KR20150043170A - System and Method for Managing Energy - Google Patents

Abstract

The energy management system according to one aspect of the present invention, which can provide an energy management system on a platform basis by standardizing and quantifying the tasks for which the energy management system is to be established, includes a standard term, a standard code Basic data including at least one of a standard attribute, a general criterion, a general criterion, a unit conversion, and a pattern code and a facility to be subjected to energy management, A workbench module for setting up an energy management system by setting work information including at least one of an energy type, a facility to be checked for energy consumption, a target area for energy management, and an environment element to be monitored; And an energy management module for analyzing energy use efficiency of the facilities or the target facilities by using measurement data obtained from the sensors disposed on the site when the energy management system is set up by the work bench module .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy management system,

The present invention relates to an energy management system, and more particularly, to an energy management system for a facility such as a building or a factory, and a construction method thereof.

Recently, various facilities such as air conditioning, energy, sanitation, lighting, electric power, crime prevention, disaster prevention, etc. are being built together as facilities such as buildings or factories are becoming larger and more sophisticated.

Here, the term "energy equipments" refers to a heat source and a heat transfer facility for producing and supplying a heat source for providing services such as cooling, heating, air conditioning, ventilation, and lighting in a facility by using energy such as electricity or gas .

This energy facility is an energy consuming facility that accounts for more than 30% of the total energy consumption of the facility. In addition, since the energy facilities are designed assuming a full load, the actual operation efficiency of the facilities energy facilities, which are operated in partial loads in most cases, may differ from the rated efficiency presented in the design standards, and this inefficient If facility operation continues without correction, the annual energy use of the facility may increase by more than 30% to 50%.

Therefore, in order to minimize energy wastage, it is necessary to continuously maintain and operate the equipment in an optimal state by continuously monitoring the actual efficiency of the operation of the energy equipment being operated.

However, there is a problem that it is not reliable for the facility operator to manually calculate the operation efficiency of the complex and large-scale air conditioning system or related equipment whenever necessary or to diagnose the efficiency decrease of the facility from the calculated efficiency value.

Therefore, in order to solve such a problem, an energy management system (Energy Management System) that automatically calculates the performance and efficiency of the facility by using the operation data of the facility measured through various sensors and provides the facility operator with various graphs, Has been proposed. An example of such an energy management system is disclosed in Korean Patent Laid-Open No. 10-2009-0066107.

Such an energy management system generally analyzes the business and requirements of a customer who desires to construct an energy management system, and designs and develops the system according to the analysis result.

However, a general energy management system has a disadvantage in that it takes a long time to construct the system because the development resource or system is configured differently for each customer.

In addition, the general energy management system has a disadvantage in that it requires additional cost and time to modify the system, because the system developer must directly modify the newly developed system in accordance with the customer's situation.

An object of the present invention is to provide an energy management system and an energy management method capable of providing an energy management system on a platform basis by standardizing and quantifying the tasks for which an energy management system should be constructed, .

It is another object of the present invention to provide an energy management system and an energy management method that can shorten the time required for constructing and modifying an energy management system.

It is another object of the present invention to provide an energy management system and an energy management method capable of providing an optimized energy management system for each customer.

According to one aspect of the present invention, there is provided an energy management system including a standard term, a standard code, a standard attribute, a general criterion, Unit Conversion, and Pattern Code, a facility to be subjected to energy management, an energy type to be monitored, a facility to be checked for energy consumption, a target area requiring energy management, A workbench module for setting up an energy management system by setting work information including at least one of environmental elements to be monitored, and environmental elements to be monitored; And an energy management module for analyzing energy use efficiency of the facilities or the target facilities by using measurement data obtained from the sensors disposed on the site when the energy management system is set up by the work bench module .

According to another aspect of the present invention, there is provided an energy management system comprising at least one of a work bench module for BEMS, a work bench module for FEMS, a work bench module for FMS, and a work bench module for SI Providing a workbench module selection screen for selecting a bench module; And executing the work bench module selected on the work bench module selection screen to set up the energy management system.

According to another aspect of the present invention, there is provided an energy management system including: a work bench module for setting up element information for energy management by four areas classified according to a business and a system; And an energy management module for collecting measurement data according to the setup and analyzing energy utilization efficiency of a facility or target facilities to be an energy management target, wherein the four areas include a basic data area and a task information area .

According to the present invention, the energy management system can be provided on a platform basis by standardizing and quantifying the tasks for which the energy management system is to be constructed, thereby flexibly reflecting the characteristics of the customer who desires to construct the energy management system .

In addition, according to the present invention, since the energy management system is provided on a platform basis, there is an effect that it is possible to shorten the time required for initial construction of the system as well as modification of the system.

In addition, according to the present invention, it is possible to provide a variety of UIs reflecting various customer needs, thereby providing an optimized energy management system for each customer.

Further, according to the present invention, since the energy management system is provided on a platform basis, the customer can directly set the environment of the energy management system according to the customer's environment, thereby maximizing the facility management level as well as the energy management level of the facility .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the configuration of an energy management system according to an embodiment of the present invention; FIG.
2 is a view showing an example of a work bench module selection screen;
3 is a conceptual diagram showing the division of a data area defined by a workbench module;
4 is a block diagram schematically illustrating the configuration of the work bench module shown in Fig.
5 is a view showing an example of a screen provided by the basic data setting unit shown in FIG.
FIG. 6 is a view showing an example of a screen provided through the task information setting unit shown in FIG. 4. FIG.
FIG. 7 is a view showing an example of a screen provided through the UI setting unit shown in FIG. 4. FIG.
8 is a view showing another example of a screen provided through the UI setting unit shown in FIG.
FIG. 9 is a view showing an example of a screen provided through the personalization unit shown in FIG. 4. FIG.
10 is a view showing an example of a screen provided through the modeling module shown in FIG.
11 is a schematic diagram illustrating an architecture of an energy management system according to an embodiment of the present invention.
12 is a flowchart showing an energy management method by an energy management system according to an embodiment of the present invention;

The meaning of the terms described herein should be understood as follows.

The word " first, "" second," and the like, used to distinguish one element from another, are to be understood to include plural representations unless the context clearly dictates otherwise. The scope of the right should not be limited by these terms.

It should be understood that the terms "comprises" or "having" does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

It should be understood that the term "at least one" includes all possible combinations from one or more related items. For example, the meaning of "at least one of the first item, the second item and the third item" means not only the first item, the second item or the third item, but also the second item and the second item among the first item, Means any combination of items that can be presented from more than one.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Energy management system

First, an energy management system according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 11. FIG.

1 is a schematic view illustrating a configuration of an energy management system according to an embodiment of the present invention.

As shown in FIG. 1, the energy management system 100 according to an embodiment of the present invention enables an operator or a user of a facility to be energy managed to efficiently manage the energy use of the facility.

Here, the term "platform" refers to a type of structure designed for common use in various applications, and refers to a base on which a complementary derivative product or service can be manufactured based on a common utilization factor .

In particular, the energy management system 100 according to the present invention is provided not in a form of an application-type system that is completed and provided for each customer, but in a platform form to a customer, It is a system in the form of completion in form.

In other words, although the conventional general energy management system has been separately provided for each customer by receiving the customer's request, the energy management system 100 according to the present invention is delivered to the customer and, until the customer completes the setup procedure, When the system is not defined and the customer completes the setup procedure, the energy management system is defined.

Accordingly, the energy management system 100 according to the present invention is connected to the system operator terminal (not shown) or the operational operator terminal (not shown) through the Internet network or the intranet network and provided to the system operator or the business operator And the energy management system is optimized for the customer. After completing the system construction in an optimized form for the customer, the energy management system 100 according to the present invention monitors and analyzes the energy efficiency of the facility to be energy managed, and provides the result to the system user.

Here, the facility to be subjected to energy management may be a building or a factory such as a hotel, a commercial building, or a campus.

Hereinafter, the configuration of the energy management system 100 according to the present invention will be described more specifically.

The energy management system 100 according to the present invention includes a work bench module selection module 110, a work bench module 120, a modeling module 125, an energy management module 130, An optimization module 140, an optimization module 150, a reporting module 160, and a data acquisition module 170.

First, the workbench module selection module 110 provides a workbench module selection screen to a system operator or a business operator when a system installation request from the system operator or a business operator is received, thereby allowing a system operator or a business operator to select a workbench module selection screen To select the appropriate workbench module for the facility.

According to this selection, the workbench module selection module 110 loads the workbench module selected by the system operator or the operation operator among the plurality of workbench modules included in the platform on the workbench module selection screen.

At this time, the system operator or the operation operator may select only one workbench module among a plurality of workbench modules, but may select a plurality of workbench modules. Hereinafter, for convenience of explanation, it is assumed that a system operator or a business operator selects one workbench module among a plurality of workbench modules.

In one embodiment, the workbench module selection module 110 may receive a workbench module selection screen 200, such as that shown in FIG. 2, upon receipt of a system installation request from a system operator or a production operator, It can be provided as a business operator. The workbench module selection screen 200 includes a first selection unit 210 for selecting a workbench module for a building energy management system (BEMS), which is formed by grouping elements necessary for building energy management A second selection unit 220 for selecting a work bench module for a factory energy management system (FEMS) manufactured by grouping factors necessary for the energy management of the plant, A third selection unit 230 for selecting a work bench module for a facility management system (FMS) produced by grouping, and a system integration unit 230 for grouping elements necessary for system integration management And a fourth selector 240 for selecting a workbench module for the workbench module.

Next, the workbench module 120 is loaded by the workbench module selection module 110 and means a tool for allowing a system operator or a production operator to set up the energy management system according to the present invention.

In one embodiment, the workbench module 120 includes a workbench module for BEMS, which is formed by grouping the elements necessary for building energy management, as described above, Workbench module for FEMS, workbench module for FMS created by grouping the necessary elements for facility management, and workbench module for SI that is made by grouping elements necessary for system integration management.

Hereinafter, for convenience of explanation, it is assumed that the work bench module for BEMS is loaded by the workbench module selection module 110.

The workbench module 120 according to the present invention can be used to flexibly accommodate various users' demands and business changes using the energy management system by associating various information used in the energy management system with the energy related tasks and the energy management system And four modules for setting or registering each information included in the four areas.

As shown in FIG. 3, the four areas are a basic data area having high association with the energy management system and low association with the energy related work, a high correlation with the energy related work, , The UI area is highly related to the low task information domain, the energy related task and the energy management system, and the personalization domain is low in relation to the energy related task and the energy management system.

4, the work bench module 120 according to the present invention includes a basic data setting unit 410 for setting basic data, a task information setting unit 420 for setting task information A UI setting unit 430 for setting a UI, and a personalization unit 440 for setting data included in the personalization area.

First, the basic data setting unit 410 sets basic data such as terms, items, codes, and tag basic information for the construction and operation of the energy management system using various data input by the system operator or the operation operator . In one embodiment, all the basic data to be set may be set as metadata. Accordingly, when a new item is to be added, an item to be added can be added as a new item in the basic data, so that addition of basic data can be easily performed.

In one embodiment, such basic data can be divided into common data elements and facility data elements used in the energy management system. Therefore, the basic data setting unit 410 can register common data elements used in the energy management system or register facility data elements to be used in the system. Here, the common data element includes a standard term, a standard code, a standard attribute, a general criterion, a unit conversion, and a pattern code used in an energy management system. Or the like.

In addition, the facility data elements can be classified into common facilities (meaning general information of the facilities) that can be included in the facility, performance codes of the respective facilities, efficiency constants of the respective facilities, indicator, constant for each facility, point unit, and raw data refinement rule.

In accordance with this embodiment, the basic data setting unit 410 registers standard terms to be used in the energy management system according to the information input from the system operator, and then generates performance codes, performance constants, The system code, the system standard, and the standard item are registered, and the equipment point unit, the common equipment information, the facility analysis pattern code, the unit conversion value, and the raw data refining rule are registered.

In the above-described embodiment, the basic data setting unit 410 sets all data necessary for building the system according to the information input from the system operator. However, in the modified embodiment, the basic data setting unit 410 sets When the system operator chooses to use various data included in the defaults as it is, various data included in the defaults are registered as they are.

An example of a screen that the basic data setting unit 410 provides to the system operator for setting basic data is shown in FIG. As shown in FIG. 5, the basic data setting unit 410 includes a basic data setting unit 410 and a basic data setting unit 410. The basic data setting unit 410 includes a basic data setting unit 410, By providing the system operator with a screen that includes the facility management, measurement point (facility point) unit management, pattern code management, unit conversion value management, and RAW refining management menu, the screen provided according to the menu selected by the system operator And registers various information input through the Internet. In the above-described embodiment, the screen shown in FIG. 5 is provided to the system operator for convenience of explanation. However, the screen provided to the system operator may be variously reconfigured according to the environment.

Referring again to FIG. 4, the task information setting unit 420 registers various kinds of information on an energy-related business to which the energy management system according to the present invention is applied.

In one embodiment, the task information setting unit 420 registers an energy type to be monitored in the facility, a target facility for which energy usage is to be checked, a target area for which energy management is required, and an environmental factor to monitor. Here, the target facility refers to facilities actually installed in the facility among the common facilities registered by the basic data setting unit 410, and the task information setting unit 420 registers specific specification information of the target facilities .

More specifically, the task information setting unit 420 registers an energy management object (a building, a hospital, a factory, or the like) according to information input from a system operator or a business operator, And registers facilities to be managed among the facilities. Thereafter, the facility points to be managed are registered among the facility points modeled through the modeling module 430, which will be described later, and the virtual points, which are actually unmeasured points, are additionally registered. Then, the task information setting unit 420 registers the energy type to be managed, and maps the registered energy type to the previously registered facility points. After that, the task information setting unit 420 registers the indoor / outdoor environment information and maps the registered indoor / outdoor environment information to pre-registered facility points. In addition, the task information setting unit 420 may register a scenario to be used in an emergency according to information input from a system operator or a business operator, or may additionally register an alarm type to be generated according to an energy status rule.

An example of a screen that the task information setting unit 420 provides to a system operator or a business operator for setting task information is shown in FIG. As shown in FIG. 6, the task information setting unit 420 includes a task information setting unit 420 for setting a menu such as building management, facility management, facility point inquiry, virtual point management, energy system / point mapping, indoor / outdoor environment information management, indoor / outdoor environment information / To the system operator, thereby registering various information inputted through the screen provided according to the menu selected by the system operator.

Next, the UI setting unit 430 registers a UI such as a menu or a screen used in the energy management system according to information input from the system operator or the operation operator. In one embodiment, the UI setting unit 430 sets the authority of the organization, user, and each user in the energy management system, registers a menu screen used in the energy management system, It is possible to register the content configuration of the page to be browsed, to register the component of the report provided to the customer, or to register the bulletin board.

An example of a screen that the UI setting unit 430 provides to the system user for UI registration is shown in FIG. 7, the UI setting unit 430 may provide a system user with a screen including menus such as menu management, screen management, variable screen configuration, user management, rights management, and bulletin board management, Various information inputted through the screen provided according to the menu selected by the operation operator is registered.

In particular, when the system user selects a menu called a variable screen configuration from the menu of the screen shown in Fig. 7, the UI setting unit 430 provides a screen as shown in Fig. 8 to the system user, Analysis results and the like can be configured so that the system operator or the business operator can output the desired image on the screen.

Referring again to FIG. 4, the personalization unit 440 redefines or alters various information used in the energy management system according to the preferences of the system operator or the operation operator. In one embodiment, the personalization unit 440 may include a UI skin, a portlet, and an icon for configuring the energy management system according to information input from the system operator or the operation operator according to the preferences of the system operator or the operation operator. Language, and time zone (TimeZone).

More specifically, the personalization unit 440 may manage the energy management system according to a UI skin, a layout, a portlet, a portlet order, a language, a type zone, and a data display form selected by a system operator or a business operator Respectively.

An example of a screen that the personalization unit 440 provides to the system operator or the business operations redefining the energy management system according to personal preferences is shown in FIG. 9, the personalization unit 440 may provide a system administrator or a business operator with a screen including menus such as a UI skin management, a portlet configuration management, and the like so as to be provided according to a menu selected by a system operator or a business operator The UI skin and the portlet of the energy management system are reconstructed according to various information inputted through the screen.

Meanwhile, in the course of using the energy management system after the completion of the construction of the energy management system according to the present invention, the system user also uses the personalization unit 440 to finance the UI skin or portlet of the energy management system according to his or her preference .

Referring again to FIG. 1, the modeling module 125 displays a connection relationship between each facility and each facility to a system operator or a business operator in order to register facility points of the facilities during business information registration by the business information setup unit 420 , And models the facility points of each facility using the information created by the system operator or the operation operator using the tool.

That is, the modeling module 125 registers information of all facilities created using the tool, specifies the input-output energy used by each facility, and registers the relationship between the facilities before and after, To model the installation points. More specifically, the modeling module 125 supports the P & ID-based design scheme symbols, allowing the operator to freely place facilities used in common manufacturing industries such as pumps, valves, tanks, dust collectors, and cranes . Particularly, the modeling module 125 according to the present invention can express the order of connection of equipment according to the process flow, so that the modeling result can be used for energy flow analysis in the future. In addition, the instrument information included in the facility can be set together so that it can be easily known where the measurement data is collected, and the type and structure of the data transmitted by the measurement sensors can be defined. Upon completion of modeling by the modeling module 125, the information can be immediately received by exporting the corresponding information to the data acquisition module 170.

In one embodiment, the modeling module 125 is activated when the Physical Modeler menu is selected on the screen shown in FIG. 6 as described above, thereby providing a screen as shown in FIG. 10 to a system operator or a business operator Allow each facility to be graphically entered.

As described above, in the present invention, various information for establishing the energy management system is set through the workbench module 120, and various information is matched to the equipments modeled by the modeling module 125, The energy management system provided in the system will be constructed.

Referring again to FIG. 1, when all the information for system construction is set by the workbench module 120, the energy management module 130 determines whether the corresponding facilities and / Analyze the energy use of the target facilities. Specifically, the energy management module 130 performs energy trend analysis, performance analysis of target facilities, energy comparison analysis of target facilities, and energy statistical analysis of the facility. The energy management module 130 provides the analysis result to the optimization module 150 and the reporting module 160.

The monitoring module 140 monitors the use of energy in the facility when all the information for system construction is described by the workbench module 120. In one embodiment, the monitoring module 140 may monitor total energy usage in the facility, energy usage by usage, energy usage by each floor or zone, and energy usage by system.

In one embodiment, the monitoring module 140 may monitor the energy usage at the facility using the metrology data collected by the data acquisition module 170.

In addition, the monitoring module 140 monitors the status of each facility and the indoor / outdoor environment of the facility. The monitoring module 140 provides the monitoring results to the energy management module 130, the optimization module 140, and the reporting module 160.

The optimization module 150 estimates energy use in the facility using the results provided from the energy management module 130 and the monitoring module 140 and generates a solution for optimal energy use according to the predicted result , And provides the generated result to the reporting module 160.

The reporting module 160 processes the results generated by the energy management module 130, the monitoring module 140, and the optimization module 150 using various charts, graphs, and the like, and provides the result to the system user. The report provided by the reporting module 160 may include an energy usage report that includes content related to energy usage at the facility, an equipment performance report that includes the performance related to each facility, and an energy usage pattern of the facility Includes one pattern analysis report.

Next, the data acquisition module 170 collects the measurement data from the sensors installed in matching with the respective facilities included in the facility, converts the collected data into a form that can be used in the energy management system, Management module 130 and the optimization module 160 or provides them to the monitoring module 140.

In one embodiment, the data acquisition module 170 may refine the metrology data collected from the sensors according to a predetermined refinement rule to select valid data, and use only the selected data in the energy management system .

The architecture of the energy management system 100 having the above-described configuration is schematically shown in FIG. As shown in FIG. 11, the energy management system 100 according to the present invention can be largely composed of three layers. First, the first layer 1010 is a Common Technical Platform layer in which components commonly used in facilities such as buildings and factories are disposed. The first layer 1010 may include an optimization engine (not shown) for optimization, an analysis / prediction engine (not shown) for energy use analysis and prediction, a data acquisition module 170 for collecting data, and the like.

Next, the second layer 1020 is a business platform layer in which components commonly used in a building or a factory are disposed in relation to an energy related business. The second layer 1020 includes the workbench module selection module 110, the workbench module 120, the energy management module 130, the monitoring module 140, the optimization module 150, and the reporting module 160 ), And the like.

Next, the third layer 1030 is an application layer in which components uniquely applied in the areas of the building and the factory are disposed. That is, the third layer 1030 may include an application for implementing BEMS, an application for FEMS implementation, an application for FMS implementation, and an application for SI implementation.

How to build an energy management system

Hereinafter, an energy management method according to the present invention will be described with reference to FIG.

12 is a flowchart illustrating an energy management method according to an embodiment of the present invention.

The energy management method shown in Fig. 12 is performed by an energy management system as shown in Fig.

12, when an installation installation request of a system is received from a system operator or a business operator (S1100), the energy management system provides a work bench module selection screen (S1110). Here, the workbench module may be a tool for allowing the system operator and the operation operator to set up the energy management system according to the present invention.

In one embodiment, the workbench module selection screen includes an icon for selecting a workbench module for a building energy management system (BEMS), which is produced by grouping factors necessary for building energy management, A facility management system (Group Management System), which is a grouping of the necessary elements for facility management, an icon for selecting a work bench module for a factory energy management system (FEMS) An icon for selecting a work bench module for the FMS, and an icon for selecting a workbench module for system integration (SI) produced by grouping elements necessary for system integration management.

Thereafter, when any one of the plurality of workbench modules is selected by the system operator or the operation operator (S1115), the energy management system displays a system setting screen corresponding to the workbench module selected by the system operator or the operation operator, (S1120). In one embodiment, a system operator or a business operator may select only one workbench module from a plurality of workbench modules, but may select a plurality of workbench modules. Hereinafter, for convenience of explanation, it is assumed that a system operator selects one workbench module among a plurality of workbench modules.

In one embodiment, the system configuration screen is associated with an icon for setting basic data that is highly related to the energy management system and low in relevance to energy related tasks, , An icon for setting a low UI, an icon for setting a UI having a high relation with an energy related task and an energy management system, and personalization information having a low association with an energy related task and an energy management system And an icon for setting.

First, when a system operator or a business operator selects an icon for setting basic data (S1130), the energy management system displays basic data such as terms, items, codes, and tag basic information for building and operating the energy management system (S1132), and sets basic data of the energy management system using various data input by the system operator or the operation operator through the menu screen (S1134) .

In one embodiment, such basic data can be divided into common data elements and facility data elements used in the energy management system. Here, the common data element includes a standard term, a standard code, a standard attribute, a general criterion, a unit conversion, and a pattern code used in an energy management system. Or the like.

In addition, the facility data elements include the common facilities that can be included in the facility, the performance code of each facility, the efficiency constant of each facility, the efficiency indicator of each facility, (Point Unit), and a measurement data refinement rule (Raw Data Refinement Rule).

If the system operator or the business operator selects an icon for setting work information in step S1120, the energy management system displays a menu screen for registering various information on an energy related business to which the energy management system is to be applied (S1142), and registers information on energy related tasks of the energy management system using various data input by the system operator or the operation operator through the menu screen (S1144).

In one embodiment, the information about the energy-related business includes energy management objects (buildings, hospitals, or factories), equipment information included in the energy management objects, facility point information, virtual point information, Mapping information between the energy type and registered facility points, indoor / outdoor environmental information, indoor / outdoor environmental information and mapping information with previously registered facility points, scenario information to be used in an emergency, and alarm information to be generated according to energy state rules do.

At this time, the facility points of each facility can be modeled using a tool capable of graphically expressing the connection relationship between each facility and each facility.

If the system operator or the current operator selects an icon for UI setting in step S1120 (S1150), the energy management system provides a menu screen for setting a UI to be used in the energy management system to the system administrator or the business operator S1152), the UI selected by the system operator or the operation operator is registered as a UI to be used in the energy management system through the menu screen (S1154).

In one embodiment, when setting UI, the authority of the organization, user, and each user in the energy management system is set, a menu screen used in the energy management system is registered, or a page Register the content configuration, register the components of the report provided to the customer, or register the bulletin board.

In the initial construction of the energy management system, such UI registration is performed by a system operator or a production operator, but UI registration may be performed by a system user after system construction.

If the system operator or the business operator selects an icon for personalization in step S1120 (S1160), the energy management system redefines various information used in the energy management system according to the personal preference of the user using the energy management system (S1162), and changes a UI skin, a portlet, a language, a time zone, etc. constituting the energy management system according to the information input through the menu screen (S1164).

In step S1170, it is determined that all the setting is completed. If all the setting is completed, it is determined that the construction of the energy management system is completed and the energy management task is performed (S1180). If the unconfigured area exists The process returns to S1120 so that data of an unset area can be set. At this time, although it is possible to return to S1120, it may be possible to set data of another region on the screen of the current state without returning to S1120.

12, the basic data setting, the task information setting, the UI setting, and the personalization setting process are performed in parallel. However, in the modified embodiment, the basic data setting process is performed first and then the task information setting process is performed The UI setting process or the personalization setting process may be performed after the task information setting process is performed.

As described above, the energy management system according to the present invention is provided in a platform form to a customer because it is not an application type system that is provided in advance for each customer, It is built with customized energy management system.

In other words, although the conventional general energy management system has been provided by completing a separate system for each customer in accordance with the customer's request, the energy management system according to the present invention is delivered to the customer and, until the customer completes the setup procedure, Is not defined and the energy management system is defined when the customer completes the setup procedure.

Meanwhile, when the energy management system according to the present invention performs the energy management task, the energy management system monitors the energy use in the facility to analyze the energy use status of the facility, and based on the analyzed result, By predicting energy use, you can create solutions for optimal energy use based on the predicted results. In addition, monitoring results, energy use status analysis results, and solutions for optimal energy usage can be provided to system users using various charts and graphs.

In the above description, it is described that the energy management system is implemented as a physical system. However, this is only one example. The energy management system is a system in which each function is programmed and mounted on a server or a computer, Lt; / RTI >

At this time, the program for implementing the energy management system is stored in a computer-readable recording medium such as a hard disk, a CD-ROM, a DVD, a ROM, a RAM, or a flash memory.

Those skilled in the art will appreciate that the invention described above may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Energy management system 110: Workbench module selection module
120: Workbench module 130: Energy management module
140: Monitoring module 150: Optimization module
160: Reporting module 170: Data acquisition module

Claims (13)

And a pattern code, which are to be used in the energy management system, including at least one of standard terminology, standard code, standard attribute, general criterion, unit conversion, It is necessary to set basic information and at least one of the facilities to be energy managed, the type of energy to be monitored, the facility to be checked for energy consumption, the target area where energy management is required, A workbench module for setting up the system; And
And an energy management module for analyzing energy use efficiency of the facility or the target facilities by using measurement data obtained from sensors disposed on the site when the energy management system is set up by the workbench module Management system. The method according to claim 1,
The basic data includes general information of facilities that can be installed in the facility, an efficiency code of each facility, an efficiency constant of each facility, an efficiency indicator of each facility, A point unit, and a measurement data refinement rule. The energy management system according to claim 1, The method according to claim 1,
Wherein the task information further includes at least one of a facility point of the target facility, a virtual point of the target facility, an energy system / facility point mapping, and an indoor / outdoor environment information / facility point mapping. The method according to claim 1,
The workbench module comprises:
At least one of the authority of the user using the energy management system at the time of setting up the energy management system, the menu screen used in the energy management system, the page content provided to the user on the energy management system, the report configuration provided to the user, Wherein the energy management system further comprises: The method according to claim 1,
The workbench module comprises:
Wherein at least one of a UI skin, a portlet, a usage language, and a time zone constituting the energy management system is additionally set when the energy management system is set up. The method according to claim 1,
The present invention provides a tool for graphically expressing a facility facility, a connection relation between target facilities, and facility points of target facilities to a system operator at the time of system setup by the workbench module, And a modeling unit for modeling the target facility by using the modeling unit. The method according to claim 1,
Further comprising a workbench selection module for selecting and loading a workbench module selected by a system operator from among a plurality of workbench modules. The method according to claim 1,
The workbench module comprises:
A workbench module for the Building Energy Management System (BEMS) in which the necessary elements for building energy management are grouped;
A workbench module for the Factory Energy Management System (FEMS) in which the necessary elements for the plant's energy management are grouped;
A workbench module for the Facility Management System (FMS) in which the necessary elements for facility management are grouped; And
And a work bench module for System Integration (SI) in which elements necessary for system integration management are grouped. Providing a workbench module selection screen for selecting a workbench module of at least one of a workbench module for BEMS, a workbench module for FEMS, a workbench module for FMS, and a workbench module for SI; And
And executing the work bench module selected on the work bench module selection screen to set up the energy management system. 10. The method of claim 9,
Wherein the step of setting up the energy management system comprises:
Setting basic data including at least one of a standard term, a standard code, a standard item, a general standard, a unit conversion, and a pattern code to be used in the energy management system;
Setting task information including at least one of a facility to be an energy management target, an energy type to be monitored, a facility to be checked for energy consumption, a target area for energy management, and an environmental factor to monitor;
Setting at least one of a right of a user who uses the energy management system, a menu screen used in an energy management system, a page content provided to a user on an energy management system, a report configuration provided to a user, and a bulletin board; And
And setting at least one of a UI skin, a portlet, a usage language, and a time zone constituting the energy management system. 11. The method of claim 10,
Wherein the step of setting up the energy management system comprises:
Providing a system operator with a tool capable of graphically representing the target facility, the connection relationship between the target facilities, and facility points of the target facilities;
Further comprising the step of modeling the target facility using information input using the tool. A computer-readable recording medium having recorded thereon a program for performing the energy management method according to any one of claims 9 to 11. A workbench module that sets up element information for energy management by four areas divided according to business and system; And
And an energy management module for collecting measurement data according to the setup and analyzing energy utilization efficiency of facilities or target facilities to be energy management targets,
Wherein the four areas include a basic data area and a task information area.

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