JP5051098B2 - Computer system considering environmental resistance - Google Patents

Description

  The present invention relates to a computer system in consideration of environmental resistance, for example, for determining the influence of equipment, equipment such as a plant, electronic / electrical equipment, and a control device or a computer for controlling them, from the installation environment.

  In recent years, computers have been used in various fields such as plant control, semiconductor embedded field, and medical system field. Similarly, the field of application is expanding to facilities such as plants, electronic / electrical equipment, control devices and computers (hereinafter collectively referred to as equipment) for controlling them. Conventionally, these devices are installed in a place cut off from the environment such as temperature, humidity, and corrosive gas, and are handled so as not to be affected by the environment. However, as the field of application expands, it is increasingly installed and used at the factory site in fields where the environment is not necessarily good, such as a rubber manufacturing factory.

  In such a field, continuous operation for 24 hours and 365 days may be required in a poor environment such as high temperature and humidity, and sometimes high concentration of corrosive gas. As a result, these devices may fail in a much shorter period than their original lifetime. The cause is that substances generated by chemical changes in the metal contained in the components of the equipment due to high temperature, humidity, corrosive gas, etc. will erode the computer motherboard, short circuit, switches, etc. Cause poor contact.

  Conventionally, these devices that require continuous operation have been installed in a place where they are not affected by the surrounding environment, and air conditioning has been provided to improve the environment of the installed place. In addition, when operating in a poor environment such as on-site without providing a dedicated room, heat resistance can be realized by increasing the housing or providing multiple fans. We have been trying to extend the service life. However, in an environment where the concentration of corrosive gas or the like is high, deterioration of the device may be promoted, for example, rotating the fan sufficiently leads to increasing the concentration of the corrosive gas in the housing. For this reason, it is desirable to take measures such as providing a device for cooling the inside of the apparatus main body or casing after sealing. However, while the cost for the countermeasure is required, the countermeasure alone is not sufficient. As described above, it has been difficult to take effective measures when these devices are continuously operated for a long period of time in a poor environment such as a high concentration of corrosive gas.

  In such a situation, the user performs a deterioration diagnosis of the device, evaluates in advance what kind of environment the device can operate without any problems, and appropriately determines that the environmental deterioration has an adverse effect on the device. A technology such as notifying is required.

Patent Document 1 discloses an example of a deterioration diagnosis apparatus that diagnoses the degree of deterioration and remaining life of devices including a computer and provides a diagnosis result to a user.
JP 2002-207837 A

  When the device is operated for a long time in the environment as described above, it is necessary to always measure and evaluate the influence of the environment on the device. It is also important to evaluate how much the deterioration of the device proceeds before starting use, and to determine in advance whether the device can withstand use. In particular, the influence of corrosive gas or the like does not appear immediately, and even if it is evaluated that there is no problem at the beginning of use of the device, it may become a problem later. Also, because the environment changes, the situation changes over time and problems may occur. Therefore, during the operation of the equipment, it is necessary to constantly evaluate the influence of the environment, and if it is judged that there is a problem, it is necessary to notify the user promptly and to take measures to prevent equipment failure etc. There is. Furthermore, if it is evaluated that the device cannot be used in a certain environment, it can be used if the environment is improved, or it can be used if the setting of the computer is changed. It is also important to propose to the user whether or not the product can be used if it is replaced with an optional product that has been subjected to environmental measures.

  In the above-described conventional technique, it is possible to determine the deterioration of the device, but the environment measurement is performed only when requested by the user to determine the deterioration of the device. Therefore, it is impossible to determine the influence of the environment at all times, and it is difficult to cope with a sudden change in the environment. Conventionally, it is possible to diagnose the degree of deterioration and remaining life of the equipment and present the result to the user, but even if it is determined that the deterioration is significant, measures to reduce the influence from the environment It does not make proposals for improving the environment or changing device settings. Therefore, there is a problem that the user cannot determine the countermeasure when the problem occurs.

  The present invention has been made in view of the above problems, and performs environmental measurement in real time after the start of use of the device, determines deterioration of the device as needed, and presents the determination result to the user. The environmental assessment can be performed at In addition, if the result of determination indicates that countermeasures are required, it is an object to be able to take measures such as presenting an alternative to the user.

  The present invention is a computer system that includes a plurality of devices and a server computer that is connected to the devices via a network and determines the influence of the devices from the environment. The device detects internal and external environmental information and measures a data detection unit, a data collection unit that collects environmental information measured by the data detection unit, and data transmission that transmits the collected environmental information to the server computer A part. Furthermore, a data receiving unit that receives the response instruction transmitted from the server computer and an influence response processing unit that performs the response process based on the received response instruction are provided. The server computer has a chemical substance registration database that stores information on chemical substances contained in the components that make up the equipment, and estimates of the amount of chemical substances and compounds produced by chemical changes caused by the environment inside and outside the equipment. A compound generation determination database defining a method is provided. Furthermore, the amount of the compound is estimated based on the data receiving unit that receives the environment information transmitted from the device, the received environment information, the chemical substance registration database, and the compound generation determination database. An environmental analysis unit for determining the degree of influence and creating a corresponding instruction according to the degree of influence. Then, a data transmission unit for transmitting the correspondence instruction created by the environment analysis unit to the device is provided.

  In addition, when an influence degree determination is performed by the environment analysis part of the server computer, it is provided with an alternative creation part that creates an alternative to reduce the influence degree when it is determined that there is a problem in the operation of the device.

  According to the present invention, it is possible to collect information on the environment in which the device is installed in real time, and to determine the influence from the environment as needed based on the information. As a result, if there is a problem in the operation of the device due to environmental influences, the user can be notified promptly.

  Furthermore, when it is determined that there is a problem in the operation of the device, an alternative for reducing the influence can be created and presented. Thereby, based on the presented information, the user can consider measures for improving the environment or measures for reducing the influence from the environment, and stable operation of the device can be realized.

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

  As an embodiment of the present invention, a computer system that takes environmental resistance into account will be described by taking, as an example, a control device that is installed in a plant and monitors and controls plant equipment and equipment as equipment for determining the influence from the environment. To do. FIG. 1 shows an overall configuration example according to an embodiment of the present invention.

  In FIG. 1, control devices 1a, 1b, 1c for monitoring and controlling the plant are connected to the control devices via the control LANs 3a, 3b, 3c, and the plant facilities and equipment are controlled based on the commands output from the control devices. And controllers 2a, 2b and 2c for collecting plant information and the like. Here, FIG. 1 shows an example in which the control device 1, the controller 2, and the control LAN 3 are each configured by three units, but in actuality, the control device 1, the controller 2, and the control LAN 3 are configured by the number corresponding to the scale of the plant and the number of control target devices. In addition, the control device 1, the controller 2, and the control LAN 3 may each be provided with a plurality of configurations such as a duplex configuration in order to ensure reliability. In addition, the structure of the apparatus for performing monitoring control of a plant is not restricted to this, Another structure may be sufficient.

  In FIG. 1, information such as the determination results accumulated in the information server 5 connected to the information server 5 and the information server 5 for determining the influence of the environment of the control devices 1 a, 1 b, and 1 c via the information LAN 8. Are provided with information clients 7a and 7b. The information server 5 is connected to the network 9 via the router 6, and the control devices 1a, 1b and 1c are connected to the network 9 via the routers 4a, 4b and 4c. The control devices 1a, 1b, and 1c and the information server 5 are connected to each other via the network 9, and the information server 5 collects information such as environmental information collected by the control devices 1a, 1b, and 1c via the network 9. Then, the influence of the environment on the control devices 1a, 1b, and 1c is determined. In FIG. 1, a plurality of information clients 7 a and 7 b are connected to the information LAN 8. However, these clients may not be provided, and the determination result may be displayed on the display device of the information server 5. . Moreover, it is good also as a structure which transmits a determination result to the portable terminal device etc. which a user designates.

  In this example, a control device will be described as an example of a target for determining the influence received from the environment. However, if the equipment is connected to the information server 5 via the network 9 and has means for transmitting information such as internal and external environmental information of the equipment to be determined for impact via the network 9, the plant equipment Also, electronic / electrical equipment may be targeted. In the following description, a control device incorporating a CPU (Central Processing Unit), such as a control computer, will be described as an example of a control device that is an influence determination target.

  FIG. 2 is a block diagram showing an outline of an internal configuration example of the information server 5 and the control device 1 of the computer system in consideration of environment resistance as an embodiment of the present invention. With reference to FIG. 2, an internal configuration example of the information server 5 and the control device 1 will be described. In FIG. 2, only one control device is illustrated, but one of the plurality of configurations described in FIG. 1 is illustrated as an example.

  The information server 5 includes an environment analysis unit 51, an alternative creation unit 52, an information display unit 53, an information server reception unit 54, an information server transmission unit 55, a chemical substance registration database 56, a compound generation determination database 57, and an environmental analysis result database 58. The alternative database 59 is provided. The information server 5 is a computer that includes an input / output device 60 that inputs / outputs information to / from a user, includes a program for executing the above processing, and includes a storage device that stores the information of the database. .

  The control device 1 includes a data collection unit 11, an influence handling processing unit 12, a control device transmission unit 13, a control device reception unit 14, and an actual measurement environment database 15. The control device 1 also includes a data detection unit 16 for measuring or detecting internal or external environmental information and an input / output device 17 for inputting / outputting information to / from the user. In addition, in FIG. 2, it does not show about the process part for implement | achieving the function for monitoring and controlling the plant with which the control apparatus 1 is equipped, and abbreviate | omits description.

  Next, processing contents of each processing unit of the information server 5 and the control device 1 will be described.

  The data collection unit 11 of the control device 1 periodically collects environmental information such as gas concentration, temperature, and humidity detected by the data detection unit 16 provided inside or outside the control device 1 and collects the collected information. The data is stored in the measured environment database 15 in time series. These data collected by the data collection unit 11 are referred to as actually measured environment data. The data detection unit 16 is a sensor or a gas measuring device provided inside or outside the control device 1, and is installed inside or outside the housing of the control device 1 or around the housing. The data of the measurement result is configured to be input to the control device 1 through a transmission line.

  The control device transmission unit 13 of the control device 1 periodically transmits the measured environment data collected by the data collection unit 11 to the information server 5 via the network 9. The transmission timing may be transmitted at regular intervals at a time interval designated in advance by the user, or may be arbitrarily transmitted at a timing designated by the user. Further, it may be configured to transmit necessary actually measured environment data in response to a request from the information server 5. With this configuration, in the past, environmental measurement was performed by arranging a specialized contractor and installing environmental measurement equipment at the request of the user. Can be collected. Thereby, while being able to detect the change of an environment rapidly, the influence by an environment can be determined at any time.

  The information server receiving unit 54 of the information server 5 receives actually measured environment data transmitted from the control device transmitting unit 13 of the control device 1 via the network 9. The environment analysis unit 51 determines whether a compound is generated based on the actually measured environment data received by the information server reception unit 54, the chemical substance registration database 56, and the compound generation determination database 57, and generates the generated compound Estimate the amount. Then, based on the estimated production amount of the compound, the degree of influence on the control device is determined, a response corresponding to the degree of influence is created, and the result is accumulated in the environmental analysis result database 58. Furthermore, when it is determined that the generated compound affects the control apparatus 1, the information server transmission unit 55 instructs the control apparatus 1 via the network 9 to take a response according to the degree of influence.

  Here, the chemical substance registration database 56 is a database in which the concentrations of chemical substances contained in devices, parts, and the like that constitute the control device 1 that is a target for determining the influence from the environment are registered. In recent years, such a chemical substance registration database has been in widespread use from the viewpoint of environmental protection. In addition, the compound generation determination database 57 is used when a chemical substance contained in equipment, parts, etc. constituting the control device 1 and a gas detected in or around the control device cause a chemical change. It is a database which defines the flow (program) which estimates the production amount of the compound produced | generated by a change. Details of the chemical substance registration database 56 and the compound generation determination database 57 will be described later.

  The alternative creation unit 52 of the information server 5 refers to the alternative database 59 when it is determined that the generated compound interferes with the operation of the control apparatus 1 as a result of the determination by the environment analysis unit 51, and the influence thereof. Measures to reduce the risk are created as an alternative. Here, the alternative database 59 stores information on measures that can be implemented as alternatives and information on the degree of influence of the compounds when the measures are implemented.

  The information display unit 53 of the information server 5 edits and outputs the determination result by the environment analysis unit 51 in response to a request from the user. The output destination is output at the request of the user, such as an input / output device 60 provided with a display device such as a monitor provided in the information server 5, a terminal such as the information client 7 connected to the information LAN 8, a portable terminal device designated by the user. You can set the destination. Further, when it is determined that the operation of the control device 1 is hindered as a result of the determination by the environment analysis unit 51, an alarm is notified from the information display unit 53 to the terminal device designated by the user according to the degree of influence. It can also be configured to.

  The control device receiving unit 14 of the control device 1 receives information on the correspondence instruction according to the degree of influence transmitted from the information server transmitting unit 55. The influence handling processing unit 12 inputs a handling instruction corresponding to the degree of influence received by the control device receiving unit 14, and performs a handling process according to the handling instruction. As response processing, an alarm corresponding to the degree of influence is displayed on an output unit such as the input / output device 17 provided in the control device 1 to notify the user, or the CPU of the control device 1 is stopped.

  Next, FIG. 3 shows a flowchart representing an overall processing outline of the information server 5 and the control device 1 as an embodiment of the present invention. The overall processing outline of the information server 5 and the control device 1 will be described with reference to FIG.

  First, the data collection unit 11 of the control device 1 periodically collects environment information inside or outside the control device 1 and stores the collected information in the measured environment database 15 in time series (step S301). Next, the collected measured environment data is transmitted to the information server 5 by the control device transmission unit 13 of the control device 1 (step S302).

  In the information server 5, the measured environment data transmitted from the control device 1 is received by the information server receiving unit 54 (step S303). Then, in the environment analysis unit 51, the actual measurement environment data received by the information server reception unit 54 is input, and whether or not the compound is generated in the control device 1 based on the chemical substance registration database 56 and the compound generation determination database 57 is determined. An environmental analysis process for determining and determining the degree of influence is executed (step S304). Next, the result of the environmental analysis process is presented to the user by the information display unit 53 (step S305). In addition, you may make it display the display of each information at the time of the request | requirement from a user.

  Next, it is determined whether or not the degree of influence determined by the environmental analysis process in step S304 is greater than 1 (step S306). Here, in this example, the influence degree is determined in five stages of 1 to 5, and when the influence degree is 2 or more, it is determined that there is an influence on the control device 1, and some corresponding processing is performed. The determination level of the influence level and the contents of the corresponding process are determined by adjusting with the user for each apparatus or system to be determined. It should be noted that a general determination level and corresponding processing are set in advance in the environment analysis unit 51 according to the degree of reliability required for the determination target device or system, and is suitable for a plant to which the system is applied. The determination level may be selected by the user.

  If the influence degree is greater than 1 as a result of the determination in step S306, a response instruction corresponding to the influence degree is transmitted to the control device 1 by the information server transmission unit 55 (step S307). Next, an alternative creation process for creating an alternative for reducing the influence from the environment by the alternative creation unit 52 is executed (step S308). After the process is completed, the process returns to step S303, waits for receiving the measured environment data from the next control device 1, and repeats the process after receiving the data. On the other hand, if the degree of influence is 1 or less as a result of the determination in step S306, the process returns to step S303 and the process is repeated. In this example, the alternative creation process is executed when the degree of influence is greater than 1. However, after the user confirms the result of the environmental analysis process, the alternative creation process is performed according to an instruction from the user. It may be configured to execute.

  In the control device 1, the control device receiving unit 14 receives a response instruction according to the degree of influence transmitted from the information server transmitting unit 55 of the information server 5 (step S309). Then, the influence handling processing unit 12 executes an influence handling process for implementing the handling according to the received instruction content (step S310). After the process is completed, the process returns to step S301 to repeat the process.

  Next, processing contents of each processing unit of the information server 5 and the control device 1 will be described.

  FIG. 4 is a flowchart showing an example of environment analysis processing performed by the environment analysis unit 51 of the information server 5 executed in step S304 of FIG. In the environment analysis process, first, measured environment data received by the information server receiving unit 54 is input (step S401). Next, based on the input actual measurement environment data, a compound generation amount estimation process for estimating the generation amount of the compound related to the target control device 1 is performed (step S402). Next, a compound influence degree determination process is performed for determining the influence degree of the compound on the control device 1 based on the estimated generation amount of the compound (step S403). Finally, the estimated production amount of the compound and the degree of influence thereof are stored in the environmental analysis result database 58 (step S404).

  FIG. 5 is a flowchart showing a process example of the compound generation amount estimation process executed in step S402 of the environmental analysis process shown in FIG. In the compound generation amount estimation process, the compound generation amount is estimated with reference to the chemical substance registration database 56 and the compound generation determination database 57 based on the measured environment data received from the control device 1. First, a database to be referred to in the compound production amount estimation process and a derivation example of the compound production amount will be described.

  FIG. 10 shows a data configuration example of the chemical substance registration database 56. In FIG. 10, a row 561 represents a part constituting a control device as an environmental analysis target, and a column 562 represents a chemical substance contained therein. Each column of the table indicates the concentration (ppm) of the chemical substance contained in the site. For example, the part 561 is a printed circuit board for controlling an HDD (Hard disk drive), an HDD platter (metal disk in a hard disk), a motherboard, and the like, and the chemical substance 562 is silver, copper, iron, or the like. It is a chemical substance contained in the material used for parts. In recent years, interest in chemical substance management and environmental conservation has increased, and companies have voluntarily improved the management of chemical substances into the environment, and information on these chemical substances contained in products has become available. Maintenance and provision are being made. Such information may be registered in the system in advance as a database.

  FIG. 11 shows a data configuration example of the compound generation determination database 57. In the compound generation determination database, the chemical substances defined in the chemical substance registration database 56 and the amounts of compounds generated by the chemical changes caused by the chemical substances and the gases detected and measured by the control device 1 are shown. Define the calculation method for estimation. In FIG. 11, a row 571 represents the name of a gas measured by the control device 1 as environmental information, and a column 572 represents a chemical substance contained in the part. Each column in the table is a name that represents a processing flow (program) for deriving the amount of compound generated by estimation when there is a compound that is generated by the reaction of a chemical substance (metal) and a gas. Identifier). For example, it is defined that the production amount of the compound produced by the chemical substance “silver” and the gas “hydrogen sulfide” is estimated by the “compound production amount derivation flow 1-1”. Here, the “compound production amount derivation flow 1-1” defines a calculation formula for calculating the production amount of a compound, and is registered as a program in the information server 5.

  In the table of FIG. 11, a column in which the name of the processing flow is not defined indicates that a chemical compound and a gas compound corresponding to the column are not generated. In addition, after starting the operation of the system, a failure may occur in the control device due to a cause other than the compound determined by the compound generation determination database 57. In this example, when the causative substance is specified and the generation amount derivation flow of the compound can be created, the effect on the new compound can be determined by additionally defining the content in the compound generation determination database 57. . In this way, in this example, it is possible to deal with chemical substances that were not considered at first by updating the database.

  FIG. 12 shows a data configuration example of the actual measurement environment database 15 that accumulates the actual measurement environment data collected by the control device 1. In FIG. 12, a row 151 represents items to be detected as environmental data, such as temperature, humidity, and name of gas to be measured. A column 152 represents information collection time. Each column of the table stores the temperature (° C.), humidity (%), and gas concentration (ppm) detected at each collection time. The actual measurement environment database 15 is a database provided in the control device 1. In the control device 1, data registered in the actual measurement environment database 15 is collected at predetermined intervals as the actual measurement environment data collected by the control device transmission unit 13. It is transmitted to the information server 5.

Next, the compound generation amount derivation flow will be described. First, estimation of the amount of compound production will be described. In general, the rate of chemical change is defined as the amount of change in reactant or product per unit time. In the following reaction,
aA + bB + ... a'A '+ b'B' + ...
The reaction rate is generally proportional to the concentration of each reactant. For example, in the case of the above reaction, the reaction rate v is expressed by the following equation.
v = k [A] ^h [B] ⁱ ...
Here, h and i are constants determined by experiments. K is a proportionality constant and depends on temperature.

For example, the reaction generation rate of the compound “silver sulfide” generated from the chemical substance “silver” and the gas “hydrogen sulfide” can be expressed by the following equation.
v = k [H ₂ S] ^h [Ag] ⁱ (Equation 1)
For h and i, values determined by experiments are used. For k, the value of k at a given temperature is used. Based on this, a compound generation amount derivation flow is created, and the silver sulfide generation amount derivation flow is defined as “compound generation amount derivation flow 1-1”.

  FIG. 13 is a flowchart showing a processing example of “compound generation amount derivation flow 1-1” for deriving the amount of silver sulfide generated as an example of the compound generation amount derivation flow. Here, the silver sulfide production rate is estimated using the above silver sulfide production rate equation (Equation 1), and the production amount is estimated based on this.

First, the temperature collected from the measured environment data is acquired, and the proportionality constant k of the silver sulfide production rate equation (Equation 1) is determined (step S131). Next, the gas concentration of hydrogen sulfide detected from the measured environment data is acquired and substituted into the hydrogen sulfide concentration (H ₂ S) of the silver sulfide production rate equation (Equation 1) (step S132). And the density | concentration of the silver of the site | part of the calculation object of the chemical substance registration database 56 is acquired, and it substitutes for the silver density | concentration (Ag) of a silver sulfide production | generation rate formula (Formula 1) (step S133). Based on the substituted value, the calculation of the silver sulfide generation rate equation (Equation 1) is performed to estimate the silver sulfide generation rate (v) (step S134). Based on the calculated silver sulfide generation rate, the amount of silver sulfide generated in a predetermined period is estimated (step S135).

  Here, the period during which the amount of compound produced is estimated is a period that serves as a criterion for determining the degree of influence of the compound, which will be described later. For example, as shown in FIG. 14, in the influence degree determination table, when the influence degree due to a compound is determined based on the amount of compound generated every month, the generation amount of the compound is set to one month. A method for estimating the amount of silver sulfide produced for one month from the silver sulfide production rate includes a method of calculating by integrating the amount of change for one month from the calculated rate. In addition, when the execution interval of the compound generation amount estimation process is, for example, every 5 days, a process such as integrating the amount of change based on the speed calculation results for the past month (six times) may be performed.

  Returning to FIG. 5, the compound production amount estimation process will be described. In the compound production amount estimation process, first, the chemical substance registration database 56 is referred to, and one part is selected from the control device constituent parts (561 in FIG. 10) related to the control device 1 to be determined from the environment, Is defined as a site X (step S501). Next, one of the chemical substances (562 in FIG. 10) registered in the chemical substance registration database 56 is selected and is designated as the chemical substance Y (step S502). Then, referring to the chemical substance registration database 56, the concentration of the chemical substance Y at the site X is acquired (step S503). Next, one type of detected gas is selected from the measured environment data received from the control device 1 and is designated as gas Z (step S504). And the density | concentration of gas Z is acquired from measured environment data (step S505).

  Next, referring to the compound generation determination database 57, a compound generation amount derivation flow of the chemical substance Y and gas Z is acquired (step S506), and it is determined whether there is a compound generation amount derivation flow of the chemical substance Y and gas Z. (Step S507). If there is a flow as a result of the determination, the concentration of the chemical substance Y and the concentration of the gas Z at the site X are substituted into the acquired compound generation amount derivation flow, and the compound generation amount derivation process is executed to estimate the compound generation amount (Step S508). Then, it is determined whether the processing has been completed for all the detected gas types (step S509). If the processing has not been completed, the process returns to step S504, and the processing is repeated for the next gas. If there is no compound generation amount derivation flow as a result of the determination in step S507, no compound is generated, so the process returns to step S504 to repeat the process for the next gas.

  As a result of the determination in step S509, if processing has been completed for all gases, it is determined whether processing has been completed for all of the chemical substances contained in the site X (step S510). Returning to S502, the process is repeated for the next chemical substance. As a result of the determination in step S510, if the process has been completed for all the chemical substances, it is determined whether the process has been completed for all of the components of the control device (step S511). If the result of determination in step S511 is that processing has not been completed, processing returns to step S501 and processing is repeated for the next site. As a result of the determination in step S511, when the process is completed, the present compound generation amount estimation process is terminated.

  As a result of the above process, the amount of compound produced for each site can be estimated for the control device 1 that is the target of the environmental impact determination.

  FIG. 6 is a flowchart showing an example of a compound influence degree determination process executed in step S403 of the environmental analysis process shown in FIG. In the compound influence degree determination process, the influence of the compound derived by the compound generation amount estimation process on the control device 1 is determined by an index called an influence degree.

  In the compound influence degree determination process, first, the chemical substance registration database 56 is referred to, and one part is selected from the control device constituent parts (561 in FIG. 10) related to the control apparatus 1 that is the target of the environmental influence determination. Is defined as a site X (step S601). Next, one of the compounds generated for the site X is selected and designated as compound P (step S602). Next, the generation amount estimation result related to the compound P at the site X is acquired (step S603). Then, with reference to the data of the part X and the compound P in the influence degree determination table, the influence degree and the corresponding content corresponding to the acquired generation amount are acquired (step S604). It is determined whether or not the processing has been completed for all the compounds at the site X (step S605). If there is a compound that has not been processed yet, the process returns to step S602, and the processing for the next compound is repeated. As a result of the determination in step S605, when the processing for all the compounds is completed, it is determined whether the processing has been completed for all of the control device constituent parts (step S606). Returning to S601, the process for the next part is repeated. As a result of the determination in step S606, when the processing for all the parts has been completed, this processing ends.

  In this example, an influence degree determination table is defined in advance as a determination criterion for determining the influence degree. FIG. 14 shows an example of data in the influence degree determination table. In this example, the influence degree determination table is defined as internal data of the compound influence degree determination process, and is defined as a table corresponding to the type of compound for each component of the control device. For example, the degree of influence on part: motherboard compound: silver sulfide is defined as one table. In FIG. 14, the influence degree determination table includes data such as an estimated compound generation amount 141, an influence degree 142, and a correspondence 143 for a predetermined period, for example, one month. In this example, the degree of influence is determined in five stages from 1 to 5 according to the amount of the generated compound, and when the degree of influence is 2 or more, it is determined that there is an influence on the control device, and it is defined to perform some kind of processing. is doing. The determination level of the degree of influence and the contents of the corresponding processing are determined in advance by adjusting with the user for each determination target device or system. Note that the influence degree determination table may be defined for each type of compound without distinguishing each part. Further, for example, a general determination level and corresponding processing may be set according to the degree of reliability required for the determination target apparatus or system.

  As described above, the environment analysis processing by the environment analysis unit 51 of the information server 5 is performed, and the result is stored in the environment analysis result database 58. FIG. 15 shows a data configuration example of the environment analysis result database 58. In FIG. 15, a row 581 represents a part constituting the control device 1 that is a target for determining the influence from the environment, and a column 582 represents a type of compound to be generated. In each column of the table, the generation amount, the degree of influence, and the correspondence of the compound at the site calculated by the environmental analysis process are stored.

  FIG. 7 is a flowchart showing an example of an alternative creation process performed by the alternative creation unit 52 of the information server 5 executed in step S308 of FIG. In this example, it is determined that there is an influence when the degree of influence from the environment is greater than 1, and a corresponding instruction is transmitted to the control device 1 and an alternative for reducing the influence is created. In this example, as an alternative, a plan for changing an environmental condition, a plan for changing parts and settings of a control device, and the like are formulated in advance, and information such as condition change contents is defined in the alternative database 59. And the environmental condition etc. at the time of implementing an alternative plan are simulated, and the effect is shown to a user by performing the influence degree determination in that case. In the flowchart of FIG. 3, the alternative creation process is performed when the influence degree is greater than 1. However, the process can be executed when the user requests, and the alternative can be presented. . Alternatively, the user may designate a target part for which an alternative is to be created, and the alternative may be created for the part.

  In the alternative creation process, first, based on the result of the environmental analysis process by the environmental analysis unit 51, a part having the maximum influence is selected (step S701). For example, in the case of the environmental analysis result data shown in FIG. 15, the influence degree with respect to the compound A of the HDD (printed circuit board) becomes the maximum at the influence degree 4. Next, referring to the alternative database 59, one alternative is selected (step S702). An example of the data structure of the alternative database 59 is shown in FIG. 16 and will be described later. Next, the environment variable condition is changed based on the selected alternative (step S703). This simulates the conditions when the alternative is executed. For example, when “temperature” is lowered by 5% from the actual measurement value as the environmental variable, a value obtained by reducing the temperature information used in the environmental analysis process by 5% from the actual measurement value is set. And the compound production amount estimation process after condition change is performed (step S704). Here, the same process as the compound generation amount estimation process described with reference to FIG. 5 is executed, but the process is performed using the value after the change of the environment variable in step S703. For example, when the above temperature is decreased by 5%, the compound generation amount derivation flow is executed using the changed temperature, so that the temperature-related constant changes and the calculated compound generation amount also changes. Next, an influence determination process after the condition change is executed (step S705). Here, the same process as the compound influence degree determination process described with reference to FIG. 6 is executed. However, since the influence degree is determined using the compound generation amount calculated in step S704, the influence degree corresponding to the generation amount is obtained. . Then, it is determined whether there are other alternatives in the alternative database (step S706). If there are alternatives, the process returns to step S702, and the processes related to the other alternatives are repeated. If the result of determination in step S706 is that there are no other alternatives, the alternatives calculated so far, the degree of influence and the supplementary information are edited and presented to the user (step S707).

  As a result, it is possible to simulate the degree of influence from the environment when the alternative is implemented, so the user can consider the alternative after referring to the effects of the multiple alternatives presented. it can. Further, in this example, the degree of influence when the alternative defined in the alternative database 59 is simulated is determined. For example, the target value of the degree of influence of an arbitrary part is designated, The environmental conditions may be sequentially changed and processed so that the influence level is within the target value. For example, change the conditions such that the “temperature” is 5% lower, 10% lower, 15% lower than the actual measured value, determine the degree of influence in that case, and derive the condition that will become the target degree of influence It can also be presented to the user.

  FIG. 16 shows a data configuration example of the alternative database 59. The alternative is set in advance in consultation with the user in accordance with the device or system for which the environmental impact is determined. As alternatives, there are a plan for improving the installation environment, a plan for replacing component parts of the control device with a substitute part, a plan for changing the operating conditions of the control device, and the like. In FIG. 16, for example, as an alternative plan for improving the installation environment, as an alternative plan 1, a condition change is performed to reduce the “temperature” of the environmental variable by 5% from the actual measured value. As an alternative 2, the environmental variable “hydrogen sulfide concentration” is changed by 10% from the actual measured value.

  Further, as a plan for changing the operating condition of the control device, Alternative 3 is to change the condition of “fan rotation speed” reduction. This is because, when a compound due to a gas such as hydrogen sulfide gas has an influence, the inflow of gas from the outside can be suppressed by reducing the number of rotations of the fan for cooling the inside of the control device. As a result, there is an effect of reducing the concentration of hydrogen sulfide gas. However, since the temperature in the control device increases by reducing the number of rotations of the fan, there is a demerit that the allowable maximum CPU capacity is reduced. Therefore, as supplementary conditions, it is necessary to present to the user data representing the maximum CPU capacity that can be tolerated when the fan speed is changed, together with alternatives, and the data for that is defined as supplemental conditions in the alternative database 59 deep. FIG. 17 shows an example of data representing the relationship between the fan speed and the CPU capacity. As a supplementary condition, when the fan speed is reduced, the gas concentration reduction ratio obtained as the effect is also defined. In the alternative creation process, a change in the degree of influence is simulated by performing a compound generation amount estimation process and an influence degree determination process based on the gas concentration reduction rate corresponding to the fan speed reduction rate. be able to. The user can check the CPU capability together with the degree of influence corresponding to the reduction in the number of rotations of the fan, and can consider measures taking these conditions into consideration.

  In addition, as a proposal for replacing the control device component parts with alternative parts, there is a condition change in which the control device component parts are replaced with optional parts having high environmental resistance. In that case, it is defined as a supplementary condition how much the influence by the environment of the part exchanged for the optional product becomes. For example, as in Alternative 4, the HDD (printed circuit board) can be replaced with an HDD (printed circuit board) whose printed circuit board is covered with silicon rubber. In this case, the degree of influence after replacement decreases to the degree of influence 1. The degree of influence when the HDD (platter) and the motherboard are replaced with optional products (such as a varnish-coated mother board) is reduced to an influence degree of 1, respectively.

  Based on the result of the above alternative preparation process, the user determines whether it is possible to prepare and operate an environment in which the temperature and hydrogen sulfide concentration are reduced. Further, when the rotational speed of the fan is decreased, it is determined whether or not a decrease in CPU capability accompanying a decrease in the rotational speed is acceptable. In addition, when each part is replaced with an optional product, a determination including the cost required for the replacement is made. In this example, it is possible to provide information necessary for the user's judgment on these alternatives.

  Next, the processing of the control device 1 will be described in the overall processing overview as an embodiment of the present invention shown in the flowchart of FIG. Below, the data collection process of step S301 implemented in the data collection part 11 of the control apparatus 1 and the influence response process of step S310 implemented in the influence response process part 12 are demonstrated.

  FIG. 8 is a flowchart showing an example of data collection processing performed by the data collection unit 11 of the control device 1 executed in step S301 of FIG. In the data collection process, first, environmental data is periodically collected by the data detection unit 16 provided inside or outside the control device 1 (step S801). Then, the collected information is stored as measured environment data in the measured environment database 15 in time series (step S802). The data collection cycle is set in advance in consideration of the plant to be applied and its environment. Further, the data collection cycle may be changed for each type of data to be detected. A data configuration example of the actual measurement environment database 15 is shown in FIG. Next, the actually measured environment data collected via the control device transmitter 13 is transmitted to the information server 5 (step S803). The data transmission cycle to the information server may be the same as or different from the collection cycle of the measured environment data, and may be set arbitrarily.

  FIG. 9 is a flowchart illustrating an example of an influence handling process performed by the influence handling processing unit 12 of the control device 1 executed in step S310 of FIG. In the influence handling process, first, information on a handling instruction corresponding to the degree of influence received from the information server 5 is input. Corresponding instruction information corresponding to the degree of influence is information such as a compound that affects the part having the greatest degree of influence, a gas that generates the compound, the degree of influence, and the contents of the corresponding instruction. Next, the process branches in response to a response instruction (T) from the control server 5 (step S902).

  When the response instruction is logging, a log of information regarding the degree of influence is output to the control device 1. When the output destination of the log is provided with the input / output device 17 having a display device in the control device 1, it is displayed on the display device and stored as data in the storage unit of the control device 1 (step S903). When the response instruction is an alarm notification, an alarm is output by voice, a lamp, or the like via an alarm output device provided in the input / output device 17 of the control device 1, and is stored as data in the storage unit of the control device 1 (step) S904).

  If the response instruction is shutdown, a confirmation message for inquiring the user whether or not shutdown can be performed is output to the input / output device 17 of the control device 1 (step S905). Next, based on the input from the user, it is determined whether the shutdown is possible (step S906). If the shutdown is possible, the control device 1 is shut down (step S907). If the result of determination in step S906 is that shutdown is not possible, a log of information relating to the degree of influence is stored in the storage unit (step S908). If the response instruction is forcible shutdown, a log of information on the degree of influence is saved in the storage unit and the shutdown is immediately performed (step S909).

  Note that the content of the response instruction may be other than this, and is determined in advance by adjustment with the user in accordance with the type of the device for which the influence is determined from the environment, the installed environment, the operation status of the system, and the like.

  In the above description, as an embodiment of the present invention, an example in which the degree of influence from the environment on the operating control device is determined has been described. However, when a plant control device or the like is newly installed, the installation environment is determined. Can be measured in advance, and the influence from the environment can be evaluated in advance. In that case, if it is evaluated that the control device is expected to be seriously affected by the environment of the place where the control apparatus is to be installed, it is possible to implement necessary measures in advance based on the alternative presented by the system. Thereby, the influence from the environment after the operation start of a control apparatus can be reduced, and the stable operation of an apparatus can be aimed at. Moreover, since the risk of device failure can be reduced by taking countermeasures in advance, the reliability can be improved particularly in the case of a plant that requires continuous operation. .

It is a block diagram which shows the example of whole structure by one embodiment of this invention. It is a block diagram which shows the example of an internal structure by one embodiment of this invention. It is a flowchart which shows the example of the whole process by one embodiment of this invention. It is a flowchart which shows the example of an environmental analysis process by one embodiment of this invention. It is a flowchart which shows the compound production amount estimation processing example by one embodiment of this invention. It is a flowchart which shows the example of a compound influence degree determination process by one embodiment of this invention. It is a flowchart which shows the example of an alternative preparation process by one embodiment of this invention. It is a flowchart which shows the example of a data collection process by one embodiment of this invention. It is a flowchart which shows the example of an influence response process by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the chemical substance registration database by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the compound production | generation determination database by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the measurement environment database by one embodiment of this invention. It is a flowchart which shows the example of compound generation amount derivation | leading-out process by one embodiment of this invention. It is explanatory drawing which shows the example of a data structure of the influence determination table by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the environmental analysis result database by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the alternative database by one embodiment of this invention. It is explanatory drawing which shows the example of data showing the relationship between the fan rotation speed and CPU capability by one embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1, 1a, 1b, 1c ... Control device 2, 2a, 2b, 2c ... Controller, 3, 3a, 3b, 3c ... Control LAN 4, 4a, 4b, 4c ... Router, 5 ... Information server, 6 ... Router 7, 7a, 7b ... information client, 8 ... information LAN, 9 ... network, 11 ... data collection unit, 12 ... influence response processing unit, 13 ... control device transmission unit, 14 ... control device reception unit, 15 ... measurement environment Database, 16 ... Data detection unit, 17 ... Input / output device, 51 ... Environment analysis unit, 52 ... Alternative creation unit, 53 ... Information display unit, 54 ... Information server reception unit, 55 ... Information server transmission unit, 56 ... Chemistry Substance registration database, 57 ... Compound generation determination database, 58 ... Environmental analysis result database, 59 ... Alternative database, 60 ... Input / output device

Claims (8)

In a computer system comprising a plurality of devices and a server computer connected to the devices via a network and judging the influence of the devices from the environment,
The equipment is
A data detector that detects and measures environmental information inside and outside the device;
A data collection unit for collecting environmental information measured by the data detection unit;
A data transmission unit for transmitting the collected environmental information to a server computer;
A data receiving unit for receiving a correspondence instruction transmitted from the server computer;
Based on the received response instruction, an impact response processing unit that performs response processing,
The server computer is
A chemical substance registration database storing information on chemical substances contained in the parts constituting the device;
A compound production determination database that defines a method for estimating the amount of a compound produced by the chemical substance and a chemical change caused by an environment inside and outside the device;
A data receiving unit for receiving environmental information transmitted from the device;
Based on the received environmental information, the chemical substance registration database, and the compound generation determination database, the generation amount of the compound is estimated, the influence degree according to the generation amount is determined, and the response instruction according to the influence degree Environmental analysis department to create
A computer system in consideration of environmental resistance, comprising a data transmission unit that transmits a correspondence instruction created by the environmental analysis unit to the device. In the computer system considering the environmental resistance according to claim 1,
A terminal device or a mobile terminal device connected to the server computer via a network is provided, and a user refers to an influence determination result and a response instruction by an environment analysis unit of the server computer via the terminal device or the mobile terminal device. A computer system that takes environmental resistance into consideration. In the computer system considering the environmental resistance according to claim 1,
As a result of the influence degree determination by the environment analysis unit of the server computer, when it is determined that there is an obstacle to the operation of the device, an alarm is transmitted to a terminal device or a mobile terminal device designated in advance and notified to the user A computer system that takes environmental resistance into consideration. In the computer system considering the environmental resistance according to claim 1,
In the environment analysis unit of the server computer, when a problem occurs in the device due to a cause other than the assumed chemical change, by adding information on the unexpected chemical change to the compound generation determination database, A computer system that considers environmental resistance, characterized by adding and changing processing to the environmental analysis department. In the computer system considering the environmental resistance according to claim 1,
As a result of the influence degree determination by the environment analysis part of the server computer, when it is determined that there is a problem in the operation of the device, an alternative preparation part that creates an alternative to reduce the influence degree is provided. A computer system that takes environmental resistance into consideration. In the computer system considering the environmental resistance according to claim 5,
A computer system in consideration of environmental resistance, wherein the alternative creation unit proposes improvement of the installation environment of the device in order to reduce the degree of influence from the environment. In the computer system considering the environmental resistance according to claim 5,
A computer system considering environmental resistance, wherein the alternative creation unit proposes an alternative part of a part constituting the device in order to reduce the degree of influence from the environment. In the computer system considering the environmental resistance according to claim 5,
A computer system in consideration of environmental resistance, wherein the alternative creation unit proposes a change in setting of the operating conditions of the device in order to reduce the degree of influence from the environment.

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