KR20230086873A - Apparatus and method for monitoring measuring instruments in factory - Google Patents

Abstract

A first communication module for receiving state information and measurement values from a measuring instrument, a switch array including a plurality of mechanically externally operable switches, mode information or parameter setting information for at least one measuring instrument, and settings of the plurality of switches A memory for storing a lookup table including a correspondence between value combinations, a combination of setting values of the plurality of switches of the switch array and mode information and parameter setting information of the instrument based on the lookup table stored in the memory processor to acquire; and a wireless communication module wirelessly transmitting the mode information of the instrument, the parameter setting information, status information, and the measurement value to a monitoring server.

Description

Apparatus and method for monitoring measuring instruments in factory}

Embodiments of the present disclosure relate to an apparatus and method for monitoring an instrument installed in a factory. According to embodiments of the present disclosure, a monitoring communication device, a monitoring communication method, and a computer readable recording medium on which a program for performing the monitoring communication method is recorded are provided.

In factories, instruments are placed on multiple pieces of equipment to monitor their status. The instrument measures various values from each device and transmits the measured values to the central server device. Each measuring instrument is installed in each device, connected to the central server using a wired cable, and transmits measured values to the central server device through the wired cable. However, in many cases, a plurality of equipment is used in a factory, and when each measuring instrument is disposed in the plurality of equipment, a great deal of time and cost is incurred to install a wired cable between the plurality of measuring instruments and the central server device. In addition, since the measuring instrument and the central server device are disposed at a long distance, it is difficult to arrange and manage a long wired cable between the measuring instrument and the central server device.

On the other hand, when a measuring instrument is being installed or inspected, or when a predetermined setting is changed in the measuring instrument, a measured value measured by the measuring instrument becomes an invalid value. However, in an environment where many instruments are installed in various locations in a factory, it is difficult to obtain operation mode information of instruments from a central server device. Since the instrument does not automatically transmit information about the operating mode to the central server device, when the instrument is inspected, the user must manually input the operating mode information of the instrument in the central server device. If the user does not modify the mode of the instrument or if an input error occurs, a false alarm is generated for an emergency in the factory and the operation of the factory's production equipment is stopped. When such a malfunction occurs in a factory, there is a problem in that enormous property damage occurs due to production facility shutdown.

Embodiments of the present disclosure are monitoring communication in which an operator can directly input the operating mode and setting values of the measuring instrument at the site where the measuring instrument is installed, and automatically transmits information such as the operating mode, setting value, and measured value of the measuring instrument to a server. It is to provide a recording medium storing a device, a method, and a computer program.

According to one aspect of an embodiment of the present disclosure, a first communication module for receiving state information and measurement values from a measuring instrument, a switch array including a plurality of switches mechanically externally operable, mode information on at least one measuring instrument, or A memory for storing a lookup table including parameter setting information and a correspondence between a combination of setting values of the plurality of switches, a combination of setting values of the plurality of switches of the switch array and a lookup table stored in the memory a processor that obtains mode information and parameter setting information of the instrument by doing so; and a wireless communication module wirelessly transmitting the mode information of the instrument, the parameter setting information, status information, and the measurement value to a monitoring server.

In addition, according to an embodiment of the present disclosure, the mode information of the instrument may be selected from among a normal mode in which the measured value of the instrument is valid, an inspection mode in which the instrument is inspected, or a power-off mode in which the instrument is powered off. at least one is defined.

In addition, according to an embodiment of the present disclosure, the processor identifies product information of the instrument based on a combination of switch setting values of at least some of the plurality of switches, and the processor identifies the product information based on the identified product information. At least one of the measurement range of the instrument or a threshold value for outputting an alarm may be defined, and at least one of the measurement range of the instrument and the threshold value may be transmitted to the monitoring server through the wireless communication module.

Further, according to an embodiment of the present disclosure, the switch array includes a first group switch for setting mode information of the instrument and a second group switch for setting product information of the instrument, and the processor comprises: Mode information of the instrument may be obtained based on a combination of switch setting values of the first group switch, and product information of the instrument may be obtained based on a combination of switch setting values of the second group switch.

In addition, according to an embodiment of the present disclosure, the processor receives device type information of the measuring instrument from the measuring instrument through the first communication module, determines a device type of the measuring instrument based on the device type information, and , When the device type of the instrument is a plug-in device, receiving the mode information and the parameter setting information based on the information received from the instrument, and transmitting the received mode information and the parameter setting information to the wireless communication module. and, when the device type of the instrument is a general device other than a plug-in device, obtaining mode information and product information of the instrument based on a combination of setting values of the plurality of switches of the switch array, , Obtain the parameter setting information based on the product information, and transmit the obtained mode information and the parameter setting information to the monitoring server through the wireless communication module.

In addition, according to an embodiment of the present disclosure, the processor obtains protocol information of the instrument from the instrument or the monitoring server when the device type of the instrument is a plug-in device, and based on the protocol of the instrument, the processor The mode information and the parameter setting information may be received from a measuring instrument.

In addition, according to an embodiment of the present disclosure, the processor, upon obtaining protocol information of the instrument, performs a test operation with the instrument based on the protocol of the instrument, and as a result of the test operation, the processor performs a test operation with the instrument. When it is determined that the communication is in a normal state, the mode information and the parameter setting information may be received from the instrument.

Also, according to an embodiment of the present disclosure, the state information may include at least one of abnormal state information, alarm state information, temperature information, remaining battery information, or measurement error information.

In addition, according to an embodiment of the present disclosure, the processor generates a monitoring data packet, transmits the generated monitoring data packet to the monitoring server, and the monitoring data packet includes an instrument ID, a data type, and a data value. The data type is one from a group including at least one of mode information, abnormal state information, alarm state information, temperature information, remaining battery information, measurement error information, measurement value, alarm output threshold, or measurement range. can be defined

In addition, according to an embodiment of the present disclosure, the processor monitors the state information and the measurement value in a first cycle, and when the state information or the measurement value is changed from a value of a previous cycle, the changed state information or When the measurement value is transmitted to the monitoring server through the wireless communication module, and the time at which the state information or the measurement value is last transmitted to the monitoring server reaches a first reference time, the state information or the measurement value A value may be transmitted to the monitoring server through the wireless communication module.

In addition, according to an embodiment of the present disclosure, when at least one of the setting values of the plurality of switches is changed, the processor determines the mode information or The parameter setting information may be updated, and the updated mode information or the parameter setting information may be transmitted to the monitoring server through the wireless communication module.

According to another aspect of an embodiment of the present disclosure, in a control method of a monitoring communication device connected to a measuring instrument, the monitoring communication device includes a switch array including a plurality of switches that can be mechanically operated externally, and the monitoring communication device includes: The device control method may include storing a lookup table including a correspondence between mode information or parameter setting information for at least one instrument and combinations of setting values of the plurality of switches; obtaining mode information and parameter setting information of the instrument based on a combination of setting values of the plurality of switches of the switch array and the stored lookup table; Receiving state information and measurement values from the measuring instrument; and wirelessly transmitting the mode information of the instrument, the parameter setting information, status information, and the measurement value to a monitoring server.

According to another aspect of an embodiment of the present disclosure, a computer-readable recording medium on which a program for performing a method for controlling a monitoring communication device in a computer is recorded is provided.

According to the embodiments of the present disclosure, the operator can directly input the operating mode and set value of the instrument at the site where the instrument is installed, and automatically transmits information such as the operating mode, set value, and measured value of the instrument to the server. There is an effect capable of providing a recording medium storing a monitoring communication device, method, and computer program.

1 is a diagram illustrating a monitoring system according to an embodiment of the present disclosure.
2 is a block diagram showing the structure of a monitoring communication device, a measuring instrument, and a monitoring server according to an embodiment of the present disclosure.
3 is a diagram showing the structure of a switch array according to an embodiment of the present disclosure.
4 is a flowchart illustrating a method for controlling a monitoring communication device according to an embodiment of the present disclosure.
5 is a diagram illustrating a process of obtaining mode information from a switch setting value according to an embodiment of the present disclosure.
6 is a diagram illustrating a process of obtaining parameter setting information from a switch setting value according to an embodiment of the present disclosure.
7 is a diagram illustrating a data sheet according to an embodiment of the present disclosure.
8 is a diagram illustrating communication monitoring information according to an embodiment of the present disclosure.
9 is a flowchart illustrating an operation of changing an operation mode of a monitoring communication device according to a type of instrument according to an embodiment of the present disclosure.
10 is a diagram showing the structure of a data packet transmitted from a monitoring communication device to a monitoring server according to an embodiment of the present disclosure.
11 is a flowchart illustrating a process of transmitting status information and measurement values according to an embodiment of the present disclosure.
12 is a diagram illustrating a process of updating mode information and parameter setting information according to an embodiment of the present disclosure.

This specification clarifies the scope of the claims of the present disclosure, and explains the principles of the embodiments of the present disclosure so that those skilled in the art can practice the embodiments of the present disclosure. And, the embodiments are disclosed. The disclosed embodiments may be implemented in various forms.

Like reference numbers designate like elements throughout the specification. This specification does not describe all elements of the embodiments, and general content or overlapping content between the embodiments in the technical field to which the embodiments of the present disclosure pertain will be omitted. The term 'part' (portion) used in the specification may be implemented in software or hardware, and according to embodiments, a plurality of 'units' may be implemented as one element (unit, element), or a single 'unit' It is also possible that ' contains a plurality of elements. Hereinafter, embodiments of the present disclosure and working principles of the embodiments will be described with reference to the accompanying drawings.

1 is a diagram illustrating a monitoring system according to an embodiment of the present disclosure.

The monitoring system 10 according to embodiments of the present disclosure may be applied to various fields. The monitoring system 10 is, for example, applied to an industrial site to implement a smart factory, applied to a home to implement a smart home, applied to an agricultural site to implement a smart farm, or applied to a city to implement a smart city. can In the embodiments of the present disclosure, the monitoring system 10 will be described focusing on an embodiment applied to an industrial field, but the embodiments of the present disclosure are not limited to being applied to an industrial field. The monitoring system 10 according to an embodiment of the present disclosure may be installed in a factory having multiple facilities. The factory may correspond to various types of factories, such as a semiconductor process and a vehicle production process.

The monitoring system 10 includes at least one instrument set 120 , a monitoring server 130 , and an Access Point (AP) device 122 . The instrument set 120 includes the instrument 110 and the monitoring communication device 100 . The instrument set 120 is attached to or installed around a device to be monitored. Devices to be monitored correspond to factory facilities installed in industrial sites. One or a plurality of instrument sets 120 may be installed in one factory facility.

Monitoring server 130 controls the overall operation of the monitoring system (10). The monitoring server 130 may communicate with a plurality of monitoring communication devices 100 . The server 130 may be connected to the AP device 122 to perform wireless communication. The monitoring server 130 may manage and monitor a plurality of monitoring target devices through the monitoring communication device 100 . The meter 110 may be disposed in each monitoring target device. For example, the monitoring target device is implemented in the form of a blower, fan, driver, motor, pump, CCTV, robot, PLC (Programmable Logic Controller), power supply device, gas supply device, water supply device, and the like.

In addition, the monitoring server 130 may be connected to the user terminal 140 through a network. The monitoring server 130 may be connected to the user terminal 140 and provide the user terminal 140 with state information of a plurality of monitoring target devices being monitored by the monitoring system 10 . In addition, the monitoring server 130 may receive a predetermined control signal from the user terminal 140 and operate based on the received control signal.

The meter 110 is attached to the device to be monitored or disposed around the device to be monitored. The meter 110 measures various values from the monitored device. For example, the meter 110 may correspond to a gas detector, a temperature detector, a vibration detector, a sound detector, an explosion-proof detector, an image detector, a weight detector, a fire detector, a motion detector, and the like.

Since the measuring instrument 110 is provided as a product of various manufacturers, the shape of the input/output interface is very diverse. In addition, since the measuring instrument 110 is implemented using a commercial product, the input/output interface functions and buttons are very limited. Therefore, performing a predetermined data transmission operation between the measuring instrument 110 and the monitoring server 130 using the measuring instrument 110 or performing a specific operation is very limited.

The monitoring communication device 100 is disposed around the meter 110 and communicates with the meter 110 . The monitoring communication device 100 may communicate with the measuring instrument 110 by wire or wirelessly. For example, the monitoring communication device 100 is connected to the measuring instrument 110 through a wired cable and communicates with the measuring instrument 110 through a predetermined protocol. The monitoring communication device 100 may be attached to the main body of the measuring instrument 110 or disposed around the measuring instrument 110 .

The monitoring communication device 100 communicates with the monitoring server 130 wirelessly. The monitoring communication device 100 may perform wireless communication with the monitoring server 130 through the AP device 122 . The monitoring communication device 100 may communicate with the monitoring server 130 using a wireless communication technology such as Lora, NB-IoT, BLE, Zigbee, or WiFi, for example.

Each instrument set 120 includes an instrument 110 and a monitoring communication device 100 . The instrument set 120 is disposed in a device to be monitored in an industrial site. Each monitoring communication device 100 of the measuring instrument set 120 obtains mode information, parameter setting information, status information, and measurement values of the measuring instrument 110 . The monitoring communication device 100 transmits the obtained mode information, parameter setting information, status information, and measurement values to the monitoring server 130 through wireless communication.

2 is a block diagram showing the structure of a monitoring communication device, a measuring instrument, and a monitoring server according to an embodiment of the present disclosure.

The monitoring communication device 100 includes a processor 210, a first communication module 212, a switch array 214, a wireless communication module 216, and a memory 218.

The processor 210 controls the overall operation of the monitoring communication device 100 . Processor 210 may be implemented as one or more processors. The processor 210 may perform a predetermined operation by executing an instruction or command stored in the memory 218 of the monitoring communication device 100 . In addition, the processor 210 controls the operation of components included in the monitoring communication device 100 .

The first communication module 212 is connected to the meter 110 and communicates with the meter 110 . The first communication module 212 may be connected to the measuring instrument 110 through wired communication. The processor 210 receives state information and measurement values from the measuring instrument 110 through the first communication module 212 . Also, the first communication module 212 may transmit predetermined control signals or data to the measuring instrument 110 .

The switch array 214 includes a plurality of switches that can be mechanically operated externally. The switch array 214 transfers setting values of a plurality of switches set by a user to the processor 210 . The processor 210 may detect and acquire the setting value of each switch of the switch array 214 . The structure of the switch array 214 is described in detail below with reference to FIG. 3 .

3 is a diagram showing the structure of a switch array according to an embodiment of the present disclosure.

The switch array 214 includes a plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h. The plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h have a structure that can be mechanically operated externally. For example, the plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h may have protrusions movable in a vertical direction.

Switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h may have two levels. The protrusion is movable between the two levels. The user can set the value of each switch 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h by moving the protrusion. Processor 210, based on the position of the protruding portion of each switch 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h, each switch (320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h) can be obtained.

According to an embodiment of the present disclosure, the switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h may be divided into a first switch group 310 and a second switch group 312. Each of the first switch group 310 and the second switch group 312 may include one or more switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h. In the example of FIG. 3 , the first switch group 310 includes the first switch 320a and the second switch 320b, and the second switch group 312 includes the third to eighth switches 320c, 320d, and 320e. , 320f, 320g, and 320h).

The first switch group 310 is allocated to set mode information of the measuring instrument 110 . Mode information may be set based on a combination of setting values of one or more switches 320a and 320b included in the first switch group 310 . The processor 210 identifies mode information of the measuring instrument 110 based on a combination of setting values of one or more switches 320a and 320b of the first switch group 310 .

The second switch group 310 is allocated to set product information of the measuring instrument 110 . A user inputs product information of the measuring instrument 110 using the second switch group 310 . The product information may include information such as a model name of the instrument 110, a measuring object (eg, gas, temperature, etc.) of the instrument, and a manufacturer. According to one embodiment, product information may consist of only one model name. According to another embodiment, product information is composed of a combination of two pieces of information, such as a combination of a model name and a measurement object of a measuring instrument. In this case, the second switch group 310 includes a plurality of sub-switch groups, and each piece of information is assigned to each sub-switch group. For example, a model name is assigned to a first sub-switch group, and a measuring target of a measuring instrument is assigned to a second sub-switch group.

According to one embodiment of the present disclosure, the switch array 214 may include an indicator 330 indicating an identification number of each of the plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h. there is. The user refers to the identification number of each of the plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h with reference to the indicator 330, and each switch 320a, 320b, 320c, 320d, and 320e , 320f, 320g, and 320h) can be input.

The memory 218 of the monitoring communication device 100 is a lookup table representing mode information and product information corresponding to a combination of set values of the plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h Save the When the setting values of the plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h are input or changed, the processor 210 uses a lookup table to obtain mode information corresponding to the switch setting values and Product information can be identified. In addition, the memory 218 stores a lookup table including parameter setting information corresponding to each product information. For example, the memory 218 stores a lookup table including information such as a measurement range corresponding to each product information and an alarm output threshold.

When the user installs, changes, or changes the settings of the measuring instrument 110, a plurality of switches 320a, 320b, 320c, 320d, 320e, 320f, 320g, and 320h of the monitoring communication device 100 are used to set the mode. You can set information or input changed parameter setting information. Since the instrument 110 has a limited input/output interface, the instrument 110 itself cannot transmit mode information or parameter setting information to the monitoring server 130 . In this case, the administrator must manually change the setting information for the instrument 110 stored in the monitoring server 130. For example, it is necessary to find rows and columns for storing the setting information of the measuring instrument 110 in a table storing the setting information of the measuring instrument 110, change and input changed mode information or parameter setting information, and then save it. However, if changed setting information is input to an incorrect row or column in this process, an error may occur in the operation of the monitoring system 10 by changing the setting information of another instrument 110 or changing a different type of setting information. As another example, if changing the setting information of the measuring instrument 110 is omitted in the table, even though the operating mode of the measuring instrument 110 is changed, such changes may not be reflected, and a false alarm may occur. For example, if changing the operation mode of the instrument 110 to the inspection mode is omitted and the instrument 110 is inspected, the measured value of the instrument 110 is not valid, but based on the measured value of the instrument 110. Therefore, an incorrect error may occur because it is determined whether an error has occurred or not.

Embodiments of the present disclosure use the switch array 214 of the monitoring communication device 100 in the measuring instrument 110, since the user can directly change the mode information of the measuring instrument 110 and change product information in the field, monitoring There is no need to directly change mode information and product information in the server 130 . In addition, since the monitoring communication device 100 acquires parameter setting information based on product information and transmits it to the monitoring server 130, there is no need to manually change the parameter setting information in the monitoring server 130.

Some instruments 110 provide a plug-in function that automatically transmits mode information, product information, and parameter setting information of the instrument 110 to the monitoring server 130 when the instrument 110 is connected to the monitoring server 130. . However, there are many types of instruments 110, and many instruments 110 do not provide such a plug-in function. According to an embodiment of the present disclosure, the user inputs product information through the switch array 214 of the monitoring communication device 100, and the monitoring communication device 100 generates insufficient information and transmits it to the monitoring server 130. . Due to this configuration, according to an embodiment of the present disclosure, the monitoring server 130 can collect mode information, product information, and parameter setting information similarly to a device with a plug-in function, even for a meter 110 without a plug-in function. There are possible effects.

In addition, since the user directly inputs the mode information or product information of the instrument 110 in the field, the user who installs or manages the instrument 110 directly inputs the information to more accurately enter the mode information or product information There are advantages.

Again referring to FIG. 2 , the structure and operation of the monitoring communication device 100 will be described.

The processor 210 obtains switch setting values of the switch array 214 . The processor 210 identifies mode information and product information set by the switch array 214 using switch setting values and a lookup table stored in memory 218, and identifies parameter setting information based on the product information.

Also, the processor 210 receives state information and measurement values received from the measuring instrument 110 through the first communication module 212 .

State information is information indicating the state of the measuring instrument 110 . The monitoring communication device 100 or the monitoring server 130 may determine the state of the measuring instrument 110 based on the state information and determine whether there is an abnormality. In addition, the monitoring communication device 100 or the monitoring server 130 may determine whether or not the battery is low, whether it is overheated, or whether there is a measurement error, based on the state information. The state information may include at least one of abnormal state information, alarm state information, temperature information, remaining battery information, or measurement error information.

The measurement value is a measurement value measured by the meter 110 from the device to be monitored. The measurement value may correspond to, for example, a gas concentration value, a temperature value, a vibration value, a sound value, an explosion risk value, an image detection value, a weight value, a fire detection value, or a motion value. The processor 210 may determine whether the measured value of the meter 110 exceeds an alarm output threshold based on the measured value. When the measured value exceeds the alarm output threshold, the processor 210 may generate alarm information and transmit the alarm information to the monitoring server 130 .

The processor 210 transmits mode information, parameter setting information, status information, and measurement values to the monitoring server 130 through the wireless communication module 216.

The wireless communication module 216 may wirelessly communicate with an external device. The wireless communication module 216 may communicate with the monitoring server 130 through the AP device 122 or communicate directly with the monitoring server 130 . The wireless communication module 216 may use, for example, Lora, Wi-Fi, Bluetooth, BLE, or the like.

The wireless communication module 216 may perform short-range communication, for example, Bluetooth, Bluetooth Low Energy (BLE), Near Field Communication (WLAN), Zigbee, infrared (IrDA) , Infrared Data Association (WFD) communication, WFD (Wi-Fi Direct), UWB (ultra wideband), Ant+ communication, etc. can be used. As another example, the wireless communication module 216 may perform long-distance communication, for example, via a legacy cellular network, a 5G network, a next-generation communication network, the Internet, or a computer network (eg, a LAN or WAN). can communicate with the device.

The wireless communication module 216 may establish communication with the monitoring server 130 under the control of the processor 210 . In addition, the wireless communication module 216 transmits control signals and data to the monitoring server 130 or receives control signals and data from the monitoring server 130 . The processor 210 controls the wireless communication module 216 to transmit mode information, parameter setting information, status information, and measured values to the monitoring server 130 .

The memory 218 stores various information, data, commands, programs, and the like necessary for the operation of the monitoring communication device 100 . Memory 218 may include at least one of volatile memory or non-volatile memory, or a combination thereof. The memory 218 is a flash memory type, a hard disk type, a multimedia card micro type, a card type memory (eg SD or XD memory, etc.), RAM (RAM, Random Access Memory), SRAM (Static Random Access Memory), ROM (ROM, Read-Only Memory), EEPROM (Electrically Erasable Programmable Read-Only Memory), PROM (Programmable Read-Only Memory), magnetic memory, magnetic It may include at least one type of storage medium among a disk and an optical disk. In addition, the memory 218 may correspond to a web storage or cloud server that performs a storage function on the Internet.

Meter 110 may include a communication module 230 , a measurement module 232 , and an input/output interface 234 .

The measurement module 232 measures a predetermined value from the device to be monitored and generates a measurement value and status information. The measurement module 232 may include, for example, a temperature sensor, an ammeter, a gas detection sensor, a vibration sensor, an acoustic sensor, an image sensor, a weight sensor, a fire sensor, or a motion sensor. The measuring module 232 transfers the measured values and status information to the communication module 230 .

The communication module 230 transmits the measurement value and status information received from the measurement module 232 to the monitoring communication device 100 . The communication module 230 is connected to the monitoring communication device 100 by wire or wirelessly. The communication module 230 may communicate with the monitoring communication device 100 using a predetermined protocol.

The input/output interface 234 receives user input or outputs predetermined information. The input/output interface 234 may include predetermined buttons, keys, dials, displays, speakers, and the like. According to one embodiment, the input/output interface 234 may provide information on how to set each switch setting value of the switch array 214 of the monitoring communication device 100 .

The monitoring server 130 includes a processor 250 , a communication module 252 , and a memory 254 .

The monitoring server 130 receives measurement values from a plurality of monitoring communication devices 100 . The monitoring server 130 receives a monitoring data packet including measurement values. The monitoring server 130 receives measurement values of each monitoring communication device 100 and stores them in the memory 254 . In addition, the monitoring server 130 monitors each monitoring target device using the stored measurement values. For example, the processor 250 determines the state of the monitored device using the collected measurement values. In addition, the processor 250 detects a predetermined event generated in the monitoring target device using the measurement value, generates event information, and outputs the generated event information to an external device such as the user terminal 140 . Also, the processor 250 detects an abnormal state using the measurement value, and generates a notification when the abnormal state is detected. The processor 250 outputs the generated notification to an external device such as the user terminal 140 .

4 is a flowchart illustrating a method for controlling a monitoring communication device according to an embodiment of the present disclosure.

Each step of the monitoring communication device control method according to an embodiment of the present disclosure may be performed by various types of electronic devices including a processor, a switch array, a wireless communication module, and a memory and communicating with a server. In the present disclosure, an embodiment in which the monitoring communication device 100 according to embodiments of the present disclosure performs a monitoring communication device control method will be mainly described. Therefore, the embodiments described for the monitoring communication device 100 are applicable to the embodiments of the monitoring communication device control method, and conversely, the embodiments described for the monitoring communication device control method are applicable to the monitoring communication device 100. Applicable to embodiments. The monitoring communication device control method according to the disclosed embodiments is not limited to being performed by the monitoring communication device 100 disclosed in the present disclosure, and may be performed by various types of electronic devices.

First, in step S402, the monitoring communication device 100 stores a lookup table in memory. The lookup table is a table defining mode information, product information, and parameter setting information corresponding to a combination of switch setting values of the switch array 214 . According to one embodiment, the lookup table may be stored in the memory 218 during manufacturing of the monitoring communication device 100 . According to another embodiment, the lookup table may be stored in the memory 218 during use or update of the monitoring communication device 100 .

Next, in step S404, the monitoring communication device 100 obtains mode information and parameter setting information of the measuring instrument 110 based on the combination of switch setting values and the lookup table. The monitoring communication device 100 obtains a combination of switch setting values set in the switch array 214 . The monitoring communication device 100 searches mode information, product information, and parameter setting information corresponding to a combination of switch setting values in the lookup table. The monitoring communication device 100 defines mode information and parameter setting information corresponding to a combination of switch setting values as mode information and parameter setting information of the measuring instrument 110 .

According to an embodiment of the present disclosure, the monitoring communication device 100 counts a duration during which the change of the switch setting value is not detected when at least one switch setting value is changed in the switch array 214 . The monitoring communication device 100 determines that the current switch setting value is a valid value when the switch setting value is not changed for a predetermined reference time. The monitoring communication device 100 obtains mode information and parameter setting information for valid switch setting values. When a user manipulates the switch array 214, it takes a certain amount of time to operate each switch. However, when mode information or parameter setting information is obtained using a switch setting value detected during switch operation, invalid mode information or parameter setting information is acquired. According to an embodiment of the present disclosure, after a user's operation of the switch array 214 is completed, mode information and parameter setting information are obtained from switch setting values, thereby preventing errors due to invalid switch setting values. there is.

Next, in step S406, the monitoring communication device 100 receives status information and measured values from the measuring instrument 110. The monitoring communication device 100 receives status information and measured values from the measuring instrument 110 at predetermined intervals (eg, several seconds, tens of seconds, or minutes).

Next, in step S408 , the monitoring communication device 100 transmits mode information, parameter setting information, status information, and measured values of the measuring instrument 110 to the monitoring server 130 . The monitoring communication device 100 transmits status information and measured values to the monitoring server 130 at predetermined intervals. In addition, when the monitoring communication device 100 detects that the switch setting value of the switch array 214 is changed, it transmits mode information or parameter setting information corresponding to the changed switch setting value to the monitoring server 130 .

According to an embodiment of the present disclosure, the monitoring communication device 100 may receive status information and measurement values from the measuring instrument 110 only when the operating mode of the measuring instrument 110 is set to the normal mode. The measuring instrument 110 may operate in a plurality of modes, and may operate in, for example, a normal mode, an inspection mode, or a power-off mode. State information and measurement values of the measuring instrument 110 are valid values only in the normal mode and are invalid values in the inspection mode or the power-off mode. The monitoring communication device 100 receives status information and measurement values from the instrument 110 only when the operation mode of the instrument 110 is set to the normal mode, thereby preventing invalid status information and measurement values from being obtained. It has the effect of reducing unnecessary operation of

According to another embodiment of the present disclosure, the monitoring communication device 100 obtains status information and measurement values regardless of the operation mode of the measuring instrument 110 . The monitoring communication device 100 transmits status information and measured values to the monitoring server 130 together with mode information and parameter setting information. Accordingly, the monitoring server 130 may know invalid state information and measurement values based on the mode information. The monitoring server 130 does not generate an alarm for invalid status information and measurement values even if the alarm output threshold is exceeded.

5 is a diagram illustrating a process of obtaining mode information from a switch setting value according to an embodiment of the present disclosure.

The processor 210 of the monitoring communication device 100 obtains mode information based on the switch setting value of the first group switch 310 . The processor 210 obtains switch setting values SW1 and SW2 of the first group switch 310 . The value SW1 is a switch setting value of the first switch, and the value SW2 may correspond to a switch setting value of the second switch. The SW1 value and the SW2 value can be defined as 0 or 1.

The memory 218 stores a first lookup table 510 including information on mode information corresponding to combinations of values SW1 and SW2 respectively. The first lookup table 510 corresponds to the normal mode, for example, when the SW1 value is 0 and the SW2 value is set to 0, and when the SW1 value is 0 and the SW2 value is set to 1, it corresponds to the maintenance mode, SW1 When the value is 1 and the SW2 value is set to 0, it can be defined as corresponding to the power-off mode. The processor 210 searches for mode information corresponding to the switch setting value of the current first group switch 310 from the first lookup table 510 . The processor 210 obtains mode information corresponding to the switch setting value from the first lookup table 510 .

6 is a diagram illustrating a process of obtaining parameter setting information from a switch setting value according to an embodiment of the present disclosure.

The processor 210 of the monitoring communication device 100 obtains product information based on the switch setting value of the second group switch 312 . The processor 210 obtains SW3 , SW4 , SW5 , SW6 , SW7 , and SW8 values, which are switch setting values of the second group switch 312 . The SW3 value corresponds to the switch setting value of the third switch, the SW4 value corresponds to the switch setting value of the fourth switch, the SW5 value corresponds to the switch setting value of the fifth switch, and the SW6 value corresponds to the switch setting value of the sixth switch. The value SW7 may correspond to the switch setting value of the seventh switch, and the value SW8 may correspond to the switch setting value of the eighth switch. The values SW3, SW4, SW5, SW6, SW7, and SW8 can be defined as 0 or 1.

The memory 218 stores second look-up tables 610 and 620 including product information corresponding to combinations of values SW3, SW4, SW5, SW6, SW7, and SW8, respectively.

According to an embodiment of the present disclosure, the third to eighth switches may be divided into a plurality of subgroups. For example, the third to fifth switches may correspond to the first subgroup switches, and the sixth to eighth switches may correspond to the second subgroup switches. Each subgroup can define different values. For example, a first subgroup switch may be assigned to set the model name of the instrument 110, and a second subgroup switch may be assigned to set a measurement target (eg, gas, temperature, etc.) of the instrument 110.

The second lookup table 610 defines product information corresponding to the set value of the second group switch. For example, the model name 'aaa' may be defined for the switch setting value combination No. 1, and the model name 'bbb' may be defined for the switch setting value combination No. 2.

The memory 218 stores at least one sub lookup table 620 or 622 including parameter setting information corresponding to each product information. For example, the memory 218 may store a first sub lookup table 620 and a second sub lookup table 622 . The monitoring communication device 100 obtains parameter setting information that is not transmitted from the measuring instrument 110 to the monitoring communication device 100 from a lookup table based on product information, and transmits the obtained parameter setting information to the monitoring server 130 do.

The first sub lookup table 620 stores measurement ranges corresponding to each product information. The first sub lookup table 620 may define, for example, that the measurement range corresponds to less than 500 in the case of product information aaa and corresponds to less than 1000 in the case of product information bbb. The processor 210 searches the first sub lookup table 620 for measurement range information corresponding to the product information obtained from the switch setting value of the second group switch 312 . The processor 210 obtains measurement range information corresponding to product information from the first sub lookup table 620 .

The second sub lookup table 622 stores measurement ranges corresponding to each product information. The second sub lookup table 622 may define, for example, that the alarm output threshold corresponds to 300 in the case of product information aaa and corresponds to 350 in the case of product information bbb. The processor 210 searches the second sub lookup table 622 for alarm output threshold value information corresponding to the product information obtained from the switch setting value of the second group switch 312 . The processor 210 obtains alarm output threshold value information corresponding to the switch setting value from the second sub lookup table 622 .

7 is a diagram illustrating a data sheet according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure, the monitoring server 130 collects, stores, and manages information on each measuring instrument 110 . The monitoring server 130 creates a data sheet 710 for each measuring instrument 110, stores and manages information on each measuring instrument 110.

Data sheet 710 contains a variety of information. For example, the data sheet 710 includes mode information 720, status information 722, 728, monitored object information 724, measurement value 726, alarm output threshold 730, and measurement range ( 732) can be stored. According to one embodiment of the present disclosure, mode information 720 , alarm output threshold 730 , and measurement range 732 are input by switch array 214 of monitoring communication device 100 . In addition, the mode information 720 set by the switch array 214, the alarm output threshold 730, and the measurement range 732 are transmitted from the monitoring communication device 100 to the monitoring server 130. The monitoring server 130 updates the data sheet 710 using the received mode information 720 , the alarm output threshold 730 , and the measurement range 732 .

8 is a diagram illustrating communication monitoring information according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure, the monitoring server 130 monitors the communication state of each monitoring communication device 100 . The monitoring server 130 may create and store a communication monitoring data sheet 810 indicating the communication state of each monitoring communication device 100 . The monitoring server 130 measures and collects information such as data amount, data loss, and data reception rate of each monitoring communication device 100 . The monitoring server 130 records information such as the amount of collected data, data loss, and data reception rate in the communication monitoring data sheet 810 . The communication monitoring data sheet 810 may record and manage communication monitoring information 812 , 814 , and 816 corresponding to each monitoring communication device 100 .

9 is a flowchart illustrating an operation of changing an operation mode of a monitoring communication device according to a type of instrument according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure, the monitoring communication device 100 may change an operation mode according to the type of measuring instrument 110 .

If the instrument 110 corresponds to a plug-in device, it automatically transmits mode information and parameter setting information to the monitoring communication device 100 . When the connection with the external device is detected, the measuring instrument 110 corresponding to the plug-in device may transmit initial setting information such as a device ID, mode information, and parameter setting information of the corresponding device to the external device. When connected to the monitoring communication device 100, the measuring instrument 110 automatically transmits initial setting information such as a device ID, mode information, and parameter setting information of the device. In addition, the measuring instrument 110 corresponding to the plug-in device automatically transmits the mode information to the monitoring communication device 100 when the mode information is changed.

On the other hand, the instrument 110, which is not a plug-in device, does not transmit mode information and parameter setting information of the instrument 110 to an external device even when a connection with the instrument 110 is detected. Even in the case of a general device other than a plug-in device, basic parameter setting information may be transmitted to the monitoring server 130, but due to some parameter setting information not being transmitted, insufficient information must be manually entered in the monitoring server 130. There is discomfort. Therefore, in the case of such a general instrument 110, the mode information and parameter setting information of the instrument 110 cannot be obtained from the monitoring communication device 100. In this case, the monitoring communication device 100 obtains mode information and parameter setting information from switch setting values of the switch array 214 .

First, in step S902, the monitoring communication device 100 is connected to the measuring instrument 110. The monitoring communication device 100 receives device type information from the meter 110 .

In step S904, the monitoring communication device 100 determines whether the meter 110 corresponds to a plug-in device based on the received device type information.

According to an embodiment, when connected to the monitoring communication device 100, the measuring instrument 110 may transmit device type information indicating that it corresponds to a plug-in device to the monitoring communication device 100. When the monitoring communication device 100 receives device type information from the meter 110 indicating that the meter 110 corresponds to a plug-in device, it determines that the meter 110 corresponds to a plug-in device. The meter 110 that is not a plug-in device may transmit device type information indicating that it is not a plug-in device to the monitoring communication device 100 or may not transmit separate device type information to the monitoring device 100 .

According to another embodiment, when the measuring instrument 110 is connected to the monitoring communication device 100, the measuring instrument ID is transmitted to the monitoring communication device 100. In this case, the instrument ID corresponds to the device type information. The monitoring communication device 100 receives the instrument ID and determines whether the connected instrument 110 corresponds to a plug-in device based on the instrument ID. The monitoring communication device 100 may store in the memory 218 information on whether each meter corresponds to a plug-in device. The monitoring communication device 100 uses the information stored in the memory 218 to determine whether the received meter 110 of the meter ID corresponds to a plug-in device.

When the meter 110 corresponds to a plug-in device, the monitoring communication device 100 operates in a plug-in device mode. In the plug-in device mode, the monitoring communication device 100 performs steps S906, S908, S910, and S912.

In step S906, the monitoring communication device 100 deactivates at least some of the inputs of the switch array 214.

According to one embodiment, the monitoring communication device 100 deactivates all inputs of the switch array 214 . Therefore, the monitoring communication device 100 does not obtain or process the switch setting value of the switch array 214 even if there is a user manipulation such as a change of the setting value of the switch array 214 .

According to another embodiment, the monitoring communication device 100 deactivates some switches of the switch array 214 . For example, the monitoring communication device 100 activates the first group switch 310 and deactivates the second group switch 312 . In this case, the monitoring communication device 100 receives the parameter setting information from the measuring instrument 110, but receives the mode information through the first group switch 310. As another example, the monitoring communication device 100 deactivates the first group switch 310 and activates the second group switch 312 . In this case, the monitoring communication device 100 receives the mode information from the meter 110, but receives the parameter setting information through the second group switch 312. As another example, the monitoring communication device 100 activates some subgroup switches of the second group switch 312 and inactivates other subgroup switches. For example, the monitoring communication device 100 deactivates the first subgroup switch and activates the second subgroup switch. In this case, the monitoring communication device 100 receives the measurement range set by the first subgroup switch from the measuring instrument 110 and receives the alarm output threshold through the second subgroup switch.

Next, in step S908, the monitoring communication device 100 obtains protocol information of the measuring instrument 110. For example, the monitoring communication device 100 may obtain protocol information based on information such as the instrument ID of the instrument 110, the instrument type, or the instrument manufacturer. As another example, the monitoring communication device 100 may receive information indicating a protocol name or type from the meter 110 .

Next, in step S910, the monitoring communication device 100 proceeds with a test operation based on the protocol of the measuring instrument 110. The monitoring communication device 100 transmits a control signal or command generated by a protocol of the instrument 110 to the instrument 110 and receives a response from the instrument 110 . The monitoring communication device 100 may transmit a predetermined test command to the measuring instrument 110 and receive a response signal from the measuring instrument 110 . When the monitoring communication device 100 successfully receives the response signal, it is determined that the communication with the measuring instrument 110 is in a normal state, and the test operation is terminated. When the monitoring communication device 100 does not successfully receive a response signal, the test operation is retried. When the monitoring communication device 100 reattempts the test operation and successfully receives a response signal, the test operation is terminated. If the response signal is not successfully received even in the retry, the monitoring communication device 100 transmits test failure information to the monitoring server 130 and waits. Retrying may be performed up to a predetermined number of times.

Next, in step S912, the monitoring communication device 100 receives at least one of mode information and parameter setting information from the measuring instrument 110 using the protocol of the measuring instrument 110. According to an embodiment, the monitoring communication device 100 transmits a request signal for at least one of mode information and parameter setting information to the measuring instrument 110, and receives the mode information and parameter setting information in response to the request signal. . According to another embodiment, the meter 110 automatically receives mode information and parameter setting information from the monitoring communication device 100 .

In step S902, if it is determined that the measuring instrument 110 is not a plug-in device, the monitoring communication device 100 operates in a normal mode. The monitoring communication device 100 performs operations of S914, S916, and S918 in the normal mode.

When it is determined that the monitoring communication device 100 is not a plug-in device, the monitoring communication device 100 detects a switch setting value of the switch array in step S914.

Next, in step S916, the monitoring communication device 100 activates the switch setting algorithm. The switch setting algorithm is an algorithm that identifies mode information, product information, and parameter setting information corresponding to switch setting values. As described above, the switch setting algorithm uses the lookup table stored in the memory 218 to identify mode information, product information, and parameter setting information using switch setting values.

Next, in step S918, the monitoring communication device 100 obtains mode information, product information, and parameter setting information by using a switch setting algorithm based on switch setting values of the switch array.

10 is a diagram showing the structure of a data packet transmitted from a monitoring communication device to a monitoring server according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure, the monitoring communication device 100 records various information in the data packet 1010 and transmits the data packet 1010 to the monitoring server 130 . According to one embodiment, data packet 1010 includes an instrument ID section 1012 , a data type section 1014 , and a data value section 1016 . The monitoring communication device 100 may generate a data packet 1010 and transmit the data packet 1010 to the monitoring server 130 at predetermined intervals.

The instrument ID section 1012 represents identification information of the corresponding instrument 110 .

The data packet section 1010 represents the type of data included in the data packet 1010 . The data type is defined as one of the predefined data type attributes 1020. The data type attribute includes at least one of mode information, parameter setting information, status information, and measured values. Parameter setting information includes alarm output threshold and measurement range. Status information includes abnormal status information, alarm status information, temperature information, remaining battery information, and measurement error information.

The monitoring communication device 100 identifies the type of data to be transmitted and records a value corresponding to the identified data type in the data type section 1014 .

In addition, the monitoring communication device 100 records the data value transmitted through the data packet 1010 in the data value section 1016 . For example, when mode information is transmitted, values corresponding to normal mode, maintenance mode, and the like are recorded in the data value section 1016 . As another example, when the measured value is transmitted, the measured value is recorded in the data value section 1016 .

11 is a flowchart illustrating a process of transmitting state information and measurement values according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure, the monitoring communication device 100 periodically receives status information and measured values from the measuring instrument 110 . For example, the monitoring communication device 100 may obtain state information and measurement values from the meter 110 at intervals of 0.4 seconds and transmit the obtained state information and measurement values. However, when status information and measurement values are obtained and transmitted in real time, communication load significantly increases due to the large amount of data to be transmitted. According to an embodiment of the present disclosure, the monitoring communication device 100 reduces the communication load of the monitoring communication device 100 by changing a method of transmitting status information or measurement values.

First, in step S1102, the monitoring communication device 100 receives state information and measured values from the measuring instrument 110. The monitoring communication device 100 receives state information and measured values at every predetermined detection period. The predetermined detection period may be, for example, 0.4 seconds.

Next, in step S1104, the monitoring communication device 100 determines whether the received state information or measured value has changed from the value of the previous detection period.

If the received status information or measurement value is changed from the value of the previous detection period, the monitoring communication device 100 transmits the received status information or measurement value to the monitoring server 130 in step S1108. If only one of the status information or measurement value is changed from the value of the previous detection period, the monitoring communication device 100 transmits only the changed value to the monitoring server 130 .

If the received status information or measurement value is not changed from the value of the previous detection period, in step S1106, the monitoring communication device 100 determines whether the first reference time has reached from the last transmission time of the status information or measurement value. judge The first reference time is set to 30 seconds, for example. When the monitoring communication device 100 does not reach the first reference time from the last transmission time, the monitoring communication device 100 proceeds to the next detection period in step S1102 without transmitting the status information or the measured value to the monitoring server 130 .

If the first reference time is reached from the last transmission time, the monitoring communication device 100 transmits status information or measured values in step S1108.

The steps of FIG. 11 may be individually performed for each of the state information and measurement values. That is, when only the status information is changed and the measurement value is not changed, the status information is transmitted and the measurement value may be transmitted every first reference time.

According to an embodiment of the present disclosure, communication load can be significantly reduced by reducing the amount of data transmission of status information and measurement values. In addition, according to an embodiment of the present disclosure, by reducing the amount of data of the status information and measurement values stored in the database of the monitoring server 130, there is an effect of significantly saving the storage space of the database.

12 is a diagram illustrating a process of updating mode information and parameter setting information according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure, the monitoring communication device 100 updates mode information and parameter information when a switch setting value of the switch array 214 is changed. The monitoring communication device 100 updates mode information and parameter setting information when the measuring instrument 110 and the monitoring communication device 100 are connected for the first time. After that, mode information and parameter information hardly change. However, when inspecting the instrument 110 or changing the setting, the user manually changes the switch setting value of the switch array 214. When detecting that the switch setting value of the switch array 214 is changed, the monitoring communication device 100 updates mode information or parameter setting information corresponding to the changed switch setting value to the monitoring server 130 .

First, in step S1202, the monitoring communication device 100 determines whether a switch setting value has been changed. The monitoring communication device 100 may detect a signal for changing a switch setting value from the switch array 214 . For example, the monitoring communication device 100 generates a predetermined switch change signal when a setting value of at least one switch among a plurality of switches is changed. When the monitoring communication device 100 detects the switch change signal, it is determined that the switch setting value has been changed.

If the switch setting value is changed, next in step S1204, the monitoring communication device 100 transmits mode information or parameter setting information corresponding to the changed switch setting value to the monitoring server 130. When only one of the mode information or parameter setting information is changed, only the changed information is transmitted to the monitoring server 130.

According to an embodiment, the monitoring communication device 100 updates the mode information or parameter setting information in step S1204 when there is no change in the switch setting value for a predetermined time or longer after the switch setting value is changed, and the monitoring server 130 can be sent to

Next, in step S1206, the monitoring communication device 100 determines whether the current mode is a normal mode after mode information or parameter setting information is updated.

If in the normal mode, in step S1208, the monitoring communication device 100 resumes the normal mode of transmitting status information and measurement values.

If the current mode is not a normal mode, an operation of transmitting state information or measurement values may be stopped. Also, when the current mode is not the normal mode, the monitoring communication device 100 repeats an operation of updating and transmitting mode information or parameter setting information in step S1204.

Meanwhile, the disclosed embodiments may be implemented in the form of a computer-readable recording medium storing instructions and data executable by a computer. The command may be stored in the form of a program code, and when executed by a processor, a predetermined program module may be generated to perform a predetermined operation. Also, when the instructions are executed by a processor, certain operations of the disclosed embodiments may be performed.

As above, the disclosed embodiments have been described with reference to the accompanying drawings. Those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in a form different from the disclosed embodiments without changing the technical spirit or essential features of the present invention. The disclosed embodiments are illustrative and should not be construed as limiting.

Claims (13)

A first communication module for receiving state information and measurement values from the measuring instrument;
A switch array including a plurality of mechanically externally operated switches;
a memory for storing a lookup table including a correspondence between mode information or parameter setting information for at least one instrument and a combination of setting values of the plurality of switches;
a processor for obtaining mode information and parameter setting information of the instrument based on a combination of setting values of the plurality of switches of the switch array and a lookup table stored in the memory; and
A monitoring communication device including a wireless communication module wirelessly transmitting the mode information, the parameter setting information, the status information, and the measurement value of the instrument to a monitoring server. According to claim 1,
The mode information of the meter is defined as at least one of a normal mode in which the measured value of the meter is valid, an inspection mode in which an inspection of the meter is performed, or a power-off mode in which the power of the meter is turned off. According to claim 1,
the processor,
Based on a combination of switch setting values of at least some of the plurality of switches, product information of the instrument is identified, and at least one of a measurement range of the instrument or a threshold value for outputting an alarm is determined based on the identified product information. and transmitting at least one of the measurement range of the instrument or the threshold to the monitoring server through the wireless communication module. According to claim 1,
The switch array,
A first group switch for setting mode information of the instrument, and
A second group switch for setting product information of the instrument,
The processor obtains mode information of the instrument based on a combination of switch setting values of the first group switch and product information of the instrument based on a combination of switch setting values of the second group switch. monitoring communications device. According to claim 1,
the processor,
Receiving device type information of the instrument from the instrument through the first communication module;
determine a device type of the meter based on the device type information;
When the device type of the instrument is a plug-in device, the mode information and the parameter setting information are received based on the information received from the instrument, and the received mode information and the parameter setting information are transmitted through the wireless communication module. transmit to the monitoring server,
When the device type of the instrument is a general device rather than a plug-in device, mode information and product information of the instrument are obtained based on a combination of setting values of the plurality of switches of the switch array, and the product information is obtained based on the product information. Obtaining parameter setting information, and transmitting the obtained mode information and the parameter setting information to the monitoring server through the wireless communication module. According to claim 5,
When the device type of the instrument is a plug-in device, the processor obtains protocol information of the instrument from the instrument or the monitoring server, and obtains the mode information and the parameter setting information from the instrument based on the protocol of the instrument. receiving, monitoring device. According to claim 6,
When the processor obtains the protocol information of the instrument, the processor performs a test operation with the instrument based on the protocol of the instrument, and when it is determined that communication with the instrument is in a normal state as a result of the test operation, the processor performs the test operation from the instrument. A monitoring device that receives mode information and the parameter setting information. According to claim 1,
The status information includes at least one of abnormal status information, alarm status information, temperature information, remaining battery information, or measurement error information. According to claim 1,
The processor generates a monitoring data packet, transmits the generated monitoring data packet to the monitoring server,
The monitoring data packet includes an instrument ID, a data type, and a data value;
The data type is defined as one from a group including at least one of mode information, abnormal state information, alarm state information, temperature information, battery level information, measurement error information, measurement value, alarm output threshold, or measurement range. communication device. According to claim 1,
the processor,
Monitoring the state information and the measured value in a first cycle;
When the state information or the measurement value is changed from a value of a previous cycle, transmitting the changed state information or the measurement value to the monitoring server through the wireless communication module;
Monitoring communication for transmitting the status information or the measurement value to the monitoring server through the wireless communication module when the last transmission time of the status information or the measurement value to the monitoring server reaches a first reference time Device. According to claim 1,
The processor, when at least one of the setting values of the plurality of switches is changed, updates the mode information or the parameter setting information of the instrument based on a combination of the changed setting values of the plurality of switches, and updates the updated setting values of the plurality of switches. The monitoring communication device for transmitting the mode information or the parameter setting information to the monitoring server through the wireless communication module. In the control method of the monitoring communication device connected to the measuring instrument,
The monitoring communication device includes a switch array including a plurality of switches that can be mechanically operated externally,
The monitoring communication device control method,
storing a lookup table including a correspondence between mode information or parameter setting information for at least one instrument and combinations of set values of the plurality of switches;
obtaining mode information and parameter setting information of the instrument based on a combination of setting values of the plurality of switches of the switch array and the stored lookup table;
Receiving state information and measurement values from the measuring instrument; and
and wirelessly transmitting the mode information, the parameter setting information, the status information, and the measurement value of the instrument to a monitoring server. A computer-readable recording medium on which a program for performing the method of claim 12 is recorded on a computer.

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