KR101803919B1 - Appratus and method for monitoring energy - Google Patents

Abstract

The present invention provides an energy integrated monitoring device, a method thereof and a storage medium storing a program for energy integrated monitoring. The integrated monitoring device comprises: a collection module receiving monitoring information corresponding to a monitoring element request signal from at least one energy facility; a standardization module standardizing the received monitoring information according to a preset reference; an integration module integrating the standardized monitoring information according to a preset format; and a management module receiving and monitoring the integrated monitoring information.

Description

  [0001] APPARATUS AND METHOD FOR MONITORING ENERGY [0002] FIELD OF THE INVENTION [0003]

  The present invention relates to a system for integrally monitoring energy.

In the case of conventional energy monitoring technology, there was only one technique for monitoring each individual energy source (solar, wind, geothermal, etc.), or each monitoring individual facility for producing energy. As described above, there is a difficulty in integrally monitoring data collection devices or communication protocols depending on individual monitoring.

Also, in the case of the individual monitoring method, since individual monitoring software forms and menus are requested for each individual energy source or for each company that produces energy, there is a problem that the initial construction cost is considerably incurred. Also, there is a problem that the maintenance cost due to individual monitoring continuously increases.

  In order to solve the above problems, it is an object of the present invention to provide an integrated energy monitoring apparatus, a method thereof, and a storage medium storing a program for energy integrated monitoring.

The integrated monitoring apparatus according to the present invention includes a collection module for receiving monitoring information corresponding to a monitoring element request signal from at least one energy facility, a standardization module for standardizing the received monitoring information according to a predetermined criterion, And a management module for receiving and monitoring the integrated monitoring information.

The integrated monitoring method according to the present invention is characterized in that the management module transmits a monitoring element request signal to a collection module, the collection module receives monitoring information from at least one or more energy facilities corresponding to the monitoring element request signal, Standardizing the received monitoring information according to a predetermined criterion, integrating the standardized monitoring information according to a predetermined format, and receiving and monitoring the integrated monitoring information by the management module .

According to another aspect of the present invention, there is provided a storage medium storing a program for integrated monitoring, the apparatus comprising: a monitoring unit configured to receive monitoring information corresponding to a monitoring element request signal from at least one or more energy facilities, standardize the received monitoring information according to a predetermined standard, The integrated monitoring information may be integrated according to a predetermined format, and the integrated monitoring information may be received and integratedly monitored.

  The present invention can reduce the initial construction cost.

  Further, the present invention can reduce the maintenance cost.

  Further, the present invention can be integratedly monitored to promptly respond to a defect.

1 is a diagram illustrating one embodiment of an energy integration monitoring system.
2 is a diagram illustrating an embodiment of the connection between the individual energy sources and the established server.
Figure 3 is an illustration of an embodiment of an integrated format for integrally monitoring an individual energy source.
4 is a diagram illustrating one embodiment of energy integration monitoring system operation when a fault occurs;
5 is a diagram for explaining an embodiment of the energy integration monitoring apparatus.
6 is a diagram for explaining an embodiment of the energy integration monitoring method.
7 is a diagram for explaining the first operation of the control module.
8 is a diagram for explaining the second operation of the control module.

  One embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a diagram illustrating one embodiment of an energy integration monitoring system.

Referring to FIG. 1, the energy integration monitoring system may include a server unit 120 (OPC-UA server) and an application program unit 130 (application program). The energy integration monitoring system may further include a client unit 110 (OPC-UA client / U-RTU) or a facility unit 100 (renewable energy source facility).

The facility 100 may include facilities corresponding to an individual energy source. The individual energy sources described above may include solar, solar, geothermal, wind, hydro or seawater heat. In addition, the facility unit 100 may cluster the facilities corresponding to the individual energy sources according to the energy sources.

The facility 100 may also include individual company facilities that produce energy. In addition, the facility unit 100 may group the energy facilities held by individual companies into individual groups. Specifically, the facility unit 100 may include the A facility (solar heat, geothermal heat), or the B company facility (wind power, solar heat) in a clustered manner.

The facility unit 100 may also communicate with the client unit 110 using a predetermined communication protocol. The predetermined communication protocol described above may include RS-485, RS-422, RS-232C or TCP-Modbus. The facility unit 100 may transmit energy related information or information about the energy facility to the client unit 110 in response to the monitoring element request signal of the client unit 110. [

The client unit 110 may include a serial converter or a communication related program. Also, the client unit 110 can access a communication network (wired / wireless communication, LoRa, LTE, etc.) through the above-mentioned communication related program. After the client unit 110 is connected to the communication network, the client unit 110 may transmit the energy-related information or information about the energy facility received from the facility unit 100 to the server unit 120. The above-described energy-related information or information on the energy equipment will be described later with reference to FIG. 2 to FIG.

The client unit 110 may also include at least one or more individual client modules. Also, at least one or more individual client modules may be connected to facilities corresponding to the individual energy sources included in the facility unit 100, or to individual company facilities that produce energy, respectively. Specifically, the individual client module may be a U-RTU (Unified Remote Terminal Unit) or an OPC UA client. Also, at least one or more individual client modules may be connected to the server unit 120 to be described later. The server unit 120 described above may be specifically an OPC UA-based server.

The above-mentioned OPC for UPC (OLE for Processing Control - Unified Architecture) is a component-based industrial automation linkage standard announced by OPC Foundation. It complements the limitation that OPC, which was previously used, can be applied only to Mi-crosoft Windows platform, And it is designed to be able to connect with each other. It has already been adopted as an IEC standard (IEC 62541) for general interconnection between industrial systems.

The server unit 120 may include an access server, a database server, a monitoring server, or a collection server. The DB server, the monitoring server, or the collection server described above may be implemented by respective hardware processors or by a single integrated processor. Also, the server unit 120 may include at least one or more individual servers. The at least one or more individual servers described above may each include individual functions.

The connection server can communicate with the communication related programs included in the client unit 110 connected to the communication network. In addition, the connection server performs a load balancing function to control the transmission speed or the transmission amount of the received data. Specifically, the connection server can control data transmitted to each server (DB server, monitoring server, or collection server) through load balancing.

The DB server can encrypt and store energy-related information or information about an energy facility. In addition, the DB server can back up received energy related information or information about energy facilities (hereinafter, monitoring element information). The collection server may verify or process the aforementioned monitoring element information. The monitoring server may be connected to the application program unit 130. In addition, the monitoring server can transmit the monitoring element information to the application program unit 130 in real time or at predetermined time intervals.

The application program 130 may include an integrated monitoring program. The application program unit 130 may further include an administrator registration program or an external status board. The integrated monitoring program can monitor the aforementioned monitoring element information in real time. Also, the administrator registration program can perform the authentication procedure so that only the pre-designated administrator can register. Also, the external status board can receive and display monitoring element information from the integrated monitoring program described above.

2 is a diagram illustrating an embodiment of the connection between the individual energy sources and the established server.

Referring to FIG. 2, when the individual energy source is solar 200, the solar facility may include an inverter, a temperature and humidity sensor, or a solar radiation sensor. The client unit 110 (the U-RTU (OPC UA client) of FIG. 2 described above in FIG. 1) can receive data from the inverter, temperature and humidity sensor or irradiation dose sensor described above. In addition, the client unit 110 can transmit control information related to the photovoltaic device to the above-described inverter. In addition, the server unit 120 (OPC-UA server in FIG. 2) described in FIG. 1 can transmit control information related to the photovoltaic facility to the client unit 110. Also, the client unit 110 may transmit power generation amount information, temperature information, or irradiation amount information to the server unit 120.

In addition, when the individual energy source is solar heat 210, the solar thermal facility may include a solar controller, a calorimeter, or a watt-hour meter. The client unit 110 (U-RTU (OPC UA client) in Fig. 2 described above in Fig. 1) can receive data from the above-described solar controller, calorimeter or watt hour meter. In addition, the client unit 110 can transmit control information regarding the solar heating facility to the solar controller described above. In addition, the server unit 120 (OPC-UA server in FIG. 2) described in FIG. 1 can transmit control information related to the solar heating facility to the client unit 110. Also, the client unit 110 may transmit temperature information, calorie information, or power information to the server unit 120.

In addition, where the individual energy source is the geothermal heat 220 or the seawater heat 220, the geothermal (seawater) facility may include a heat pump or watt-hour meter. The client unit 110 (U-RTU (OPC UA client) in Fig. 2 described above in Fig. 1) can receive data from the above-mentioned heat pump or watt-hour meter. In addition, the client unit 110 can transmit control information regarding geothermal (seawater heat) facilities to the above-described heat pump. Also, the server unit 120 (OPC-UA server in FIG. 2) described in FIG. 1 can transmit control information regarding the geothermal (seawater heat) facility to the client unit 110. Also, the client unit 110 may transmit temperature information, flow rate information, or power amount information to the server unit 120.

 Also, when the individual energy source is hydrogen 230 or fuel cell 230, the hydrogen (fuel cell) facility may include an inverter. The client unit 110 (the U-RTU (OPC UA client) in FIG. 2) described above in FIG. 1 can receive data from the inverter described above. In addition, the client unit 110 may transmit control information regarding a hydrogen (fuel cell) facility to the inverter described above. In addition, the server unit 120 (OPC-UA server in FIG. 2) described in FIG. 1 can transmit control information regarding the hydrogen (fuel cell) facility to the client unit 110. Also, the client unit 110 may transmit power generation amount information, calorie information, or production time information to the server unit 120.

Also, in the case where the individual energy source is wind power 240 or hydraulic power 240, the wind power (hydraulic) facility may include an inverter. The client unit 110 (the U-RTU (OPC UA client) in FIG. 2) described above in FIG. 1 can receive data from the inverter described above. Also, the client unit 110 can transmit control information regarding the wind power (hydropower) facility to the inverter described above. Also, the server unit 120 (OPC-UA server in FIG. 2) described in FIG. 1 can transmit control information on the wind power (hydraulic) facility to the client unit 110. Also, the client unit 110 may transmit power generation amount information or production time information to the server unit 120.

Figure 3 is an illustration of an embodiment of an integrated format for integrally monitoring an individual energy source.

Referring to FIG. 3, the energy facility 300 may correspond to the facility 100 (renewable energy source facility) described above with reference to FIG. The individual RTU 310 may correspond to the individual client modules included in the client 110 or the client 110 described above with reference to FIG. The server 320 may correspond to the server 120 described above with reference to FIG.

The energy facility 300 may include facility information for an individual energy source or information about an individual company facility that produces energy. The individual RTUs 310 may be constructed by the individual energy sources described above or by individual energy companies. Specifically, when an individual RTU 310 is constructed for each individual energy source, it can be installed in each energy source facility such as solar heat, solar light, geothermal heat, and wind power, and data can be received and standardized. In addition, when an individual RTU (310) is constructed for each individual energy company, it can be constructed and standardized at each company facility such as Company A, Company B, and Company C.

The individual RTU 310 can also receive and standardize data from the energy-related facility 300 described above. In addition, the individual RTU 310 may include predetermined monitoring information 330 for data received from the energy facility 300. The above-mentioned standardization means that the received data is sorted according to a predetermined rule in a predetermined integrated standard format in order to perform integrated monitoring. The predetermined rule may include a first criterion, a second criterion or a third criterion, which will be described later.

The predetermined integrated standard format 350 may include at least one field value information. A specific example of the field value information may include address information, id information, or numerical value. The above-described field value information can be changed in accordance with the intention of the designer, and thus is not limited to the above.

Also, the address information included in the integrated standard format 350 may be separated into a first reference corresponding to the type of the individual energy source. In addition, the address information separated by the first reference may include a second reference corresponding to the common monitoring element information 340 or a third reference corresponding to the predetermined specific monitoring element information 360 for the individual energy company Information about the company-specific monitoring element, and information about other company-specific monitoring elements).

Also, the individual RTU 310 can receive data related to the preset monitoring information 330 from the energy-related facility 300 described above. The individual RTU 310 may also standardize the received data into the integrated standard format described above. Also, the individual RTU 310 can receive monitoring information to be collected from the energy-related equipment 300 from the server 320. The user can transmit a request signal for information to be monitored through the monitoring program described above with reference to FIG. 1 to the individual RTU 310 through the server 320. The above-mentioned monitoring information to be collected is shown in Table 1 below.

 Energy source Item sunlight Installed capacity, current generation, cumulative generation, abnormality, output (voltage, current, power, frequency) Solar heat Installed Capacity, Current Production, Cumulative Production, Abnormal Condition, Collector Outlet Temperature, Storage Tank Outlet Temperature, Current Calories, Cumulative Calories Geothermal Installed Capacity, Present Production, Cumulative Production, Abnormal Status, Geothermal Outflow Temperature, On-going Outflow Temperature, Current Flow, Cumulative Flow, Current Calories, Cumulative Calories wind force Installed capacity, current generation, cumulative generation, abnormality, PCS (voltage, current, power) Small hydro power Current capacity, cumulative power generation, abnormality, aberration generator power generation and operation information Fuel cell Installation capacity, current generation, cumulative generation, current heat recovery, cumulative heat recovery, abnormality, gas flow, output, frequency ESS Battery and PCS capacity, charge / discharge amount, current production, cumulative production, abnormality, voltage, current, power, SOC, SOH, cell temperature

  In addition, the individual RTU 310 can standardize the received data to the integrated standard format as described above, in order of priority from a specific individual company having many monitoring elements. Also, the individual RTU 310 may first transmit aggregated standard format information including monitoring information for a particular individual company with a large number of monitoring elements.

Also, the individual RTU 310 can standardize a specific energy source (solar heat, solar light, geothermal heat, etc.) having a large number of monitoring elements to a priority when standardizing the received data into the integrated standard format described above. Also, the individual RTU 310 may first transmit the integrated standard format information for the monitoring information for a specific energy source with a large number of monitoring elements. In addition, the individual RTU 310 can selectively standardize the received data in the integrated standard format in association with the predetermined monitoring information 330 from the energy-related facility 300 described above.

4 is a diagram illustrating one embodiment of energy integration monitoring system operation when a fault occurs;

Referring to FIG. 4, the energy integration monitoring system may further include a diagnosis unit 420. The supervisory monitoring system 400 may monitor the individual sites A, B, C, Individual sites (A, B, C, D) may correspond to individual energy source facilities or individual energy company facilities. Also, the individual site may correspond to the above-described facility 100 in FIG. 1 or the energy-related facility 300 described in FIG.

Also, when a failure signal is generated at an individual site, the supervisory monitoring system 400 can transmit failure information (site information, failure information, failure period) to the diagnosis unit 420. The diagnosis unit 420 may compare the fixed information with the previously collected information to determine whether the information is malfunctioning. In addition, the diagnosis unit 420 can transmit failure information and manual information to the A / S company server 430 according to the A / S manual configuration. In response, the A / S company can transmit the A / S availability time information to the diagnosis unit 420.

In addition, the diagnosis unit 420 may store monitoring information including failure information in the server. In addition, the diagnosis unit 420 can transmit the A / S information (simple trouble information, A / S visit time, and article contact) to the user monitoring system 410.

5 is a diagram for explaining an embodiment of the energy integration monitoring apparatus.

Referring to FIG. 5, the integrated monitoring device may include a collection module 500, a standardization module 510, an integration module 520, or a management module 530. The integrated monitoring device may further include a control module (not shown). The collection module 500, the standardization module 510, the integration module 520 management module 530, or the control module described above may be implemented by respective hardware processors or by a single integrated processor.

The collection module 500, the standardization module 510 or the integration module 520 may correspond to a part of the client 110 or the server 120 (OPC-UA server) described above with reference to FIG. The management module 530 may correspond to a part of the server unit 120 (OPC-UA server) or the application program unit 130 described above with reference to FIG.

The acquisition module 500 may receive monitoring information corresponding to the monitoring element request signal from at least one or more energy facilities. The above-described energy facility can correspond to the facility 100 described above with reference to Fig. Further, the above-mentioned energy facility is a renewable energy related facility, and the renewable energy may include at least one of sunlight, solar heat, geothermal heat, or wind power. Also, the acquisition module 500 may be based on an OLE for Processing Control - Unified Architecture (OPU-UA).

In addition, the acquisition module can check the collected data on a daily basis based on user identification (ID) and measurement time, and request data collection for a specific time in the subsystem (energy facility) if necessary. The collection module may also set the first identifier indication on the reacquired data. In addition, the collection module may set the second identifier display so that the missing data that can not be re-collected can be automatically corrected at a predetermined time and identified as the corrected data.

In addition, in the case of the data correction described above, the collection module can process the average value based on the front and back of the data to be corrected or the average value on the entire system.

The standardization module 510 may standardize the received monitoring information according to predetermined criteria. In addition, the standardization module 510 can standardize the priority monitoring information when the number of the received monitoring information exceeds the predetermined standard. In addition, the standardization module 510 can standardize the received monitoring information according to the predetermined criteria by clustering the received monitoring information into common monitoring element information and specific monitoring element information.

The control module can set the above-described preset reference. Specifically, the predetermined criteria described above may include the number of information to be monitored or a classification criterion between the common monitoring information and specific monitoring information. In addition, the control module can determine the priority among the monitoring information. Specifically, the control module can determine the priority among individual monitoring information. In addition, the control module can determine the monitoring information set as the common monitoring element with priority over the monitoring information set as the specific monitoring element. The control module may also reset the standardization module 510 or the integration module 520 at a time when the acquisition module does not collect data or when the energy facilities are not operational. The control module can display an identifier on the reset module when the above reset is performed.

The integration module 520 may integrate the standardized monitoring information according to a predetermined format. The integration module 520 may integrate the priority standardized monitoring information into the priority order and transmit it to the management module 530 to be described later. Also, the predetermined format includes at least one field value information, and the field value information includes a first criterion according to the kind of the individual energy source, a second criterion corresponding to the common monitoring element information, or a third criterion corresponding to the specific monitoring element information Can be separated by reference.

The management module 530 may receive and monitor the integrated monitoring information. Further, the management module 530 may transmit the above-described monitoring element request signal to the collection module 500. [

6 is a diagram for explaining an embodiment of the energy integration monitoring method.

Referring to FIG. 6, the energy integration monitoring method includes transmitting a monitoring element request signal (S600), receiving monitoring information from at least one or more energy facilities corresponding to the monitoring element request signal (S610) (S620), integrating the standardized monitoring information according to a predetermined format (S630), and receiving and monitoring the integrated monitoring information (S640).

The management module may perform the step of transmitting the monitoring element request signal or the step of receiving and monitoring the integrated monitoring information. A detailed description thereof has been given above with reference to Figs. 1 to 5. Collecting module may receive monitoring information from at least one or more energy facilities in response to the monitoring element request signal. A detailed description thereof has been given above with reference to Figs. 1 to 5. The standardization module may perform the step of standardizing the received monitoring information according to a predetermined criterion. A detailed description thereof has been given above with reference to Figs. 1 to 5. The integration module may perform the step of integrating standardized monitoring information according to a predetermined format. A detailed description thereof has been given above with reference to Figs. 1 to 5.

7 is a diagram for explaining the first operation of the control module.

In FIG. 7, the energy facility stages 700 and 730 may correspond to the energy facility 300 described above with reference to FIG. In FIG. 7, the middleware 710 and 740 may correspond to the individual RTU 310 described above with reference to FIG. In FIG. 7, the servers 720 and 750 may correspond to the server 320 described above with reference to FIG.

The control module can determine whether an operating system (OS) is installed in the energy facility units 700 and 730. If the control module determines that an OS is not installed in the energy facility stages 700 and 730, the control module uses the middleware 710 and 740 including the individual RTUs to acquire data from the energy facility stages 700 and 730 (First operation).

In addition, the control module can control the configurations of the middleware 710 and 740 and the servers 720 and 750. When the server 720 is configured as a single OPU-UA server, the control module may configure the middleware 710 into separate RTUs corresponding to the individual energy utilities included in the energy facility 700. [ In addition, the control module can configure individual RTUs as individual OPU-UA servers and individual OPU-UA clients. In addition, the individual energy facilities included in the energy facility unit 700 can transmit data to the individual OPU-UA servers described above via individual communication modules.

Also, when the server 750 is configured with individual OPU-UA servers, the control module may configure the middleware 740 as a single RTU. Also, the control module can configure the RTU as an OPC-UA server. When the middleware 740 is configured as a single RTU, the control module may install an individual OPU-UA client on each of the individual OPU-UA servers included in the server 750. [

8 is a diagram for explaining the second operation of the control module.

In FIG. 8, the energy facility stages 800 and 820 may correspond to the energy facility 300 described above with reference to FIG. In FIG. 7, the servers 810 and 830 may correspond to the server 320 described above with reference to FIG.

The control module can determine whether an operating system (OS) is installed in the energy facility units 800 and 820 as described above. If the control module determines that an OS is installed in the energy facility 800 or 820, the control module deactivates the middleware 710 or 740 described in FIG. 7 and transmits the data directly from the energy facility 800 or 820 (Second operation).

The control module may also control the configuration of the communication module connected to the individual energy utilities included in the energy facility stages 800, When the server 810 is configured as a single OPU-UA server, the control module may install a separate OPU-UA client in each of the communication modules included in the energy facility end 800.

In addition, the individual communication module included in the energy facility unit 800 may convert the collected data by calling the OPC-UA client API into the OPU-UA format and transmit the data to the single OPU-UA server 810.

Also, when the server 830 is configured with individual OPU-UA servers, the control module may configure the OPC-UA server in the communication module included in the energy facility unit 820. [ The communication module including the OPC-UA server can collect data and transmit it to the individual servers included in the server 830 described above.

The embodiments disclosed in the specification of the present invention do not limit the present invention. The scope of the present invention should be construed according to the following claims, and all the techniques within the scope of equivalents should be construed as being included in the scope of the present invention.

500: collection module
510: Standardization module
520: Integration module
530: Management module

Claims (19)

A collection module for receiving monitoring information corresponding to a monitoring element request signal from at least one energy facility;
A standardization module for standardizing the received monitoring information according to a predetermined criterion;
An integration module for integrating the standardized monitoring information according to a predetermined format; And
And a management module for receiving and monitoring the integrated monitoring information,
Wherein the acquisition module is based on an OPC for Processing Control - Unified Architecture (OPC). The integrated monitoring apparatus according to claim 1, wherein the energy facility is a renewable energy related facility, and the renewable energy is at least one of solar, solar, geothermal, or wind power.   3. The integrated monitoring apparatus according to claim 2, wherein the standardization module standardizes the received monitoring information in priority order when the received monitoring information exceeds a preset reference.   4. The integrated monitoring apparatus of claim 3, wherein the integration module integrates the priority standardized monitoring information into the priority order and transmits the combined priority to the management module.   5. The integrated monitoring device of claim 4, wherein the management module sends the monitoring element request signal to the collection module.   The integrated monitoring apparatus of claim 5, wherein the standardization according to the predetermined criteria clusters the received monitoring information into common monitoring element information and specific monitoring element information.   7. The method of claim 6, wherein the predetermined format includes at least one field value information, the field value information includes a first criterion according to an individual energy source type, a second criterion corresponding to the common monitoring element information, And a third criterion corresponding to the element information. delete   The method according to claim 7, wherein when the renewable energy is sunlight, the monitoring element request signal is at least one of information on installation capacity, information on current production amount, information on cumulative production amount, or power output information, In the case where the renewable energy is solar heat, the monitoring element request signal is at least one of information on the installed capacity, information on the current production amount, information on the cumulative production amount, information on the outflow temperature, or information on the amount of heat. The management module transmitting a monitoring element request signal to the collection module;
Receiving the monitoring information from the at least one energy facility corresponding to the monitoring element request signal;
Standardizing the received monitoring information according to a predetermined criterion;
Integrating the standardized monitoring information according to a predetermined format; And
And receiving and monitoring the integrated monitoring information by the management module,
Wherein the acquisition module is based on an OPC for Processing Control - Unified Architecture (OPC).   The integrated monitoring method according to claim 10, wherein the energy facility is a renewable energy related facility, and the renewable energy is at least one of solar, solar, geothermal, or wind power.   12. The method of claim 11, wherein the standardization module standardizes the received monitoring information in priority order when the received monitoring information exceeds a preset reference.   The integrated monitoring method of claim 12, wherein the integration module integrates the priority standardized monitoring information into the priority order and transmits the combined priority to the management module.   14. The method of claim 13, wherein the management module sends the monitoring element request signal to the collection module.   15. The method of claim 14, wherein the standardization based on the predetermined criteria comprises clustering the received monitoring information into common monitoring element information and specific monitoring element information.   16. The method of claim 15, wherein the predetermined format includes at least one field value information, the field value information includes a first criterion according to an individual energy source type, a second criterion corresponding to the common monitoring element information, And a third criterion corresponding to the element information. delete   17. The method as claimed in claim 16, wherein when the renewable energy is solar light, the monitoring element request signal is at least one of information on installation capacity, information on current production amount, information on cumulative production amount, In the case where the renewable energy is solar heat, the monitoring element request signal is at least one of the information on the installation capacity, the information on the current production amount, the information on the cumulative production amount, the outflow temperature information or the calorific information. Receiving monitoring information corresponding to a monitoring element request signal from at least one or more energy equipments based on OPC (OLE for Processing Control - Unified Architecture), standardizing the received monitoring information according to a predetermined standard, A storage medium storing an integrated monitoring program for integrating monitoring information according to a predetermined format and receiving the integrated monitoring information and integrally monitoring the integrated monitoring information.

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