the case of an evaluation level of "4" as an individual sense of smell.

That is, in Example 3, the sensory test condition acquisition means 900 also obtains the relationship between each operator's sensory information (eg, odor intensity) and five sensory sensor information (eg, odor level), and stores the relationship in the database.

In this way, the manager of each operator can give appropriate instructions based on each operator's individual sense of smell, and can perform optimum maintenance and management work.

According to the third embodiment, the provision of the sensory test condition acquisition means 900 increases the value of the sensory information, and makes it possible to more accurately determine the operating state of the plant equipment.

By storing information such as the operator's physical condition (cold, etc.) as sensory test conditions, it is possible to visualize the differences in the sense of smell of each operator according to the individual situation of each operator. .

Moreover, it is preferable that the maintenance management system described in the third embodiment has the environmental information acquisition means 700 and the environmental impact assessment means 800 . As a result, the value of the information from the five senses and the value of the sensory information can be increased, and the operating state of the plant equipment can be determined more accurately.

In addition, the present invention is not limited to the above-described embodiments, and includes various modifications. For example, the above-described embodiments are specifically described in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the configurations described.

Also, part of the configuration of one embodiment can be replaced with part of the configuration of another embodiment. Also, the configuration of another embodiment can be added to the configuration of one embodiment. Also, a part of the configuration of each embodiment can be deleted, a part of another configuration can be added, and a part of another configuration can be substituted.

100 Sensor information acquisition means 200 Sensory information acquisition means 300 Sense information/sensor information integration means 400 Plant information acquisition means 500 Plant normality/abnormality determination means 600 Sense information/plant information integration means 700 Environmental information acquisition means 800 Environmental impact evaluation means 900 Sensory test condition acquisition means

Claims (10)

a five-sensory sensor information acquisition means for acquiring five-sensory sensor information measured by five-sensory sensors installed in plant equipment;
sensory information acquisition means for acquiring sensory information confirmed by the operator at the site;
sensory information/sensor information integrating means for integrating the sensory information acquired by the sensory information acquiring means and the sensory information acquired by the sensory information acquiring means;
plant information acquisition means for acquiring plant information that is the operating state of the plant equipment;
plant normality/abnormality determination means for determining whether the operating state of the plant equipment is normal or abnormal based on the plant information;
sensory information/plant information integration means for integrating the integrated sensor information and sensory information with plant information having a discrimination result;
A maintenance system characterized by having A maintenance management system according to claim 1,
The maintenance management system, wherein the five senses sensor is an odor sensor that measures odor, and the five senses sensor information is odor sensor information that is measurement information of the odor sensor. A maintenance management system according to claim 2,
A maintenance management system, wherein the plant equipment is a reaction tank in a sewage treatment plant. A maintenance management system according to claim 2,
A maintenance management system characterized in that, when the sensory information is olfactory, there are odor information including strength of odor, comfortability of odor, acceptability of odor, and impression of odor. A maintenance management system according to claim 2,
The maintenance and management characterized in that the sensory information acquisition means acquires odor information evaluated by an operator on-site as an evaluation item that is an item for evaluating the odor information and an evaluation stage that is a level for evaluating the evaluation item. system. A maintenance management system according to claim 1,
A maintenance management system comprising a database for storing the sensor information and the sensory information at the same time. A maintenance management system according to claim 6,
The maintenance management system, wherein the database further stores the plant information and the determination result at the same time. A maintenance management system according to claim 1,
A maintenance and management characterized by comprising environmental information acquisition means for acquiring environmental information that affects the sensor information of the five senses, and environmental impact evaluation means for evaluating the impact of the environmental information on the sensor information acquired by the sensor. system. A maintenance management system according to claim 1,
A maintenance management system comprising sensory test condition acquisition means for acquiring sensory test conditions of an operator. A maintenance management system according to claim 9,
The maintenance management system, wherein the sensory test condition acquisition means obtains a relationship between each operator's sensory information and five sensory sensor information.

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