KR101595768B1 - Building management system and method of generating database of equipments in building - Google Patents

Abstract

A building management system and a method thereof for building a building in a database are disclosed. The building management server displays a list of point-of-control points for the equipment selected by the user on the equipment map, which represents groups of equipment in the building, displays the controller point-of-view interface on the screen, The above mapping points and the mapping relationship of the controller selected through the controller perspective interface are stored in the database.

Description

FIELD OF THE INVENTION The present invention relates to a building management system and a method thereof,

The present invention relates to a building management system and a method for creating a database for controlling and managing various equipment including an air conditioner in a building.

1, a plurality of controllers 110 and a plurality of controllers 110 are connected to a building management system (BMS) in order to control various devices 120 such as an air conditioner, an air conditioner, (100).

The equipment and the controller are connected in a relation of n: m (n, m is an integer of 1 or more), and the controller includes k points (k is an integer of 1 or more). If there is a change of equipment or a change of physical or logical position of controller or point, user should set mapping relation between equipment-controller-control point each time.

However, in the case of large buildings, there are not a few devices to be managed, and there are many controllers and control points for controlling them. Therefore, when the mapping relation between them is changed, it is difficult for the user to accurately reflect the changes. Therefore, it is necessary to build a database that can easily reflect the change of the mapping relationship due to the physical location change of the controller and the like.

Patent Publication No. 2013-0096601

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a building management server and a method for constructing a database that can easily reflect a mapping relationship of a control point due to a physical location change or the like of the controller .

According to an aspect of the present invention, there is provided a building management server comprising: a device registration unit for receiving equipment information including a name of each equipment type through a graphic interface; A control point registering unit which is registered through the equipment registration unit and receives control point information on the equipment type selected by the user from the equipment type list displayed on the screen through the graphic interface; And an equipment reference information database for mapping, storing, and managing equipment information and control point information input through the equipment registration unit and the control point registration unit.

According to another aspect of the present invention, there is provided a building management server, comprising: an equipment reference information database storing types of equipment in a building and control point information of each equipment; A display unit for displaying a device map composed of items indicating buildings in the building; A mapping unit configured to set the type of equipment represented by each item of the equipment map with reference to the equipment reference information database; And an equipment map database for storing the equipment map.

According to another aspect of the present invention, there is provided a building management server comprising: a device map display unit displaying an equipment map, which is displayed by grouping equipment in a building, on a screen; A control point display unit for displaying on the screen a list of control points for equipment selected by the user in the equipment map; A controller display unit for displaying the controller viewpoint interface on the screen; And a link unit for storing at least one control point selected through the control point list and a mapping relation of a controller selected through the controller viewpoint interface in a database.

According to another aspect of the present invention, there is provided a method of managing a building, the method comprising: displaying an equipment map, which is formed by grouping items indicating units in a building, on a screen; Displaying a list of equipment types on the screen by referring to a device reference information database storing types of equipment in buildings and control point information for each type of equipment; And storing the mapping relationship between the item selected through the device map and the device type selected through the device type list in the database.

According to the present invention, it is possible to easily grasp which control point is mapped to the control point from the viewpoint of equipment. In addition, if the control point is to be remapped due to the change of the position of the controller, the control points can be easily remapped from the viewpoint of the user easily recognizable. Also, by using the standardized name from the equipment point of view, it is easy for the user to identify the point of control of the equipment with the control point name alone. In addition, even when there is a change of the position of the controller, there is no need to perform a remapping operation on the control point registered in the application such as the graphic interface, the control logic, and the scheduling. do.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a diagram illustrating an example of a general structure for building management of a building management system,
Figure 2 illustrates an example of a controller perspective interface for management of equipment in a building;
3 illustrates an example of mapping control points of a controller and a device using a controller perspective interface;
Figure 4 illustrates an example of utilizing pointed mapped points through a controller perspective interface;
5 is a diagram illustrating an example of a remapping process when changing a point of control in a database based on a controller viewpoint interface;
6 is a view showing a configuration of an example of a building management server for building a database based on the equipment perspective interface,
Figure 7 illustrates a flow of an example of a method for building a database based on a machine perspective interface;
8 is a view showing an example of a graphic interface screen for building a database based on the equipment perspective interface,
9 is a view showing a configuration of an example of a building management server for creating a device perspective view interface based on a device reference information database;
10 is a view showing an example of a graphic interface screen for constructing an equipment map based on the equipment reference information database,
11 shows a flow of an example of a method for constructing an equipment map based on an equipment criteria information database,
12 shows a configuration of an example of a building management server for mapping a point of view and a controller using an equipment perspective interface;
13 is a view showing an example of a graphical interface screen for mapping the point of view and the controller using the equipment perspective interface;
14 shows a flow of an example of a method of mapping a point of view and a controller using an equipment perspective interface,
15 illustrates an example of a method for generating a name of a point to be mapped to a controller based on a device perspective interface;
FIG. 16 illustrates an example of utilizing a point created using the equipment perspective interface, and FIG.
17 is a diagram showing an example of a method of changing a point of control when a point created using the equipment perspective interface is changed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, with reference to the accompanying drawings, a detailed description will be given of a building management system and a method thereof for database-building equipment according to the present invention.

First, a building management server according to the present invention includes an input device such as a keyboard, a mouse, and a touch screen for receiving various commands and data from a user, a display device, a processor for performing various operations and data processing, A storage device such as a memory, etc. Hereinafter, for the sake of convenience of explanation, each configuration of a building management server is expressed by a term such as "equipment registration part " to better illustrate the features of the present invention, Memory, input / output devices, and the like.

FIG. 2 illustrates an example of a controller perspective interface for management of in-building equipment, and FIG. 3 illustrates an example of mapping controllers and equipment point of view using a controller perspective interface.

2 and 3, the controller perspective interface 300 represents the in-building controller in a hierarchical structure. For example, the building management server groups the controllers in units of "COUNTRY" - "SITE GROUP" - "SITE" - "STATION GROUP" - "STATION" Lt; / RTI > "STATION", "DEVICE", and "MODULE", which are located at the bottom of the hierarchical structure of the controller viewpoint interface 300, represent controllers, and "SITE" and "STATION-GROUP" . For example, controllers may be grouped in units of a floor of a building, each zone of each floor, and the like, and expressed as a controller viewpoint interface 300.

The particular controller 310 of the controller perspective interface 300 is mapped to the control points 350, 352, 254, 356, 358, 360 of at least one or more of the devices 320. There are several ways in which the system can identify points of control. As a first method, the controller has a controller unique code and has a controller specific code included in the controller and a mapping point unique code mapped. For example, when the inherent code of the controller 310 is 'A', the control points 350, 352, 254, 356, 358 and 360 belonging to the controller 310 combine 'A' -3, and so on. In this case, the point code is unique in the system, and the system that intends to use the point is referred to the point code directly.

As a second identification method, it has a unique code of the control point only in the controller. For example, when the inherent code of the controller 310 is 'A', the control points 350, 352, 254, 356, 358 and 360 belonging to the controller 310 have unique codes such as 1, Also, when the unique code of another controller 310 is 'B', the control points 350, 352, 254, 356, 358 and 360 belonging to the controller 310 have unique codes such as 1, In this case, the control point code is unique only in the controller, and the system which intends to use the control point refers first to the unique code of the controller 310 to which the control point belongs, and then refers to the unique code of the control point again.

However, whichever method is used, the system can refer to the unique code value of the controller and the point of control and find the point of control.

Figure 4 is an illustration of an example of utilizing pointed mapped points through a controller perspective interface.

Referring to FIG. 4, the building management server includes a graphical interface 400 that represents objects in a building as objects, a control logic 410 for a specific operation, and a scheduling 420 that can automatically manage operation time and schedule of the equipment ), And the like. The building management server may map the point of control 350 to the object 402 of the graphical interface 400 for implementation of each application or map the point of control 352 to the input / output of the diagram 412 of the control logic 410 Or maps them to the control object 422 of the schedule 420. [ For example, the unique code A-1 of the control point 350 is mapped to the object 402 of the graphical interface, and the control code logic diagram 412 is mapped to the unique code of the controller 352, do.

The building management server can recognize the state of the equipment (for example, the temperature of the heating water) through the mapped control point and the object 402 displayed on the graphic interface, Off, specific value, and the like.

FIG. 5 is a diagram illustrating an example of a remapping process when changing a control point in a database based on a controller viewpoint interface.

Referring to FIG. 5, when the physical location of the controller or the like is changed, the unique code of the control point must be mapped again. For example, the control points Z-1 and Z-2 of a particular device Z were mapped to A-1 and A-2 of the device A, B-1, B-2, the diagram 412 of the control logic should also be mapped back to the unique code B-2 of the mapped control point.

The controller viewpoint interface has an advantage that it is possible to easily identify which control point is mapped from the viewpoint of the controller, but if the mapping relation of the control point is changed after the position of the controller is changed, the mapping relation for the control point is re- There is a hassle.

Hereinafter, an example of building a database using a device-view interface that does not require the mapping operation in each application to occur again even if a position change of the controller occurs.

6 is a diagram showing a configuration of an example of a building management server for building a database based on the equipment perspective view interface.

6, the building management server 600 includes a device registration unit 610, a point registration unit 620, and an equipment reference information database 630.

The equipment registration unit 610 receives equipment information including the name of each equipment type from a user through a graphical interface. For example, as shown in FIG. 8, the equipment registration unit 610 displays a device type list 800 on one side of the screen, and instructs the user to add, delete, And processes it.

For example, when the equipment registration unit 610 receives a command for adding or correcting a new equipment type from a user, the equipment registration unit 610 displays a equipment type profile screen 820 for registering or correcting equipment information on one side of the screen as shown in FIG. And various information such as a device type name, a manufacturer name, an equipment model name, a protocol type, and a data format can be inputted from the user through the equipment type profile screen 820.

The equipment registering unit 610 is registered not only for all the equipment existing in the building, but only once for the same type of equipment. For example, if there are five refrigerators of the same model of company A in the building, one device information for the refrigerator type is registered for the refrigerator type A of the company A, not for registering the five pieces of equipment information. Since the same type of equipment has the same point list, equipment with the same point list can be regarded as the same type of equipment.

The control point registering unit 620 provides the user with a graphical interface for inputting control point information of the selected equipment type when a specific equipment type for registering the control point is selected from the list of equipment types displayed on the screen. For example, when the user selects the absorption type refrigerator 802 in the equipment type list 800 as shown in FIG. 8, a graphical interface 810 for inputting point information for the absorption type refrigerator 802 is displayed, Point information is input.

In this case, when the user selects a specific equipment type, the control point registering unit 620 displays a list of control points registered in advance for the corresponding equipment type on the screen , The user is registered for selection of a control point or addition of a control point based on the control point list.

The equipment reference information database 630 maps and stores equipment information and control point information received through the equipment registration unit 610 and the control point registration unit 620. Since the equipment reference information database 630 stores equipment information for each type of equipment, it is desirable not to store redundant information for the same type of equipment having the same point list.

For example, if there is a building control system that manages 10 aids in a building, and 10 aids are all the same type of ace, the equipment base information database 630 registers and stores the ace information only once.

7 is a diagram illustrating a flow of an example of a method for constructing a database based on the equipment perspective interface.

Referring to FIG. 7, the building management server drives a program for device information registration to provide a graphical interface (S700). The graphic interface provides equipment registration screens 800 and 820 and a control point registration screen 810 as shown in FIG. The building management server receives the equipment information including the name of each equipment type from the user through the equipment registration screen (S710). In addition, the building management server registers the control point of the equipment type selected by the user on the control point registration screen (S720). The building management server stores the equipment information and the control point information in the equipment reference information database (S730).

8 is a diagram illustrating an example of a graphic interface screen for building a database based on the equipment perspective view interface.

Referring to FIG. 8, the building management server provides a graphical interface screen including a device type list 800, a control point list 810, and a device type profile 820. The device type list 800 displays various types of devices registered by the user and performs operations such as adding, deleting, and correcting device types through various icons or commands provided on the device type list screen 800. The information for each device type can be inputted through the device type profile screen 820. [

When the user selects a particular equipment type, e.g., absorption refrigerator 802, in the equipment type list 800, the building management server displays the point list 810 associated with the absorption chiller through a graphical interface. The user can select a control point to map with the absorption type refrigerator through the interface of the control point list (810) or additionally register a control point. Type, channel number, name, unit information, and the like can be registered as attribution information of the point of control.

FIG. 9 is a diagram showing a configuration of an example of a building management server that creates an equipment perspective view interface based on the equipment reference information database.

9, the building management server 900 includes an equipment map database 910, an equipment reference information database 920, a display unit 930, and a mapping unit 940.

The equipment map database 910 stores a device map composed of items indicating buildings in the building. The equipment map shows all the equipment in the building by various display methods such as hierarchical structure and graphic structure. For example, as shown in FIG. 10, the equipment map can divide buildings into physical spaces (for example, first floor, second floor), and classify the devices based on the respective physical spaces and display them hierarchically . Of course, various other criteria can be used as a basis for classifying the equipment. The user can easily grasp the equipment in the building using the equipment perspective interface.

The equipment reference information database 920 is a database that stores and manages equipment types existing in a building and control point information for each type of equipment as described with reference to FIGS.

The display unit 930 reads out the equipment map already built in the equipment map database 910 and displays it on the screen. If there is no equipment map established in the equipment map database 910, the display unit provides a graphical interface for generating equipment maps. For example, the display unit 930 displays the equipment map 1000 as shown in FIG. 10 on the equipment map database 910 and provides the user with a graphical interface for generating the equipment map. The user can perform operations such as adding, deleting, or correcting specific equipment in the equipment map.

The mapping unit 940 refers to the equipment reference information database to set which equipment type each item of the equipment map represents. Specifically, when the user selects a specific item of the equipment map, the display unit 930 reads the equipment type list from the equipment reference database 920 and displays it on the screen. The user selects a device map type and a device type mapped by the display unit 930 from the equipment type list displayed on the screen. The mapping unit 940 maps the items of equipment type and equipment map selected by the user and stores them in the equipment map database 910. Since the equipment reference information database 920 has the equipment type and the mapped control point information, the item of the equipment map is also mapped to the control point information.

In the present embodiment, the equipment map database and the equipment reference information database are separately displayed for the sake of convenience of description. However, it is needless to say that the two databases can be implemented as one embodiment in another embodiment.

10 is a diagram illustrating an example of a graphic interface screen for constructing an equipment map based on the equipment reference information database.

Referring to FIG. 10, the building management server displays a device map 1000 and a device type list 1010 on a screen, and provides a graphical interface that can process various commands and inputs from a user.

The user can easily select the equipment item and the equipment type from the equipment map 1000 and the equipment type list 1010 through the graphical interface to easily set the mapping relationship therebetween. For example, when the user selects the refrigerator # 1-1 (1002) of the equipment map, the building management server displays the equipment type list 1010 on the screen. When the user selects the freezer 1012 in the equipment type list 1010, the building management server maps the freezer # 1-1 1002 and the freezer 1010 and stores them in the equipment map database.

11 is a diagram showing a flow of an example of a method for constructing an equipment map based on the equipment reference information database.

Referring to FIG. 11, the building management server provides a graphical interface for editing each item of the equipment map (S1100). The building management server receives various commands such as addition, deletion, and correction of equipment map items from the user through the graphic interface. In case of the delete command, the building management server removes the corresponding item from the equipment map, adds a new item to the equipment map in the case of an additional command, and receives the name of the item from the user.

When mapping the equipment type to the equipment map item, the building management server selects the equipment map item mapped from the user (S 1110). Then, the building management server provides the user with a graphical interface for selecting the equipment type, and the user selects the equipment type from the equipment type list displayed on the screen (S1120). The building management server maps and stores items of the equipment map and equipment types (S1130, S1140).

12 is a diagram showing a configuration of an example of a building management server that maps a point of view and a controller using the equipment perspective interface.

12, the building management server includes an equipment map database 1200, an equipment map display unit 1210, a control point display unit 1220, a controller database 1230, a controller display unit 1240, a link unit 1250, A point name setting unit 1260, a channel setting unit 1265, and a control point mapping database 1270.

In the present embodiment, the equipment map database 1200, the controller database 1230, and the control point mapping database 1270 are separately displayed for the sake of convenience of explanation, but they may be constructed as one database as another embodiment.

The equipment map database 1200 is the same as the equipment map database described in Fig. The controller database 1230 is a database storing a controller list in the building as shown in FIG.

The equipment map display unit 1210 reads the equipment map from the equipment map database 1200 and displays the equipment map on the screen. When the user selects a specific item of the equipment map through the equipment map displayed on the screen, the control point display unit 1220 displays the list of control points mapped with the item. For example, the control point display unit 1220 searches the equipment reference information database (920 in FIG. 9) based on the selected equipment map item and the mapped equipment type, and finds and displays the control point list.

The controller display unit 1240 refers to the controller database 1230 and displays a list of controllers in the building on the screen.

The link unit 1250 maps the control point selected by the user and the controller selected by the user on the controller display unit 1240 out of the control point list displayed by the control point display unit 1220 and stores them in the control point mapping database 1270.

The control point name setting unit 1260 generates and provides the names of the control points mapped to the controller based on the unique code of the equipment to which the control point belongs. In the case of the controller viewpoint interface shown in FIG. 4, the point name is generated based on the inherent code of the controller, while the point name setting unit 1260 of the present embodiment sets a unique point code . An example of generation of a point name will be described with reference to Fig.

The channel setting unit 1265 sets a unique channel to the control points mapped to the controller. The channel setting unit 1265 may automatically allocate a unique channel that is not duplicated for each control point or input a channel for each control point from the user, It is preferable to prevent duplication.

13 is a diagram illustrating an example of a graphical interface screen for mapping a point of view and a controller using the equipment perspective interface.

13, the building management server provides a device perspective interface 1300, a device map and controller perspective interface 1370, and a mapping screen 1380 for mapping control points and controllers.

When the user selects a specific item of the equipment map 1300, the building management server displays a control point list 1310 belonging to the item on one side of the mapping screen 1380. The control point list 1310 may include information such as name, time, and unit of each control point.

In the next column of the point list 1310, a link box 1320 exists. The user can select a link box from the controller perspective interface 1370 after selecting a controller to map with the point of view.

When the link section selection is completed, the building management server maps the control point and the selected control point through the link box, and displays the control point name 1330, the controller name 1360, and the like on the mapping screen. The point name 1330 can be automatically generated and displayed or input from the user. The point name 1330 may also be normalized according to the method shown in FIG.

In the mapping screen 1380, there is a channel field 1350 for channel setting for communication between the control point and the controller. The controller point of view of the controller viewpoint interface 1370 may be previously mapped to point-of-control information to which a particular channel is assigned. When the user inputs a specific channel number into the channel column 1350, the building management server searches channels allocated to the controller in the controller database (1230 in FIG. 12), and if the same channel number as the channel number inputted by the user already exists (1340). ≪ / RTI >

14 is a diagram showing a flow of an example of a method of mapping a point of view and a controller using the equipment perspective interface.

Referring to FIG. 14, the building management server reads the equipment map stored in the equipment map database at the request of the user and displays the equipment map on the screen (S1400). When a user selects an item indicating a specific device from the equipment map displayed on the screen, the building management server displays a list of mapped points on the screen and selects a point to be mapped to the controller from the user through the point list (S1410).

After receiving the controller selection from the user (S1420), the building management server maps the selected point to the controller (S1430), sets the name of the mapped control point (S1440), and stores the mapping point and the mapping information of the controller in the database (S1450).

15 is a diagram illustrating an example of a method for generating a name of a point to be mapped to a controller based on a device perspective interface.

Referring to Fig. 15, when the user clicks the "standardization" icon in the mapping screen of Fig. 13, the building management server displays the standardized control points by using the unique identification information of the corresponding control point and the unique identification information of the equipment to which the control point belongs Create a name.

For example, if the equipment name to which the control point is clicked is "HVAC 1", the equipment unique code is "2", the control point code is "3", the channel number is "5" AHU (air conditioner 1) _DAMPER_OPEN_AI_5 "when the equipment name for the equipment unique code '2' stored in the information table is 'AHU' and the control point name for control point code '3' is 'DAMPER_OPEN' And assigns the standardized name to the corresponding point.

The standardized name generation method is not limited to the method described in Fig. 15, but may be a name generated in a formalized manner based on the control point name so that the user can easily grasp to which equipment the control point belongs, There can be a way.

FIG. 16 is a view showing an example of utilizing a point created by using the equipment perspective interface, and FIG. 17 is an example of a method of changing a point when a point created using the equipment perspective interface is changed FIG.

Referring to FIG. 16, the point of control is mapped to all the objects to be monitored and controlled after being registered as objects of the graphical interface, input / output of the control logic, control targets of the schedule, In the case of the equipment perspective interface, the control point unique code is generated based on the unique code of the equipment to which the control point belongs.

For example, the equipment point of view point code consists of a combination of equipment unique code and equipment point specific code. For example, when the equipment inherent code is '111', codes of control points belonging to the equipment are set as 111-1 and 111-2, and control point specific codes 111-1 and 111-2 are set as shown in FIG. 16 It is mapped to objects of various applications.

Therefore, when the mapping relationship of the control point is changed due to the physical position change of the controller or the like, as shown in FIG. 17, the user only needs to newly set the mapping relationship of the control point through the equipment perspective interface shown in FIG. 13, There is no need to modify the mapping relationship of points again. That is, the unique code of the point mapped at the application end is not changed.

The present invention can also be embodied as computer-readable codes on a computer-readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like. The computer-readable recording medium may also be distributed over a networked computer system so that computer readable code can be stored and executed in a distributed manner.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

Claims (13)

A device registration unit for receiving device information including a name of each device type through a graphic interface;
A list of control points registered in a preset form for the type of equipment selected by the user from the equipment type list displayed on the screen and registered through the equipment registration unit, and the selection of the cooking point or the addition of the control points in the control point list is input through a graphic interface Receiving point register; And
And an equipment reference information database for mapping and storing equipment information and control point information inputted through the equipment registration unit and the control point registration unit,
Wherein the equipment reference information database regards equipment types including the same point information as equipment of the same type to prevent duplicate registration of equipment types including the same point information. delete The control point registration system according to claim 1,
A list of points of control set in advance according to the type of equipment registered by the equipment registration unit is displayed on a screen through a graphical interface, and a selection of control points displayed on the control point list or addition of control points is input from the user, Wherein the management server is configured to generate the management information. The equipment that stores the types of equipment in buildings and control point information for each type of equipment is regarded as the same kind of equipment including the same control point information and prevents duplicate registration of equipment types including the same control point information A reference information database;
A display unit for displaying a device map composed of items indicating buildings in the building;
A mapping unit configured to set the type of equipment represented by each item of the equipment map with reference to the equipment reference information database; And
And an equipment map database for storing the equipment map. 5. The method of claim 4,
And a display unit for displaying the equipment type list on the screen by referring to the equipment standard information database and displaying the equipment map item on the screen,
Wherein the mapping unit maps the selected item and equipment type through the equipment map and the equipment type list displayed on the screen. The display device according to claim 5,
Wherein the building management server divides a building into at least one physical space, and displays an equipment map in which items of equipment located in respective physical spaces are grouped. An equipment map display unit for displaying on the screen an equipment map representing groups of equipment in a building;
A control point display unit for displaying on the screen a list of control points for equipment selected by the user in the equipment map;
A controller display unit for displaying on the screen a controller viewpoint interface indicating a list of in-building controllers;
A link unit for storing at least one control point selected through the control point list and a mapping relation of a controller selected through the controller viewpoint interface in a database; And
And a channel setting unit for receiving channel information between the control point and the controller and storing the received channel information in a database,
Wherein the channel setting unit searches channels allocated to each controller to display whether or not the channels are duplicated. 8. The method of claim 7,
And a control point name generation unit for generating a name of the selected at least one control point by a combination of identification information of the equipment and identification information of the control point. 8. The method of claim 7,
And a channel input unit for receiving channel information between the control point and the controller and storing the received channel information in a database. Displaying on the screen an equipment map configured by grouping items indicating units in a building;
Displaying a list of equipment types on the screen by referring to a device reference information database storing types of equipment in buildings and control point information for each type of equipment; And
And storing the mapping relationship between the item selected through the device map and the device type selected through the device type list in a database,
Wherein the equipment reference information database regards equipment types including the same point information as equipment of the same type to prevent duplicate registration of equipment types including the same point information. 11. The method of claim 10,
Displaying a list of mapped points mapped with items of the equipment map;
And mapping and storing at least one control point selected through the control point list and a controller selected through the controller viewpoint interface. 12. The method of claim 11,
And generating the name of the control point mapped to the controller as a combination of the identification information of the equipment to which the control point belongs and the control point identification information. A computer-readable recording medium recording a program for performing the method according to any one of claims 10 to 12.

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