JP2017055302A - Apparatus information management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus information management system capable of avoiding increase in a processing load on a management server device 2 at particular time.SOLUTION: An apparatus information management system comprises; a plurality of facility apparatuses 10 fixedly installed in buildings 3; and a management server device 2 that is capable of information communication with each of the facility apparatuses 10 via a communication line 1, and receives and stores apparatus operation information indicative of the operation situations of the facility apparatuses 10 from the respective facility apparatuses 10. Each of the facility apparatuses 10 transmits apparatus operation information indicative of a particular operation situation to the management server device 2 after waiting for the elapse of a delay time specific to each facility apparatus 10 after the occurrence of event indicating the particular operation situation.SELECTED DRAWING: Figure 1

Description

  The present invention comprises a plurality of facility devices fixedly installed in a building, can communicate information with each of the facility devices via a communication line, and includes device operation information indicating the operation status of the facility device. The present invention relates to a device information management system including a management server device that receives and stores from each device.

  In recent years, it is also possible to send device operation information of equipment such as home appliances (for example, information about ON / OFF, operation mode, set temperature, etc. for an air conditioner) to a management server device in real time via a communication line. It has become. In that case, the user of the equipment can access the management server device and browse the equipment operation information, so that the operation of the equipment can be confirmed from a remote location. In addition, it can be considered to improve the maintenance service, such as monitoring the operation status of the equipment, and if there is an abnormality, promptly contact the user to perform maintenance.

  For example, Patent Document 1 describes a device information management system that includes a facility server that is fixedly installed in a building and includes a management server device that can communicate information with the facility device via a communication line. ing. In this device information management system, the facility device transmits device operation information indicating its own operation status to the management server device, and the management server device stores the device operation information. Then, when there is an access from a user communication device used by a user of the facility device, the management server device transmits the device operation information to the user communication device to allow the user to browse. As a result, the user can confirm how the equipment is operating from a remote location.

  In such a device information management system, the amount of information transmitted from the facility device to the management server device increases as the number of facility devices that transmit information increases. There is a need to improve performance. Therefore, the initial cost and operation cost of the management server device tend to increase as the number of facility devices increases. Further, the number and performance of the management server devices at that time are determined according to the load at the moment when the access is most concentrated from the equipment. Therefore, when the equipment is set to transmit data when an event occurs, access to the management server device from a plurality of equipment may be concentrated at the event occurrence timing.

  Japanese Patent Application Laid-Open No. 2004-228561 describes a technique aimed at avoiding such concentration of access. Specifically, in the system described in Patent Document 2, device operation information (immediately transmitted data) about an event that is highly urgent and needs to be transmitted in real time, data transmitted from the equipment to the management server device, emergency 3 types of device operation information (accumulated transmission data) for events to be transmitted after accumulating data for a certain period of time, and device operation information (event transmission data for events that need to be transmitted at regular intervals) Classification. Accordingly, an attempt is made to avoid concentration of communication traffic at a specific time in the management server device by distributing communication generation timing for each equipment device.

JP 2004-005496 A Japanese Patent No. 4204431

  In the system described in Patent Document 2, attempts are made to avoid concentration of communication traffic at a specific time in the management server device by distributing communication generation timing for each equipment device. May overlap. That is, in the system described in Patent Document 2, only the transmission timing of the device operation information is changed for each type of event that occurs in the facility device, and the same type of event occurs in a plurality of facility devices at the same time. The communication generation timing for each equipment device overlaps.

  For example, the facility device is a heat source device for hot water supply installed at home, and the device operation information about the event of “operation start” is transmitted to the management server device at the timing when the heat source device starts operation. Assuming that When a user makes a hot water bath reservation, the user often does not set the time in minute units, but sets the reservation at a sharp time (for example, 7 pm). Therefore, the same kind of event that the operation of the heat source machine is started may occur simultaneously in a plurality of facility devices. As a result, the communication generation timing for each equipment device overlaps, and communication traffic concentration in the management server device occurs.

  The present invention has been made in view of the above problems, and an object thereof is to provide a device information management system capable of avoiding an increase in processing load of a management server device at a specific time.

In order to achieve the above object, the feature configuration of the equipment information management system according to the present invention includes a plurality of equipment equipment fixedly installed in a building, and information between each equipment equipment via a communication line. A device information management system comprising a management server device that is communicable and receives and stores device operation information indicating the operation status of the facility device from each of the facility devices,
After the event indicating the specific operation status occurs, the facility device waits for the elapse of a delay time specific to each of the facility devices, and sends the device operation information indicating the specific operation status to the management server device. The point is to send.

According to the above characteristic configuration, after an event indicating a specific operation situation occurs, the equipment device waits for the elapse of a delay time specific to each of the equipment devices, and manages the device operation information indicating the specific operation condition. Send to server device. In other words, even if an event indicating a specific operation status occurs simultaneously in a plurality of equipment devices, and each equipment device transmits device operation information indicating a specific operation status to the management server device, the device operation information The transmission timing is specific to each equipment device. As a result, even if an event indicating a specific operation situation occurs simultaneously in a plurality of equipment devices, the timing at which the management server apparatus receives the device operation information from the plurality of equipment devices does not concentrate at the specific time.
Therefore, it is possible to provide a device information management system capable of avoiding an increase in the processing load of the management server device at a specific time.

  Another characteristic configuration of the device information management system according to the present invention is that the facility device is determined by using identification information uniquely given to the facility device after an event indicating the specific operation state occurs. The device operation information is transmitted to the management server device after the delay time has elapsed.

  According to the characteristic configuration, since the identification information is uniquely given to each equipment device, the delay time determined by using the identification information becomes a different value for each equipment device. As a result, even if an event indicating a specific operation situation occurs simultaneously in a plurality of equipment devices, the timing at which the management server device receives the equipment operation information from the plurality of equipment devices does not overlap.

  Still another characteristic configuration of the device information management system according to the present invention is that the facility device is determined by using identification information uniquely given to the facility device after an event indicating the specific operation state occurs. The device operation information is transmitted to the management server device after waiting for the delay time determined by the product of the waiting time and the event coefficient set according to the event type.

According to the above characteristic configuration, since the identification information is uniquely given to each equipment device, the standby time determined using the identification information becomes a different value for each equipment device.
In addition, the delay time is determined by the product of the waiting time and the event coefficient, but an event (for example, a failure of the equipment) that promptly transmits the device operation information to the management server device is required. If the event coefficient is set to a relatively small value, the delay time determined by the product of the standby time and the event coefficient becomes relatively short. On the other hand, if the event does not have to be sent to the management server device quickly, if the event coefficient is set to a relatively large value, the standby time and the event coefficient The delay time determined by the product is relatively long. Thus, even if an event indicating a specific driving situation occurs simultaneously in a plurality of equipment devices, the timing at which the management server apparatus receives the device operation information from the plurality of equipment devices does not overlap, and the event Depending on the type, the timing at which the management server apparatus receives device operation information from a plurality of facility devices can be changed in time.

Still another characteristic configuration of the device information management system according to the present invention is that the management server device transmits load information indicating the size of its processing load to each of the facility devices,
The facility device has a standby time determined by using identification information uniquely given to itself after an event indicating the specific driving situation, and a load coefficient set according to the load information, The device operation information is transmitted to the management server device after the delay time determined by the product of elapses.

According to the above characteristic configuration, since the identification information is uniquely given to each equipment device, the standby time determined using the identification information becomes a different value for each equipment device.
In addition, the delay time is determined by the product of the waiting time and the load coefficient. When the processing load of the management server device is small (that is, when the margin for processing the device operation information is large), the load coefficient is relative. If the value is set to a small value, the delay time determined by the product of the standby time and the load coefficient becomes relatively short. In contrast, when the processing load of the management server device is large (that is, when the margin for processing the device operation information is small), if the load coefficient is set to a relatively large value, the standby time and The delay time determined by the product with the load coefficient is relatively long. In this way, even when an event indicating a specific operation situation occurs simultaneously in a plurality of equipment devices, the timing at which the management server device receives the equipment operation information from the plurality of equipment devices does not overlap, and the management server Depending on the processing load of the apparatus, the timing at which the management server apparatus receives the device operation information from the plurality of facility devices can be changed in time.

Still another characteristic configuration of the device information management system according to the present invention is that the management server device transmits load information indicating the size of its processing load to each of the facility devices,
After the event indicating the specific driving situation occurs, the facility device is set in accordance with the standby time determined using the identification information uniquely given to itself and the type of the event. The device operation information is transmitted to the management server device after the delay time determined by the product of a coefficient and a load coefficient set according to the load information elapses.

According to the above characteristic configuration, since the identification information is uniquely given to each equipment device, the standby time determined using the identification information becomes a different value for each equipment device.
In addition, the delay time is determined by the product of the standby time, the event coefficient, and the load coefficient, but an event (for example, a failure of equipment) that requires prompt transmission of device operation information to the management server device. If the event coefficient is set to a relatively small value, the delay time determined by the product of the standby time, the event coefficient, and the load coefficient becomes relatively short. On the other hand, if the event does not have to be sent to the management server device quickly, the event time can be set to a relatively large value. The delay time determined by the product with the coefficient is relatively long.
Furthermore, when the processing load of the management server device is small (that is, when the margin for processing the device operation information is large), if the load coefficient is set to a relatively small value, the standby time and the event coefficient The delay time determined by the product with the load coefficient is relatively short. In contrast, when the processing load of the management server device is large (that is, when the margin for processing the device operation information is small), if the load coefficient is set to a relatively large value, the standby time and The delay time determined by the product of the event coefficient and the load coefficient is relatively long. Thus, even if an event indicating a specific driving situation occurs simultaneously in a plurality of equipment devices, the timing at which the management server apparatus receives the device operation information from the plurality of equipment devices does not overlap, and the event Depending on the type and the size of the processing load on the management server device, the timing at which the management server device receives the device operation information from the plurality of facility devices can be shifted in time.

  Still another characteristic configuration of the device information management system according to the present invention is that the identification information is a serial number or a MAC address uniquely assigned to each of the facility devices.

  According to the above characteristic configuration, the delay time can be determined using the serial number or MAC address uniquely assigned to each of the facility devices.

Still another characteristic configuration of the device information management system according to the present invention is that the management server device transmits reference information to be referred to for determining the delay time to each of the facility devices,
The equipment is in the point of determining the delay time using the reference information.

  According to the above characteristic configuration, the facility device determines the delay time specific to each facility device using the reference information transmitted from the management server device to the facility device. That is, the management server device can manipulate the length of the delay time.

It is a figure which shows the structure of an apparatus information management system. It is a figure which shows the example of the delay time derived | led-out by each equipment.

<First Embodiment>
A device information management system according to a first embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a device information management system. As shown in the figure, the device information management system includes a plurality of facility devices 10 fixedly installed in the building 3 and is capable of information communication with each of the facility devices 10 via the communication line 1. A device 2 is provided. FIG. 1 illustrates an example in which three buildings 3 (3A, 3B, 3C) are drawn, and one facility device 10 (10A, 10B, 10C) is provided in each building 3 (3A, 3B, 3C). However, there is no limitation on the number of buildings 3 installed and the number of equipment 10 installed in each building 3.

  In each building 3 (3A, 3B, 3C) such as a dwelling unit, the internal private network 14 (14A, 14B, 14C) and the external communication line 1 are connected using the router 13 (13A, 13B, 13C). ing. The equipment 10 (10A, 10B, 10C) is connected to the external communication line 1 via the router 13 (13A, 13B, 13C). In the example shown in FIG. 1, the facility device 10 includes a heat source device 12 used for supplying hot water to a hot water bath or a hot water supply, and a remote controller for setting the temperature of the hot water supplied from the heat source device 12 and operating instructions. Device 11. Note that the example of the equipment 10 is not limited to the combination of the heat source device 12 and the remote control device 11, but a combination of various devices and the remote control device 11 that performs setting of the device, operation commands, etc. It can be used as the equipment 10.

  The remote control device 11 constituting the equipment 10 includes a storage unit 11a, an information processing unit 11b, a display unit 11c, and an input receiving unit 11d. The storage unit 11 a has a function of storing information handled by the remote control device 11. The information processing unit 11b has a function of performing arithmetic processing of information handled by the remote control device 11. The display unit 11c has a function of displaying information handled by the remote control device 11 to the user. The input receiving unit 11d has a function of receiving input of a hot water temperature setting, an operation command, a reservation command and the like from the user. The remote control device 11 is also a communication device having a function of performing information communication with the outside while being connected to the communication line 1 via the router 13. Therefore, each remote control device 11 has a MAC address.

  The storage unit 11 a of the remote control device 11 stores a manufacturing number uniquely assigned to the heat source device 12 and a MAC address of the remote control device 11. That is, the storage unit 11a of the remote control device 11 includes the manufacturing number of the facility device 10 (manufacture number of the heat source device 12) uniquely assigned to each of the facility devices 10 and the MAC address of the facility device 10 (of the remote control device 11). MAC address) is stored.

  The management server device 2 performs information communication with the facility device 10, receives device operation information indicating the operation status of the facility device 10 from each of the facility devices 10, and stores it. Therefore, the management server device 2 is realized using a computer having a storage unit 2a responsible for an information storage function and an information processing unit 2b responsible for an arithmetic processing function. Although not shown, the management server device 2 also has an information communication function for performing information communication with other devices via the communication line 1. In the present embodiment, after an event indicating a specific operation status occurs, each facility device 10 waits for the elapse of a delay time specific to each of the facility devices 10 and transmits device operation information indicating the specific operation status. It transmits to the management server device 2.

  When the facility device 10 has the heat source unit 12 as described above, the event indicating the specific operation status includes the start of operation of the heat source unit 12 or the occurrence of a failure of the heat source unit 12. Each facility device 10 transmits to the management server device 2 device operation information such as the start of operation of the heat source device 12 and the occurrence of a failure in the heat source device 12.

  The timing at which each facility device 10 transmits device operation information to the management server device 2 is a timing specific to each facility device 10. For example, the facility device 10 waits for the elapse of the delay time determined using the identification information uniquely given to itself after the occurrence of an event indicating a specific operation state, and then manages the device operation information. 2 to send. This identification information is a serial number or a MAC address described or converted into a number that is uniquely assigned to each of the equipment devices 10 as described above.

  The storage unit 11a of the remote control device 11 stores a function of identification information for deriving the delay time. The information processing unit 11b of the remote control device 11 derives the delay time using the function and the identification information. For example, the information processing unit 11b of the remote control device 11 can use a solution obtained by introducing the identification information into a predetermined pseudo-random number generation method such as a linear congruence method as the delay time. And after the event which shows a specific driving condition generate | occur | produces, the information processing part 11b of the remote control apparatus 11 waits for progress of the delay time, and transmits the apparatus driving information which shows a specific driving condition to the management server apparatus 2. .

FIG. 2 is a diagram illustrating an example of the delay time derived by each facility device 10.
In the present embodiment, the delay time derived by the information processing unit 11b of the remote control device 11 is derived using identification information uniquely assigned to the facility device 10, and therefore the same value is used in each facility device 10. become. However, different delay times are derived for each of the facility devices 10. As illustrated in FIG. 2, the delay time Ta derived by the equipment 10A, the delay time Tb derived by the equipment 10B, and the delay time Tc derived by the equipment 10C have different values. As a result, even if an event occurs in each equipment device 10 at the same time, the timing at which the equipment operation information is transmitted from each equipment device 10 to the management server device 2 is different. Therefore, the timing at which the management server device 2 receives the device operation information from the plurality of facility devices 10 does not concentrate on the specific time. Therefore, it is possible to provide a device information management system that can avoid an increase in the processing load of the management server device 2 at a specific time. Furthermore, since the timing at which the management server device 2 receives the device operation information from the plurality of equipment devices 10 does not concentrate at a specific time, even if the number of the equipment devices 10 increases, the number of installed management server devices 2 A significant increase in performance requirements can be avoided.

Second Embodiment
The device information management system of the second embodiment is different from the above embodiment in the delay time determination method. Although the apparatus information management system of 2nd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

  In the present embodiment, the facility device 10 is set according to the standby time determined using the identification information uniquely given to itself and the type of event after an event indicating a specific driving situation occurs. The apparatus operation information is transmitted to the management server device 2 after the delay time determined by the product of the event coefficient is increased. Table 1 shows an example of the relationship between the event type and the event coefficient.

  The storage unit 11a of the remote control device 11 stores a function of identification information for deriving the standby time, and stores the relationship between event types and event coefficients as shown in Table 1. This waiting time derivation method is the same as the delay time derivation method described in the first embodiment. As shown in [Equation 1] below, the information processing unit 11b of the remote control device 11 derives a standby time using the function and the identification information, and multiplies the standby time by an event coefficient to thereby obtain a delay time. To decide. And after the event which shows a specific driving condition generate | occur | produces, the information processing part 11b of the remote control apparatus 11 waits for progress of the delay time, and transmits the apparatus driving information which shows a specific driving condition to the management server apparatus 2. .

[Formula 1]
Delay time = waiting time x event coefficient

  As described above, since the identification information is uniquely given to each facility device 10, the standby time determined by using the identification information becomes a different value for each facility device 10. In addition, the delay time is determined by the product of the standby time and the event coefficient. However, an event (for example, a failure of the equipment 10) that promptly transmits the device operation information to the management server device 2 is required. If the event coefficient is set to a relatively small value, the delay time determined by the product of the standby time and the event coefficient becomes relatively short. On the other hand, if the event does not have to be transmitted to the management server device 2 quickly, if the event coefficient is set to a relatively large value, the standby time and the event coefficient The delay time determined by the product is relatively long. Thus, even if an event indicating a specific driving situation occurs simultaneously in a plurality of facility devices 10, the timing at which the management server device 2 receives device operation information from the plurality of facility devices 10 does not overlap, and Depending on the type of event, the timing at which the management server device 2 receives the device operation information from the plurality of facility devices 10 can be changed in time.

  In the present embodiment, the smaller the event coefficient, the shorter the delay time. In the example shown in Table 1, the event coefficient is the smallest when the type of event that has occurred is “failure”, and the device operation information (from the equipment device 10 to the management server device 2) with a relatively short delay time ( That is, the occurrence of failure) is transmitted.

<Third Embodiment>
The device information management system of the third embodiment is different from the above embodiment in the method for determining the delay time. Although the apparatus information management system of 3rd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

  In the present embodiment, the management server device 2 transmits load information indicating the size of its own processing load to each of the equipment devices 10. Specifically, the management server device 2 displays load information indicating the size of the processing load such as its own CPU usage rate at each predetermined timing (for example, every 30 minutes, every hour, etc.). Send to. Then, the information processing unit 11b of the remote control device 11 configuring each facility device 10 stores the load information transmitted from the management server device 2 in the storage unit 11a.

Each equipment device 10 has a standby time determined by using identification information uniquely given to itself after an event indicating a specific driving situation, and a load coefficient set according to the load information, The device operation information is transmitted to the management server device 2 after the delay time determined by the product of elapses. This waiting time derivation method is the same as the delay time derivation method described in the first embodiment. Illustrated in Table 2 is a relationship example between the size of the processing load (for example, the CPU usage rate of the management server device 2) and the load coefficient.

  The storage unit 11a of the remote control device 11 stores a function of identification information for deriving a standby time, and stores load information (size of processing load) received from the management server device 2, and The relationship between the processing load magnitude and the load coefficient as shown in Table 2 is stored. As shown in [Equation 2] below, the information processing unit 11b of the remote control device 11 derives a standby time using the function and the identification information, and based on the relationship shown in Table 2 with respect to the standby time. The delay time is determined by multiplying the determined load coefficient. And after the event which shows a specific driving condition generate | occur | produces, the information processing part 11b of the remote control apparatus 11 waits for progress of the delay time, and transmits the apparatus driving information which shows a specific driving condition to the management server apparatus 2. .

[Formula 2]
Delay time = standby time x load factor

  As described above, since the identification information is uniquely given to each facility device 10, the standby time determined by using the identification information becomes a different value for each facility device 10. In addition, the delay time is determined by the product of the standby time and the load coefficient. When the processing load of the management server device 2 is small (that is, when the margin for processing the device operation information is large), the load coefficient is If it is set to be a relatively small value, the delay time determined by the product of the standby time and the load coefficient becomes relatively short. On the other hand, when the processing load of the management server device 2 is large (that is, when the margin for processing the device operation information is small), the standby time can be set by setting the load coefficient to a relatively large value. The delay time determined by the product of and the load coefficient is relatively long. Thus, even if an event indicating a specific driving situation occurs simultaneously in a plurality of facility devices 10, the timing at which the management server device 2 receives device operation information from the plurality of facility devices 10 does not overlap, and Depending on the processing load of the management server device 2, the timing at which the management server device 2 receives the device operation information from the plurality of facility devices 10 can be varied in time.

<Fourth embodiment>
The device information management system according to the fourth embodiment is different from the above embodiment in the method for determining the delay time. Although the apparatus information management system of 4th Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

  In the present embodiment, the management server device 2 transmits load information indicating the size of its own processing load to each of the equipment devices 10. Specifically, the management server device 2 displays load information indicating the size of the processing load such as its own CPU usage rate at each predetermined timing (for example, every 30 minutes, every hour, etc.). Send to. Then, the information processing unit 11b of the remote control device 11 configuring each facility device 10 stores the load information transmitted from the management server device 2 in the storage unit 11a.

  After an event indicating a specific driving situation occurs, the facility device 10 has a standby time determined using identification information uniquely given to itself, and an event coefficient set according to the type of event. Then, after the delay time determined by the product of the load coefficient set according to the load information elapses, the device operation information is transmitted to the management server device 2. This waiting time derivation method is the same as the delay time derivation method described in the first embodiment.

  Specifically, a function of identification information for deriving the standby time is stored in the storage unit 11a of the remote control device 11, and the relationship between the event type and the event coefficient as shown in Table 1 is stored. In addition, the load information (the size of the processing load) received from the management server device 2 is stored, and the relationship between the processing load size and the load coefficient as shown in Table 2 is stored. As shown in the following [Equation 3], the information processing unit 11b of the remote control device 11 derives the standby time using the function and the identification information, and the event coefficient and the relationship of Table 2 are related to the standby time. The delay time is determined by multiplying the load coefficient determined based on the delay coefficient. And after the event which shows a specific driving condition generate | occur | produces, the information processing part 11b of the remote control apparatus 11 waits for progress of the delay time, and transmits the apparatus driving information which shows a specific driving condition to the management server apparatus 2. .

[Formula 3]
Delay time = Standby time x Event factor x Load factor

  As described above, since the identification information is uniquely given to each facility device 10, the standby time determined by using the identification information becomes a different value for each facility device 10. In addition, the delay time is determined by the product of the standby time, the event coefficient, and the load coefficient. However, an event (for example, the equipment device 10) that promptly transmits the device operation information to the management server device 2 is required. If the event coefficient is set to a relatively small value, the delay time determined by the product of the standby time, the event coefficient, and the load coefficient becomes relatively short. On the other hand, if the event does not have to be transmitted to the management server device 2 quickly, if the event coefficient is set to a relatively large value, the standby time and the event coefficient The delay time determined by the product with the load coefficient is relatively long. Further, when the processing load of the management server device 2 is small (that is, when the margin for processing the device operation information is large), if the load coefficient is set to a relatively small value, the standby time and the event coefficient The delay time determined by the product of and the load coefficient is relatively short. On the other hand, when the processing load of the management server device 2 is large (that is, when the margin for processing the device operation information is small), the standby time can be set by setting the load coefficient to a relatively large value. The delay time determined by the product of the event coefficient and the load coefficient is relatively long. Thus, even if an event indicating a specific driving situation occurs simultaneously in a plurality of facility devices 10, the timing at which the management server device 2 receives device operation information from the plurality of facility devices 10 does not overlap, and Depending on the type of event and the size of the processing load on the management server device 2, the timing at which the management server device 2 receives the device operation information from the plurality of facility devices 10 can be shifted in time.

<Another embodiment>
<1>
In the above embodiment, the configuration of the device information management system has been described with a specific example, but the configuration can be changed as appropriate.
For example, in the above-described embodiment, the example in which the combination of the heat source device 12 and the remote control device 11 that performs setting and operation commands of the heat source device 12 is used as the equipment 10 of the present invention has been described. A combination of various devices installed remotely and the remote control device 11 can be used as the equipment 10 of the present invention. For example, a combination of an air conditioner (air conditioner) that performs cooling operation, heating operation, and the like and a remote control device 11 that performs setting and operation instructions can be used as the equipment 10 of the present invention.
In addition, a combination of a power generation device such as a fuel cell and a remote control device 11 that performs settings and operation instructions thereof can be used as the equipment 10 of the present invention.
Further, the combination of various devices fixedly installed in the building 3 and the remote control device 11 is not used as the facility device 10, but the facility device 10 is composed of only one device fixedly installed in the building 3. May be configured.

<2>
In the above-described embodiment, numerical examples of the event coefficient (Table 1) and the load coefficient (Table 2) are described. However, they are described only for illustrative purposes and can be changed as appropriate.

<3>
In the said embodiment, the management server apparatus 2 transmits the reference information referred in order to determine delay time to each of the installation equipment 10, and the installation equipment 10 uses the reference information, and each of the installation equipment 10 It is also possible to determine the inherent delay time. That is, the length of the delay time determined by each facility device 10 can be operated by the management server device while maintaining its uniqueness.
For example, when the number of facility devices 10 decreases or when the processing capacity of the management server device 2 is increased, the timing at which the management server device 2 receives device operation information from the plurality of facility devices 10 is at a specific time. Even if concentrated, the management server device 2 may be able to cope with the processing capability. In such a case, the management server device 2 transmits a new event coefficient (reference information referred to for determining the delay time) smaller than the original event coefficient as illustrated in Table 1 to each facility device 10. May be.
Alternatively, the management server device 2 transmits a new congestion coefficient (reference information referred to for determining the delay time) different from the original congestion coefficient as illustrated in Table 2 to each facility device 10. The delay time may be determined based on the information.
In addition, a new function (reference information that is referred to for determining the delay time) that is different from the identification information function (such as a pseudo-random number generator) that was originally used to derive the delay time is used. The delay time may be determined based on the information transmitted to the facility device 10.

<4>
Although some examples of apparatus operation information were given in the said embodiment, various information regarding the driving | operation of the equipment 10 which is not described in the said embodiment is employable as apparatus operation information.

<5>
The configuration disclosed in the above embodiment (including another embodiment, the same applies hereinafter) can be applied in combination with the configuration disclosed in the other embodiment as long as no contradiction arises. The embodiment disclosed in the document is an exemplification, and the embodiment of the present invention is not limited to this, and can be appropriately modified without departing from the object of the present invention.

  The present invention can be used for a device information management system capable of avoiding an increase in processing load of a management server device at a specific time.

DESCRIPTION OF SYMBOLS 1 Communication line 2 Management server apparatus 3 Building 10 Equipment

Claims (7)

It is equipped with multiple equipment that is fixedly installed in the building.
Device information comprising a management server device capable of communicating information with each of the facility devices via a communication line, and receiving and storing device operation information indicating the operation status of the facility device from each of the facility devices. A management system,
After the event indicating the specific operation status occurs, the facility device waits for the elapse of a delay time specific to each of the facility devices, and sends the device operation information indicating the specific operation status to the management server device. Device information management system to send.   The facility device waits for the elapse of the delay time determined using the identification information uniquely given to itself after the occurrence of the event indicating the specific operation status, and manages the device operation information. The device information management system according to claim 1, wherein the device information management system is transmitted to a server device.   After the event indicating the specific driving situation occurs, the facility device is set in accordance with the standby time determined using the identification information uniquely given to itself and the type of the event. The device information management system according to claim 1, wherein the device operation information is transmitted to the management server device after the delay time determined by a product with a coefficient has elapsed. The management server device transmits load information indicating the size of its processing load to each of the facility devices,
The facility device has a standby time determined by using identification information uniquely given to itself after an event indicating the specific driving situation, and a load coefficient set according to the load information, The device information management system according to claim 1, wherein the device operation information is transmitted to the management server device after waiting for the delay time determined by the product of the product to elapse. The management server device transmits load information indicating the size of its processing load to each of the facility devices,
After the event indicating the specific driving situation occurs, the facility device is set in accordance with the standby time determined using the identification information uniquely given to itself and the type of the event. The device information according to claim 1, wherein the device operation information is transmitted to the management server device after the delay time determined by a product of a coefficient and a load coefficient set according to the load information elapses. Management system.   The device information management system according to any one of claims 2 to 5, wherein the identification information is a manufacturing number or a MAC address uniquely assigned to each of the facility devices. The management server device transmits reference information referred to for determining the delay time to each of the facility devices,
The equipment information management system according to any one of claims 1 to 6, wherein the facility equipment determines the delay time using the reference information.

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