WO2016098320A1 - Operation management server, operation management system, and operation management method - Google Patents

Abstract

A generation unit (100) provided in this operation management server (10) generates third weather data from first weather data and second weather data. The first weather data includes a predicted highest temperature and a predicted lowest temperature corresponding to the location of a building for every day for a control period. The second weather data represents a temperature change corresponding to the location of the building on a measured date before the control period. The third weather data represents a temperature change in time series during the control period. The generation unit (100) generates an operation program that controls equipment during the control target period on the basis of the third weather data.

Description

Operation management server, operation management system, and operation management method

The present invention generally relates to an operation management server, an operation management system, and an operation management method, and more particularly to an operation management server, an operation management system, and an operation management method for managing one or more devices installed inside a building.

Conventionally, there is an apparatus that generates operation information (operation program) for controlling a target property device (for example, an air conditioner) (see, for example, Patent Document 1).

The device (air conditioning control device) disclosed in Patent Document 1 acquires weather information for up to 48 hours ahead from the outside (meteorological company). Here, the weather information includes the time and the temperature and humidity at the time. The air conditioning control device calculates the discomfort index for 48 hours from the present time for each time (or every day) from the acquired weather information, and based on the calculated discomfort index, whether or not the device needs to be operated and the set temperature Driving information including at least one is generated.

Japanese Patent Laid-Open No. 2003-74943

By the way, depending on the region, there are meteorological companies that send weather information that does not include the time (expected time) after the current time, that is, weather data with a rough accuracy of the predicted contents. In Patent Document 1, the discomfort index at the predicted time is calculated from the time after the current time (expected time) included in the weather information and the humidity at the predicted time (expected humidity). Therefore, in a region where weather information that does not include the expected time is transmitted, the discomfort index for each time cannot be calculated using the technique of Patent Document 1. This is because the time of temperature and humidity included in the weather information is unknown.

Therefore, the present invention has been made in view of the above-mentioned reasons, and an object of the present invention is to provide an operation management server, an operation management system, and an operation management method capable of generating an operation program using meteorological data having a rough prediction accuracy. It is to provide.

An operation management server according to an aspect of the present invention is an operation management server installed outside a building, the generation unit generating an operation program for controlling a device installed inside the building, and the generation unit A communication unit that transmits the operation program generated in step 1 to a local management device that controls the device according to the operation program, wherein the generation unit is configured to control the device for each day in the control target period. The first meteorological data including the predicted maximum temperature and the predicted minimum temperature corresponding to the location, and the second weather data representing the temperature change corresponding to the location of the building on the measurement date before the controlled target period, in the controlled target period. The third meteorological data representing the temperature change along the time series is generated, and based on the generated third meteorological data, used in the control target period And generating a use program.

An operation management system according to an aspect of the present invention is an operation management system including the operation management server and the local management device, and the local management device uses the operation program to connect the device. A control processing unit for controlling is provided.

An operation management method according to one aspect of the present invention includes a generation process for generating an operation program for controlling equipment installed in a building, and the operation program generated by the generation process according to the operation program. A communication process that is transmitted to a local management device that controls the device, and the generation process includes a predicted maximum temperature and a predicted minimum temperature corresponding to the location of the building for each day in a control target period for controlling the device. The third weather representing the temperature change along the time series in the control target period from the first weather data and the second weather data representing the temperature change corresponding to the location of the building on the measurement date before the control target period. Generating data, and generating the operation program used in the control target period based on the generated third weather data. .

According to the operation management server, operation management system, and operation management method of the present invention, it is possible to generate an operation program using weather data having a rough prediction accuracy.

FIG. 1 is a block diagram illustrating the configuration of the operation management server in the first embodiment. FIG. 2 is a diagram illustrating the configuration of the operation management system according to the first embodiment. FIG. 3 is a diagram for explaining generation of third weather data in the first embodiment. FIG. 4A is a diagram illustrating setting operation information according to the first embodiment. FIG. 4B is a diagram illustrating setting operation information according to the first embodiment. FIG. 4C is a diagram illustrating setting operation information according to the first embodiment. FIG. 4D is a diagram illustrating setting operation information according to the first embodiment. FIG. 5 is a diagram illustrating a data structure of control data according to the first embodiment. FIG. 6 is a block diagram illustrating the configuration of the local management device according to the first embodiment. FIG. 7 is a sequence diagram for explaining the operation of the operation management server when the operation program is generated in the first embodiment. FIG. 8 is a sequence diagram for explaining the operation of the operation management server at the time of evaluation in the first embodiment. FIG. 9 is a sequence diagram for explaining the operation of the local management apparatus when the device is controlled using the operation program in the first embodiment. FIG. 10 is a diagram illustrating a device configuration inside a building according to the second embodiment. FIG. 11 is a sequence diagram for explaining the operation of the operation management server at the time of evaluation in the second embodiment.

Hereinafter, an operation management server, an operation management system, and an operation management method according to an embodiment of the present invention will be described in detail with reference to the drawings. Each of the embodiments described below shows a preferred specific example of the present invention. Accordingly, numerical values, components, arrangement and connection forms of components, steps, order of steps, and the like shown in the following embodiments are merely examples, and are not intended to limit the present invention. Therefore, among the constituent elements in the following embodiments, constituent elements that are not described in the independent claims indicating the highest concept of the present invention are described as optional constituent elements.

(1 Embodiment 1)
[1.1 Overview]
The operation management server 10 of this embodiment is an apparatus that generates an operation program for controlling one or more devices installed inside a building. As illustrated in FIG. 1, the operation management server 10 includes a generation unit 100, a storage unit 101, a change unit 102 (setting information change unit), an evaluation unit 103, and a communication unit 104.

The operation management server 10 is included in the operation management system 1 as shown in FIG. As shown in FIG. 2, the operation management system 1 includes a weather server 11, a local management device 20, a controller 21, a sub-controller 22, and a device 23 in addition to the operation management server 10.

The local management device 20, the controller 21, the sub-controller 22, and the device 23 are installed inside the building 12, as shown in FIG. Further, there are a plurality of buildings 12 in which the local management device 20, the controller 21, the sub-controller 22, and the devices 23 are installed (see FIG. 2). In addition, when distinguishing the some building 12, it describes as building 12a, 12b, 12c, 12d, 12e. Each of the sub-controller 22 and the device 23 is installed in the building 12 as shown in FIG. One or more devices 23 among the plurality of devices 23 are connected to each of the plurality of sub-controllers 22 (see FIG. 2). Here, the equipment 23 is an air conditioner, a cold heat source machine, a cooling tower for cooling the cold heat source machine, a cold water pump, a cooling water pump, a hot heat source machine (boiler), or the like.

In the present embodiment, the controller 21 and the sub-controller 22 are connected to the sub-controller 22 and one or more devices 23 by an Ethernet (registered trademark) standard cable, an RS485 standard cable, or the like.

The operation management server 10 is installed outside the plurality of buildings 12 as shown in FIG.

The buildings 12a to 12c exist in the area 14, and the buildings 12d and 12e exist in the area 15. Here, the region 14 and the region 15 are different regions among a plurality of regions that divide a predetermined range of land.

The operation management server 10 generates an operation program for each of the plurality of buildings 12. At this time, the operation management server 10 generates the same operation program for one or more buildings 12 existing in the same area. Specifically, the operation management server 10 generates the same operation program for the buildings 12a to 12c existing in the area 14, and generates the same operation program for the buildings 12d and 12e existing in the area 15. To do.

The local management device 20 stores an operation program generated by the operation management server 10 in order to control a plurality of devices 23 installed in the building 12. The local management device 20 outputs first instruction information for controlling the plurality of devices 23 installed in the building 12 to the controller 21 in accordance with the stored operation management program.

The controller 21 outputs second instruction information for controlling one or more devices 23 connected to the sub controller 22 to each of the sub controllers 22.

The sub-controller 22 controls one or more devices 23 connected to itself.

Hereinafter, configurations and operations of the operation management server 10 and the local management device 20 will be described.

[1.2 Configuration]
(1) Operation management server 10
As described above, the operation management server 10 of the present embodiment includes the generation unit 100, the storage unit 101, the change unit 102, the evaluation unit 103, and the communication unit 104 (see FIG. 1). The operation management server 10 includes a processor or a computer-readable memory (recording medium), and the functions of the generation unit 100, the change unit 102, and the evaluation unit 103 are programs that are stored in the memory. Is realized by executing.

(1-1) Generation unit 100
The generation unit 100 generates an operation program that controls one or more devices 23 installed inside the building 12. The generation unit 100 acquires the first weather data and the second weather data from the weather server 11 via the communication unit 104, and controls the device 23 using the acquired first weather data and second weather data. 3rd weather data showing the temperature change along the time series in the control object period to be generated is generated. The generation unit 100 generates an operation program used in the control target period based on the generated third weather data. Here, the first weather data is data including the predicted maximum temperature and the predicted minimum temperature corresponding to the location of the building 12 (for example, the region 14) for each day in the control target period. Specifically, the first weather data includes data indicating the predicted maximum temperature and the predicted minimum temperature for each day, but does not include data indicating the time when the predicted maximum temperature and the predicted minimum temperature are reached. . The second weather data is data representing a temperature change corresponding to the location of the building 12 (for example, the region 14) on the measurement date before the control target period.

First, the generation of the third weather data will be specifically described with reference to FIG.

The generation unit 100 acquires, as the second weather data, temperature change information measured from time t0 (for example, 0:00) on the measurement date D0 to t2 which is the generation time of the operation program. Here, it is assumed that the measurement date D0 is the day before the control target period. The generation unit 100 specifies the time t1 when the maximum temperature is reached on the measurement date D0 from the acquired second weather data, that is, the time length TH from the time t0 to the time t1. The generation unit 100 considers that the maximum temperature is reached at the same time as the time t1 in the plurality of target dates D1, D2,. For example, the generation unit 100 arranges the predicted maximum temperature h1 on the target date D1 from the time t3 (0:00) on the target date D1 to the time t5 of the time length TH. Similarly, the generation unit 100 arranges the predicted maximum temperature h3 on the target date D2 from the time t6 (0 o'clock) on the target date D2 to the time t8 of the time length TH.

In addition, the generation unit 100 performs linear interpolation on the temperature change after the time t2 based on the temperature change from the time t1 to the time t2 on the measurement date D0 to obtain the expected minimum temperature h0 on the target date D1. t4, that is, the time length TL from time t3 to time t4 is specified. Here, time t3 is 0:00 on the target date D1. The generation unit 100 regards the other target dates D2,... Included in the control target period as reaching the lowest temperature at the same time as the time t4, and has the time length TL from the time t6 (0 o'clock) on the target date D2. At time t7, the expected minimum temperature h2 on the target date D1 is arranged. Here, the times t4 and t7 described above correspond to the first time, and the times t5 and t8 correspond to the second time.

As described above, the generation unit 100 generates the third weather data by interpolating the temperature change between the adjacent predicted minimum temperature and the predicted maximum temperature along the time series in the control target period.

Next, the operation program generation will be described specifically.

The generation unit 100 generates an operation program using the operation setting information for the one device 23 installed in the building 12 and the third weather data. The operation setting information is information indicating the operation state of the one device according to the temperature.

As a first example, operation setting information of a device 23 (air conditioner) that performs cooling and heating by taking in outside air and exchanging heat will be described. The operation setting information in this case is information indicating the output state of the fan of the device 23 (air conditioner) as shown in FIG. 4A. At an air temperature W1 or lower shown in FIG. 4A, the amount (air volume) for taking in outside air during heating is minimized, and at an air temperature C1 or higher, the air volume for taking in outside air during cooling is minimized. As the temperature rises from the temperature W1, the amount of air that takes in outside air during heating increases, and as the temperature decreases from the temperature C1, the amount of air that takes in outside air during cooling increases.

When the temperature of the outside air is between the temperature L1 and the temperature H1, the fan of the air conditioner is stopped, that is, the air conditioner is stopped. Specifically, when the temperature of the outside air is the temperature L1 during heating, the air volume by the fan is set to the upper limit value E2, and the air volume by the fan is decreased as the temperature decreases. When the temperature of the outside air becomes W1 or lower during heating, the air volume by the fan is set to the lower limit value E1. At the time of cooling, when the temperature of the outside air is the temperature H1, the air volume by the fan is set to the upper limit value E2, and the air volume by the fan is decreased as the temperature rises. When the temperature of the outside air becomes C1 or higher during cooling, the air volume by the fan is set to the lower limit value E1.

Thereby, since the amount of outside air taken into the room of the building 12 is adjusted during heating and cooling, the air conditioner can perform appropriate cooling and heating operations.

As another example, the operation setting information may be information indicating the state of the blowout temperature of the device 23 (air conditioner) as shown in FIG. 4B. When the temperature is W2 or lower shown in FIG. 4B, the load on the air conditioner during heating is maximum, and when the temperature is C2 or higher, the load on the air conditioner during cooling is maximum.

When the outside air temperature is between the temperature L2 and the temperature H2, the air conditioner is stopped. At the time of heating, when the temperature of the outside air is the temperature L2, the blowing temperature is set to the lower limit value E5, and the blowing temperature is increased as the temperature decreases. When the temperature of the outside air becomes W2 or lower during heating, the blowing temperature is set to the upper limit value E6. Further, when the temperature of the outside air is the air temperature H2 during cooling, the blowing temperature is set to the upper limit value E4, and the blowing temperature is decreased as the temperature rises. When the temperature of the outside air becomes C2 or higher during cooling, the blowing temperature is set to the lower limit value E3.

This allows the air temperature to be adjusted appropriately according to the temperature of the outside air during heating and cooling.

Furthermore, as another example, as shown in FIG. 4C, the operation setting information may be information indicating the temperature (water supply temperature) of the water sent to the heat source of the device 23 (air conditioner). Below the temperature W3 shown in FIG. 4C, the load on the air conditioner during heating is maximized, and at the temperature C3, the load on the air conditioner during cooling is maximized.

When the outside air temperature is between the temperature L3 and the temperature H3, the air conditioner is stopped. At the time of heating, when the temperature of the outside air is the temperature L3, the water supply temperature is set to the lower limit E9, and the water supply temperature is raised as the air temperature decreases. When the temperature of the outside air becomes W3 or less during heating, the water supply temperature is set to the upper limit value E10. Further, during cooling, when the temperature of the outside air is the temperature H3, the water supply temperature is set to the upper limit value E8, and the water supply temperature is decreased as the air temperature increases. When the temperature of the outside air becomes C3 or higher during cooling, the water supply temperature is set to the lower limit value E7.

Thereby, the water supply temperature is adjusted according to the temperature of the outside air at the time of heating and cooling, so that the air conditioner can perform an appropriate cooling / heating operation.

Furthermore, as another example, the operation setting information may be information indicating the state of the cooling water temperature (cooling water temperature) of the heat source of the device 23 (air conditioner) as shown in FIG. 4D. The temperature H4 shown in FIG. 4D is the temperature at which the load on the air conditioner during cooling is maximized. In addition, since cooling of a heat source is performed only at the time of air_conditioning | cooling, only temperature H4 is set.

When the outside air temperature is lower than the temperature H4, the air conditioner is stopped. When the temperature of the outside air becomes equal to or higher than the temperature H4 during cooling, the cooling water temperature is set to a predetermined temperature E11. Usually, the lower the temperature of the cooling water, the higher the operating efficiency of the air conditioner. In this example, when the temperature of the outside air is equal to or higher than the temperature H4, the temperature of the cooling water is always constant.

This allows the air conditioner to operate properly during cooling.

Note that the operation setting information is not limited to the information represented in the examples shown in FIGS. 4A to 4D. Operation setting information should just be information which can change the setting of apparatus 23 according to temperature. In FIGS. 4A to 4D, the value of the device output is linearly changed according to the temperature change, but may be changed stepwise.

The generation unit 100 performs FIG. 5 for each of the plurality of devices 23 based on the change in the device output corresponding to the temperature change represented by the operation setting information and the temperature change represented by the third weather data. The control data 150 shown in FIG. Here, as shown in FIG. 5, the control data 150 includes a controller address 151, a sub-controller address 152, a device address 153, a control time 154 and a control content 155.

The controller address 151 is information indicating the address of the controller 21 that controls the device 23 to be controlled, and is, for example, the MAC address or IP address of the controller 21. The sub controller address 152 is information indicating the address of the sub controller 22 connected to the control target device 23, and is, for example, the MAC address or IP address of the sub controller 22. The device address is information indicating the address of the device 23 to be controlled, and is, for example, the MAC address or IP address of the device 23. The control time 154 is information representing the time at which the control target device 23 is controlled. The control content 155 is the content of control performed on the device 23 to be controlled, for example, turning on / off the power, changing the set temperature, or changing the air volume.

The operation management server 10 stores in advance an address information table in which the addresses of the sub-controller 22 and the controller 21 that are directly or indirectly connected are associated with each device 23 installed in the building 12.

Here, as an example, generation of control data 150 for controlling the cooling operation when the device 23 is an air conditioner will be described.

Based on the change in the device output corresponding to the temperature change represented by the operation setting information and the temperature change represented by the third weather data, the generation unit 100 increases the temperature of the outside air to the temperature H1 at 9:00 am. When expected, the time “9:00” is stored at the control time 154. The generation unit 100 further stores “cooling operation ON” in the control content. Further, the addresses of the sub-controller 22 and the controller 21 that are directly or indirectly connected to the device 23 (air conditioner) are acquired from the address information table. The generation unit 100 stores the acquired address of the controller 21 in the controller address 151 and the sub controller 22 in the sub controller address 152.

The generation unit 100 includes the control data 150 generated for each of the plurality of devices 23 installed in the building 12 and generates an operation program generated in time series based on the control time 154. The generation unit 100 transmits the generated operation program to the local management device 20 connected to the controller having the address stored in the controller address 151 via the communication unit 104. Further, the generation unit 100 stores the generated operation program in the storage unit 101 in association with the address (IP address or MAC address) of the transmission destination local management device 20.

As described above, the generation unit 100 can generate and operate an operation program in consideration of the efficiency and performance of the device 23 by using the operation setting information described above when generating the operation program.

(1-2) Storage unit 101
The storage unit 101 is a rewritable semiconductor memory, for example, and stores the operation program generated by the generation unit 100. Specifically, the storage unit 101 stores the address of the transmission destination local management device in association with each operation program transmitted to each of the local management devices 20. Furthermore, the storage unit 101 stores the operation setting information and the address information table described above.

(1-3) Change unit 102
The changing unit 102 changes the contents of the operation setting information, and updates the operation setting information stored in the storage unit 101 to the operation setting information after the change. Specifically, when the performance of the device 23 (air conditioner) installed in the building 12 deteriorates, the changing unit 102 operates the operation setting information so that the temperature range in which the device 23 is stopped becomes narrower. Change the contents of.

Also, the changing unit 102 changes the contents of the operation setting information according to the usage status of the room in which the device 23 (air conditioner) is installed. For example, when the operation management server 10 receives an instruction from the user to advance the start time for using the air conditioning function of the device 23, the changing unit 102 changes the temperature range in which the device 23 is stopped. Thereby, it is possible to change the start time of using the air conditioning function of the device 23 from 9:00 to 8:00, for example.

As described above, by changing the temperature range in which the device 23 is stopped, the operation management server 10 changes the operation according to the deterioration of the performance of the device 23 and changes the periodic operation of the device 23. Can do.

(1-4) Evaluation unit 103
The evaluation unit 103 evaluates the divergence of the third weather data with respect to the fourth weather data representing the temperature change measured within the control target period. Here, it is assumed that the fourth weather data is data measured in the area 14, for example.

Hereinafter, the evaluation unit 103 will be specifically described.

The evaluation unit 103 acquires the fourth weather data transmitted from the weather server 11 via the communication unit 104. The evaluation unit 103 compares the temperature change on the same day as the measurement date of the temperature change represented by the fourth weather data among the third weather data, and the temperature change represented by the fourth weather data, Evaluate the divergence of the third meteorological data from the meteorological data. For example, the evaluation unit 103 subtracts the temperature (expected temperature) represented by the third weather data at the time from the temperature (actual temperature) represented by the fourth weather data at the time at every predetermined time. And accumulate the results. When the accumulated result (cumulative value) is equal to or higher than the first predetermined value (for example, +10) or equal to or lower than the second predetermined value (for example, −10), the evaluation unit 103 instructs the generation of the operation program again. The instruction information is output to the generation unit 100.

In this case, when receiving the instruction information, the generation unit 100 generates the third weather data representing the temperature change after the current time again using, for example, the first weather data and the fourth weather data. The production | generation part 100 produces | generates an operation program again using the 3rd weather data and operation setting information which were produced | generated again. At this time, the operation management server 10 again generates the same operation program for the buildings 12a to 12c existing in the area 14. The generation unit 100 transmits the regenerated operation program to the buildings 12a to 12c existing in the area 14 via the communication unit 104.

(1-5) Communication unit 104
When the communication unit 104 receives first weather data and second weather data from the weather server 11 via the Internet 13, the communication unit 104 outputs the received first weather data and second weather data to the generation unit 100. When the communication unit 104 receives the fourth weather data from the weather server 11 via the Internet 13, the communication unit 104 outputs the received fourth weather data to the evaluation unit 103.

When the communication unit 104 receives the operation program from the generation unit 100, the communication unit 104 transmits the operation program to each of the one or more buildings 12, that is, the local management devices 20 in the area to which the operation program is applied, via the Internet 13.

(2) Local management device 20
As shown in FIG. 6, the local management device 20 includes a control unit 200, a first storage unit 201, a second storage unit 202, a first communication unit 203, and a second communication unit 204.

The local management device 20 has a memory (recording medium) that can be read by a processor or a computer, and the function of the control unit 200 is realized by the processor executing a program stored in the memory.

(2-1) Control unit 200
As shown in FIG. 6, the control unit 200 includes a control processing unit 210, a generation unit 211 (program generation unit), a change unit 212 (program change unit), and an instruction unit 213.

Hereinafter, the control processing unit 210, the generation unit 211, the change unit 212, and the instruction unit 213 will be described.

The control processing unit 210 controls each of the one or more devices 23 connected via the controller 21 and the sub-controller 22 using the operation program. The control processing unit 210 will be specifically described.

When receiving the operation program transmitted from the operation management server 10 via the first communication unit 203, the control processing unit 210 stores the operation program in the first storage unit 201.

The control processing unit 210 individually controls the devices 23 installed in the building 12 using each of the control data 150 included in the operation program stored in the first storage unit 201. Specifically, the control processing unit 210 controls the control time 154 and the control content included in each of the operation program stored in the first storage unit 201 and the local operation program stored in the second storage unit 202 described later. Based on 155, the devices 23 are individually controlled. For example, when the content of the control content 155 is “cooling operation on”, the control processing unit 210 sends a signal (control signal) indicating “cooling operation on” to the device address 153 via the second communication unit 204. Is output to the device 23 represented by Here, the control signal includes the controller address 151, the sub-controller address 152, the device address 153, the control time 154, and the control content 155 shown in FIG. In addition, when a local operation program described later is stored in the second storage unit 202, the control processing unit 210 uses the local operation program instead of the operation program stored in the first storage unit 201. Each of the one or more connected devices 23 is controlled.

The generation unit 211 generates a local operation program in order to perform control different from the control using the operation program for each of the connected devices 23. The local operation program includes the sub controller address 152, the device address 153, the control time 154, and the control content 155 shown in FIG.

The changing unit 212 changes the operation program stored in the first storage unit 201. Specifically, the changing unit 212 changes the content of at least one control data 150 included in the operation program, for example, the content represented by the control content 155. For example, the changing unit 212 changes the control data 150 of the device 23 for each device 23 installed in the building 12. Alternatively, all the devices 23 connected to the sub-controller 22 are set as one group, and the control data 150 of the devices 23 included in the group is changed. Thereby, for example, the control data 150 of the device 23 installed at the installation location can be changed for each installation location of the device 23.

The instruction unit 213 makes the same change to the predetermined number of devices 23 among the plurality of devices 23 installed in the building 12 by the changing unit 212, that is, to the control data 150 of the predetermined number of devices 23. In the case where it is notified, a creation instruction is transmitted to the operation management server 10. The creation instruction is information for instructing generation of a new operation program so that the control processing unit 210 controls all of the plurality of devices 23 installed in the building 12 with the contents of the change described above. The change information representing the same change content made to the is included. For example, when the same change is made to the control data 150 of each of the devices 23 of 80% or more of all the devices 23 installed in the building 12, the changing unit 212 gives a creation instruction, It transmits to the operation management server 10 via the first communication unit 203. In this case, the generation unit 100 of the operation management server 10 uses the operation program in which the same address as the address of the local management device that is the transmission source is associated based on the change content represented by the change information included in the change instruction. All the control data 150 included in is changed.

(2-2) First storage unit 201 and second storage unit 202
The first storage unit 201 is, for example, a rewritable semiconductor memory, and stores the operation program transmitted from the operation management server 10.

The second storage unit 202 is a rewritable semiconductor memory, for example, and stores the local operation program generated by the generation unit 211.

(2-3) First communication unit 203
When the first communication unit 203 receives the operation program transmitted from the operation management server 10 via the Internet 13, the first communication unit 203 outputs the received operation program to the control unit 200.

The first communication unit 203 transmits the creation instruction output from the instruction unit 213 to the operation management server 10 via the Internet 13.

(2-4) Second communication unit 204
The second communication unit 204 outputs a control signal for controlling the device 23 connected via the controller 21 and the sub-controller 22 to the controller 21. Specifically, when the second communication unit 204 receives a control signal from the control processing unit 210, the second communication unit 204 outputs the received control signal to the controller 21 using the controller address 151.

At this time, the controller 21 outputs the control signal received from the local management device 20 to the sub-controller 22 to which the control target device 23 is connected using the sub-controller address 152. Further, the sub-controller 22 controls the device 23 indicated by the device address 153 included in the control signal received from the controller 21 according to the control content 155.

[1.3 Operation]
Here, operations of the operation management system 1, particularly operations of the operation management server 10 and the local management device 20 will be described.

(1) Operation of Operation Management Server 10 First, the operation of the operation management server 10 when generating an operation program will be described with reference to the sequence diagram shown in FIG.

The generation unit 100 of the operation management server 10 performs the first request processing, and generates first request information for requesting the first weather data and the second weather data (step S5). The generation unit 100 transmits the generated first request information to the weather server 11 via the communication unit 104 (step S10).

When the weather server 11 receives the first request information, it transmits the first weather data and the second weather data to the operation management server 10 via the Internet 13 (step S15).

Upon receiving the first weather data and the second weather data, the generation unit 100 of the operation management server 10 performs a generation process (step S20). Specifically, the generation unit 100 generates the third weather data representing the temperature change in the control target period using the first weather data and the second weather data (step S25). The generation unit 100 generates an operation program based on the generated third weather data (step S30).

The operation management server 10 transmits the generated operation program to the local management device 20 via the Internet 13 (step S35).

Next, the operation of the operation management server 10 at the time of evaluation will be described using the sequence diagram shown in FIG.

The evaluation unit 103 of the operation management server 10 performs the second request process and generates second request information for requesting the fourth weather data (step S100). The evaluation unit 103 transmits the generated second request information to the weather server 11 via the communication unit 104 (step S105).

Upon receipt of the second request information, the weather server 11 transmits the fourth weather data to the operation management server 10 via the Internet 13 (step S110).

Upon receiving the fourth weather data via the communication unit 104, the evaluation unit 103 of the operation management server 10 performs an evaluation process (Step S115). Specifically, the operation management server 10 calculates the temperature change on the same day as the measurement date of the temperature change represented by the fourth weather data among the third weather data, and the temperature change represented by the fourth weather data. In comparison, the deviation of the third weather data from the fourth weather data is evaluated.

The evaluation unit 103 determines whether the deviation is large based on the evaluation result (step S120). When the evaluation unit 103 determines that the deviation is large (“Yes” in step S120), the generation unit 100 performs re-creation processing of the operation program (step S125). Specifically, the generation unit 100 uses the first weather data and the fourth weather data to generate again the third weather data representing the temperature change after the current time. The production | generation part 100 produces | generates an operation program again using the 3rd weather data and operation setting information which were produced | generated again. For example, the generation unit 100 recreates an operation program to be transmitted to all local management devices 20 existing in the area where the fourth weather data is measured.

The generation unit 100 performs a retransmission process (step S130). Specifically, the generation unit 100 transmits the operation program generated again to the local management device 20 via the Internet 13. Further, the generation unit 100 updates all of the operation programs associated with the re-transmission destination address among the plurality of operation programs stored in the storage unit 101 to the re-created operation program.

If the evaluation unit 103 does not determine that the divergence is large (“No” in step S120), the generation unit 100 does not perform re-creation processing and re-transmission processing of the operation program.

(2) Operation of Local Management Device 20 Here, the operation of the local management device 20 when controlling the device 23 using the operation program will be described with reference to the sequence diagram shown in FIG.

The first communication unit 203 of the local management device 20 receives the operation program transmitted from the operation management server 10 via the Internet 13 (step S200). The control processing unit 210 stores the operation program received by the first communication unit 203 in the first storage unit 201 (step S205).

The control processing unit 210 determines whether to start control of at least one device 23 among the one or more connected devices 23 (step S210). Specifically, the control processing unit 210 performs control starting control among the control data 150 included in each of the operation program stored in the first storage unit 201 and the local operation program stored in the second storage unit. It is determined whether data 150 exists. For example, the control processing unit 210 measures time and determines whether or not there is control data 150 including the same control time as the time that has been counted.

When it is determined to start control (“Yes” in step S210), a control signal for controlling the device 23 to be controlled is generated, and the generated control signal is output to the controller 21 (step S215, S220). Specifically, the control processing unit 210 acquires control data 150 including the same control time as the time measured from the first storage unit 201 or the second storage unit 202. The control processing unit 210 generates a control signal corresponding to the control content included in the acquired control data 150, and outputs the generated control signal to the controller 21 connected to the control target device 23. When there are a plurality of control data 150 including the same control time as the time measured, the control processing unit 210 generates and outputs a control signal for each control data 150.

The controller 21 controls the device 23 to be controlled (step S225). Specifically, the controller 21 outputs the control signal received from the local management device 20 to the sub-controller 22 to which the control target device 23 is connected using the sub-controller address 152. The sub-controller 22 controls the device 23 indicated by the device address 153 included in the control signal received from the controller 21 according to the control content 155.

[1.4 Modification of Embodiment 1]
In the present embodiment, it is assumed that the local management device 20 always receives an operation program. However, the local management device 20 may not be able to receive the operation program due to a communication failure or the like. Therefore, the local management device 20 may operate autonomously based on a provisional operation program stored in advance when the operation program cannot be received.

In the present embodiment, when receiving the operation program, the local management device 20 may transmit response information indicating the reception to the operation management server 10. In this case, the operation management server 10 may transmit the operation program again when the response information is not received within a certain period after the operation program is transmitted.

In the present embodiment, the predicted maximum temperature and the predicted minimum temperature of other regions (for example, the region 15) may be included in the first weather data. In this case, a region identifier for identifying a region is associated with a set of the predicted maximum temperature and the predicted minimum temperature. The local management device 20 stores in advance an area identifier of the area where the building 12 where the device is installed is located. When the local management device 20 receives the first weather data, the local management device 20 acquires the predicted maximum temperature and the predicted minimum temperature associated with the area identifier stored in advance.

In the present embodiment, the second weather data (fourth weather data) may include data representing a temperature change in another region (for example, the region 15). In this case, the area identifier for identifying the area is associated with the data representing the temperature change. When receiving the second meteorological data (fourth meteorological data), the local management device 20 acquires data representing a temperature change associated with a pre-stored area identifier.

In the present embodiment, the generation unit 100 generates one control data 150 for one device 23, but is not limited thereto. The generation unit 100 may generate one control data 150 for a plurality of devices 23 connected to the same sub-controller 22. In this case, the control data 150 includes a plurality of device addresses 153.

Moreover, in this embodiment, the production | generation part 100 performs a linear interpolation with respect to the temperature change after the time t2 based on the temperature change from the time t1 of the measurement date D0 to the time t2, and the prediction minimum of the target date D1. Although the time t4 when the temperature becomes h0 is specified, the present invention is not limited to this. The generation unit 100 may set the time when the lowest temperature on the measurement date D0 is reached as the time when the predicted lowest temperature on the target date D1 is reached. In this case, the second meteorological data only needs to include the time when the lowest temperature is reached on the measurement date D0 and the time when the highest temperature is reached.

(2 Embodiment 2)
[2.1 Configuration]
In the present embodiment, the transmission source of the fourth weather data is different from that in the first embodiment. In the following, the present embodiment will be described focusing on differences from the first embodiment. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

In this embodiment, as shown in FIG. 10, a sensor 24 connected to the local management device 20 is installed in the building 12. The local management device 20 and the sensor 24 are connected by an Ethernet (registered trademark) standard cable, an RS485 standard cable, or the like.

The sensor 24 is a temperature sensor that measures temperature, and periodically notifies the local management device 20 of the measurement result.

When the control unit 200 of the local management device 20 according to the present embodiment receives the measurement result output from the sensor 24, the control unit 200 stores the measurement result in the first storage unit 201, for example. Here, the storage destination of the measurement result is not limited to the first storage unit 201. The storage destination of the measurement result may be the second storage unit 202 or a storage unit different from the first storage unit 201 and the second storage unit 202.

The control unit 200 receives the second request information transmitted from the operation management server 10 via the first communication unit 203. When the control unit 200 receives the second request information, the control unit 200 operates the data representing the temperature change obtained from one or more measurement results measured by the sensor 24 on the day as the fourth weather data via the first communication unit 203. It transmits to the management server 10.

[2.2 Operation]
Hereinafter, the operation of the operation management server 10 at the time of evaluation in the present embodiment will be described with reference to the sequence diagram shown in FIG.

The evaluation unit 103 of the operation management server 10 of the present embodiment performs the second request process, and generates the second request information for requesting the fourth weather data (step S300). The evaluation unit 103 transmits the generated second request information to the weather server 11 via the communication unit 104 (step S305).

When receiving the second request information, the control unit 200 of the local management device 20 transmits the fourth weather data to the operation management server 10 via the Internet 13 (step S310).

Evaluation unit 103 receives the fourth weather data via communication unit 104, and performs evaluation processing (step S315). Since the specific evaluation method is the same as that of Embodiment 1, description here is abbreviate | omitted.

The evaluation unit 103 determines whether or not the deviation is large based on the evaluation result (step S320). When the evaluation unit 103 determines that the divergence is large (“Yes” in step S320), the generation unit 100 performs an operation program re-creation process (step S325). Specifically, the generation unit 100 uses the first weather data and the fourth weather data to generate again the third weather data representing the temperature change after the current time. The production | generation part 100 produces | generates an operation program again using the 3rd weather data and operation setting information which were produced | generated again. For example, the generation unit 100 recreates an operation program to be transmitted to the local management device 20 that has transmitted the fourth weather data.

The generation unit 100 performs a retransmission process (step S330). Specifically, the generation unit 100 transmits the operation program generated again to the local management device 20 via the Internet 13. Further, the generation unit 100 updates the operation program associated with the re-transmission destination address among the plurality of operation programs stored in the storage unit 101 to the re-created operation program.

If the evaluation unit 103 does not determine that the deviation is large (“No” in step S320), the generation unit 100 does not perform the re-creation process and the retransmission process of the operation program.

[2.3 Modification of Embodiment 2]
In the present embodiment, one sensor 24 is installed in the building 12, but the present invention is not limited to this. For example, a plurality of sensors 24 may be connected to a plurality of sub-controllers 22 installed in the building 12 on a one-to-one basis. In this case, the control unit 200 may use one temperature change obtained from the measurement results of the plurality of sensors 24 as the fourth weather data. For example, an average value of the temperatures measured at the same time is calculated, and a temperature change including the average value at each time is set as the fourth weather data.

Alternatively, the control unit 200 may generate fourth weather data for each sensor 24. In this case, the evaluation unit 103 of the operation management server 10 evaluates the divergence between each of the plurality of fourth weather data and the third weather data. When the evaluation unit 103 determines that the deviation is large in the evaluation result, the generation unit 100 includes control data including the sub-controller address 152 of the sub-controller 22 connected to the sensor 24 that measures the fourth weather data used for the evaluation. Recreate all 150.

(3 Modifications)
As mentioned above, although this invention was demonstrated based on each embodiment, this invention is not limited to embodiment mentioned above. For example, the following modifications can be considered.

(1) In each of the above embodiments, the controller 21 and the sub-controller 22 and the sub-controller 22 and one or more devices 23 are connected by a cable and communicate with each other. However, the present invention is not limited to this. .

Communication between the controller 21 and the sub-controller 22 and between the sub-controller 22 and one or more devices 23 may be performed wirelessly.

Similarly, communication between the sensor 24 and the controller 21 may be performed wirelessly.

(2) Although the first meteorological data described above includes the predicted maximum temperature and the predicted minimum temperature for each day in the control target period, the humidity, weather, and solar radiation predicted for each day in the control target period are also included. It may include volume, wind speed, wind direction or pressure.

For example, the case where the humidity (expected humidity) estimated for each day of the control target period is included in the first weather data will be described. When the generation unit 100 determines that the predicted humidity included in the first weather data is high, the generation unit 100 performs control so as to control on / off of the dehumidifying function of the device 23 (air conditioner) on the target day where the predicted humidity is expected. Generate data. In addition, when the generation unit 100 determines that the predicted humidity included in the first weather data is low, the generation unit 100 controls on / off of the humidification function of the device 23 (air conditioner) on the target date where the predicted humidity is expected. Generate control data.

(3) A comprehensive or specific aspect of the present invention may be realized by a system, a method, an integrated circuit, a computer program, or a recording medium such as a computer-readable CD-ROM. You may implement | achieve with arbitrary combinations of a computer program or a recording medium.

Other forms obtained by subjecting the embodiments to various modifications conceived by those skilled in the art, and forms realized by arbitrarily combining the components and functions in the embodiments without departing from the spirit of the present invention. It is included in the present invention.

(4 Summary)
As described above, the operation management server 10 is the operation management server 10 installed outside the building 12 and includes the generation unit 100 and the communication unit 104. The generation unit 100 generates an operation program for controlling the device 23 installed in the building 12. The communication unit 104 transmits the operation program generated by the generation unit 100 to the local management device 20 that controls the device 23 according to the operation program. The generation unit 100 generates third weather data from the first weather data and the second weather data. The first weather data includes a predicted maximum temperature and a predicted minimum temperature corresponding to the location of the building 12 for each day in the control target period for controlling the device 23. The second weather data represents a change in temperature corresponding to the location of the building 12 on the measurement date before the control target period. The third weather data represents a temperature change along a time series in the control target period. The generation unit 100 generates an operation program used in the control target period based on the generated third weather data.

According to this configuration, the operation management server 10 generates an operation program for the control target period by using the first weather data of the control target period that does not include the expected arrival times of the predicted maximum temperature and the predicted minimum temperature. Yes. As a result, the operation management server 10 can generate an operation program using weather data having a rough prediction content.

Here, it is preferable that the production | generation part 100 specifies 1st time and 2nd time. The first time is a time at which the predicted minimum temperature is reached for each day belonging to the control target period from the temperature change represented by the second weather data. The second time is a time at which the predicted maximum temperature is reached for each day belonging to the control target period from the temperature change represented by the second weather data. The generation unit 100 interpolates the temperature change between the predicted lowest temperature at the first time adjacent to the first time and the predicted highest temperature at the second time along the time series in the control target period. It is preferable to generate weather data.

According to this configuration, the operation management server 10 can generate the third weather data from the predicted minimum temperature time and the predicted maximum temperature time.

Here, it is preferable that the generation unit 100 generates an operation program from operation setting information that is information on the device 23 and represents an operation state of the device 23 according to the temperature, and third weather data.

According to this configuration, the operation management server 10 can generate an operation program based on the operation state of the device 23 by using the operation setting information.

Here, it is preferable that the operation management server 10 further includes a changing unit 102 (setting information changing unit) that changes the operation setting information.

According to this configuration, the operation management server 10 can change the operation setting information. For example, the operation management server 10 can change the operation according to the deterioration of the performance of the device 23 and change the regular operation of the device 23.

Here, it is preferable that the operation management server 10 further includes an evaluation unit 103 that evaluates a divergence of the third weather data with respect to the fourth weather data representing the temperature change measured within the control target period. When the evaluation unit 103 evaluates that the deviation is large, the generation unit 100 preferably regenerates the operation program.

According to this configuration, the operation management server 10 can correct the difference between the actual temperature change and the predicted temperature change. Therefore, the operation management server 10 can generate a more appropriate operation program.

Here, a plurality of buildings 12 exist in a predetermined area, and a local management device 20 exists for each building 12. The operation program is generated by the generation unit 100 and transmitted by the communication unit 104 for each building 12. The evaluation unit 103 evaluates the divergence using the data representing the temperature change measured in the predetermined area as the fourth weather data, and the generation unit 100 evaluates that the divergence is large by the evaluation unit 103. It is preferable to recreate each of the plurality of operation programs.

According to this configuration, the operation management server 10 can generate an appropriate operation program for each area where the building 12 exists.

Here, it is preferable that the evaluation unit 103 acquires, from the local management device 20, data representing a temperature change measured by the building 12 as the fourth weather data.

According to this configuration, the operation management server 10 can generate an appropriate operation program for each building 12.

The operation management system is an operation management system 1 including any one of the operation management servers 10 and the local management device 20, and the local management device 20 uses the operation program to control the device 23. A unit 210 is provided.

According to this configuration, the operation management system 1 can generate an operation program using meteorological data (first meteorological data) with rough prediction accuracy.

Here, the local management device 20 preferably includes a generation unit 211 (program generation unit) that generates a local operation program in order to control the device 23 differently from the control using the operation program.

According to this configuration, the operation management system 1 can make a temporary operation change to the device 23 installed in the building 12 by using the local operation program.

Here, it is preferable that the local management device 20 includes a changing unit 212 (program changing unit) that changes the operation program.

According to this configuration, the operation management system 1 can change the operation program.

Here, there are a plurality of devices 23. The generation unit 100 generates an operation program for controlling each of the plurality of devices 23. The control processing unit 210 individually controls the plurality of devices 23 using the operation program, and the change unit 212 changes the operation program for each device 23. The local management device 20 preferably further includes an instruction unit 213. When the change unit 212 makes the same change to a predetermined number of devices 23 among the plurality of devices 23, the control unit 210 changes all the devices 23 with the same change contents. In order to control, the operation management server 10 is instructed to generate a new operation program.

According to this configuration, the operation management system 1 can generate a new operation program according to the contents changed for each device 23.

Further, the operation management method includes generation processing and communication processing. In the generation process, an operation program for controlling the equipment 23 installed in the building 12 is generated. In the communication process, the operation program generated by the generation process is transmitted to the local management device 20 that controls the device 23 according to the operation program. The generation process generates third weather data from the first weather data and the second weather data. The first weather data includes a predicted maximum temperature and a predicted minimum temperature corresponding to the location of the building 12 for each day in the control target period for controlling the device 23. The second weather data represents a change in temperature corresponding to the location of the building 12 on the measurement date before the control target period. The third weather data represents a temperature change along a time series in the control target period. The generation process generates an operation program used in the control target period based on the generated third weather data.

According to this operation management method, an operation program can be generated using meteorological data (first meteorological data) whose accuracy of forecast contents is rough.

DESCRIPTION OF SYMBOLS 1 Operation management system 10 Operation management server 12 Building 20 Local management apparatus 23 Equipment 100 Generation part 102 Change part (setting information change part)
103 Evaluation Unit 104 Communication Unit 210 Control Processing Unit 211 Generation Unit (Program Generation Unit)
212 Change part (program change part)
213 Instruction section

Claims (12)

1. An operation management server installed outside the building,
   A generating unit that generates an operation program for controlling equipment installed in the building;
   A communication unit that transmits the operation program generated by the generation unit to a local management device that controls the device according to the operation program;
   The generation unit includes first meteorological data including an estimated maximum temperature and an estimated minimum temperature corresponding to a location of the building for each day in a control target period for controlling the device, and the building on a measurement date before the control target period. From the second meteorological data representing the temperature change corresponding to the location of the location, generating the third meteorological data representing the temperature change along the time series in the control target period, based on the generated third meteorological data, An operation management server that generates the operation program used in a control target period.
2. The generator is
   From the temperature change represented by the second weather data, specify the first time that becomes the predicted minimum temperature for each day belonging to the control target period,
   From the temperature change represented by the second weather data, specify the second time that becomes the predicted maximum temperature for each day belonging to the control target period,
   Interpolating the temperature change between the predicted minimum temperature at the first time adjacent to the control target period and the predicted maximum temperature at the second time, along the time series, the first time The operation management server according to claim 1, wherein three weather data are generated.
3. The generator is
   3. The operation according to claim 1, wherein the operation program is generated from operation setting information representing the operation state of the device according to an air temperature and the third weather data. Management server.
4. The operation management server according to claim 3, further comprising a setting information changing unit that changes the operation setting information.
5. And an evaluation unit that evaluates a deviation of the third weather data with respect to the fourth weather data representing a temperature change measured in the control target period,
   The operation management server according to any one of claims 1 to 4, wherein the generation unit regenerates the operation program when the evaluation unit evaluates that the deviation is large.
6. A plurality of the buildings exist in a predetermined area,
   The local management device exists for each building,
   The operation program is generated by the generation unit and transmitted by the communication unit for each building,
   The evaluation unit evaluates the deviation using data representing a temperature change measured in the predetermined area as the fourth weather data,
   The operation management server according to claim 5, wherein the generation unit recreates each of the plurality of operation programs when the evaluation unit evaluates that the deviation is large.
7. The evaluation unit is
   The operation management server according to claim 5, wherein the fourth weather data is acquired from the local management device as data representing a temperature change measured at the building.
8. An operation management system comprising the operation management server according to any one of claims 1 to 7 and the local management device,
   The local management device is:
   An operation management system comprising a control processing unit that controls the device using the operation program.
9. The local management device is:
   The operation management system according to claim 8, further comprising a program generation unit that generates a local operation program in order to perform control different from control using the operation program for the device.
10. The local management device is:
    The operation management system according to claim 8, further comprising a program change unit that changes the operation program.
11. There are a plurality of the devices,
    The generation unit generates the operation program for controlling each of the plurality of devices,
    The control processing unit individually controls the plurality of devices using the operation program,
    The program change unit changes the operation program for each device,
    The local management device further includes:
    When the same change is made to a predetermined number of devices among the plurality of devices by the program change unit, the control processing unit controls all of the plurality of devices with the contents of the same change. The operation management system according to claim 10, further comprising: an instruction unit that instructs the operation management server to generate a new operation program.
12. Generation processing for generating an operation program for controlling equipment installed in the building;
    A communication process for transmitting the operation program generated by the generation process to a local management device that controls the device according to the operation program;
    The generation process includes first meteorological data including a predicted maximum temperature and a predicted minimum temperature corresponding to a location of the building for each day in a control target period for controlling the device, and the building on a measurement date before the control target period. From the second meteorological data representing the temperature change corresponding to the location of the location, generating the third meteorological data representing the temperature change along the time series in the control target period, based on the generated third meteorological data, An operation management method, comprising: generating the operation program used in a control target period.

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