JP2020080163A - Information processor, information processing method, and computer program - Google Patents

Abstract

To provide an information processor, an information processing method, and a computer program capable of more efficiently inputting results of inspection work.SOLUTION: An information processor 100 has a data acquisition part 109, a document data input part 111, an abnormal value determination part 112. The data acquisition part 109 acquires numerical data as operation information of a facility to be inspected. The document data input part 111 inputs, in association with inspection items related to the facility and items related to acquisition date or acquisition time of the numerical data, the numerical data acquired by the data acquisition part 109 into document data with cells in which the numerical data can be inputted. The abnormal value determination part 112 determines, for each of the inspection items related to the facility, whether or not the numerical data related to the operation information is within a normal range. The abnormal value determination part 112 causes a display part 104 to display the cells related to any numerical values out of the normal range in a mode different from that of the cells related to any numerical values in the normal range.SELECTED DRAWING: Figure 2

Description

  Embodiments of the present invention relate to an information processing device, an information processing method, and a computer program.

  Conventionally, in public utilities such as electric power, water, gas, etc., or in the inspection work of building facilities such as buildings, inspectors collect data such as sensors and meters at terminals. There is a demand for a method of reporting abnormalities in data.

JP-A-8-7078

  The problem to be solved by the present invention is to more effectively provide an information processing apparatus, an information processing method, and a computer program that can notify an abnormality of collected data as a result of inspection work.

  The information processing apparatus according to the embodiment includes a data acquisition unit, a form data input unit, and an abnormal value determination unit. The data acquisition unit acquires numerical data that is operation information of the equipment to be inspected. The form data input unit associates the inspection item related to the facility with the item related to the acquisition date or acquisition time of the numerical data, and the data acquisition unit for the form data having a cell into which the numerical data can be input. Enter the numerical data obtained in. The abnormal value determination unit determines whether or not the numerical data related to the operation information is within the normal range for each inspection item regarding the facility. The abnormal value determination unit causes the display unit to display cells having numerical values outside the normal range in a manner different from cells having numerical values within the normal range.

The system configuration figure showing the example of composition of inspection support system 1 of an embodiment. The functional block diagram showing the functional composition of information processor 100 of an embodiment. The functional block diagram showing the functional composition of sensor 200 of an embodiment. The functional block diagram showing the functional composition of building equipment 300 of an embodiment. 3 is a functional block diagram showing a functional configuration of a higher-level server 400 according to the embodiment. FIG. The figure which shows the 1st specific example of the form data of embodiment. The figure which shows the 1st specific example when environmental information is input into the form data of embodiment. The figure which shows the 1st specific example in case operation information is input into the form data of embodiment. The figure which shows the 2nd specific example of the form data of embodiment. The figure which shows the 2nd one specific example when environmental information is input into the form data of embodiment. FIG. 6 is a diagram showing a second specific example when a plurality of environment information is input to the form data of the embodiment. The figure which shows the 2nd specific example in case operation information is input into the form data of embodiment. The figure which shows the 3rd specific example of the form data of embodiment. The figure which shows the 3rd specific example when environmental information and operation information are input into the form data of embodiment. 5 is a flowchart showing a flow of processing from generation of form data to recording of the embodiment.

  Hereinafter, an information processing apparatus, an information processing method, and a computer program according to the embodiments will be described with reference to the drawings.

  FIG. 1 is a system configuration diagram showing a configuration example of an inspection support system 1 of the embodiment. The inspection support system 1 includes an information processing device 100, a sensor 200, a building facility 300, and a host server 400. The information processing apparatus 100 and the upper server 400 are connected to each other via a network 500 so that they can communicate with each other. The network 500 may be, for example, the Internet or a dedicated line. The information processing apparatus 100 and the sensor 200 or the building equipment 300 are communicatively connected to each other by wireless communication. The wireless communication may be, for example, a wireless LAN (Local Area Network), Bluetooth (registered trademark), or NFC (Near field radio communication).

  The information processing device 100 is configured using a device such as a smartphone, a tablet computer, or a personal computer. The information processing device 100 includes a processor, a memory, an auxiliary storage device, and the like connected by a bus. The information processing apparatus 100 acquires data from the sensor 200, the building equipment 300, or the host server 400 that is communicatively connected. The data may be environment information indicating the environment around the sensor 200, operation information indicating the operation status of the building equipment 300, or measurement information recorded in the host server 400. Good. The environmental information may include, for example, acquisition date, time, temperature, humidity, illuminance, noise, UV, discomfort index, or heat stroke index, but is not limited thereto. In the operation information, for example, when the building equipment 300 is an external air conditioner, acquisition date, time, intake temperature, intake air volume, motor frequency, motor power consumption, Co2 concentration, cold water flow rate, hot water flow rate, filter pressure, intake dew point. Temperature or inverter failure alarms may be included, but are not limited to. The measurement information includes a measurement value received from a sensor or measuring instrument that can communicate with the Internet. The measurement information may include, for example, a numerical value indicating the temperature, the amount of electricity used, the amount of water used, or the amount of gas used, but is not limited thereto.

  The sensor 200 acquires environmental information around the device itself. The sensor 200 transmits the acquired environmental information to the information processing device 100 together with the identification information of the device itself. As the environmental information, different information may be acquired for each sensor 200. The sensor 200 may be installed around the facility to be inspected. A plurality of sensors 200 may be installed. The identification information is information for uniquely identifying the own device. The identification information may be a manufacturing number or may be given in advance by the user. The identification information may be any information as long as the information uniquely identifies the own device.

  The building facility 300 is a facility to be inspected installed in a building such as a building or a condominium. The building facility 300 is, for example, a facility installed in a building such as an air conditioner, an outdoor conditioner, an elevator, and a water heater. The building equipment 300 records the operation information of the equipment. The building facility 300 transmits the recorded operation information to the information processing device 100 together with the identification information of the device itself. As the operation information, different information may be acquired for each building facility 300. Plural building facilities 300 may be installed. The identification information may be any information as long as the information uniquely identifies the own device.

  The upper server 400 is configured by using a device such as a personal computer, a server, a workstation or an industrial computer. The upper server 400 includes a processor, a memory, an auxiliary storage device, and the like connected by a bus. The upper server 400 transmits the measurement information to the information processing device 100 via the network 500. The upper server 400 may be realized by a cloud computing system.

  FIG. 2 is a functional block diagram showing a functional configuration of the information processing apparatus 100 of the embodiment. The information processing apparatus 100 executes the form generation program to cause the first communication unit 101, the second communication unit 102, the input unit 103, the display unit 104, the form numerical data storage unit 105, the inspection information storage unit 106, and the control unit 107. Functioning as a device.

  The first communication unit 101 is a network interface. The first communication unit 101 communicates with the upper server 400 via the network 500. The first communication unit 101 may communicate by a communication method such as a wireless LAN, 3G (Generation) or LTE (Long Term Evolution) (registered trademark).

  The second communication unit 102 is a network interface. The second communication unit 102 communicates with the sensor 200 or the building equipment 300 via a short-range wireless communication system. The second communication unit 102 may communicate using a communication method such as Bluetooth, NFC or wireless LAN.

  The input unit 103 is configured by using an input device that a user sends an instruction to the information processing device 100. The input device is, for example, a touch pen, a mouse, a keyboard, or the like. The input unit 103 may be configured as a touch panel integrated with the display unit 104. When the input unit 103 is configured as a touch panel, the input unit 103 receives touch input. The input unit 103 may be an interface for connecting the input device to the information processing device 100. In this case, the input unit 103 generates input data (for example, instruction information indicating an instruction to the information processing device 100) from the input signal input by the input device, and inputs the input data to the information processing device 100.

  The display unit 104 is an output device such as a liquid crystal display or an organic EL (Electro Luminescence) display. The display unit 104 may be an interface for connecting the output device to the information processing device 100. In this case, the display unit 104 generates a video signal from the video data and outputs the video signal to the video output device connected to itself.

  The form numerical data storage unit 105 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device. The form numerical data storage unit 105 records the form definition data and the form numerical data. The form definition data is data for generating form data. As the form definition data, a plurality of types may be recorded according to the form of the form. The form definition data may be, for example, a file showing a template of the form data. Inspection items may be input in advance in the form definition data. The form numerical data is a numerical value indicating the data received from the sensor 200, the building equipment 300 or the host server 400 (hereinafter referred to as “received data”) in a predetermined format. The predetermined format may be any format as long as the form numerical data and the inspection item are associated with each other.

  The inspection information storage unit 106 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device. The inspection information storage unit 106 records the inspection information. The inspection information is information in which form numerical data and inspection items are associated with each other. The inspection item is associated with each piece of information included in the reception data received from the sensor 200, the building equipment 300, or the host server 400. The inspection information may have a threshold value indicating whether or not the form numerical data is a normal value. Hereinafter, the threshold value indicating whether or not the form numerical data is a normal value is referred to as “normal value data” in the present embodiment.

  The control unit 107 controls the operation of each unit of the information processing device 100. The control unit 107 is executed by, for example, a device including a processor and a memory. The control unit 107 functions as the form data generation unit 108, the data acquisition unit 109, the inspection information acquisition unit 110, the form data input unit 111, and the abnormal value determination unit 112 by executing the form generation program.

  The form data generation unit 108 generates the form data based on the selection instruction of the form definition data received from the user. The form data has an input image associated with a device such as the sensor 200, the building facility 300, or the host server 400 that is the target for acquiring the received data. The input image receives, via the input unit 103, an instruction to acquire the received data from the device to be acquired. When the input image is operated, the data acquisition instruction is input to the information processing device 100. The form data may have a plurality of input images. The form data has a data input area associated with the input image. The generated form data is displayed on the display unit 104. Numerical data of a form is input to the data input area.

  The data acquisition unit 109 acquires received data. The data acquisition unit 109 acquires the reception data from the device that is the acquisition target of the reception data, such as the sensor 200, the building equipment 300, or the host server 400, which is associated with the input image, according to the data acquisition instruction from the user. The data acquisition unit 109 may display an error screen when there is no reception data that can be acquired. The data acquisition unit 109 may be configured to acquire the reception data at a predetermined timing. The predetermined timing may be, for example, every 10 seconds or every 5 seconds. The data acquisition unit 109 stores the acquired received data in the form numerical data storage unit 105 as form numerical data.

  The inspection information acquisition unit 110 acquires inspection information from the inspection information storage unit 106. The inspection information acquisition unit 110 acquires the inspection information associated with the identification information based on the identification information of the sensor 200, the building equipment 300, or the upper server 400 included in the received data. The inspection information acquisition unit 110 may display an error screen when the inspection information storage unit 106 does not record the inspection information associated with the identification information.

  The form data input unit 111 inputs form numerical value data to the generated form data. The form data input unit 111 sets the inspection item included in the inspection information in the form data when the inspection item is not set in the form data. The form data input unit 111 inputs the form numerical data into the form data in association with the inspection item. When the inspection information includes normal value data, the form data input unit 111 inputs the normal value data to the form data at a predetermined location of the form data in association with the inspection item. The form data input unit 111 may receive the form numerical data from the data acquisition unit 109 or may acquire the form numerical data from the form numerical data storage unit 105.

  When the normal value data is input to the form data, the abnormal value determination unit 112 determines whether the input form numerical data is included in the range of the normal value data. The abnormal value determination unit 112 does not need to perform any processing when the form numerical data is included in the normal value data range, and displays that the form numerical data is all included in the normal value data range. You may let me. When the form numerical value data is not included in the normal value data range, the abnormal value determination unit 112 may emphasize and display the form numerical value data that is not included in the normal value data range, or change the color. It may be displayed by displaying, or an alarm may be sounded. The abnormal value determination unit 112 may use any means as long as it can inform the user that the form numerical data is not included in the range of normal value data.

  FIG. 3 is a functional block diagram showing a functional configuration of the sensor 200 of the embodiment. The sensor 200 functions as a device including the communication unit 201, the sensing unit 202, and the control unit 203 by executing the environment information acquisition program.

  The communication unit 201 communicates with the information processing device 100 via a short-range wireless communication method. The communication unit 201 may communicate using a communication method such as Bluetooth, NFC, or wireless LAN.

  The sensing unit 202 acquires environmental information around the device itself. The sensing unit 202 acquires, for example, temperature, humidity, illuminance, noise, or UV. The sensing unit 202 outputs the acquired information to the data acquisition unit 204.

  The control unit 203 controls the operation of each unit of the sensor 200. The control unit 203 is executed by, for example, a device including a processor and a memory. The control unit 203 functions as the data acquisition unit 204 and the transmission unit 205 by executing the environment information acquisition program.

  The data acquisition unit 204 receives the environmental information from the sensing unit 202. The data acquisition unit 204 may calculate other information such as a discomfort index, a heat stroke index, or relative humidity based on the received environmental information. A known method may be used as a method for calculating the discomfort index, the heat stroke index, or the relative humidity. The data acquisition unit 204 adds the acquisition date, time, and identification information to the environment information, and outputs it to the transmission unit 205. The transmission unit 205 transmits the environment information to the information processing device 100.

  FIG. 4 is a functional block diagram showing a functional configuration of the building equipment 300 of the embodiment. The building facility 300 functions as a device including the communication unit 301, the operation information storage unit 302, and the control unit 303 by executing the operation information acquisition program.

  The communication unit 301 communicates with the information processing device 100 via a short-range wireless communication method. The communication unit 301 may communicate using a communication method such as Bluetooth, NFC or wireless LAN. The communication unit 301 may be a communication device built in the building facility 300 or an external communication device. The external communication device may be, for example, an SD card having a wireless communication function, a wireless LAN card, or an Ethernet (registered trademark) converter.

  The operation information storage unit 302 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device. The operation information storage unit 302 records operation information. The operation information storage unit 302 may be an external storage device connected to the building equipment 300. The external storage device may be any storage device such as an SD card, an external hard disk, an SSD (Solid State Drive), a CF (Compact Flash) card, or a USB (Universal Serial Bus) memory. Good.

  The control unit 303 controls the operation of each unit of the building equipment 300. The control unit 303 is executed by, for example, a device including a processor and a memory. The control unit 303 functions as the operation information generation unit 304 and the transmission unit 305 by executing the operation information acquisition program.

  The operation information generation unit 304 generates operation information indicating the operating condition of the building equipment 300 from the log of the building equipment 300 at a predetermined timing. The operation information generation unit 304 adds the acquisition date, time, and identification information to the generated operation information and records it in the operation information storage unit 302. The transmission unit 305 acquires operation information from the operation information storage unit 302. The transmission unit 305 transmits the operation information to the information processing device 100.

  FIG. 5 is a functional block diagram showing a functional configuration of the upper server 400 of the embodiment. The upper server 400 functions as a device including the communication unit 401, the measurement information storage unit 402, and the control unit 403 by executing the information acquisition program.

  The communication unit 401 communicates with the information processing device 100 via the network 500. The communication unit 401 may communicate using a communication method such as wireless LAN, 3G, or LTE.

  The measurement information storage unit 402 is configured using a storage device such as a magnetic hard disk device or a semiconductor storage device. The measurement information storage unit 402 records the measurement information.

  The control unit 403 controls the operation of each unit of the upper server 400. The control unit 403 is executed by, for example, a device including a processor and a memory. The control unit 403 functions as the measurement information generation unit 404 and the transmission unit 405 by executing the measurement information acquisition program.

  The measurement information generation unit 404 adds the acquisition date and time to the data received by the upper server 400 to generate measurement information. The measurement information generation unit 404 records the generated measurement information in the measurement information storage unit 402. The transmission unit 405 acquires the measurement information from the measurement information storage unit 402. The transmission unit 405 transmits the measurement information to the information processing device 100.

  FIG. 6 is a diagram showing a first specific example of the form data of the embodiment. The form data is displayed on the display unit 104. The form data shown in FIG. 6 is the form data immediately after being generated by the form data generation unit 108. The form data includes an input image 141, an input image 142, a sensor table 143, and a building equipment table 144. The structure of the form data is not limited to the structure shown in FIG. For example, the form data may further include an input image in addition to the input image 141 and the input image 142, and may further include a table in addition to the sensor table 143 and the building equipment table 144. Hereinafter, the display unit 104 will be described as a touch panel configured integrally with the input unit 103. Hereinafter, FIGS. 7 and 8 will be described based on the structure of the form data of FIG. The sensor table 143 or the building equipment table 144 is one mode of the data input area.

  The input image 141 is an image for acquiring environmental information from the sensor 200 associated with the input image 141. When the input image 141 displayed on the display unit 104 is touched, the input unit 103 receives a data acquisition instruction for the input image 141. Upon receiving the data acquisition instruction for the input image 141, the data acquisition unit 109 acquires the received data from the sensor 200. The input image 141 may be configured not to accept a data acquisition instruction from the user when the input image 142 is touched. When the input image 141 is touched, the input image 141 may be configured not to accept the data acquisition instruction for a predetermined time. The predetermined time may be, for example, 5 seconds or 10 seconds. When the input image 141 is associated with the upper server 400, the measurement information may be acquired from the upper server 400.

  The input image 142 is an image for acquiring operation information from the building equipment 300 associated with the input image 142. When the input image 142 displayed on the display unit 104 is touched, the input unit 103 receives a data acquisition instruction to the input image 142. Upon receiving the data acquisition instruction for the input image 142, the data acquisition unit 109 acquires the reception data from the building equipment 300. The input image 142 may be configured not to accept a data acquisition instruction from the user when the input image 141 is touched. The input image 142 may be configured not to accept the data acquisition instruction for a predetermined time when touched. The predetermined time may be, for example, 5 seconds or 10 seconds. When the input image 142 is associated with the upper server 400, the measurement information may be acquired from the upper server 400.

  In the sensor table 143, environmental information included in the reception data acquired from the sensor 200 is input. The sensor table 143 includes an item column 143a and a data column 143b. The information described in the item column 143a is an inspection item included in the inspection information. The form data input unit 111 inputs the environmental information associated with the inspection item into the data column 143b. The inspection items described in the item column 143a are input when the form data is generated. When the sensor table 143 receives the measurement information from the upper server 400, the measurement information may be input. The data column 143b is not limited to one column. For example, it may be two rows or three rows.

  According to the item column 143a, environmental information regarding the date of acquisition, time, temperature (° C.), humidity (%), illuminance (Lx), noise (dB), UV, discomfort index, and heat stroke may be input as items. Recognize.

  The operation information included in the received data acquired from the building equipment 300 is input to the building equipment table 144. The building equipment table 144 includes an item column 144a, a data column 144b, and a normal value data column 144c. The information described in the item column 144a is an inspection item included in the inspection information. The form data input unit 111 inputs the operation information associated with the inspection item into the data column 144b. The data column 144b includes 10 columns. The operation information is input for each column included in the data column 144b. The information described in the normal value data column 144c is normal value data included in the inspection information. The inspection item and the normal value data described in the item column 144a and the normal value data column 144c are input when the form data is generated. The 10 columns included in the data column 144b are not limited to 10. For example, it may be 5 rows or 15 rows. The measurement information received from the host server 400 may be input to the building equipment table 144.

According to the item column 144a, items are as follows: acquisition date, time, intake air temperature (°C), intake air volume (m ³ /h), motor frequency (Hz), motor power (kw), Co2 concentration (ppm), cold water flow rate. (L/m), hot water flow rate (l/m), filter pressure (Pa), intake dew point temperature (°C DP), and operation information regarding the inverter failure alarm are input.

According to the normal value data column 144c, as the normal value data, the intake air temperature (° C.) is 26.0±3.0, the intake air flow rate (m ³ /h) is 3000±500, and the motor frequency (Hz) is 35±. 5, motor power consumption (kw) 6.0±1, Co2 concentration (ppm) 800±100, cold water flow rate (l/m) 20±5, hot water flow rate (l/m) 20±5 , 50±5 for the filter pressure (Pa), 19.0±2 for the intake dew point temperature (° C. DP), and 0 for the inverter failure alarm.

  FIG. 7 is a diagram showing a first specific example when environment information is input to the form data of the embodiment. The form data shown in FIG. 7 is the form data after the input image 141 is touched. The form data includes an input image 141, an input image 142, a sensor table 143, and a building equipment table 144. Hereinafter, differences from the form data of FIG. 6 will be described.

  The sensor table 143 includes an item column 143a and a data column 143b. Environmental information is input to the data column 143b. According to the data column 143b, the acquisition date is 2017.10.31, the time is 13:42, the temperature (° C.) is 20.1, the humidity (%) is 45, the illuminance (Lx) is 1500, and the noise ( It can be seen that dB) is 53, UV is blank, discomfort index is 65.1, and heat stroke is blank. Therefore, according to the data column 143b, the form numerical data is acquired at 13:42 on October 31, 2017, the temperature around the sensor 200 is 20.1° C., the humidity is 45%, the illuminance is 1500 Lx, It can be seen that the noise is 53 dB and the discomfort index is 65.1. Further, it can be seen that the UV and heat stroke indexes could not be obtained.

  FIG. 8 is a diagram showing a first specific example when operation information is input in the form data of the embodiment. The form data shown in FIG. 8 is the form data after the input image 142 is touched. The form data includes an input image 141, an input image 142, a sensor table 143, and a building equipment table 144. Hereinafter, differences from the form data of FIG. 6 will be described.

The building equipment table 144 includes an item column 143a, a data column 143b, and a normal value data column 144c. In the data column 144b, operation information is input for each column included in the data column 144b. According to the first column included in the data column 143b, the acquisition date is 2017.10.31, the time is 13:42, the intake air temperature (° C.) is 25.0, and the intake air flow rate (m ³ /h) is 3400. , The motor frequency (Hz) is 35, the motor power consumption (kw) is 6.0, the Co2 concentration (ppm) is 800, the cold water flow rate (l/m) is 22, and the hot water flow rate (l/m) is 20. It can be seen that the filter pressure (Pa) is 46, the intake dew point temperature (°C DP) is 19.0, and the inverter failure alarm is 0. According to the second column included in the data column 143b, the acquisition date is 2017.10.31, the time is 13:43, the intake air temperature (°C) is 25.0, and the intake air flow rate (m ³ /h). Is 3600, motor frequency (Hz) is 35, motor power (kw) is 6.0, Co2 concentration (ppm) is 800, cold water flow rate (l/m) is 23, hot water flow rate (l/m) is , 20, the filter pressure (Pa) is 47, the intake dew point temperature (°C DP) is 19.0, and the inverter failure alarm is 0. Therefore, it is possible to continuously confirm the change in the operating status.

  The cell 145 is a cell indicating operation information that is not included in the range of normal value data. When the operation information is input to the data column 144b, the abnormal value determination unit 112 determines whether the value input to each cell is within the range of normal value data. The abnormal value determination unit 112 displays values that are not included in the range of normal value data in different colors.

  FIG. 9 is a diagram showing a second specific example of the form data of the embodiment. The form data is displayed on the display unit 104. The form data shown in FIG. 9 is the form data immediately after being generated by the form data generation unit 108. The form data includes an input image 141a, an input image 142a, and a form table 146. The structure of the form data is not limited to the structure shown in FIG. For example, the form data may further include an input image in addition to the input image 141 and the input image 142. Hereinafter, FIGS. 10, 11 and 12 will be described based on the structure of the form data of FIG.

  The input image 141a is an input image for acquiring environment information from the associated sensor 200. When the input image 141a displayed on the display unit 104 is touched, the input unit 103 receives a data acquisition instruction for the input image 141a. Upon receiving the data acquisition instruction for the input image 141a, the data acquisition unit 109 acquires the reception data from the sensor 200. The input image 141a may be configured not to accept a data acquisition instruction from the user when the input image 142a is touched. The input image 141a may be configured not to accept the data acquisition instruction for a predetermined time when touched. The predetermined time may be, for example, 5 seconds or 10 seconds. When the upper server 400 is associated with the input image 141a, the measurement information may be acquired from the upper server 400.

  The input image 142a is an image for acquiring operation information from the associated building equipment 300. When the input image 142a displayed on the display unit 104 is touched, the input unit 103 receives a data acquisition instruction for the input image 142a. Upon receiving the data acquisition instruction for the input image 142a, the data acquisition unit 109 acquires the reception data from the building equipment 300. The input image 142a may be configured not to accept a data acquisition instruction from the user when the input image 141a is touched. The input image 142a may be configured not to accept a data acquisition instruction for a predetermined time when touched. The predetermined time may be, for example, 5 seconds or 10 seconds. When the upper server 400 is associated with the input image 142a, the measurement information may be acquired from the upper server 400.

  The acquired reception data is input to the form table 146. The form table 146 includes an item column 147, a data column 148, and a normal value data column 149. The information described in the item column 147 is an inspection item included in the inspection information. Immediately after the form data is generated, the item column 147 is blank. The form data input unit 111 inputs the inspection item included in the inspection information acquired from the inspection information storage unit 106 into the item column 147 according to the touched input image. The data column 148 includes 10 columns. Environmental information, operation information, or measurement information is input for each column included in the data column 148. The 10 columns included in the data column 148 are not limited to 10. For example, it may be 5 rows or 15 rows. The form table 146 is one mode of the data input area.

  The information described in the normal value data column 149 is normal value data included in the inspection information. Immediately after the form data is generated, the normal value data column 149 is blank. The form data input unit 111 inputs the normal value data included in the inspection information acquired from the inspection information storage unit 106 to the normal value data column 149 according to the touched input image.

  FIG. 10 is a diagram showing a second specific example when environment information is input to the form data of the embodiment. The form data shown in FIG. 10 is the form data after the input image 141a is touched. The form data includes an input image 141a, an input image 142a, and a form table 146. The form table 146 includes an item column 147, a data column 148, and a normal value data column 149. The points different from the form data of FIG. 9 will be described below.

  The data column 148 includes a region 148a. The area 148a is an area in which environment information or measurement information is input when the input image 141a is touched. When the input image 141a is touched, the data acquisition unit 109 acquires environment information from the associated sensor 200. The inspection information acquisition unit 110 acquires inspection information associated with the authentication information included in the environmental information. The form data input unit 111 inputs the inspection item included in the inspection information into the item column 147. The form data input unit 111 inputs the environment information associated with the inspection item into the area 148a.

  According to the area 148a, the acquisition date is 2017.10.31, the time is 13:42, the temperature (° C.) is 20.1, the humidity (%) is 45, the illuminance (Lx) is 1500, and the noise (dB). ), 53, UV is blank, discomfort index is 65.1, and heat stroke is blank. Therefore, according to the data column 143b, the form numerical data is acquired at 13:42 on October 31, 2017, the temperature around the sensor 200 is 20.1° C., the humidity is 45%, the illuminance is 1500 Lx, It can be seen that the noise is 53 dB and the discomfort index is 65.1. Further, it can be seen that the UV and heat stroke indexes could not be obtained.

  FIG. 11 is a diagram showing a second specific example when a plurality of environment information is input to the form data of the embodiment. The form data shown in FIG. 11 is the form data after the input image 141a is touched twice. The form data includes an input image 141a, an input image 142a, and a form table 146. The form table 146 includes an item column 147, a data column 148, and a normal value data column 149. The points different from the form data of FIG. 9 will be described below.

  The data column 148 includes a region 148b. The area 148b is an area where environment information or measurement information is input when the input image 141a is touched for the second time. When the input image 141a is touched, the data acquisition unit 109 acquires environment information from the associated sensor 200. The inspection information acquisition unit 110 acquires inspection information associated with the authentication information included in the environmental information. The form data input unit 111 inputs the environmental information associated with the inspection item into the area 148b.

  According to the region 148b, the date of acquisition is 2017.10.31, the time is 13:43, the temperature (° C.) is 20.8, the humidity (%) is 45, the illuminance (Lx) is 1500, and the noise (dB). ) Indicates that 54, UV is blank, discomfort index is 65.1, and heat stroke is blank. Therefore, according to the area 148b, the form numerical data is acquired at 13:43 on October 31, 2017, the temperature around the sensor 200 is 20.8° C., the humidity is 45%, the illuminance is 1500 Lx, and the noise is Is 54 dB and the discomfort index is 65.1. Further, it can be seen that the UV and heat stroke indexes could not be obtained.

  FIG. 12 is a diagram showing a second specific example when the operation information is input to the form data of the embodiment. The form data shown in FIG. 12 is the form data after the input image 142a is touched. The form data includes an input image 141a, an input image 142a, and a form table 146. The form table 146 includes an item column 147, a data column 148, and a normal value data column 149. The points different from the form data of FIG. 9 will be described below.

  When the input image 142a is touched, the data acquisition unit 109 acquires operation information from the associated building equipment 300. The inspection information acquisition unit 110 acquires inspection information associated with the authentication information included in the operation information. The form data input unit 111 inputs the inspection item included in the inspection information into the item column 147. The form data input unit 111 inputs the operation information associated with the inspection item into the data column 148. The form data input unit 111 inputs the normal value data included in the inspection information into the normal value data column 149.

According to the first column included in the data column 148, the acquisition date is 2017.10.31, the time is 13:42, the intake air temperature (° C.) is 25.0, and the intake air flow rate (m ³ /h) is 3400. , The motor frequency (Hz) is 35, the motor power consumption (kw) is 6.0, the Co2 concentration (ppm) is 800, the cold water flow rate (l/m) is 22, and the hot water flow rate (l/m) is 20. It can be seen that the filter pressure (Pa) is 46, the intake dew point temperature (°C DP) is 19.0, and the inverter failure alarm is 0. According to the second column included in the data column 143b, the acquisition date is 2017.10.31, the time is 13:43, the intake air temperature (° C.) is 25.0, and the intake air flow rate (m ³ /h). Is 3,600, the motor frequency (Hz) is 35, the motor power consumption (kw) is 6.0, the Co2 concentration (ppm) is 800, the cold water flow rate (l/m) is 23, and the hot water flow rate (l/m) is , 20, the filter pressure (Pa) is 47, the intake dew point temperature (°C DP) is 19.0, and the inverter failure alarm is 0. Therefore, it is possible to continuously confirm the change in the operating status.

  The cell 150 is a cell indicating operation information that is not included in the range of normal value data. When the operation information is input to the data column 148, the abnormal value determination unit 112 determines whether the value input to each cell is within the normal value data range. The abnormal value determination unit 112 displays values that are not included in the range of normal value data in different colors.

  FIG. 13 is a diagram showing a third specific example of the form data of the embodiment. The form data is displayed on the display unit 104. The form data shown in FIG. 13 is the form data immediately after being generated by the form data generation unit 108. The form data includes an input image 141a, an input image 142a, an input image 151, and a form table 146. The form table 146 includes an item column 147, a data column 148, and a normal value data column 149. The structure of the form data is not limited to the structure shown in FIG. For example, the form data may further include an input image in addition to the input image 141a, the input image 142a, and the input image 151. Hereinafter, FIG. 14 will be described based on the structure of the form data of FIG. The points different from the form data of FIG. 9 will be described below.

  The input image 151 is an image that executes the same processing as when the input image 141a and the input image 142a are touched. That is, when the input image 151 displayed on the display unit 104 is touched, the input unit 103 receives a data acquisition instruction for the input image 151. Upon receiving the data acquisition instruction for the input image 151, the data acquisition unit 109 acquires the received data from the associated sensor 200. Upon receiving the data acquisition instruction for the input image 151, the data acquisition unit 109 acquires the reception data from the associated building equipment 300. When the input image 151 is touched, the input image 141a or the input image 142a may be configured not to accept a data acquisition instruction from the user. The input image 151 may be configured not to accept the data acquisition instruction for a predetermined time when touched. The predetermined time may be, for example, 5 seconds or 10 seconds. When the upper server 400 is associated with the input image 151, the measurement information may be acquired from the upper server 400.

  FIG. 14 is a diagram showing a third specific example when environment information and operation information are input to the form data of the embodiment. The form data shown in FIG. 14 is the form data after the input image 151 is touched. The form data includes an input image 141a, an input image 142a, an input image 151, and a form table 146. The form table 146 includes an item column 147, a data column 148, and a normal value data column 149. Hereinafter, differences from the form data of FIG. 13 will be described.

  The data column 148 includes a region 148c and a region 148d. The area 148c is an area in which operation information is input when the input image 151 is touched. The area 148d is an area in which environmental information is input when the input image 151 is touched. When the input image 151 is touched, the data acquisition unit 109 acquires operation information from the building equipment 300. The inspection information acquisition unit 110 acquires inspection information associated with the authentication information included in the operation information. The form data input unit 111 inputs the inspection item included in the inspection information into the item column 147. The form data input unit 111 inputs the operation information associated with the inspection item into the data column 148. The form data input unit 111 inputs the normal value data included in the inspection information into the normal value data column 149.

According to the first column included in the region 148c, the acquisition date is 2017.10.31, the time is 13:42, the intake air temperature (° C.) is 25.0, the intake air flow rate (m ³ /h) is 3400, The motor frequency (Hz) is 35, the motor power consumption (kw) is 6.0, the Co2 concentration (ppm) is 800, the cold water flow rate (l/m) is 22, the hot water flow rate (l/m) is 20, It can be seen that the filter pressure (Pa) is 46, the intake dew point temperature (°C DP) is 19.0, and the inverter failure alarm is 0. Further, according to the second column included in the region 148c, the date of acquisition is 2017.10.31, the time is 13:43, the intake air temperature (°C) is 25.0, and the intake air flow rate (m ³ /h) is 3600, motor frequency (Hz) is 35, motor power (kw) is 6.0, Co2 concentration (ppm) is 800, cold water flow rate (l/m) is 23, hot water flow rate (l/m) is 20, the filter pressure (Pa) is 47, the intake dew point temperature (°C DP) is 19.0, and the inverter failure alarm is 0. Therefore, it is possible to continuously confirm the change in the operating status.

  The cell 152 is a cell indicating operation information that is not included in the range of normal value data. When the operation information is input to the data column 148, the abnormal value determination unit 112 determines whether the value input to each cell is within the normal value data range. The abnormal value determination unit 112 displays values that are not included in the range of normal value data in different colors.

  When the input image 151 is touched, the data acquisition unit 109 acquires environment information from the associated sensor 200. The inspection information acquisition unit 110 acquires inspection information associated with the authentication information included in the environmental information. The form data input unit 111 inputs the inspection item included in the inspection information into the item column 147. The form data input unit 111 inputs the environment information associated with the inspection item into the area 148d. The form data input unit 111 may be configured to add a line when there is a shortage of lines in the form table 146 when inputting inspection items or environmental information.

  FIG. 15 is a flowchart showing the flow of processing from generation of form data to recording of the form data according to the embodiment. In FIG. 15, the form data shown in FIG. 9 will be described as an example. The form data generation unit 108 of the information processing apparatus 100 generates form data based on the form definition data selection instruction received from the user (step S101). The data acquisition unit 109 of the information processing device 100 receives a data acquisition instruction via the input unit 103 (step S102). The data acquisition unit 109 acquires the reception data from the sensor 200, the building equipment 300, or the host server 400 according to the data acquisition instruction (step S103). The data acquisition unit 109 stores the received data as form numerical data in the form numerical data storage unit 105. The inspection information acquisition unit 110 of the information processing apparatus 100 determines whether the inspection information associated with the identification information included in the received data is recorded (step S104).

  When the inspection information is recorded (step S104: YES), the inspection information acquisition unit 110 acquires the inspection information associated with the identification information (step S105). When the inspection information is not recorded (step S104: NO), the inspection information acquisition unit 110 displays an error screen on the display unit 104 (step S106). The form data input unit 111 of the information processing apparatus 100 inputs the inspection item included in the inspection information into the item column. The form data input unit 111 inputs the normal value data included in the inspection information into the normal value data column (step S107). The form data input unit 111 inputs the form numerical data into the data column (step S108).

  The abnormal value determination unit 112 determines whether or not the acquired inspection information includes normal value data (step S109). When the normal value data is included (step S109: YES), the abnormal value determination unit 112 determines whether the form numerical value data input to the data column is included in the range of the normal value data (step S109). S110). The abnormal value determination unit 112 does not execute any processing when the form numerical data is included in the range of normal value data. If the form numerical value data is not included in the normal value data range, the abnormal value determination unit 112 changes the color of the form numerical value data that is not included in the normal value data range and displays the value. The control unit 107 records the generated form data in the form numerical data storage unit 105 (step S111).

  In the inspection support system 1 configured as described above, the form data generation unit 108 generates form data and touches the input image displayed on the generated form data, so that the input image is touched according to the touched input image. The data acquisition unit 109 acquires data from the sensor 200, the building equipment 300, or the host server 400. Therefore, the information processing apparatus 100 can acquire information from a plurality of acquisition target devices with one form data. Further, since the form data input unit 111 inputs the data into the form data, it is possible to input the inspection work result more accurately. Further, the form data input unit 111 inputs the form data, so that it is possible to suppress an input error associated with the input work. Further, the abnormal value determination unit 112 determines whether the input data is included in the range of normal values. When the data is not included in the range of normal values, it is possible to easily notice the abnormality to be inspected by highlighting and displaying the data that is not included in the range of normal values.

  The control unit 107 may be configured to record the generated form data on a cloud server communicatively connected via the network 500. With such a configuration, it is possible to collectively manage the form data generated by another information processing device 100. Further, even if the information processing apparatus 100 fails, there is no risk of losing the form data.

  The form data may be configured to have an input image for acquiring the form data generated in the past. With such a configuration, the user can confirm the past state of the inspection target on the spot. The form data generated in the past may be the form data recorded in the form numerical value data storage unit 105 or may be the form data recorded on a cloud server such as the upper server 400.

  In each of the above-described embodiments, the form data generation unit 108, the data acquisition unit 109, the inspection information acquisition unit 110, the form data input unit 111, and the abnormal value determination unit 112 are software function units. It may be a functional unit.

In the above embodiment, the received data acquired from the sensor 200 and the building equipment 300 is input to the form data and displayed on the display unit 104. The form data may be modifiable by the user. The corrected form data may be configured such that the display mode such as the typeface or cell color is changed according to the presence or absence of the correction. With such a configuration, the visibility of the user is improved, and the user can distinguish the corrected portion from the uncorrected portion. Further, the abnormal value determination unit 112 may determine whether or not the form data corrected by the user is included in the normal value range based on the normal value data. It should be noted that it is desirable that the display mode showing the corrected portion and the display mode showing that the abnormal value determination unit 112 determines that the correction value is not included in the range of the normal value data are displayed in different display modes. Further, when the information processing apparatus 100 cannot acquire the received data from the sensor 200 or the building equipment 300, the same display unit as the item acquired from the sensor 200 or the building equipment 300 is used for items that require manual input such as numerical values by the user. Alternatively, they may be displayed on the same form data.
Furthermore, the input type information indicating whether the item requires manual input or the item acquired from the sensor 200 or the building equipment 300 may be displayed in a different display mode for each inspection item. In this way, the visibility can be further improved by changing the display mode such as the typeface and cell color for each inspection item.

  According to at least one embodiment described above, by having the data acquisition unit 109, the inspection information acquisition unit 110, and the form data input unit 111, the inspection work result can be input more easily.

  Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. The embodiments and their modifications are included in the scope of the invention and the scope thereof, and are included in the invention described in the claims and the scope of equivalents thereof.

DESCRIPTION OF SYMBOLS 1... Inspection support system, 100... Information processing apparatus, 101... 1st communication part, 102... 2nd communication part, 103... Input part, 104... Display part, 105... Form numerical data storage part, 106... Inspection information storage part , 107... Control unit, 108... Form data generation unit, 109... Data acquisition unit, 110... Inspection information acquisition unit, 111... Form data input unit, 112... Abnormal value determination unit, 200... Sensor, 201... Communication unit, 202 ... Sensing unit, 203... Control unit, 204... Data acquisition unit, 205... Transmission unit, 300... Building equipment, 301... Communication unit, 302... Operation information storage unit, 303... Control unit, 304... Operation information generation unit, 305 ... transmission unit, 400... upper server, 401... communication unit, 402... measurement information storage unit, 403... control unit, 404... measurement information generation unit, 405... transmission unit

Claims (7)

A data acquisition unit that acquires numerical data that is operation information of the equipment to be inspected,
The numerical value acquired by the data acquisition unit for the form data having a cell into which the numerical data can be input in association with the inspection item regarding the facility and the item regarding the acquisition date or acquisition time of the numerical data. Form data input section for inputting data,
An abnormal value determination unit that determines whether the numerical data related to the operation information is within a normal range for each inspection item regarding the equipment,
The information processing apparatus, wherein the abnormal value determination unit causes the display unit to display cells having numerical values outside the normal range in a manner different from cells having numerical values within the normal range.   The information processing apparatus according to claim 1, wherein the abnormal value determination unit causes a cell having a numerical value outside the normal range to be displayed in a color different from that of a cell having a numerical value within the normal range.   The information processing apparatus according to claim 1, wherein the abnormal value determination unit indicates a cell having a numerical value outside the normal range by a display emphasized more than a cell having a numerical value within the normal range.   The information processing apparatus according to claim 1, wherein the normal range has a threshold value indicating an upper limit value of a normal numerical value and a threshold value indicating a lower limit value of a normal numerical value.   The information processing apparatus according to any one of claims 1 to 4, wherein the form data has cells in which the numerical data are input in an order according to an acquisition timing of each numerical data. A data acquisition step of acquiring numerical data which is operation information of the equipment to be inspected,
The numerical data acquired in the data acquisition step for the form data having a cell in which the numerical data can be input in association with the inspection item related to the facility and the item related to the acquisition date or acquisition time of the numerical data. Form data input step for inputting
An abnormal value determination step of determining whether the numerical data related to the operation information is within a normal range for each inspection item regarding the facility,
A display step of displaying a cell having a numerical value outside the normal range in a display mode different from that of a cell having a numerical value within the normal range.   A computer program for causing a computer to function as the information processing device according to claim 1.

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