JP4032416B2 - Environmental state quantity measurement and monitoring system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an environmental state quantity measurement monitoring system that measures an environmental state quantity representing an environmental state and monitors the measurement state.
[0002]
[Prior art]
  Conventionally, when measuring environmental state quantities at a plurality of positions using a plurality of measuring devices having sensors for measuring environmental state quantities such as temperature sensors, humidity sensors, fire detection sensors, human body detection sensors, etc., the Internet is used. The monitoring state of each measuring device is monitored by a monitoring device that is communicably connected to each measuring device. Moreover, the measurement result by a measuring apparatus, etc. were stored by the database server apparatus (henceforth DB server) connected so that communication was possible to the measuring apparatus and the monitoring apparatus via the internet (for example, refer patent document 1).
[0003]
  FIG. 6 is an example of a configuration diagram of a conventional environmental state quantity measurement and monitoring system. The measurement monitoring system includes a plurality of measurement devices 100 that measure environmental state quantities, a monitoring device 200 that is connected to the measurement device 100 via the Internet 900 so as to communicate with the measurement device 100, and monitors the measurement state of the measurement device 100, and the Internet 900. And a DB server 300 that is communicably connected to the measurement apparatus 100 and the monitoring apparatus 200 and stores the measurement result information of the measurement apparatus 100.
[0004]
  The monitoring device 200 requests the measurement device 100 to return the measurement result information via the Internet 900, receives the response of the measurement result information, and transmits the response to the DB server 300 via the Internet 900. The DB server 300 Receive and store measurement result information.
[0005]
  In this way, the monitoring device 200 stores the measurement result information in the DB server 300 (monitoring of the measurement state).
[0006]
[Patent Document 1]
          JP-A-11-88967
[0007]
[Problems to be solved by the invention]
  However, in the above-described conventional measurement monitoring system, the measurement apparatus 100 includes the Internet connection unit 101 having a connection function to the Internet 900 and the measurement unit 102 having a measurement function by a sensor. When changing the type of environmental state quantity to be measured at the position where the measurement apparatus 100 is installed (for example, when changing the sensor from a temperature sensor to a fire detection sensor), the Internet connection unit 101 and the measurement unit 102 are included. Since it is necessary to replace the measuring device 100, the cost for newly manufacturing the measuring device 100, the construction cost required for the replacement, and the like are increased, and the replacement work is obstructed.
[0008]
  The present invention has been made in view of the above problems, and an object of the present invention is to provide an environmental state quantity measurement and monitoring system capable of easily changing the type of environmental state quantity as a measurement target.
[0009]
[Means for Solving the Problems]
  The environmental state quantity measurement and monitoring system according to claim 1 is an environmental state quantity measurement and monitoring system that measures an environmental state quantity representing an environmental state and monitors the measurement state. A sensor unit that measures the environmental state quantity of the sensor unit, and is connected to the sensor unit so that the sensor unit can be replaced. A data control device that is communicably connected to the measurement device via a local area network and acquires the measurement result information from the measurement device.The measurement apparatus further includes a mounting determination unit that determines whether or not the sensor unit is mounted and transmits sensor mounting information, which is information to that effect, to the data control device when the sensor unit is mounted. The data control device is configured to count an elapsed time from a timing at which the sensor unit is mounted on the measuring device based on the sensor mounting information; and a first time set based on the elapsed time. Second correction information storing means for storing two correction data, and second correction data for reading out the second correction data corresponding to the elapsed time by the elapsed time measuring means from the second correction information storing means and transmitting it to the sensor unit. Data transmission means, the sensor unit via the local area network and the measurement device. Calibration that is data for acquiring the second correction data from the correction data sending means, correcting the measurement result information by the sensor unit using the acquired second correction data, and calibrating the sensor of the sensor unit. Second data correction means for performing at least one of data correction is further provided.It is characterized by that.
[0010]
  According to the above configuration, the environmental state quantity is measured by the sensor unit using the sensor, and the measurement result information is acquired from the sensor unit by the measuring device. Then, the measurement result information is acquired from the measurement device via the local area network by the data control device. In this way, the measurement result information of the environmental state quantity by the sensor unit attached to the measurement device connected to the data control device via the local area network is centrally managed by the data control device.
[0011]
  Furthermore, since the measuring device is connected so that the sensor unit can be replaced, the connected sensor unit is detached from the measuring device, and replaced with a sensor unit that can measure a desired environmental state quantity, and attached to the measuring device. By this, it is possible to change the environmental state quantity that is the measurement target. Therefore, it is possible to easily change the environmental state quantity as the measurement target.
[0012]
  Further, it is determined whether or not the sensor unit is mounted by the mounting determination means of the measuring device, and when the sensor unit is mounted, sensor mounting information that is information to that effect is transmitted to the data control device. The second correction information storage means of the data control device stores second correction data set based on the elapsed time from the timing when the sensor unit is mounted on the measuring device, and the elapsed time of the data control device. The measurement means counts the elapsed time from the timing when the sensor unit is attached to the measurement device based on the sensor attachment information, and the second correction data sending means of the data control device corresponds to the elapsed time by the elapsed time measurement means. The second correction data to be read is read from the second correction information storage means and transmitted to the sensor unit. Further, the second data correction means of the sensor unit acquires second correction data from the second correction data sending means via the local area network and the measuring device, and the sensor unit is obtained using the acquired second correction data. At least one of correction of the measurement result information by, and correction of calibration data, which is data for calibrating the sensor of the sensor unit, is performed.
[0013]
  In this way, using the second correction data set based on the elapsed time from the timing when the sensor unit is mounted on the measuring device, the correction of the measurement result information by the sensor unit and the sensor of the sensor unit are performed. Since at least one of calibration data, which is data for calibration, is corrected, at least one of correction of measurement result information and correction of calibration data suitable for changes in characteristics of the sensor, etc. of the sensor unit over time is performed. It is.
[0014]
  The environmental state quantity measurement monitoring system according to claim 2 is communicably connected to the data control device via the Internet, acquires the measurement result information from the data control device, and acquires the acquired measurement result information. It is characterized by comprising: a monitoring device that displays visually from the outside; and a database server device that is connected to the monitoring device so as to be communicable via the Internet and that acquires and stores the measurement result information from the monitoring device. .
[0015]
  According to said structure, measurement result information is acquired from a data control apparatus via the internet by the monitoring apparatus, and the acquired measurement result information is displayed so that visual recognition is possible from the outside. Then, the measurement result information is acquired from the monitoring device via the Internet and stored by the database server device.
[0016]
  Thus, since the measurement result information by the sensor unit is displayed by the monitoring device so as to be visible from the outside, the measurement state can be easily monitored. In addition, since the measurement result information by the sensor unit is stored centrally by the database server device, data management is performed efficiently.
[0017]
  The environmental state quantity measurement and monitoring system according to claim 3, wherein the sensor unit includes sensor type storage means for storing sensor type information representing a type of sensor, and the measurement device has a connected sensor unit. Installation comprising sensor type acquisition means for acquiring sensor type information and transmitting it to the data control device via a local area network, wherein the data control device represents an installation position of a measuring device connected via the local area network The installation position storage means for storing the position information in association with the local address, the sensor type information from the sensor type acquisition means is received, the corresponding installation position information based on the local address is read from the installation position storage means, Installation position for transmitting sensor type information and installation position information in association with each other to the monitoring device And at least one of the monitoring device and the database server device includes installation position display means for displaying the sensor type information and the corresponding installation position information so as to be visible from the outside. .
[0018]
  According to the above configuration, the sensor type information indicating the sensor type is stored in the sensor type storage unit of the sensor unit, and the sensor type information of the connected sensor unit is obtained by the sensor type acquisition unit of the measuring device. Obtained and transmitted to the data control device via the local area network. The installation position information indicating the installation position of the measuring device connected via the local area network is stored in the installation position storage means of the data control apparatus in association with the local address, and the installation position of the data control apparatus is supported. The attachment means receives the sensor type information from the sensor type acquisition means, reads the corresponding installation position information based on the local address from the installation position storage means, and associates the sensor type information with the installation position information. And transmitted to the monitoring device. Furthermore, the installation position display means of at least one of the monitoring apparatus and the database server apparatus displays the sensor type information and the corresponding installation position information so as to be visible from the outside.
[0019]
  Therefore, since the sensor type of the sensor unit connected to the measuring device and its installation position are displayed in association with each other, even if the sensor unit is replaced, the sensor currently connected to the measuring device The type and installation position can be easily confirmed.
[0020]
  The environmental state quantity measurement and monitoring system according to claim 4 includes a first correction information storage unit in which the measurement device stores first correction data set based on an environmental condition in which the measurement device is installed. The sensor unit acquires the first correction data from the first correction information storage unit, and corrects the measurement result information by the sensor unit using the acquired first correction data and the sensor included in the sensor unit. It is characterized by comprising first data correction means for performing at least one of correction of calibration data that is data for calibration.
[0021]
  According to said structure, the 1st correction data set based on the environmental conditions in which the measurement apparatus was installed are stored in the 1st correction information storage means of the measurement apparatus, The 1st data correction means of a sensor unit The first correction data is acquired from the first correction information storage unit, the measurement result information is corrected by the sensor unit and the sensor of the sensor unit is calibrated using the acquired first correction data. At least one of correction of calibration data that is data is performed.
[0022]
  Therefore, using the first correction data set based on the environmental conditions in which the measuring device is installed, the correction of the measurement result information by the sensor unit and the correction of the calibration data which is data for calibrating the sensor of the sensor unit. Therefore, the correction of the measurement result information and the correction of the calibration data suitable for the environmental condition in which the measuring device on which the sensor unit is mounted is installed (that is, the environmental condition in which the sensor unit is installed). At least one is done.
[0023]
  The environmental state quantity measurement monitoring system according to claim 5, wherein the data control device is set based on an environmental condition in which a measurement device is installed for each measurement device connected via a local area network. First correction information storage means for storing correction data, and first correction information change means for receiving the input from the outside and changing the first correction data stored in the first correction information storage means, The sensor unit acquires the first correction data from the first correction information storage means via a local area network and the measuring device, and uses the acquired first correction data to store measurement result information of the sensor unit. First data correction for performing at least one of correction and correction of calibration data that is data for calibrating the sensor of the sensor unit It is characterized in that it comprises a stage.
[0024]
  According to said structure, the 1st correction data set based on the environmental conditions in which the measuring apparatus was installed for every measuring apparatus connected via the local area network to the 1st correction information storage means of a data control apparatus Is stored, and the first correction information changing means of the data control device accepts an external input and changes the first correction data stored in the first correction information storage means. Then, the first correction data of the sensor unit is acquired from the first correction information storage unit via the local area network and the measurement device, and the first correction data is acquired using the acquired first correction data. At least one of correction of measurement result information by the sensor unit and correction of calibration data, which is data for calibrating the sensor of the sensor unit, is performed.
[0025]
  In this way, calibration data which is data for correcting the measurement result information by the sensor unit and calibrating the sensor of the sensor unit using the first correction data set based on the environmental condition in which the measurement apparatus is installed. Since at least one of the corrections is performed, the correction of the measurement result information and the calibration data suitable for the environmental conditions in which the measuring device on which the sensor unit is mounted are installed (that is, the environmental conditions in which the sensor unit is installed). At least one of the corrections is performed.
[0026]
  In addition, since the first correction information changing means of the data control device accepts an input from the outside and changes the first correction data stored in the correction information storage means, the change to the appropriate first correction data is made. Is easily done.
[0027]
  Further, the first correction data set based on the environmental conditions in which the measuring device is installed for each measuring device connected via the local area network is stored in the first correction information storage means of the data control device in a centralized manner. Therefore, the management of data is performed efficiently.
[0028]
  Claim6When the data control device receives the sensor mounting information, the measurement and monitoring system for an environmental state quantity described in the above item starts acquiring measurement result information for the measuring device that has transmitted the sensor mounting information. It is said.
[0029]
  According to the above configuration, when sensor mounting information, which is information indicating that the sensor unit is mounted on the measuring device, is received by the data control device, the measurement result about the measuring device to which the sensor mounting information is transmitted. Acquisition of information begins.
[0030]
  Therefore, when the sensor unit is not attached to the measurement device, the sensor attachment information is not received by the data control device, so that the measurement result information is not acquired by the data control device. That is, only for the measuring devices connected to the data control device via the local area network that need to acquire the measurement result information (that is, the measuring device to which the sensor unit is mounted). Since the measurement result information acquisition operation is performed, the measurement result information is efficiently acquired.
[0031]
  Claim7When the data control device receives the sensor mounting information, the measurement and monitoring system for the environmental state quantity described in the above describes the acquisition frequency of the measurement result information for the measuring device that has transmitted the sensor mounting information. It is characterized by being raised for a predetermined period.
[0032]
  According to the above configuration, when the sensor control information, which is information indicating that the sensor unit is attached to the measurement device, is received by the data control device, the measurement result information of the measurement device that has transmitted the sensor attachment information is received. The acquisition frequency is increased for a predetermined period with respect to the normal acquisition frequency.
[0033]
  Therefore, when the sensor unit is newly attached to the measuring device, or when the sensor unit is once removed from the measuring device for some reason and then attached again (or another sensor unit) to the measuring device. The measurement result may not be stable for a predetermined period. In such a case, as described above, since the acquisition frequency of the measurement result information is increased by a predetermined period (a period until the measurement result is stabilized) with respect to the normal acquisition frequency, the measurement result is stabilized by a monitoring device or the like. It is possible to accurately determine whether or not the operation has been performed.
[0034]
  Claim8The environmental state quantity measurement and monitoring system described in 1 is connected to the personal information storage means storing personal information, which is information for identifying an individual, so that the personal information storage means can be exchanged. A personal information processing unit having personal information reading means for reading personal information from the personal information storage means and personal information transmission means for transmitting the read personal information to the measuring device, wherein the measuring device comprises the personal information In addition to being communicably connected to the information processing unit, the sensor unit and the personal information processing unit are connected to be exchangeable, and when the personal information is received, the data control device is connected to the data control device via a local area network. When the personal information is transmitted and the data control device receives the personal information, the measuring device that transmitted the personal information Personal information associated with a local address and personal information is transmitted to the monitoring device, and at least one of the monitoring device and the database server device associates the local address with the personal information and displays the personal information so as to be visible from the outside. A display means is provided.
[0035]
  According to the above configuration, the personal information reading means of the personal information processing unit reads the personal information that is information for identifying the individual stored in the personal information storage means, and the personal information transmitting means of the personal information processing unit reads the personal information. The read personal information is transmitted to the measuring device. Then, the measurement device transmits personal information to the data control device via the local area network, and the data control device associates the personal information with the local address of the measurement device that has received the personal information and transmits it to the monitoring device. Is done. Further, the personal information display means of the monitoring device (or database server device) displays the local address and personal information in association with each other so as to be visible from the outside.
[0036]
  Here, the measurement apparatus is communicably connected to the personal information processing unit, and the sensor unit and the personal information processing unit are interchangeably connected, so that the personal information processing unit is used instead of the sensor unit. Is attached to the measuring device, and the personal information stored in the personal information storage means attached to the personal information processing unit is easily read out to the measuring device.
[0037]
  The personal information, which is information for identifying the individual stored in the personal information storage means, and the local address of the measuring device that has received the personal information are displayed in association with each other so that they can be viewed from the outside. It is possible to specify the person and location where the personal information storage means is attached to the attached personal information processing unit.
[0038]
  Furthermore, since the measuring device can communicate with the personal information processing unit and the sensor unit and the personal information processing unit can be exchanged, when measuring the environmental state quantity, the measuring device is provided with a sensor. When the unit is mounted and the arrangement of personnel is grasped, the personal information processing unit may be mounted on the personal information processing unit by mounting the personal information processing unit instead of the sensor unit in the measuring apparatus. That is, the measurement of the environmental state quantity and the confirmation of the personnel arrangement can be easily and efficiently performed.
[0039]
DETAILED DESCRIPTION OF THE INVENTION
  FIG. 1 is an example of a configuration diagram showing a configuration of an environmental state quantity measurement monitoring system according to the present invention. The measurement monitoring system includes a sensor unit 5 that has a sensor and measures an environmental state quantity, and an individual that reads personal information from an ID card 7 (corresponding to personal information storage means) that stores personal information that is information for identifying an individual. The information processing unit 6 and the sensor unit 5 (or the personal information processing unit 6) are communicably connected to each other, and the sensor unit 5 and the personal information processing unit 6 are connected to be exchangeable. The measurement result information is acquired from the sensor unit 5, and is connected to the measurement apparatus 1 that acquires personal information from the personal information processing unit 6 so as to be communicable with the measurement apparatus 1 via a local area network (hereinafter referred to as LAN) 8. A data control device 4 for obtaining measurement result information and personal information from the measurement device 1; Network (hereinafter referred to as WWW) 9 is communicably connected, acquires measurement result information and personal information from the data control device 4, and displays the acquired measurement result information and personal information so as to be visible from the outside. The monitoring device 2 includes a monitoring server 2 and a database server device 3 (hereinafter referred to as a DB server) 3 that is connected to the monitoring device 2 via the WWW 9 so as to be communicable and obtains measurement result information and personal information from the monitoring device 2 Yes.
[0040]
  The sensor unit 5 includes an interface unit 51 that transmits and receives information to and from the measurement device 1 and a sensor unit 52 that includes a sensor and measures environmental state quantities and generates measurement result information. It is transmitted to the measuring device 1 in accordance with a request from the measuring device 1 (or at predetermined time intervals (for example, 5 seconds)).
[0041]
  The personal information processing unit 6 reads the personal information from the ID card 7 at the timing when the interface unit 61 (corresponding to personal information transmission means) for transmitting and receiving information to and from the measuring apparatus 1 and the ID card 7 are attached. And a personal information reading unit 62. When the personal information reading unit 62 (corresponding to personal information reading means) reads the personal information from the ID card 7 (or after a predetermined time (for example, 1 second)), It is transmitted to the measuring device 1.
[0042]
  The measuring device 1 includes data for transmitting / receiving information between the interface unit 12 for transmitting / receiving information between the sensor unit 5 and the personal information unit 6 and data control device 4 having a local address via the LAN 8. And a transmission unit 11 for transmitting measurement result information and personal information to the data control device 4 in accordance with a request from the data control device 4.
[0043]
  Here, the interface unit 51 of the sensor unit 5, the interface unit 61 of the personal information processing unit 6, and the interface unit 12 of the measurement apparatus 1 can communicate based on, for example, a communication protocol and data format conforming to the IEEE 1451.2 standard. Done.
[0044]
  The data control device 4 transmits / receives information to / from each measuring device 1 connected via the LAN 8 and the information transmission device 42 having an IP address and the monitoring device 2 via the WWW 9. An Internet connection unit 41 that performs transmission and reception, acquires measurement result information and personal information from each measurement device 1 connected via the LAN 8 at predetermined time intervals (for example, 1 second), and performs predetermined time intervals (for example, The measurement result information and the personal information are transmitted to the monitoring device 2 at intervals of 10 seconds) (or according to a request from the monitoring device 2). The data control device 4 transmits the personal information to the monitoring device 2 in association with the local address of the measuring device 1 to which the personal information is transmitted and the personal information when transmitting the personal information to the monitoring device 2. .
[0045]
  The monitoring device 2 displays the local address and personal information in association with each other so as to be visible from the outside (for example, a personal information display unit that includes a monitor and displays the local address and personal information in association with each other on the monitor screen). 22 (corresponding to personal information display means), obtains measurement result information from the data control device 4 and displays it externally so as to be visible (for example, a monitor is provided and the measurement result information is displayed on a monitor screen). At the same time, the measurement result information and the personal information are transmitted to the DB server 3.
[0046]
  Here, a processing flow from when the measurement result information is obtained by the sensor unit 52 of the sensor unit 5 until it is stored in the DB server 3 will be briefly described. First, measurement result information is generated by the sensor unit 52 of the sensor unit 5. Then, measurement result information is transmitted from the sensor unit 5 to the measuring device 1 by the interface unit 51 of the sensor unit 5 and the interface unit 12 of the measuring device 1. Next, the measurement result information is transmitted from the measurement device 1 to the data control device 4 via the LAN 8 by the data transmission unit 11 of the measurement device 1 and the data transmission unit 42 of the data control device 4 in accordance with a request from the data control device 4. The Next, measurement result information is transmitted from the data control device 4 to the monitoring device 2 via the WWW 9 by the Internet connection unit 41 of the data control device 4 in accordance with a request from the monitoring device 2. Then, measurement result information is displayed on the monitor screen by the monitoring device 2. Next, measurement result information is transmitted from the monitoring device 2 to the DB server 3 via the WWW 9 and stored in the DB server 3.
[0047]
  Next, a processing flow from when personal information is read from the ID card 7 by the personal information reading unit 62 of the personal information processing unit 6 until it is stored in the DB server 3 will be briefly described. First, personal information is read from the ID card 7 by the personal information reading unit 62 of the personal information processing unit 6. Then, personal information is transmitted from the personal information processing unit 6 to the measuring device 1 by the interface unit 61 of the personal information processing unit 6 and the interface unit 12 of the measuring device 1. Next, the data transmission unit 11 of the measurement device 1 and the data transmission unit 42 of the data control device 4 measure personal information in association with the local address of the measurement device 1 according to a request from the data control device 4 via the LAN 8. The data is transmitted from the device 1 to the data control device 4. Next, personal information and a local address are transmitted from the data control device 4 to the monitoring device 2 via the WWW 9 by the Internet connection unit 41 of the data control device 4 in accordance with a request from the monitoring device 2. Then, the personal information display unit 22 of the monitoring device 2 displays the personal information in association with the local address on the monitor screen. Next, personal information and a local address are transmitted from the monitoring device 2 to the DB server 3 via the WWW 9 and stored in the DB server 3.
[0048]
  In this way, the measurement result information of the environmental state quantity by the sensor unit 5 attached to the measurement device 1 connected to the data control device 4 via the LAN 8 is grasped by the data control device 4 in a unified manner. And since the measurement result information by the sensor unit 5 is displayed by the monitoring device 2 so as to be visible from the outside, the measurement state can be easily monitored. Moreover, since the measurement result information by the sensor unit 5 is stored centrally by the DB server 3, data management is performed efficiently.
[0049]
  Further, since the measuring device 1 is connected so that the sensor unit 5 can be replaced, the connected sensor unit 5 is detached from the measuring device 1 and replaced with a sensor unit 5 that can measure a desired environmental state quantity. By mounting on the apparatus 1, the environmental state quantity as the measurement target can be changed. Therefore, it is possible to easily change the environmental state quantity as the measurement target.
[0050]
  Furthermore, since the measuring apparatus 1 is communicably connected to the personal information processing unit 6 and the sensor unit 5 and the personal information processing unit 6 are interchangeably connected, the personal information processing is performed instead of the sensor unit 5. By attaching the unit 6 to the measuring apparatus 1, personal information stored in the ID card 7 attached to the personal information processing unit 6 can be easily read out to the measuring apparatus 1. Since the personal information, which is information for identifying the individual stored in the ID card 7, and the local address of the measuring device 1 that has transmitted the personal information are associated with each other and displayed so as to be visible from the outside, the measuring device 1 It becomes possible to specify the person (the owner of the ID card 7) who has attached the ID card 7 to the personal information processing unit 6 attached to and the location.
[0051]
  In addition, since the measuring apparatus 1 can communicate with the personal information processing unit 6 and the sensor unit 5 and the personal information processing unit 6 can be exchanged, when measuring the environmental state quantity, the measuring apparatus 1 When the sensor unit 5 is attached to 1 and the arrangement of personnel is grasped, the personal information processing unit 6 is attached to the measuring apparatus 1 instead of the sensor unit 5 and the ID card 7 is attached to the personal information processing unit 6. That's fine. That is, the measurement of the environmental state quantity and the confirmation of the personnel arrangement can be easily and efficiently performed.
[0052]
  Returning again to FIG. The sensor unit 5 includes a sensor type storage unit 53 (corresponding to a sensor type storage unit) that stores sensor type information indicating the type of sensor (for example, a type such as a temperature sensor, a humidity sensor, or a human body detection sensor). The apparatus 1 includes a sensor type acquisition unit 13 (corresponding to a sensor type acquisition unit) that acquires the sensor type information of the connected sensor unit 5 and transmits it to the data control apparatus 4 via the LAN 8.eThe Then, the data control device 4 has an installation position storage unit 43 (corresponding to an installation position storage means) that stores installation position information indicating the installation position of the measuring apparatus 1 connected via the LAN 8 in association with a local address. The sensor type information from the sensor type acquisition unit 13 is received, the corresponding installation position information is read from the installation position storage unit 43 based on the local address, and the sensor type information and the installation position information are associated with each other to the monitoring device 2. An installation position associating unit 44 (corresponding to an installation position associating means) for transmission is provided. Further, the monitoring device 2 displays the sensor type information and the corresponding installation position information so as to be visible from the outside (for example, a monitor is provided and the sensor type information and the installation position information are displayed in association with each other on the monitor screen). ) An installation position display unit 21 (corresponding to installation position display means) is provided.
[0053]
  Here, a process flow from when the sensor type information is read from the sensor type storage unit 53 of the sensor unit 5 until it is stored in the DB server 3 will be briefly described. First, sensor type information stored in the sensor type storage unit 53 of the sensor unit 5 is read based on an instruction from the sensor type acquisition unit 13 of the measurement device 1, and measurement is performed with the interface unit 51 of the sensor unit 5. The read sensor type information is transmitted from the sensor unit 5 to the measuring apparatus 1 by the interface unit 12 of the apparatus 1. Next, the sensor type information is measured via the LAN 8 by the data transmission unit 11 of the measurement device 1 and the data transmission unit 42 of the data control device 4 based on an instruction from the installation position association unit 44 of the data control device 4. While being transmitted from the apparatus 1 to the data control apparatus 4, the corresponding installation position information is read from the installation position storage unit 43 based on the local address of the measurement apparatus 1, and the sensor type information and the installation position information are associated with each other. It is done. Next, according to a request from the monitoring device 2, sensor type information and installation position information are transmitted from the data control device 4 to the monitoring device 2 via the WWW 9 by the Internet connection unit 41 of the data control device 4. Then, the sensor type information and the installation position information are displayed on the monitor screen by the installation position display unit 21 of the monitoring device 2. Next, the sensor type information and the installation position information are transmitted from the monitoring device 2 to the DB server 3 via the WWW 9 and stored in the DB server 3.
[0054]
  FIG. 2 is an example of a screen diagram in which sensor type information and installation position information are displayed on the monitor of the monitoring device 2. (A) is a conceptual diagram of a cross section of a building in which the sensor unit 5 is arranged in each room, and (b) is a screen diagram on which sensor type information and installation position information are displayed for the building shown in (a). It is. As shown in (a), the building is a three-story building, and each floor has two rooms (total of six rooms) PA to PF, and the measuring devices 1a to 1f are provided in the rooms PA to PF, respectively. Is provided. The measuring devices 1a and 1f include CO₂Sensor units 5a and 5f having sensors for measuring the concentration are attached, and sensor units 5b and 5d having sensors for detecting a human body are attached to the measuring devices 1b and 1d, and the measuring devices 1c and 1e are attached to the measuring devices 1c and 1e. Sensor units 5c and 5e having sensors for measuring temperature are mounted.
[0055]
  As shown in (b), in the screen diagram 800, rooms 8PA to 8PF representing the rooms PA to PF of the building (a) are displayed in the approximate center of the screen, and installed in the rooms 8PA to 8PF. Marks 802 such as “Δ”, “◯”, etc., are displayed so that the types of sensors of the sensor units 5a to 5f can be identified. In the screen diagram 800, a legend display portion 803 indicating the meaning of the mark 802 is displayed on the right side of the screen. From the legend display unit 803, for example, a mark “◯” 802 indicates that a sensor unit including a sensor for measuring temperature is mounted, and a mark “802” indicates that the CO 2₂It can be seen that this indicates that a sensor unit having a sensor for measuring the concentration is attached. Therefore, it is possible to check the type of sensor of the sensor unit installed in each room of the building shown in FIG.
[0056]
  Again, returning to FIG. The data control device 4 includes a first correction information storage unit 45 (first correction unit) that stores first correction data that is set based on the environmental conditions in which the measuring device 1 is installed for each measuring device 1 connected via the LAN 8. Correction information storage means) and a first correction information change section 46 (first correction information change means) that receives external input and changes the first correction data stored in the first correction information storage section 45. The sensor unit 5 acquires the first correction data from the first correction information storage unit 45 via the LAN 8 and the measuring apparatus 1 and uses the acquired first correction data to obtain the sensor unit 5. Is provided with a first data correction unit 54 (corresponding to a first data correction means) for correcting the measurement result information.
[0057]
  The case where the sensor unit 5 includes a sensor for measuring the temperature and measures the indoor temperature will be specifically described. When the measuring device 1 to which the sensor unit 5 is mounted is installed at a position that is affected by heat (including radiant heat) from a heat source such as a light bulb or a boiler, if the influence is not corrected, the sensor 1 The temperature T which is measurement result information from the unit 5 becomes a value (T> T0) higher than the average indoor temperature T0, and the indoor temperature T0 which is the original purpose is not measured.
[0058]
  Therefore, a value defined by the following equation (1) is set as the first correction data ΔT stored in the first correction information storage unit 45.
ΔT = T0−T (1)
Then, the first data correction unit 54 corrects the temperature T that is measurement result information from the sensor unit 5 to a temperature T ′ defined by the following equation (2).
T ′ = T + ΔT (2)
In this way, the average indoor temperature can be measured by correcting the temperature T, which is measurement result information from the sensor unit 5, to the temperature T ′ defined by the equation (2).
[0059]
  In this way, the measurement result information is corrected by the sensor unit 5 using the first correction data set based on the environmental conditions in which the measurement apparatus 1 is installed, and therefore the measurement in which the sensor unit is mounted. Correction of measurement result information suitable for the environmental conditions in which the apparatus is installed (that is, the environmental conditions in which the sensor unit is installed) is performed.
[0060]
  Further, since the first correction information changing unit 46 of the data control device 4 accepts an input from the outside and changes the first correction data stored in the correction information storage unit 45, the appropriate first correction data Changes to are easily made. Furthermore, the first correction data set based on the environmental conditions in which the measuring device 1 is installed for each measuring device 1 connected via the LAN 8 is integrated into the first correction information storage unit 45 of the data control device 4. Therefore, the data is efficiently managed.
[0061]
  Although the case where the first data correction unit 54 corrects the measurement result information by the sensor unit 5 using the first correction data has been described here, the first data correction unit 54 uses the first correction data. The form which correct | amends the calibration data which is the data for calibrating the sensor which the sensor unit 5 has may be sufficient. In this case, correction of calibration data suitable for the environmental condition in which the measuring device to which the sensor unit is mounted is installed (that is, the environmental condition in which the sensor unit is installed) is performed.
[0062]
  Again, returning to FIG. The measuring device 1 determines whether or not the sensor unit 5 is mounted, and when the sensor unit 5 is mounted, the mounting determination unit 14 (mounting) that transmits sensor mounting information that is information to that effect to the data control device 4. (Corresponding to determination means). The data control device 4 includes an elapsed time measurement unit 47 (elapsed time) that counts elapsed time from the timing when the sensor unit 5 is attached to the measurement device 1 based on the sensor attachment information transmitted from the attachment determination unit 14 of the measurement device 1. And a second correction information storage unit 48 (corresponding to a second correction information storage unit) for storing second correction data set based on the elapsed time obtained by the elapsed time measurement unit 47 The second correction data sending section 49 (corresponding to the second correction data sending means) that reads the second correction data corresponding to the elapsed time by the elapsed time measuring section 47 from the second correction information storage section 48 and transmits it to the sensor unit 5. And). The sensor unit 5 acquires the second correction data from the second correction data sending unit 49 via the LAN 8 and the measuring apparatus 1 and calibrates the sensor of the sensor unit 5 using the acquired second correction data. A second data correction unit 55 (corresponding to a second data correction unit) that corrects the calibration data that is the above data.
[0063]
  The case where the sensor unit 5 includes a sensor for measuring humidity and measures indoor humidity will be specifically described. In general, a humidity sensor has a tendency to decrease measurement accuracy over time (as time elapses) due to dust or the like adhering to the sensor surface. Therefore, as described below, the calibration frequency is increased as time elapses.
[0064]
  First, as the second correction data stored in the second correction information storage unit 48, second correction data ΔT2 that decreases as the elapsed time T2 becomes longer is stored in advance. Then, the second data correction unit 55 uses the acquired second correction data ΔT2, and sets the calibration data so that the sensor of the sensor unit 5 is calibrated every time ΔT2 (= second correction data ΔT2) elapses. It shall be corrected. Here, it is assumed that the calibration data includes data defining the calibration frequency.
[0065]
  Thus, the elapsed time T2 from the timing when the sensor unit 5 is mounted on the measuring device 1 is counted by the elapsed time measuring unit 47, and the elapsed time by the elapsed time measuring unit 47 is counted by the second correction data sending unit 49. Second correction data ΔT2 corresponding to T2 is read from the second correction information storage unit 48 and transmitted to the sensor unit 5. The second data correction unit 55 of the sensor unit 5 acquires the second correction data ΔT2 from the second correction data sending unit 49 via the LAN 8 and the measuring device 1, and uses the acquired second correction data ΔT2 to obtain the time. The calibration data is corrected so that the sensor of the sensor unit 5 is calibrated every time ΔT2 (= second correction data ΔT2) elapses.
[0066]
  In this way, the longer the elapsed time T2 from when the sensor unit 5 is attached, the shorter the calibration period (= time ΔT2) (that is, the higher the calibration frequency), and thus the decrease in measurement accuracy is suppressed. The
[0067]
  As described above, it is data for calibrating the sensor of the sensor unit 5 using the second correction data set based on the elapsed time from the timing when the sensor unit 5 is mounted on the measuring device 1. Since calibration data is corrected, calibration data suitable for a change in characteristics over time of a sensor or the like of the sensor unit is corrected.
[0068]
  Here, the case where the data correction unit 55 of the sensor unit 5 corrects calibration data that is data for calibrating the sensor of the sensor unit 5 has been described. However, correction of measurement result information by the sensor unit 5 is described. The form which performs is also possible. In this case, correction of measurement result information suitable for changes in characteristics over time of a sensor or the like included in the sensor unit is performed.
[0069]
  Again, returning to FIG. When the data control device 4 receives sensor mounting information from the mounting determination unit 14 of the measuring device 1, the data control device 4 starts acquiring measurement result information for the measuring device 1 that has transmitted the sensor mounting information.
[0070]
  3 and 4 are explanatory diagrams illustrating an example of an operation of acquiring measurement result information from the measurement device 1 of the data control device 4. Here, for convenience, two measuring devices 1a and 1b are communicably connected to the data control device 4 via the LAN 8, and in the initial state, the two measuring devices 1a and 1b are connected to the sensor unit 5. A case where the sensor unit 5 is attached to the measuring apparatus 1b at a certain timing TC will be described. It is assumed that time has passed from the upper side to the lower side in the figure.
[0071]
  Here, the data control device 4 sends a “unit search signal” which is a signal requesting a response as to whether or not the sensor unit 5 is attached to the measuring devices 1a and 1b, and measurement result information by the sensor unit 5. A “measurement value request signal” requesting the transmission of is transmitted. On the other hand, when receiving the “unit search signal” from the data control device 4, the measuring devices 1a and 1b determine whether or not the sensor unit 5 is attached, and if the sensor unit 5 is attached, “Response (present)” is returned as sensor mounting information which is information to that effect, and “response (none)” is returned as information to that effect when the sensor unit 5 is not mounted. Further, upon receiving the “measurement value request signal” from the data control device 4, the measurement devices 1 a and 1 b return “response (measurement value)” as measurement result information by the sensor unit 5.
[0072]
  FIG. 3 is continued when the data control device 4 alternately transmits “unit search signals” to the measuring devices 1a and 1b, and “response (present)” is returned from the measuring devices 1a and 1b. In this mode, a “measurement value request signal” is transmitted to the measuring device.
[0073]
  FIG. 4 shows a mode in which the data control device 4 alternately transmits “unit search signals” or “measurement value request signals” to the measuring devices 1a and 1b. ”Is returned, the“ measurement value request signal ”is transmitted at the next transmission timing to the measurement apparatus.
[0074]
  As shown in FIG. 3 and FIG. 4, when the sensor unit 5 is not attached to the measuring apparatus 1, the sensor attachment information is not received by the data control apparatus, and therefore the measurement result information is acquired by the data control apparatus 5. I can't. That is, only the measuring device 1 that needs to acquire the measurement result information (that is, the measuring device 1 in which the sensor unit 5 is mounted) among the measuring devices 1 connected via the LAN 8 by the data control device 4. Since the measurement result information is acquired, the measurement result information is efficiently acquired.
[0075]
  Again, returning to FIG. When the data control device 4 receives the sensor mounting information from the mounting determination unit 14 of the measuring device 1, the data control device 4 sets the acquisition frequency of the measurement result information with respect to the normal acquisition frequency for the measuring device 1 that has transmitted the sensor mounting information. It is increased for a predetermined period.
[0076]
  FIG. 5 is an explanatory diagram illustrating an example of an operation of acquiring measurement result information from the measurement device 1 of the data control device 4. Here, for convenience, two measuring devices 1a and 1b are communicably connected to the data control device 4 via the LAN 8, and in the initial state, the two measuring devices 1a and 1b are connected to the sensor unit 5. A case where the sensor unit 5 is attached to the measuring apparatus 1b at a certain timing TC will be described. It is assumed that time has passed from the upper side to the lower side in the figure.
[0077]
  Here, “unit search signal” and “measurement value request signal” that are signals from the data control device 4 to the measurement devices 1a and 1b, and “response (present) that is a signal from the measurement devices 1a and 1b to the data control device 4”. ) ”,“ Response (none) ”, and“ response (measured value) ”are the same as those in FIGS.
[0078]
  FIG. 5 shows that the data control device 4 alternately sends “unit search signal” to the measurement devices 1a and 1b until “response (present)” is returned from the measurement device 1a or measurement device 1b. ”Is transmitted, and when“ response (present) ”is returned from the measurement apparatuses 1a and 1b, a“ measurement value request signal ”is continuously transmitted to the measurement apparatus. Then, the transmission frequency of the “measurement value request signal” to the measurement device (here, the measurement device 1b) to which “response (present)” is returned is set to the measurement device (here, “response (present)” is not returned). This is a mode in which the transmission frequency of the “unit search signal” to the measuring device 1a) is doubled. The period for increasing the frequency is not shown, but is a predetermined period (for example, 10 seconds).
[0079]
  When the sensor unit 5 is newly attached to the measuring apparatus 1, or the sensor unit 5 is once removed from the measuring apparatus 1 for some reason, and then (or another sensor unit 5) is attached to the measuring apparatus 1 again. In such a case, the measurement result may not be stable for a predetermined period. In such a case, as shown in FIG. 5, since the acquisition frequency of the measurement result information is increased by a predetermined period (a period until the measurement result is stabilized) with respect to the normal acquisition frequency, the measurement is performed by the monitoring device 2 or the like. It is possible to accurately determine whether or not the result is stable.
[0080]
  In addition, this invention can take the following forms.
[0081]
  (A) In the present embodiment, the case where the monitoring device 2 includes the installation position display unit 21 and the personal information display unit 22 has been described. However, the DB server 3 includes at least one of the installation position display unit 21 and the personal information display unit 22. The form provided with.
[0082]
  (B) Although the case where the data control device 4 includes the first correction information storage unit 45 has been described in the present embodiment, the measurement device 1 may include the first correction information storage unit 45.
[0083]
【The invention's effect】
  According to the first aspect of the present invention, since the measuring device is connected so that the sensor unit can be exchanged, the environmental state quantity as the measurement target can be easily changed.. Further, correction of measurement result information by the sensor unit (or calibration of the sensor of the sensor unit is calibrated) using second correction data set based on the elapsed time from the timing when the sensor unit is mounted on the measuring device. Therefore, correction of measurement result information (or correction of calibration data) suitable for changes in characteristics over time of the sensor or the like of the sensor unit is performed.
[0084]
  According to the second aspect of the present invention, since the measurement result information by the sensor unit is displayed by the monitoring device so as to be visible from the outside, the measurement state can be easily monitored. Moreover, since the measurement result information by the sensor unit is stored centrally by the database server device, data management can be performed efficiently.
[0085]
  According to the third aspect of the present invention, since the sensor type of the sensor unit connected to the measuring device and the installation position thereof are displayed in association with each other, even when the sensor unit is replaced, Thus, it is possible to easily confirm the type and installation position of the sensor connected to the measuring apparatus.
[0086]
  According to the fourth and fifth aspects of the present invention, the first correction data set based on the environmental condition in which the measuring device is installed is used to correct the measurement result information by the sensor unit (or the sensor of the sensor unit). Correction of calibration data, which is data for calibrating the measurement unit), correction of measurement result information (or correction of calibration data) suitable for the environmental conditions in which the measurement device on which the sensor unit is mounted is installed. Can be done.
[0087]
  Claim6According to the invention described in (3), the operation of acquiring the measurement result information is performed by the data control device only for the measurement devices that need to acquire the measurement result information among the measurement devices connected via the local area network. As a result, measurement result information can be efficiently acquired.
[0088]
  Claim7When the sensor unit is newly attached to the measuring device, the acquisition frequency of the measurement result information is increased by a predetermined period (a period until the measurement result is stabilized) with respect to the normal acquisition frequency. Therefore, it is possible to accurately determine whether or not the measurement result is stable by a monitoring device or the like.
[0089]
  Claim8According to the invention described in the above, the personal information, which is information for identifying the individual stored in the personal information storage means, and the local address of the measuring device that has received the personal information are associated with each other and displayed in a visible manner from the outside. Therefore, the person and the place where the personal information storage means is attached to the personal information processing unit attached to the measuring apparatus can be specified.
[Brief description of the drawings]
FIG. 1 is an example of a configuration diagram showing a configuration of an environmental state quantity measurement monitoring system according to the present invention.
FIG. 2 is an example of a screen diagram in which sensor type information and installation position information are displayed on a monitor of a monitoring device.
FIG. 3 is an explanatory diagram illustrating an example of an operation of acquiring measurement result information from a measurement device of the data control device.
FIG. 4 is an explanatory diagram illustrating an example of an operation of acquiring measurement result information from a measurement device of the data control device.
FIG. 5 is an explanatory diagram showing an example of an operation of acquiring measurement result information from the measurement device of the data control device.
FIG. 6 is an example of a configuration diagram of a conventional environmental state quantity measurement and monitoring system.
[Explanation of symbols]
  1 Measuring device
  11 Data transmission part
  12 Interface section
  13 Sensor type acquisition part (equivalent to sensor type acquisition means)
  14 Wear determination unit (corresponds to wear determination means)
  2 Monitoring device
  21 Installation position display section (equivalent to installation position display means)
  22 Personal information display (equivalent to personal information display means)
  3 DB server (database server device)
  4 Data controller
  41 Internet connection
  42 Data transmission unit
  43 Installation position storage unit (equivalent to installation position storage means)
  44 Installation position association unit (equivalent to installation position association means)
  45 1st correction information storage part (equivalent to 1st correction information storage means)
  46 1st correction information change part (equivalent to 1st correction information change means)
  47 Elapsed time measuring unit (equivalent to elapsed time measuring means)
  48 2nd correction information storage part (equivalent to 2nd correction information storage means)
  49 2nd correction data sending part (equivalent to 2nd correction data sending means)
  5 Sensor unit
  51 Interface section
  52 Sensor unit
  53 Sensor type storage unit (equivalent to sensor type storage means)
  54 1st data correction part (equivalent to 1st data correction means)
  55 Second data correction unit (corresponding to second data correction means)
  6 Personal information processing unit
  61 Interface section (equivalent to personal information transmission means)
  62 Personal information reading unit (equivalent to personal information reading means)
  7 ID card (equivalent to personal information storage means)
  8 LAN (Local Area Network)
  9 WWW (Internet)

Claims (8)

An environmental state quantity measurement monitoring system for measuring an environmental state quantity representing an environmental state and monitoring the measurement state,
A sensor unit having a sensor and measuring an environmental quantity;
A measurement device that is communicably connected to the sensor unit, is connected to be exchangeable with the sensor unit, and acquires measurement result information of the environmental state quantity from the sensor unit,
A data control device that is communicably connected to the measurement device via a local area network and acquires the measurement result information from the measurement device ;
The measurement apparatus further includes a mounting determination unit that determines whether or not the sensor unit is mounted and transmits sensor mounting information that is information to that effect to the data control device when the sensor unit is mounted. ,
The data control device includes an elapsed time measuring unit that counts an elapsed time from a timing at which the sensor unit is attached to the measurement device based on the sensor attachment information, and a second correction that is set based on the elapsed time. Second correction information storage means for storing data, and second correction data transmission for reading out the second correction data corresponding to the elapsed time by the elapsed time measuring means from the second correction information storage means and transmitting it to the sensor unit And further comprising means,
The sensor unit acquires the second correction data from the second correction data sending means via a local area network and the measurement device, and measurement result information by the sensor unit using the acquired second correction data correction and further comprising measuring monitoring system environment state quantity, wherein Rukoto the second data correction means for performing at least one of correction of the calibration data is a data for calibrating a sensor having the said sensor unit. A monitoring device that is communicably connected to the data control device via the Internet, acquires the measurement result information from the data control device, and displays the acquired measurement result information so as to be visible from the outside;
The environmental state quantity measurement according to claim 1, further comprising a database server device that is communicably connected to the monitoring device via the Internet and that acquires and stores the measurement result information from the monitoring device. Monitoring system. The sensor unit includes sensor type storage means for storing sensor type information representing the type of sensor,
The measurement device includes sensor type acquisition means for acquiring sensor type information of a connected sensor unit and transmitting the information to the data control device via a local area network.
The data control apparatus includes an installation position storage unit that stores installation position information representing an installation position of a measurement apparatus connected via a local area network in association with a local address, and sensor type information from the sensor type acquisition unit. Installation position associating means for reading out the corresponding installation position information based on the local address from the installation position storage means, and associating the sensor type information and the installation position information to the monitoring device,
3. The environment according to claim 2, wherein at least one of the monitoring device and the database server device includes an installation position display unit that displays sensor type information and corresponding installation position information so as to be visible from the outside. State quantity measurement monitoring system. The measurement apparatus includes first correction information storage means for storing first correction data set based on an environmental condition in which the measurement apparatus is installed,
The sensor unit acquires the first correction data from the first correction information storage unit, uses the acquired first correction data to correct the measurement result information by the sensor unit and calibrate the sensor of the sensor unit. The environmental state quantity measurement and monitoring system according to any one of claims 1 to 3, further comprising a first data correction unit that performs at least one of correction of calibration data that is data to be performed. The data control device includes first correction information storage means for storing first correction data that is set based on an environmental condition in which the measurement device is installed for each measurement device connected via a local area network, and externally. And first correction information changing means for changing the first correction data stored in the first correction information storage means.
The sensor unit acquires the first correction data from the first correction information storage unit via a local area network and the measurement device, and uses the acquired first correction data to transmit measurement result information of the sensor unit. The first data correction means for performing at least one of correction and correction of calibration data, which is data for calibrating the sensor of the sensor unit, according to any one of claims 1 to 3, Environmental state quantity measurement and monitoring system. Wherein the data control device, when receiving the sensor mounting information, the measurement apparatus that has transmitted the sensor mounting information, the environmental state quantity according to claim 1, characterized in that starting the acquisition of the measurement result information Measurement monitoring system. When the sensor mounting information is received, the data control device increases the acquisition frequency of the measurement result information for a predetermined period with respect to the normal acquisition frequency for the measuring device that has transmitted the sensor mounting information. The measurement and monitoring system for an environmental state quantity according to claim 1 or 6 . Personal information that is communicably connected to personal information storage means storing personal information that is information for identifying an individual, and that is connected to be exchangeable with the personal information storage means, and reads personal information from the personal information storage means A personal information processing unit comprising reading means and personal information transmission means for transmitting the read personal information to the measuring device;
The measuring device is communicably connected to the personal information processing unit, and the sensor unit and the personal information processing unit are interchangeably connected. When the personal information is received, a local area network is connected. Sending the personal information to the data control device via
When the data control device receives the personal information, the local address of the measuring device that has received the personal information is associated with the personal information and transmitted to the monitoring device.
The at least one of the monitoring device and the database server device includes personal information display means for displaying a local address and the personal information in association with each other so as to be visible from the outside. Monitoring system for environmental state quantity.

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