JP2017046180A - Remote monitoring system - Google Patents

Abstract

In a remote monitoring system operated based on a dynamic IP address, the state of a monitored device is directly acquired at an arbitrary timing without imposing an excessive load on the entire system. A sensor terminal 104 is given a dynamic IP address of the Internet 106 and detects state data of a power generation apparatus 102. The monitoring server 108 and the monitoring terminal 110 are connected to the sensor terminal 104 via the Internet 106. The sensor terminal 104 periodically transmits state data to the monitoring server 108 together with the terminal ID of the sensor terminal 104. The monitoring server 108 holds the terminal ID, the state data, and the dynamic IP address of the sensor terminal 104 in association with each other. When a query specifying the terminal ID is received from the monitoring terminal 110, the monitoring terminal 110 receives the sensor corresponding to the terminal ID. The dynamic address of the terminal 104 is returned. [Selection] Figure 1

Description

  The present invention relates to a technique for remotely monitoring the operation of a power generation device or the like.

  Many companies have their own power generation and storage devices such as solar cells, lithium ion secondary batteries, and gas turbine generators. With the spread of private power generation, there is a growing need to entrust external specialists to monitor and manage power generation resources.

  In Patent Document 1, an elevator is monitored, but an elevator monitoring device transmits elevator status data to an information center via an analog telephone network and the Internet. With this configuration, the information center can remotely monitor the elevator.

JP 2006-290523 A

  Since a global IP (Internet Protocol) address (static IP address) is valuable, the monitoring device of Patent Document 1 is identified by a dynamic IP address. A new dynamic IP address is reassigned when the session between the monitoring apparatus and the information center is terminated. Therefore, the monitoring device of Patent Document 1 itself detects a change in the dynamic IP address, and notifies the information center of the new dynamic IP address when the change occurs.

  However, making all of the monitoring devices detect the change of the dynamic IP address and notifying the information center of the change tends to be a cost increase factor for the entire remote monitoring system. Further, there may be a situation in which it is desired to directly acquire the status data of the monitoring target device from a device other than the information center as necessary.

  The present invention has been made in view of such a situation, and the main object of the present invention is a remote monitoring system operated on the basis of a dynamic IP address, without overloading the entire system. The object is to provide a technique for enabling a state to be directly acquired at an arbitrary timing.

A remote monitoring system according to an aspect of the present invention includes a sensor terminal that is assigned a dynamic address of a communication network and detects status data of a device to be monitored, and a monitoring server that is connected to the sensor terminal via the communication network And a monitoring terminal.
The sensor terminal periodically transmits the status data together with the terminal ID of the sensor terminal to the monitoring server, and the monitoring server associates the terminal ID, the status data, and the dynamic address of the sensor terminal with each other. When the query specifying the terminal ID is received from the monitoring terminal, the dynamic address of the sensor terminal corresponding to the terminal ID is returned to the monitoring terminal.

  The monitoring server can easily acquire the latest dynamic address of the sensor terminal by periodically communicating with the sensor terminal. For this reason, the monitoring terminal makes an inquiry to the monitoring server to acquire the latest dynamic address of the sensor terminal, so that the monitoring terminal can easily access the sensor terminal at an arbitrary timing.

  According to the present invention, in a remote monitoring system operated based on a dynamic IP address, the state of a monitoring target device can be directly acquired at an arbitrary timing without imposing an excessive load on the entire system.

It is a hardware block diagram of a remote monitoring system. It is a sequence diagram which shows the communication process in a remote monitoring system. It is a data structure figure of the log which a monitoring server has.

FIG. 1 is a hardware configuration diagram of the remote monitoring system 100.
The remote monitoring system 100 includes one or more power generation devices 102 (monitored devices), one or more sensor terminals 104 connected to each power generation device 102, a monitoring server 108 connected to the sensor terminal 104 via the Internet 106, and monitoring. A terminal 110 is included. The monitoring server 108 and the monitoring terminal 110 are operated by a specialist who collectively manages one or more power generation devices 102.

  The power generation apparatus 102a is a power generation resource possessed by a certain company A, and the power generation apparatus 102b is a power generation resource possessed by another company B. The power generation devices 102a and 102b may be various power generation resources (or capacitors) such as a gas turbine generator, a solar battery, a lithium ion secondary battery, and a fuel cell. The sensor terminal 104a is a sensor that detects state data of the power generation apparatus 102a. The sensor terminal 104b is a sensor that detects state data of the power generation apparatus 102b. That is, the company A has the power generation device 102a, and the state data of the power generation device 102a is sensed by the sensor terminal 104a. When the power generation device 102a and the power generation device 102b are not particularly distinguished, they are simply expressed as “power generation device 102”, and when the sensor terminal 104a and the sensor terminal 104b are not particularly distinguished, they are simply expressed as “sensor terminal 104”.

  The sensor terminal 104 may be a separate device (for example, a personal computer) from the power generation device 102, or may be configured as an IC (Integrated Circuit) chip mounted on the power generation device 102. The sensor terminal 104 periodically acquires the status data of the power generation apparatus 102 and transmits the status data to the monitoring server 108 via the Internet 106. In the present embodiment, the sensor terminal 104 senses and transmits state data once per minute. The state data may be information indicating the control state and output state of the power generation apparatus 102 such as the amount of power generation, the amount of electricity stored, the amount of discharge, the environmental temperature, and the continuous operation time.

  The monitoring server 108 receives the status data sent from the sensor terminals 104 of a plurality of companies and records it in a log (see also FIG. 3 for the log). The monitoring server 108 may provide various additional services such as shaping this log and displaying it on the screen, or showing the transition of power generation / storage of each company or each power generation apparatus 102.

A “terminal ID” is assigned to the sensor terminal 104. The terminal ID is a unique and fixed ID for the sensor terminal 104, and the monitoring server 108 and the monitoring terminal 110 know the terminal ID of each sensor terminal 104 in advance.
The terminal ID may be given as an ID for identifying the power generation apparatus 102 instead of the sensor terminal 104. When one company has one sensor terminal 104, the terminal ID may be a company ID. In the present embodiment, the terminal ID identifies the sensor terminal 104, but since the sensor terminal 104 and the power generation apparatus 102 have a one-to-one correspondence, the terminal ID also identifies the power generation apparatus 102.

  The sensor terminal 104 is given a dynamic IP address from a provider (not shown) of the Internet 106. The monitoring server 108 is identified by a static IP address. The monitoring server 108 may also be assigned a dynamic IP address by management of DDNS (Dynamic Domain Name System).

FIG. 2 is a sequence diagram showing a communication process in the remote monitoring system 100.
Here, the sensor terminal 104a which the company A has among the sensor terminals 104 is illustrated as a representative. The sensor terminal 104a detects the status data every minute, and transmits the status data together with the terminal ID to the monitoring server 108 (S10). The monitoring server 108 can know the dynamic IP address (source address) of the sensor terminal 104a from the IP packet. The monitoring server 108 associates the terminal ID, the dynamic IP address, and the status data and records them in a log on a recording medium such as a hard disk (S12).

  When one minute has elapsed, the sensor terminal 104a newly detects the state data again, and transmits the new state data together with the terminal ID to the monitoring server 108 (S14). The monitoring server 108 associates the terminal ID, the dynamic IP address, and the status data and records them again in the log (S16). By repeating such processing, the status data of the sensor terminal 104a is accumulated in the monitoring server 108. The dynamic IP address may change midway, but the terminal ID is a unique value and does not change.

  There is a case where it is desired to monitor the sensor terminal 104a in real time at an arbitrary timing without being restricted by the time interval of once per minute as described above. At this time, the monitoring terminal 110 may establish a session directly with the sensor terminal 104a. However, the monitoring terminal 110 knows the terminal ID of the sensor terminal 104a, but does not know the latest dynamic IP address.

  Therefore, the monitoring terminal 110 first transmits a query to the monitoring server 108 using the terminal ID of the sensor terminal 104a to be monitored in real time as a parameter (S18). The monitoring server 108 refers to the log and notifies the monitoring terminal 110 of the latest dynamic IP address associated with this terminal ID (S20). The monitoring terminal 110 makes a connection request to the sensor terminal 104a with this dynamic IP address as a destination (S22). The sensor terminal 104a transmits the status data together with the terminal ID to the monitoring terminal 110 (S24). Thereafter, the monitoring terminal 110 can request status data from the sensor terminal 104 at an arbitrary timing. Further, the sensor terminal 104a may acquire the state data every time interval shorter than 1 minute, for example, every second and continuously transmit it to the monitoring terminal 110.

FIG. 3 is a data structure diagram of the log 112 included in the monitoring server 108.
In addition to the terminal ID, the dynamic IP address, and the status data, the log 112 also records the date and time of reception of the status data. In the log 112 shown in FIG. 3, the power generation (kwh) of the power generator 102 is recorded as state data.

  In FIG. 3, the dynamic IP address (219.99.152.xxx) and the generated power 3.7 (kwh) are notified from the sensor terminal 104 (terminal ID: 042) at 23:04:27 (t1). Has been. Five seconds later, at 23:04:32, another sensor terminal 104 (terminal ID: 084) notifies the dynamic IP address (2199.76.143.xxx) and the generated power 5.2 (kwh). Has been.

  The sensor terminal 104 (terminal ID: 042) again receives the dynamic IP address (219.99.152.1) at 23:05:27 (t2), one minute after 23:04:27 (t1). xxx) and the generated power 3.8 (kwh). Furthermore, at 23:06:27 (t3), one minute later, the sensor terminal 104 (terminal ID: 042) receives the dynamic IP address (144.196.43.xxx) and the generated power 4.2 (kwh). Notice. That is, the dynamic IP address of the sensor terminal 104 (terminal ID: 042) changes between time t2 and time t3. This is considered to be because the session was temporarily disconnected for some reason such as restart of the sensor terminal 104 (terminal ID: 042).

  When the monitoring terminal 110 inquires of the monitoring server 108 about the dynamic IP address of the sensor terminal 104 (terminal ID: 042) before the time t3, the monitoring server 108 determines the dynamic IP address (219.99.152.xxx). Reply. When the monitoring terminal 110 inquires of the monitoring server 108 about the dynamic IP address of the sensor terminal 104 (terminal ID: 042) after the time t3, the monitoring server 108 determines the dynamic IP address (144.196.43.xxx). Reply.

The remote monitoring system 100 has been described above based on the embodiment.
In this embodiment, it is not necessary to impose an obligation to report the change of the dynamic IP address to the sensor terminal 104. Since the sensor terminal 104 periodically reports the status data to the monitoring server 108, the monitoring server 108 can know the latest dynamic IP address of the sensor terminal 104. The monitoring terminal 110 can know the latest dynamic IP address of the sensor terminal 104 at any time by making an inquiry to the monitoring server 108 using the terminal ID as a key.

  The monitoring server 108 connected to many sensor terminals 104 regularly monitors the state of each power generation apparatus 102 at a relatively low frequency of once per minute. When more precise monitoring is required at a higher frequency, the monitoring staff can directly access the monitoring target sensor terminal 104 (power generation apparatus 102) from the monitoring terminal 110 at an arbitrary timing. Therefore, real-time monitoring can be performed as necessary while performing constant monitoring.

  In addition, since the monitoring terminal 110 can directly access the sensor terminal 104 without relaying the monitoring server 108, there is also an advantage that no load is applied to the monitoring server 108 at this time.

  The present invention has been described based on the embodiments. The embodiments are exemplifications, and it will be understood by those skilled in the art that various modifications can be made to combinations of the respective constituent elements and processing processes, and such modifications are within the scope of the present invention. .

  In the present embodiment, the description has been made on the assumption that the Internet and the IP address are used. However, the present invention is also applied to a situation in which a communication address is dynamically assigned in a communication network other than the Internet (for example, an intranet or a LAN (Local Area Network)). Is applicable.

  100 remote monitoring system, 102 power generation device, 104 sensor terminal, 106 internet, 108 monitoring server, 110 monitoring terminal, 112 log.

Claims (1)

A sensor terminal which is given a dynamic address of a communication network and detects status data of a monitored device;
A monitoring server and a monitoring terminal connected to the sensor terminal via the communication network;
The sensor terminal periodically transmits the status data together with the terminal ID of the sensor terminal to the monitoring server,
The monitoring server holds the terminal ID, the state data, and the dynamic address of the sensor terminal in association with each other, and when receiving a query designating the terminal ID from the monitoring terminal, the monitoring server sets the terminal ID to the terminal ID. A remote monitoring system which returns a dynamic address of the corresponding sensor terminal.

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