JP2005261094A - Non-interruptible power supply device management system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily reconstruct system constitution information that have been changed by replacement or the like of an apparatus connected to a UPS. <P>SOLUTION: When replacing the apparatus connected to the UPS 12A, it is detected that a new apparatus 11M has been connected to the UPS 12A by a UPS sub-machine agent 14A, and the information of the apparatus 11M is obtained. Then, the apparatus information is transferred to a component checker 15A, the component checker 15A re-constructs system constitution data on the basis of the obtained apparatus information, and the data are transferred to a data collection part 16A and held. The data collection part 16A transmits new system constitution information data to a UPS state indicating part 17, and also transfers them to a system manager, a support center and the like. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention manages the operation state and setting state of each uninterruptible power supply when multiple uninterruptible power supply units that back up the power supply in the event of a power failure are used in one system such as a communication system. The present invention relates to an uninterruptible power supply management system managed by software.

In a system that manages multiple uninterruptible power supplies (hereinafter referred to as UPS) as a group unit, when a location change of a UPS or a device connected to the UPS or a failure of a device occurs, the addition of a device, device information Work such as changing the device or replacing a failed device.
Accordingly, when changing the system configuration information monitored and managed by the management software, it is necessary to investigate the actual system configuration by the user and reconstruct the system configuration information on the management software side.

  Therefore, as a conventional uninterruptible power supply management system, the network adapter attached to the uninterruptible power supply periodically transmits the operating state of the load device of the uninterruptible power supply to the host controller via the network. Thus, it is known that the latest operating state information is always sent and the uninterruptible power supply and the load device are centrally managed in the host controller (see, for example, Patent Document 1).

In addition, by periodically transmitting information indicating the connection relationship of the uninterruptible power supply from the uninterruptible power supply device or the communication terminal that manages the uninterruptible power supply device to the upper computer terminal, the connection relationship is indicated at the upper computer terminal. It is known to centrally manage information. In such a conventional device, for example, once the uninterruptible power supply is installed, even if the connection relationship is changed, the updated connection is only required if the uninterruptible power supply or the communication terminal is connected to the network again. Information indicating the relationship can be transmitted to the host computer terminal (see, for example, Patent Document 2).
JP 2003-216285 A (Means for solving the problems) JP 2003-348772 A (Means for Solving the Problems)

However, in the conventional uninterruptible power supply management system, the system configuration information cannot be restored on the management system side when the computer goes down or the system configuration information is destroyed for some reason. However, there is an unsolved problem that it is necessary to investigate and reconstruct the system by the user's hand.
Therefore, the present invention has been made paying attention to the unsolved problems of the above-described conventional example, and monitors and manages the system configuration information in the management system, and the system configuration information on the management system side as necessary. An object is to provide an uninterruptible power supply management system that can be restored.

  To achieve the above object, an uninterruptible power supply management system according to claim 1 of the present invention receives information indicating the state of the uninterruptible power supply and manages the uninterruptible power supply one-on-one. Inquiries to the management means, equipment connected to the uninterruptible power supply, receives information indicating the status of the equipment and manages the equipment, and at least one or more of the grouped A system comprising the state information by receiving the state information of the uninterruptible power supply managed by the UPS management unit and the state information of the device managed by the device management unit. The system configuration management means for managing the configuration information and the mutually connected one another are set in either parent-child relationship, and the child stores the system configuration information managed by the system configuration management means. It is characterized in that transferred to the parent, and a data acquisition unit that manages the transfer system information parents while.

  In the first aspect of the present invention, the status information of the uninterruptible power supply managed by each UPS management unit and the status information of the device managed by each device management unit are temporarily stored by the child data collection unit. Since the data is collected by the parent data collection means, all the uninterruptible power supply units can be indirectly managed by the parent data collection means. For example, when the system configuration information is changed due to replacement of equipment connected to the uninterruptible power supply, etc. Since a change in information is detected and the system configuration data is reconstructed by the system configuration management means, the reconfiguration operation can be performed without investigating the actual system configuration by the user.

Further, the uninterruptible power supply management system according to claim 2 is the invention according to claim 1, wherein the child data collection means collects system configuration information collected from the system configuration management means at least with a system administrator and support. It is configured to transmit / receive to / from any of the centers.
In the invention according to claim 2, since the system configuration information is transferred to a third-party system administrator or support center, even if the system configuration information is destroyed for some reason, the system configuration information is transferred to the third party. The system configuration can be restored by downloading the system configuration information via the network.

An uninterruptible power supply management system according to claim 3 is the invention according to claim 1 or 2, wherein the uninterruptible power supply management system is connected to the data collecting means and based on the system configuration information collected by the data collecting means. It is characterized by comprising display means for displaying the states of the power failure power supply device, the equipment, the UPS management means, the equipment management means, the system configuration management means, and the data collection means.
In the invention according to claim 3, since the system components are displayed on the display means, for example, when the system configuration is changed by adding or replacing the equipment connected to the uninterruptible power supply, the user Can visually recognize it. Therefore, it is not necessary for the user to investigate the actual system configuration, and the system reconstruction work can be easily performed.

According to the first aspect of the present invention, the system configuration information is monitored and managed on the management software side. Therefore, every time the system configuration changes, the user performs all investigations of the actual system and reconstruction of the configuration information. This eliminates the need for the system configuration information and facilitates the reconstruction of the system configuration information.
In addition, since the system configuration information is managed by grouping management software, it is possible to reduce and transfer damage when damage occurs compared to the case where all management is performed with one software. It is possible to reduce the problem of communication traffic due to an increase in the amount of data and further reduce the server load.

Furthermore, according to the invention according to claim 2 of the present invention, when the system configuration information is destroyed for some reason, the system configuration information transferred to a third party such as a system administrator or a support center is managed. Since the software is downloaded via the network, the system configuration information can be easily restored based on the data.
Further, according to the invention according to claim 3 of the present invention, since the function of displaying the state of the uninterruptible power supply and the devices connected thereto is provided, when the system configuration is changed, the target change The information can be notified to the user, and the effect that the system configuration information can be easily reconstructed can be obtained.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a configuration diagram of an uninterruptible power supply management system according to an embodiment of the present invention.
The uninterruptible power supply management system includes a UPS (Uninterruptible Power Supply), a device connected to the UPS, a UPS agent as a UPS management unit, a UPS submachine agent as a device management unit, a system A component checker as a configuration management unit, a data collection unit as a data collection unit, and a UPS status display unit as a display unit are provided.

The UPS agent, the data collection unit, the UPS status display unit, and the UPS submachine agent are configured to operate on a computer connected on the network. The component checker is configured to operate on a computer in which a data collection unit is installed.
Specifically, as shown in FIG. 1, the devices 11A to 11C are connected to the UPS 12A, and the devices 11D to 11F are connected to the UPS 12B. Further, the UPS 12A and the UPS agent 13A, and the UPS 12B and the UPS agent 13B are connected one-to-one with a serial cable, wireless, USB, LAN, or the like.

The UPS agents 13A and 13B perform one-to-one communication with the UPS connected to the UPS agents 13A and 13B, receive UPS status information, and manage the UPS status. The UPS status information received from the UPS is configured to be transferred to a component checker 15A described later.
The UPS submachine agent uses UPS agents or power line communication to communicate with devices connected to the UPS, and acquires device status information. The UPS submachine agent 14A then counts the number of devices connected to the UPS 12A, the IP address set for each device, and various detailed information on the devices (11A to 11C) (for example, the device type and device). The actual power amount, connection date, failure information, etc.) are acquired, and the information is transferred to the component checker 15A described later.

Similarly, the UPS submachine agent 14B acquires the number of devices connected to the UPS 12B, the IP addresses set for each device, and various pieces of detailed information on the devices (11D to 11F). Transfer to checker 15A.
Here, it is assumed that the UPS submachine agent is operable on the same computer on which the UPS agent is operating or a computer connected to the network.
Therefore, it operates on a computer connected to the network like the UPS submachine agent 14C, and communicates with the devices 11G to 11I connected to the UPS 12C and the devices 11J to 11L connected to the UPS 12D, and the status of each device It is also possible to obtain information.

  The component checker 15A communicates with the UPS agents 13A and 13B and UPS submachine agents 14A and 14B managed in units of groups, and various UPS agent information (for example, registered in the group) from the UPS agents 13A and 13B. The number of the UPS agents, the IP address, and the UPS model managed by the UPS agent) are acquired, and various information on the devices 11A to 11F is acquired from the UPS submachine agents 14A and 14B. The system configuration information obtained by processing these pieces of information is transferred to the data collection unit 16A.

  The data collection unit 16A holds the system configuration information transferred from the component checker 15A and transfers the system configuration information to a system administrator or support center as a third party. Furthermore, as will be described later, when the system configuration information is destroyed for some reason, the system configuration can be reconstructed by downloading the system configuration information transferred to the system administrator or the support center. .

Further, a parent-child relationship is set in the data collection units 16A to 16C, and the data collection units 16A and 16B are children and the data collection unit 16C is a parent. Communication is performed between the data collection units 16A and 16C and between the data collection units 16B and 16C, and the parent collects each state information from the child.
In addition, the UPS status display unit 17 sequentially communicates with the data collection units 16A to 16C, and the statuses of the UPSs 12A to 12D and the devices 11A to 11A based on the status information collected by the data collection units 16A to 16C. It has a user interface that can display the state of 11L and can perform operations on the displayed UPSs 12A to 12D.

The user performs an operation (system configuration tree) for theoretically grouping a plurality of UPSs and devices connected to the UPSs on the UPS state display unit 17. FIG. 2 is a diagram illustrating an example of a system configuration tree.
The information configured in this way is stored as system configuration information. As shown in FIG. 3, the system configuration information includes information for specifying the type of device connected to the UPS from the UPS submachine agent, and the type of UPS agent that manages the UPS from the UPS agent. And information for identification.

Next, in the uninterruptible power supply management system having such a configuration, system management when the system configuration information is changed by exchanging devices will be described.
Now, as shown in FIG. 4, it is assumed that the device 11C connected to the UPS 12A fails and is replaced with a new device 11M. In this case, first, the UPS submachine agent 14A detects that a new device is connected to the UPS 12A (S1), and acquires information on the new device 11M (S2).

As a method of acquiring the status information of each device, a method of communicating with each of the devices 11A to 11C and 11M and the UPS submachine agent 14A by setting a communication module (software) for a device having no communication function. Use. Device information is acquired by using SNMP or a unique protocol as a communication protocol.
As a method of detecting each device, a method in which the UPS submachine agent 14A that manages and monitors the device connected to the UPS 12A makes an inquiry by broadcast to each device and confirms the existence of the connected device. Is used.

Specifically, first, the IP address, port number, and the like set in the device are acquired, and the device information held by the UPS submachine agent 14A for the device that has acquired the device information. The data is compared with the acquired device information data.
If all the compared data match, it is recognized that the device already exists, and if they do not match, it is determined that a new device has been added (or a failure has occurred in the device itself).

As described above, when a new device is confirmed by the UPS submachine agent 14A, the device information acquired by the UPS submachine agent 14A is transferred to the component checker 15A (S3).
The component checker 15A reconstructs the system configuration data based on the acquired device information, and transfers the data to the data collection unit 16A (S4) and holds it. Then, new system configuration information data is transferred from the data collection unit 16A to the UPS status display unit 17 (S5).

  The component checker 15A has system configuration information data as a file, and holds two types of data, the previous data and the latest data. For example, as shown in FIG. 5, the system configuration is changed while data A is stored as the previous system configuration data and data B is the latest system configuration data, and new system configuration data C is detected. And In this case, the previous data A is discarded first, and then the data B held as the latest system configuration data is transferred as the previous system configuration data. After this data migration is completed, the newly detected system configuration data C is held as the latest system configuration data.

In this way, since the component checker holds two types of system configuration information data, the previous data and the latest data, when the system configuration is destroyed for some reason, the system configuration is restored by using the previous data. It becomes possible to do.
The system configuration information is transferred to the data collection unit every time the system configuration data is reconstructed by the component checker, and is automatically transferred from the data collection unit to a system administrator, a support center, or the like.

Next, system management when the UPS agent is stopped will be described.
Assume that the UPS agent 13A has stopped as shown in FIG. In this case, the component checker 15A inquires the state of the UPS agent 13A to the data collection unit 16A that monitors each UPS agent (S1). If the component checker 15A is really stopped, the component checker 15A itself makes an inquiry to the UPS agent 13A (S2).

When the component checker 15A confirms that the UPS agent 13A is stopped (S3), the component checker 15A can perform either manual shutdown or automatic shutdown in order to prevent dirty shutdown.
In the manual shutdown, first, the component checker 15A notifies the data collection unit 16A that the UPS agent 13A is stopped (S4). Then, when the information of the UPS agent 13A that the data collection unit 16A has matches the received notification information, the data collection unit 16A causes the UPS state display unit 17 to output a message that prompts the shutdown (S5). As a result, the user confirms this message and performs a shutdown operation on each of the devices 11A to 11C and the UPS submachine agent 14A (S6).

  On the other hand, in the automatic shutdown, the shutdown is performed without going through the UPS status display unit 17. Specifically, when the stop state of the UPS agent 13A is detected as described above, the component checker 15A uses the system configuration information held by itself to the devices 11A to 11C and the UPS submachine agent 14A. Shutdown is automatically started (S7, S8).

Next, a case where system configuration information destroyed due to some cause is restored will be described.
Restoring the system configuration information can be realized by downloading the system configuration information from the network to the data collection unit. Assuming that the actual system is assembled as shown in FIG. 2, first, as shown in FIG. 7, the system administrator or the support center holds the data collection unit 16A from the UPS status display unit 17. Processing for downloading the backup system configuration data is performed, and the system configuration data is downloaded to the data collection unit 16A (S1).

  Then, the data collection unit 16A transfers the downloaded data to the component checker 15A (S2). The component checker 15A searches for UPS agents existing on the network using the IP address included in the data, the number of UPS agents registered in the group, and the like. As a result, when a suitable UPS agent 13A is found, it is restored to the system configuration (S3).

Next, when the confirmation message is transmitted from the restored UPS agent 13A to the component checker 15A and the component checker 15A receives it (S4), the component checker 15A sends the confirmation message to the UPS submachine agent 14A. The activation message is transferred (S5).
Then, a confirmation response message is transmitted from the activated UPS submachine agent 14A to the component checker 15A (S6), and system configuration information data is transferred from the received component checker 15A to the UPS submachine agent 14A (S7). ).

The UPS submachine agent 14A uses the number of devices connected to the UPS 12A included in the transferred data, the device type, the amount of power used by the devices, and the connected devices 11A to 11C are connected to the system configuration information data. And confirm whether or not. And if it is compatible, the devices 11A to 11C can be restored (S8).
A similar operation is performed on the UPS agent 13B, and if all are matched, the group A is restored.

  Also, the configuration information of the UPS agent that manages the UPS (for example, schedule data created by the user, events, UPS type, etc.) is held as system configuration information, so that the system configuration as described above is obtained. In the process of restoring the information, the user can restore the information completely without resetting the information.

  Furthermore, if the system configuration cannot be restored, the component checker that holds the system configuration information data for the devices, UPS agents, and UPS subagents that are supposed to exist in the group has the IP address, port It is possible to automatically search using information such as a number and a communication protocol (UPS agent communication type), and to reconstruct the system while receiving (or automatically) receiving user approval.

If the UPS agent that manages the UPS cannot be restored, the component checker determines that the UPS cannot be managed, and uses the system configuration information data to replace the UPS that should be managed by the UPS agent. Shutdown can be performed on connected servers and devices.
As described above, in the above embodiment, the system configuration information is monitored and managed on the management software side, so that every time the system configuration is changed, the user does not have to perform all investigations of the actual system and reconstruction of the configuration information. It is possible to easily reconstruct the system configuration information.

In addition, since the system configuration information is managed by grouping management software, it is possible to reduce and transfer damage when damage occurs compared to the case where all management is performed with one software. It is possible to reduce the problem of communication traffic due to an increase in the amount of data and further reduce the server load.
In addition, if the system configuration information is destroyed for some reason, the system configuration information transferred to the third party via the network is downloaded to the management software. It can be easily restored.
In addition, since a function to display the status of the uninterruptible power supply and the devices connected to it is provided, if the system configuration changes, the target change information can be notified to the user, and the system configuration information Can be easily reconstructed.

It is a block diagram which shows the structure of the uninterruptible power supply management system in embodiment of this invention. It is a figure which shows a system structure tree. It is a figure which shows the system configuration information currently hold | maintained at the data collection part. It is a block diagram which shows the management flow in the system configuration information change by replacement | exchange of apparatus. It is a figure which shows the holding | maintenance method of the system configuration data in a component checker. It is a block diagram which shows the management flow in the system configuration information change by the stop of a UPS agent. It is a block diagram which shows the management flow in system configuration information restoration.

Explanation of symbols

11A-11L Equipment 12A-12D Uninterruptible power supply (UPS)
13A to 13D UPS agents 14A to 14C UPS submachine agents 15A and 15B Component checkers 16A to 16C Data collection unit 17 UPS status display unit

Claims (3)

In the uninterruptible power supply management system that manages the status of multiple uninterruptible power supplies,
The UPS management means that receives the information indicating the state of the uninterruptible power supply and manages the uninterruptible power supply one-to-one and the device connected to the uninterruptible power supply are inquired to determine the state of the device. Of an uninterruptible power supply apparatus that is connected to at least one UPS management unit and the device management unit that receive information indicating and manages the device, and that are managed by the UPS management unit The system configuration management means for receiving the status information and the status information of the equipment managed by the equipment management means, and managing the system configuration information composed of each status information, and either one of the mutually connected parent-child relationship The data collection means that the child collects and transfers the system configuration information managed by the system configuration management means to the parent and the parent manages the transferred system information Uninterruptible power supply management system characterized in that it comprises a.   2. The child data collection unit is configured to transmit and receive system configuration information collected from the system configuration management unit to at least one of a system administrator and a support center. Uninterruptible power supply management system described in 1.   The uninterruptible power supply, the device, the UPS management unit, the device management unit, the system configuration management unit, and the data connected to the data collection unit and based on the system configuration information collected by the data collection unit The uninterruptible power supply management system according to claim 1 or 2, further comprising display means for displaying the status of the collecting means.

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